Mercurial > repos > galaxyp > morpheus
changeset 0:ac0a6f10d8b1 draft
Uploaded
| author | galaxyp |
|---|---|
| date | Thu, 05 Nov 2015 08:59:15 -0500 |
| parents | |
| children | a5a1c3367774 |
| files | morpheus.xml test-data/test_input.mzML test-data/uniprot-proteome_UP000002311-first100entries.fasta test-data/uniprot-proteome_UP000002311Condensed-first100entries.xml tool_dependencies.xml |
| diffstat | 5 files changed, 6303 insertions(+), 0 deletions(-) [+] |
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--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/morpheus.xml Thu Nov 05 08:59:15 2015 -0500 @@ -0,0 +1,306 @@ +<tool id="morpheus" name="Morpheus" version="1.171.1"> + <description>database search algorithm for high-resolution tandem mass spectra</description> + <macros> + <xml name="modification_options"> + <option value="carbamidomethylation of C">carbamidomethylation of C</option> + <option value="oxidation of M">oxidation of M</option> + <option value="acetylation of protein N-terminus">acetylation of protein N-terminus</option> + <option value="acetylation of lysine">acetylation of lysine</option> + <option value="phosphorylation of S">phosphorylation of S</option> + <option value="phosphorylation of T">phosphorylation of T</option> + <option value="phosphorylation of Y">phosphorylation of Y</option> + <option value="deamidation of N">deamidation of N</option> + <option value="deamidation of Q">deamidation of Q</option> + <option value="pyro-cmC">pyro-cmC</option> + <option value="pyro-E">pyro-E</option> + <option value="pyro-Q">pyro-Q</option> + <option value="TMT zero on peptide N-terminus">TMT zero on peptide N-terminus</option> + <option value="TMT zero on K">TMT zero on K</option> + <option value="TMT zero on Y">TMT zero on Y</option> + <option value="TMT duplex on peptide N-terminus">TMT duplex on peptide N-terminus</option> + <option value="TMT duplex on K">TMT duplex on K</option> + <option value="TMT duplex on Y">TMT duplex on Y</option> + <option value="TMT sixplex/tenplex on peptide N-terminus">TMT sixplex/tenplex on peptide N-terminus</option> + <option value="TMT sixplex/tenplex on K">TMT sixplex/tenplex on K</option> + <option value="TMT sixplex/tenplex on Y">TMT sixplex/tenplex on Y</option> + <option value="iTRAQ 4-plex on peptide N-terminus">iTRAQ 4-plex on peptide N-terminus</option> + <option value="iTRAQ 4-plex on K">iTRAQ 4-plex on K</option> + <option value="iTRAQ 4-plex on Y">iTRAQ 4-plex on Y</option> + <option value="iTRAQ 8-plex on peptide N-terminus">iTRAQ 8-plex on peptide N-terminus</option> + <option value="iTRAQ 8-plex on K">iTRAQ 8-plex on K</option> + <option value="iTRAQ 8-plex on Y ">iTRAQ 8-plex on Y </option> + </xml> + </macros> + + <requirements> + <requirement version="4.0">mono</requirement> + <requirement version="171">morpheus</requirement> + </requirements> + + <stdio> + <exit_code range="1:" /> + <regex match="System..*Exception" + source="both" + level="fatal" + description="Error encountered" /> + </stdio> + + <command><![CDATA[ + #set $searchdb_name = $searchdb + #if isinstance($searchdb.datatype, $__app__.datatypes_registry.get_datatype_by_extension('uniprotxml').__class__): + #set $searchdb_name = 'searchdb.xml' + #else + #set $searchdb_name = 'searchdb.fasta' + #end if + mkdir output_reports; + ln -s $input input.mzml + && ln -s $searchdb $searchdb_name + && mono \${MORPHEUS_PATH}/morpheus_cl.exe + -d="input.mzml" + -db=$searchdb_name + #if isinstance($searchdb.datatype, $__app__.datatypes_registry.get_datatype_by_extension('uniprotxml').__class__): + #if str( $advanced.adv_options_selector) == "set": + $advanced.noup + #end if + #end if + ## fm vm fdr mvmi precmt precmtv precmtu + #if str($fdr) != '': + -fdr=$fdr + #end if + #if str($mvmi) != '': + -mvmi=$mvmi + #end if + #if str($precmt) != 'None': + -precmt=$precmt + #end if + #if str($precmtv) != '': + -precmtv=$precmtv + #end if + #if str($precmtu) != 'None': + -precmtu=$precmtu + #end if + #if str( $advanced.adv_options_selector) == "set": + #if str($advanced.minprecz) != '': + -minprecz=$advanced.minprecz + #end if + #if str($advanced.maxprecz) != '': + -maxprecz=$advanced.maxprecz + #end if + #if str($advanced.at) != '': + -at=$advanced.at + #end if + #if str($advanced.rt) != '': + -rt=$advanced.rt + #end if + #if str($advanced.mp) != '': + -mp=$advanced.mp + #end if + #if str($advanced.mmc) != '': + -mmc=$advanced.mmc + #end if + #if str($advanced.prodmt) != 'None': + -prodmt=$advanced.prodmt + #end if + #if str($advanced.prodmtv) != '': + -prodmtv=$advanced.prodmtv + #end if + #if str($advanced.prodmtu) != 'None': + -prodmtu=$advanced.prodmtu + #end if + #if str($advanced.minpmo) != '': + -minpmo=$advanced.minpmo + #end if + #if str($advanced.maxpmo) != '': + -maxpmo=$advanced.maxpmo + #end if + #if str($advanced.imb) != 'None': + -imb=$advanced.imb + #end if + #if str($advanced.ad) != 'None': + -ad=$advanced.ad + #end if + $advanced.acs $advanced.di $advanced.pmc $advanced.cmu $advanced.mmu + #end if + #if str($fm) != 'None': + #set $fmods = str($fm).replace(',',';') + -fm="$fmods" + #end if + #if str($vm) != 'None': + #set $vmods = str($vm).replace(',',';') + -vm="$vmods" + #end if + -mt=\${GALAXY_SLOTS:-4} + && ( basepath=`grep 'Input Data File:' input.log.txt | sed 's/Input Data File: \(.*\)input.mzml/\1/'`; + for i in summary.tsv input.log.txt input.PSMs.tsv input.unique_peptides.tsv input.protein_groups.tsv input.pep.xml; + do cat \$i | sed "s#\${basepath}input.mzml#$input.name#" | sed "s#\${basepath}$searchdb_name#$search.name#" > output_reports/\$i; + done ) + ]]></command> + <inputs> + <param name="input" type="data" format="indexedmzML" label='Indexed mzML' /> + <param name="searchdb" type="data" format="fasta,uniprotxml" label="MS Protein Search Database: UniProt Xml or Fasta"/> + <param name="fm" type="select" multiple="true" optional="true" label="Fixed Modifications"> + <expand macro="modification_options" /> + </param> + <param name="vm" type="select" multiple="true" optional="true" label="Variable Modifications"> + <expand macro="modification_options" /> + </param> + <param name="fdr" type="float" value="1" optional="true" min="0.0" max="100.0" label="FDR (Maximum False Discovery Rate percent)" /> + <param name="mvmi" type="integer" value="1024" optional="true" min="0" label="Maximum Variable Modification Isoforms Per Peptide" /> + <param name="precmt" type="select" optional="true" label="Precursor Mass Type"> + <option value="Monoisotopic">Monoisotopic</option> + <option value="Average">Average</option> + </param> + <param name="precmtv" type="float" value="10." optional="true" label="Precursor Mass Tolerance Value" /> + <param name="precmtu" type="select" optional="true" label="Precursor Mass Tolerance Units"> + <option value="ppm" selected="true">ppm</option> + <option value="Da">Daltons</option> + </param> + <conditional name="advanced"> + <param name="adv_options_selector" type="select" label="Set advanced options?" help="Provides additional controls"> + <option value="set">Set</option> + <option value="do_not_set" selected="True">Do not set</option> + </param> + <when value="set"> + <param name="noup" type="boolean" truevalue="" falsevalue="-noup=True" checked="True" label="Use G-PTM with Uniprot Proteome Search Databases" /> + <param name="minprecz" type="integer" value="2" optional="true" label="Minimum Unknown Precursor Charge State" /> + <param name="maxprecz" type="integer" value="4" optional="true" label="Maximum Unknown Precursor Charge State" /> + <param name="at" type="float" value="" optional="true" min="0.0" label="Absolute MS/MS Intensity Threshold" /> + <param name="rt" type="float" value="" optional="true" min="0.0" label="Relative MS/MS Intensity Threshold" /> + <param name="mp" type="integer" value="" optional="true" min="-1" label="Maximum Number of MS/MS Peaks" help="to disable set to: -1"/> + <param name="acs" type="boolean" truevalue="-acs=True" falsevalue="-acs=False" checked="true" optional="true" label="Assign Charge States" /> + <param name="di" type="boolean" truevalue="-di=True" falsevalue="-di=False" checked="true" optional="true" label="Deisotope" /> + <param name="ad" type="select" optional="true" label="Append Decoys on the fly" + help="Set to No if Search Database ia a fasta that already includes decoys."> + <option value="False">No</option> + <option value="True">Yes</option> + </param> + <param name="mmc" type="integer" value="2" optional="true" min="0" max="20" label="Maximum Missed Cleavages" /> + <param name="pmc" type="boolean" truevalue="-pmc=True" falsevalue="-pmc=False" checked="false" optional="true" label="Precursor Monoisotopic Peak Correction" /> + <param name="minpmo" type="integer" value="" optional="true" label="Minimum Precursor Monoisotopic Peak Correction" /> + <param name="maxpmo" type="integer" value="" optional="true" label="Maximum Precursor Monoisotopic Peak Correction" /> + <param name="prodmt" type="select" optional="true" label="Product Mass Type"> + <option value="Monoisotopic">Monoisotopic</option> + <option value="Average">Average</option> + </param> + <param name="prodmtv" type="float" value="" optional="true" label="Product Mass Tolerance Value" /> + <param name="prodmtu" type="select" optional="true" label="Product Mass Tolerance Units"> + <option value="Da">Daltons</option> + <option value="ppm">ppm</option> + </param> + <param name="imb" type="select" optional="true" label="Initiator Methionine Behavior"> + <option value="Variable">Variable</option> + <option value="Retain">Retain</option> + <option value="Cleave">Cleave</option> + </param> + <param name="cmu" type="boolean" truevalue="-cmu=True" falsevalue="-cmu=False" checked="false" optional="true" label="Consider Modifications Unique" /> + <param name="mmu" type="boolean" truevalue="-mmu=True" falsevalue="-mmu=False" checked="false" optional="true" label="Minimize Memory Usage" /> + </when> + <when value="do_not_set"/> + </conditional> + </inputs> + <outputs> + <data name="summary" format="txt" label="${input.name.rsplit('.',1)[0]} summary.tsv" from_work_dir="output_reports/summary.tsv" /> + <data name="log" format="txt" label="${input.name.rsplit('.',1)[0]}.log.txt" from_work_dir="output_reports/input.log.txt" /> + <data name="output_psms" format="tabular" label="${input.name.rsplit('.',1)[0]}.PSMs.tsv" from_work_dir="output_reports/input.PSMs.tsv" /> + <data name="output_unique_peptides" format="tabular" label="${input.name.rsplit('.',1)[0]}.unique_peptides.tsv" from_work_dir="output_reports/input.unique_peptides.tsv" /> + <data name="output_protein_groups" format="tabular" label="${input.name.rsplit('.',1)[0]}.protein_groups.tsv" from_work_dir="output_reports/input.protein_groups.tsv" /> + <data name="output_pepxml" format="pepxml" label="${input.name.rsplit('.',1)[0]}.pep.xml" from_work_dir="output_reports/input.pep.xml" /> + </outputs> + <tests> + <test> + <param name="input" value="test_input.mzML" ftype="mzml"/> + <param name="searchdb" value="uniprot-proteome_UP000002311-first100entries.fasta" ftype="fasta"/> + <param name="fdr" value="1"/> + <param name="mvmi" value="1024"/> + <param name="precmt" value="Monoisotopic"/> + <param name="precmtu" value="Da"/> + <param name="precmtv" value="2.5"/> + <output name="output_psms"> + <assert_contents> + <has_text text="K.TTGSSSSSSSK.K" /> + <not_has_text text="carbamidomethylation of C" /> + <not_has_text text="(oxidation of M)" /> + </assert_contents> + </output> + </test> + <test> + <param name="input" value="test_input.mzML" ftype="mzml"/> + <param name="searchdb" value="uniprot-proteome_UP000002311-first100entries.fasta" ftype="fasta"/> + <param name="fdr" value="1"/> + <param name="mvmi" value="1024"/> + <param name="precmt" value="Monoisotopic"/> + <param name="precmtu" value="Da"/> + <param name="precmtv" value="2.5"/> + <param name="fm" value="carbamidomethylation of C"/> + <param name="vm" value="oxidation of M"/> + <output name="output_psms"> + <assert_contents> + <has_text text="K.VETYM(oxidation of M)ETK.I" /> + <not_has_text text="K.TTGSSSSSSSK.K" /> + </assert_contents> + </output> + </test> + <test> + <param name="input" value="test_input.mzML" ftype="mzml"/> + <param name="searchdb" value="uniprot-proteome_UP000002311Condensed-first100entries.xml" ftype="uniprotxml"/> + <param name="fdr" value="1"/> + <param name="mvmi" value="1024"/> + <param name="precmt" value="Monoisotopic"/> + <param name="precmtu" value="Da"/> + <param name="precmtv" value="2.5"/> + <param name="fm" value="carbamidomethylation of C"/> + <param name="vm" value="oxidation of M"/> + <output name="output_psms"> + <assert_contents> + <has_text text="R.KRSLFDS(UniProt: Phosphoserine)AFSSR.A" /> + <not_has_text text="K.KYFLENKIGTDR.R" /> + </assert_contents> + </output> + </test> + <test> + <param name="input" value="test_input.mzML" ftype="mzml"/> + <param name="searchdb" value="uniprot-proteome_UP000002311Condensed-first100entries.xml" ftype="uniprotxml"/> + <param name="fdr" value="1"/> + <param name="mvmi" value="1024"/> + <param name="precmt" value="Monoisotopic"/> + <param name="precmtu" value="Da"/> + <param name="precmtv" value="2.5"/> + <param name="fm" value="carbamidomethylation of C"/> + <param name="vm" value="oxidation of M"/> + <param name="adv_options_selector" value="set"/> + <param name="prodmtv" value=".01"/> + <output name="output_psms"> + <assert_contents> + <has_text text="K.KYFLENKIGTDR.R" /> + <not_has_text text="R.KRSLFDS(UniProt: Phosphoserine)AFSSR.A" /> + </assert_contents> + </output> + </test> + + </tests> + <help><![CDATA[ +Morpheus_ is a database search algorithm for high-resolution tandem mass spectra. + +When a Uniprot Proteome XML file is used for the search database, Morpheus will include all known modifications from the proteome in searching for peptide spectral matches. To fetch Uniprot Proteome XML files see: http://www.uniprot.org/help/retrieve_sets + +**INPUTS** + + - spectral data file in mzML format + - protein search database, either a fasta file or a uniprot proteome xml file + +**OUTPUTS** + + - summary.tsv + - input.log.txt + - input.PSMs.tsv + - input.unique_peptides.tsv + - input.protein_groups.tsv + - input.pep.xml + +.. _Morpheus: http://morpheus-ms.sourceforge.net/ + + ]]></help> + <citations> + <citation type="doi">10.1021/pr301024c</citation> + </citations> +</tool>
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</binary> + </binaryDataArray> + </binaryDataArrayList> + </chromatogram> + </chromatogramList> + </run> + </mzML> + <indexList count="2"> + <index name="spectrum"> + <offset idRef="controllerType=0 controllerNumber=1 scan=1970">4496</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1971">45505</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1972">52392</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1973">59702</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1974">66466</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1975">72509</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1976">79609</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1977">85720</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1978">92603</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1979">98677</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1980">105107</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1981">146748</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1982">153078</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1983">159740</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1984">166825</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1985">172633</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1986">179547</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1987">222607</offset> + <offset idRef="controllerType=0 controllerNumber=1 scan=1988">228533</offset> + </index> + <index name="chromatogram"> + <offset idRef="TIC">234671</offset> + </index> + </indexList> + <indexListOffset>496045</indexListOffset> + <fileChecksum>a6884acf9007eaf671b404780356f0bc15a0e33b</fileChecksum> +</indexedmzML>
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/test-data/uniprot-proteome_UP000002311-first100entries.fasta Thu Nov 05 08:59:15 2015 -0500 @@ -0,0 +1,947 @@ +>sp|P38903|2A5D_YEAST Serine/threonine-protein phosphatase 2A 56 kDa regulatory subunit delta isoform OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=RTS1 PE=1 SV=2 +MMRGFKQRLIKKTTGSSSSSSSKKKDKEKEKEKSSTTSSTSKKPASASSSSHGTTHSSAS +STGSKSTTEKGKQSGSVPSQGKHHSSSTSKTKTATTPSSSSSSSRSSSVSRSGSSSTKKT +SSRKGQEQSKQSQQPSQSQKQGSSSSSAAIMNPTPVLTVTKDDKSTSGEDHAHPTLLGAV +SAVPSSPISNASGTAVSSDVENGNSNNNNMNINTSNTQDANHASSQSIDIPRSSHSFERL +PTPTKLNPDTDLELIKTPQRHSSSRFEPSRYTPLTKLPNFNEVSPEERIPLFIAKVDQCN +TMFDFNDPSFDIQGKEIKRSTLDELIEFLVTNRFTYTNEMYAHVVNMFKINLFRPIPPPV +NPVGDIYDPDEDEPVNELAWPHMQAVYEFFLRFVESPDFNHQIAKQYIDQDFILKLLELF +DSEDIRERDCLKTTLHRIYGKFLSLRSFIRRSMNNIFLQFIYETEKFNGVAELLEILGSI +INGFALPLKEEHKVFLVRILIPLHKVRCLSLYHPQLAYCIVQFLEKDPLLTEEVVMGLLR +YWPKINSTKEIMFLNEIEDIFEVIEPLEFIKVEVPLFVQLAKCISSPHFQVAEKVLSYWN +NEYFLNLCIENAEVILPIIFPALYELTSQLELDTANGEDSISDPYMLVEQAINSGSWNRA +IHAMAFKALKIFLETNPVLYENCNALYLSSVKETQQRKVQREENWSKLEEYVKNLRINND +KDQYTIKNPELRNSFNTASENNTLNEENENDCDSEIQ +>sp|P31383|2AAA_YEAST Protein phosphatase PP2A regulatory subunit A OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=TPD3 PE=1 SV=3 +MSGARSTTAGAVPSAATTSTTSTTSNSKDSDSNESLYPLALLMDELKHDDIANRVEAMKK +LDTIALALGPERTRNELIPFLTEVAQDDEDEVFAVLAEQLGKFVPYIGGPQYATILLPVL +EILASAEETLVREKAVDSLNNVAQELSQEQLFSDFVPLIEHLATADWFSSKVSACGLFKS +VIVRIKDDSLRKNILALYLQLAQDDTPMVKRAVGKNLPILIDLLTQNLGLSTDEDWDYIS +NIFQKIINDNQDSVKFLAVDCLISILKFFNAKGDESHTQDLLNSAVKLIGDEAWRVRYMA +ADRFSDLASQFSSNQAYIDELVQPFLNLCEDNEGDVREAVAKQVSGFAKFLNDPSIILNK +ILPAVQNLSMDESETVRSALASKITNIVLLLNKDQVINNFLPILLNMLRDEFPDVRLNII +ASLKVVNDVIGIELLSDSLLPAITELAKDVNWRVRMAIIEYIPILAEQLGMQFFDQQLSD +LCLSWLWDTVYSIREAAVNNLKRLTEIFGSDWCRDEIISRLLKFDLQLLENFVSRFTILS +ALTTLVPVVSLDVVTEQLLPFISHLADDGVPNIRFNVAKSYAVIVKVLIKDEAKYDALIK +NTILPSLQTLCQDEDVDVKYFAKKSLAECQELLKN +>sp|Q00362|2ABA_YEAST Protein phosphatase PP2A regulatory subunit B OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=CDC55 PE=1 SV=2 +MAQNNFDFKFSQCFGDKADIVVTEADLITAVEFDYTGNYLATGDKGGRVVLFERSNSRHC +EYKFLTEFQSHDAEFDYLKSLEIEEKINEIKWLRPTQRSHFLLSTNDKTIKLWKVYEKNI +KLVSQNNLTEGVTFAKKGKPDNHNSRGGSVRAVLSLQSLKLPQLSQHDKIIAATPKRIYS +NAHTYHINSISLNSDQETFLSADDLRINLWNLDIPDQSFNIVDIKPTNMEELTEVITSAE +FHPQECNLFMYSSSKGTIKLCDMRQNSLCDNKTKTFEEYLDPINHNFFTEITSSISDIKF +SPNGRYIASRDYLTVKIWDVNMDNKPLKTINIHEQLKERLSDTYENDAIFDKFEVNFSGD +SSSVMTGSYNNNFMIYPNVVTSGDNDNGIVKTFDEHNAPNSNSNKNIHNSIQNKDSSSSG +NSHKRRSNGRNTGMVGSSNSSRSSIAGGEGANSEDSGTEMNEIVLQADKTAFRNKRYGSL +AQRSARNKDWGDDIDFKKNILHFSWHPRENSIAVAATNNLFIFSAL +>sp|P47177|2NDP_YEAST Putative nitronate monooxygenase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=YJR149W PE=1 SV=2 +MYFLNQLIFQDVSVMSVDKREDMSRSFQKCLNLRYPIIQAPMAGVTTIEMAAKACIAGAI +ASLPLSHLDFRKVNDIEKLKLMVSQFRDQVADESLEGNLNLNFFCHDIVDKPTDLQTANW +AKLYRKSMNVPIDMNEIKFDNGNVSFKAFEKENALQDFFQYLSDGFRPKIISFHFGHPSK +STIEYLQKIGILIFVTATSVREVRLLARLGINGIVCQGYEAGGHRGNFLVNDPKDDENLS +TVQLVKRTVDELAEMKNKGLIHATPFVIAAGGIMDSKDISYMLSQQADAVQVGTAFLGCS +ESNASKNFSSPFTRETTTKMVNIISGKPARTISTPFIEKVIANFQGEELPPYGYMYSAFK +QVRKKYPELANFILAGQGFQNVQSGITTDKKIETMGARLKIDGK +>sp|P47096|3HAO_YEAST 3-hydroxyanthranilate 3,4-dioxygenase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=BNA1 PE=1 SV=1 +MFNTTPINIDKWLKENEGLLKPPVNNYCLHKGGFTVMIVGGPNERTGYHINPTPEWFYQK +KGSMLLKVVDETDAEPKFIDIIINEGDSYLLPGNVPHSPVRFADTVGIVVEQDRPGGEND +KIRWYCSHCRQVVHESELQMLDLGTQVKEAILDFENDVEKRTCFHCKTLNYARPQSN +>sp|P40433|6P21_YEAST 6-phosphofructo-2-kinase 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=PFK26 PE=1 SV=1 +MFKPVDFSETSPVPPDIDLAPTQSPHHVAPSQDSSYDLLSRSSDDKIDAEKGPHDELSKH +LPLFQKRPLSDTPISSNWNSPGITEENTPSDSPENSATNLKSLHRLHINDETQLKNAKIP +TNDTTDYMPPSDGANEVTRIDLKDIKSPTRHHKRRPTTIDVPGLTKSKTSPDGLISKEDS +GSKLVIVMVGLPATGKSFITNKLSRFLNYSLYYCKVFNVGNTRRKFAKEHGLKDQDSKFF +EPKNADSTRLRDKWAMDTLDELLDYLLEGSGSVGIFDATNTSRERRKNVLARIRKRSPHL +KVLFLESVCSDHALVQKNIRLKLFGPDYKGKDPESSLKDFKSRLANYLKAYEPIEDDENL +QYIKMIDVGKKVIAYNIQGFLASQTVYYLLNFNLADRQIWITRSGESEDNVSGRIGGNSH +LTPRGLRFAKSLPKFIARQREIFYQNLMQQKKNNENTDGNIYNDFFVWTSMRARTIGTAQ +YFNEDDYPIKQMKMLDELSAGDYDGMTYPEIKNNFPEEFEKRQKDKLRYRYPGIGGESYM +DVINRLRPVITELERIEDNVLIITHRVVARALLGYFMNLSMGIIANLDVPLHCVYCLEPK +PYGITWSLWEYDEASDSFSKVPQTDLNTTRVKEVGLVYNERRYSVIPTAPPSARSSFASD +FLSRKRSNPTSASSSQSELSEQPKNSVSAQTGSNNTTLIGSNFNIKNENGDSRIPLSAPL +MATNTSNNILDGGGTSISIHRPRVVPNQNNVNPLLANNNKAASNVPNVKKSAATPRQIFE +IDKVDEKLSMLKNKSFLLHGKDYPNNADNNDNEDIRAKTMNRSQSHV +>sp|Q12471|6P22_YEAST 6-phosphofructo-2-kinase 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=PFK27 PE=1 SV=1 +MGGSSDSDSHDGYLTSEYNSSNSLFSLNTGNSYSSASLDRATLDCQDSVFFDNHKSSLLS +TEVPRFISNDPLHLPITLNYKRDNADPTYTNGKVNKFMIVLIGLPATGKSTISSHLIQCL +KNNPLTNSLRCKVFNAGKIRRQISCATISKPLLLSNTSSEDLFNPKNNDKKETYARITLQ +KLFHEINNDECDVGIFDATNSTIERRRFIFEEVCSFNTDELSSFNLVPIILQVSCFNRSF +IKYNIHNKSFNEDYLDKPYELAIKDFAKRLKHYYSQFTPFSLDEFNQIHRYISQHEEIDT +SLFFFNVINAGVVEPHSLNQSHYPSTCGKQIRDTIMVIENFINHYSQMFGFEYIEAVKLF +FESFGNSSEETLTTLDSVVNDKFFDDLQSLIESNGFA +>sp|P38720|6PGD1_YEAST 6-phosphogluconate dehydrogenase, decarboxylating 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=GND1 PE=1 SV=1 +MSADFGLIGLAVMGQNLILNAADHGFTVCAYNRTQSKVDHFLANEAKGKSIIGATSIEDF +ISKLKRPRKVMLLVKAGAPVDALINQIVPLLEKGDIIIDGGNSHFPDSNRRYEELKKKGI +LFVGSGVSGGEEGARYGPSLMPGGSEEAWPHIKNIFQSISAKSDGEPCCEWVGPAGAGHY +VKMVHNGIEYGDMQLICEAYDIMKRLGGFTDKEISDVFAKWNNGVLDSFLVEITRDILKF +DDVDGKPLVEKIMDTAGQKGTGKWTAINALDLGMPVTLIGEAVFARCLSALKNERIRASK +VLPGPEVPKDAVKDREQFVDDLEQALYASKIISYAQGFMLIREAAATYGWKLNNPAIALM +WRGGCIIRSVFLGQITKAYREEPDLENLLFNKFFADAVTKAQSGWRKSIALATTYGIPTP +AFSTALSFYDGYRSERLPANLLQAQRDYFGAHTFRVLPECASDNLPVDKDIHINWTGHGG +NVSSSTYQA +>sp|P53319|6PGD2_YEAST 6-phosphogluconate dehydrogenase, decarboxylating 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=GND2 PE=1 SV=1 +MSKAVGDLGLVGLAVMGQNLILNAADHGFTVVAYNRTQSKVDRFLANEAKGKSIIGATSI +EDLVAKLKKPRKIMLLIKAGAPVDTLIKELVPHLDKGDIIIDGGNSHFPDTNRRYEELTK +QGILFVGSGVSGGEDGARFGPSLMPGGSAEAWPHIKNIFQSIAAKSNGEPCCEWVGPAGS +GHYVKMVHNGIEYGDMQLICEAYDIMKRIGRFTDKEISEVFDKWNTGVLDSFLIEITRDI +LKFDDVDGKPLVEKIMDTAGQKGTGKWTAINALDLGMPVTLIGEAVFARCLSAIKDERKR +ASKLLAGPTVPKDAIHDREQFVYDLEQALYASKIISYAQGFMLIREAARSYGWKLNNPAI +ALMWRGGCIIRSVFLAEITKAYRDDPDLENLLFNEFFASAVTKAQSGWRRTIALAATYGI +PTPAFSTALAFYDGYRSERLPANLLQAQRDYFGAHTFRILPECASAHLPVDKDIHINWTG +HGGNISSSTYQA +>sp|P47182|AAD10_YEAST Putative aryl-alcohol dehydrogenase AAD10 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAD10 PE=3 SV=1 +MASRKLRDQIVIATKFTTDYKGYDVGKGKSANFCGNHKRSLHVSVRDSLRKLQTDWIDIL +YVHWWDYMSSIEEVMDSLHILVQQGKVLYLGVSDTPAWVVSAANYYATSHGKTPFSIYQG +KWNVLNRDFERDIIPMARHFGMALAPWDVMGGGRFQSKKAVEERKKKGEGLRTFFGTSEQ +TDMEVKISEALLKVAEEHGTESVTAIAIAYVRSKAKHVFPLVGGRKIEHLKQNIEALSIK +LTPEQIKYLESIVPFDVGFPTNFIGDDPAVTKKPSFLTEMSAKISFED +>sp|Q08361|AAD15_YEAST Putative aryl-alcohol dehydrogenase AAD15 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAD15 PE=3 SV=1 +MARHFGMALAPWDVMGGGRFQSKKAMEERRKNGECIRSFVGASEQTDAEIKISEALAKVA +EEHGTESVTAIAIAYVRSKAKNVFPSVEGGKIEDLKENIKALSIDLTPDNIKYLENVVPF +DIGFPNTFIVLNSLTQKYGTNNV +>sp|Q02895|AAD16_YEAST Putative aryl-alcohol dehydrogenase AAD16 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAD16 PE=1 SV=1 +MVLVKQVRLGNSGLKISPIVIGCMSYGSKKWADWVIEDKTQIFKIMKHCYDKGLRTFDTA +DFYSNGLSERIIKEFLEYYSIKRETVVIMTKIYFPVDETLDLHHNFTLNEFEELDLSNQR +GLSRKHIIAGVENSVKRLGTYIDLLQIHRLDHETPMKEIMKALNDVVEAGHVRYIGASSM +LATEFAELQFTADKYGWFQFISSQSYYNLLYREDERELIPFAKRHNIGLLPWSPNARGML +TRPLNQSTDRIKSDPTFKSLHLDNLEEEQKEIINRVEKVSKDKKVSMAMLSIAWVLHKGC +HPIVGLNTTARVDEAIAALQVTLTEEEIKYLEEPYKPQRQRC +>sp|P25612|AAD3_YEAST Putative aryl-alcohol dehydrogenase AAD3 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAD3 PE=3 SV=1 +MIGSASDSSSKLGRLRFLSETAAIKVSPLILGEVSYDGARSDFLKSMNKNRAFELLDTFY +EAGGNFIDAANNCQNEQSEEWIGEWIQSRRLRDQIVIATKFIKSDKKYKAGESNTANYCG +NHKRSLHVSVRDSLRKLQTDWIDILYVHWWDYMSSIEEFMDSLHILVQQGKVLYLGVSDT +PAWVVSAANYYATSYGKTPFSIYQGKWNVLNRDFERDIIPMARHFGMALAPWDVMGGGRF +QSKKAMEERRKNGEGIRSFVGASEQTDAEIKISEALAKIAEEHGTESVTAIAIAYVRSKA +KNFFPSVEGGKIEDLKENIKALSIDLTPDNIKYLESIVPFDIGFPNNFIVLNSLTQKYGT +NNV +>sp|Q07747|AAD4_YEAST Probable aryl-alcohol dehydrogenase AAD4 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAD4 PE=2 SV=1 +MGSMNKEQAFELLDAFYEAGGNCIDTANSYQNEESEIWIGEWMKSRKLRDQIVIATKFTG +DYKKYEVGGGKSANYCGNHKHSLHVSVRDSLRKLQTDWIDILYVHWWDYMSSIEEVMDSL +HILVQQGKVLYLGVSDTPAWVVSAANYYATSHGKTPFSIYQGKWNVLNRDFERDIIPMAR +HFGMALAPWDVMGGGRFQSKKAMEERKKNGEGLRTVSGTSKQTDKEVKISEALAKVAEEH +GTESVTAIAIAYVRSKAKNVFPLVGGRKIEHLKQNIEALSIKLTPEQIEYLESIIPFDVG +FPTNFIGDDPAVTKKASLLTAMSAQISFD +>sp|P42884|AAD14_YEAST Putative aryl-alcohol dehydrogenase AAD14 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAD14 PE=1 SV=1 +MTDLFKPLPEPPTELGRLRVLSKTAGIRVSPLILGGASIGDAWSGFMGSMNKEQAFELLD +AFYEAGGNCIDTANSYQNEESEIWIGEWMASRKLRDQIVIATKFTGDYKKYEVGGGKSAN +YCGNHKRSLHVSVRDSLRKLQTDWIDILYIHWWDYMSSIEEVMDSLHILVQQGKVLYLGV +SDTPAWVVSAANYYATSHGKTPFSVYQGKWNVLNRDFERDIIPMARHFGMALAPWDVMGG +GRFQSKKAMEERKKNGEGLRTFVGGPEQTELEVKISEALTKIAEEHGTESVTAIAIAYVR +SKAKNVFPLIGGRKIEHLKQNIEALSIKLTPEQIEYLESIVPFDVGFPKSLIGDDPAVTK +KLSPLTSMSARIAFDN +>sp|P43547|AAD6_YEAST Putative aryl-alcohol dehydrogenase AAD6 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAD6 PE=5 SV=1 +MADLFAPAPEPSTELGRLRVLSKSAGIRVSPLILGGMSIGDAWSEILGSMSKERAFELLD +AFYEAGGNFIDTANNYQNEQSEAWIGEWMVSRKLRDQIVIATKFTTDYKKYDVGGGKSAN +YCGNHKRSLHVSVRDSLRKLQTDWIDILYVHWWDYMSSIEEVMDSLHILVQQARSSIWVC +LIRLPGLFLRQITTLNLMVKPLLASIKVNGTC +>sp|P12904|AAKG_YEAST 5'-AMP-activated protein kinase subunit gamma OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=SNF4 PE=1 SV=1 +MKPTQDSQEKVSIEQQLAVESIRKFLNSKTSYDVLPVSYRLIVLDTSLLVKKSLNVLLQN +SIVSAPLWDSKTSRFAGLLTTTDFINVIQYYFSNPDKFELVDKLQLDGLKDIERALGVDQ +LDTASIHPSRPLFEACLKMLESRSGRIPLIDQDEETHREIVVSVLTQYRILKFVALNCRE +THFLKIPIGDLNIITQDNMKSCQMTTPVIDVIQMLTQGRVSSVPIIDENGYLINVYEAYD +VLGLIKGGIYNDLSLSVGEALMRRSDDFEGVYTCTKNDKLSTIMDNIRKARVHRFFVVDD +VGRLVGVLTLSDILKYILLGSN +>sp|P37898|AAP1_YEAST Alanine/arginine aminopeptidase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAP1 PE=1 SV=2 +MSREVLPNNVTPLHYDITLEPNFRAFTFEGSLKIDLQINDHSINSVQINYLEIDFHSARI +EGVNAIEVNKNENQQKATLVFPNGTFENLGPSAKLEIIFSGILNDQMAGFYRAKYTDKVT +GETKYMATTQMEATDARRAFPCFDEPNLKATFAVTLVSESFLTHLSNMDVRNETIKEGKK +YTTFNTTPKMSTYLVAFIVADLRYVESNNFRIPVRVYSTPGDEKFGQFAANLAARTLRFF +EDTFNIEYPLPKMDMVAVHEFSAGAMENWGLVTYRVIDLLLDIENSSLDRIQRVAEVIQH +ELAHQWFGNLVTMDWWEGLWLNEGFATWMSWYSCNKFQPEWKVWEQYVTDNLQRALNLDS +LRSSHPIEVPVNNADEINQIFDAISYSKGSSLLRMISKWLGEETFIKGVSQYLNKFKYGN +AKTGDLWDALADASGKDVCSVMNIWTKRVGFPVLSVKEHKNKITLTQHRYLSTGDVKEEE +DTTIYPILLALKDSTGIDNTLVLNEKSATFELKNEEFFKINGDQSGIFITSYSDERWAKL +SKQANLLSVEDRVGLVADAKALSASGYTSTTNFLNLISNWKNEDSFVVWEQIINSLSALK +STWVFEPEDILNALDKFTLDLVLNKLSELGWNIGEDDSFAIQRLKVTLFSAACTSGNEKM +QSIAVEMFEEYANGNKQAIPALFKAVVFNTVARLGGENNYEKIFNIYQNPVSSEEKIIAL +RALGRFEDKELLERTLSYLLDGTVLNQDFYIPMQGIRVHKKGIERLWAWMQEHWDEIAKR +LQPGSPVLGGVLTLGLTNFTSFEALEKISAFYSRKVTKGFDQTLAQALDTIRSKAQWVSR +DREIVATYLREHEYDQ +>sp|P08521|AAP_YEAST Arginine attenuator peptide OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=YOR302W PE=1 SV=1 +MFSLSNSQYTCQDYISDHIWKTSSH +>sp|P32357|AAR2_YEAST A1 cistron-splicing factor AAR2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAR2 PE=1 SV=1 +MNTVPFTSAPIEVTIGIDQYSFNVKENQPFHGIKDIPIGHVHVIHFQHADNSSMRYGYWF +DCRMGNFYIQYDPKDGLYKMMEERDGAKFENIVHNFKERQMMVSYPKIDEDDTWYNLTEF +VQMDKIRKIVRKDENQFSYVDSSMTTVQENELLKSSLQKAGSKMEAKNEDDPAHSLNYTV +INFKSREAIRPGHEMEDFLDKSYYLNTVMLQGIFKNSSNYFGELQFAFLNAMFFGNYGSS +LQWHAMIELICSSATVPKHMLDKLDEILYYQIKTLPEQYSDILLNERVWNICLYSSFQKN +SLHNTEKIMENKYPELLGKDNEDDALIYGISDEERDDEDDEHNPTIVGGLYYQRP +>sp|P23542|AATC_YEAST Aspartate aminotransferase, cytoplasmic OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAT2 PE=1 SV=3 +MSATLFNNIELLPPDALFGIKQRYGQDQRATKVDLGIGAYRDDNGKPWVLPSVKAAEKLI +HNDSSYNHEYLGITGLPSLTSNAAKIIFGTQSDAFQEDRVISVQSLSGTGALHISAKFFS +KFFPDKLVYLSKPTWANHMAIFENQGLKTATYPYWANETKSLDLNGFLNAIQKAPEGSIF +VLHSCAHNPTGLDPTSEQWVQIVDAIASKNHIALFDTAYQGFATGDLDKDAYAVRLGVEK +LSTVSPVFVCQSFAKNAGMYGERVGCFHLALTKQAQNKTIKPAVTSQLAKIIRSEVSNPP +AYGAKIVAKLLETPELTEQWHKDMVTMSSRITKMRHALRDHLVKLGTPGNWDHIVNQCGM +FSFTGLTPQMVKRLEETHAVYLVASGRASIAGLNQGNVEYVAKAIDEVVRFYTIEAKL +>sp|Q01802|AATM_YEAST Aspartate aminotransferase, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAT1 PE=1 SV=2 +MLRTRLTNCSLWRPYYTSSLSRVPRAPPDKVLGLSEHFKKVKNVNKIDLTVGIYKDGWGK +VTTFPSVAKAQKLIESHLELNKNLSYLPITGSKEFQENVMKFLFKESCPQFGPFYLAHDR +ISFVQTLSGTGALAVAAKFLALFISRDIWIPDPSWANHKNIFQNNGFENIYRYSYYKDGQ +IDIDGWIEQLKTFAYNNQQENNKNPPCIILHACCHNPTGLDPTKEQWEKIIDTIYELKMV +PIVDMAYQGLESGNLLKDAYLLRLCLNVNKYPNWSNGIFLCQSFAKNMGLYGERVGSLSV +ITPATANNGKFNPLQQKNSLQQNIDSQLKKIVRGMYSSPPGYGSRVVNVVLSDFKLKQQW +FKDVDFMVQRLHHVRQEMFDRLGWPDLVNFAQQHGMFYYTRFSPKQVEILRNNYFVYLTG +DGRLSLSGVNDSNVDYLCESLEAVSKMDKLA +>sp|Q08641|AB140_YEAST tRNA(Thr) (cytosine(32)-N(3))-methyltransferase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ABP140 PE=1 SV=3 +MGVADLIKKFESISKEEGDATVDTNSSSKPLKSNDETKELHQQESTAVPQEVDVNEEFEN +EPETINSSRTAEKPLETNLPKPETNEEDEEEGSMSENKIYSKGENADINVNDFQEYKEME +NTGAEVLASSVEESDAIQEGVAEETEGIATPKQKENEKNDESEEESANNASEPAEEYSQS +EEDADIEQSNGKETENAENASQQANDGSTSTTTSKNKKKKNKKKNKKKRNGNVNTNANVD +DSTKTGENDDTTGDTTSSTTSAIQEVNDLEVVDDSCLGIDQQHNREHLKALTQDVKEETL +ENIAHEGRGDNTGDQNAVEKSDFEKSDTEGSRIGRDLPFEFGKRNLTEESDVWDHNAWDN +VEWGEEQVQQAEEKIKEQFKHPVPEFDKKLYNENPARYWDIFYKNNKENFFKDRKWLQIE +FPILYASTRKDAEPVTIFEIGCGAGNTFFPILKDNENENLRIIAADFAPRAVELVKNSEQ +FNPKYGHATVWDLANPDGNLPDGVEPHSVDIAVMIFVFSALAPNQWDQAMDNLHKILKPG +GKIIFRDYGAYDLTQVRFKKNRILEENFYVRGDGTRVYFFSEEKLREIFTKKYFLENKIG +TDRRLLVNRKRQLKMYRCWVQAVFDVPQ +>sp|P14164|ABF1_YEAST ARS-binding factor 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ABF1 PE=1 SV=4 +MDKLVVNYYEYKHPIINKDLAIGAHGGKKFPTLGAWYDVINEYEFQTRCPIILKNSHRNK +HFTFACHLKNCPFKVLLSYAGNAASSETSSPSANNNTNPPGTPDHIHHHSNNMNNEDNDN +NNGSNNKVSNDSKLDFVTDDLEYHLANTHPDDTNDKVESRSNEVNGNNDDDADANNIFKQ +QGVTIKNDTEDDSINKASIDRGLDDESGPTHGNDSGNHRHNEEDDVHTQMTKNYSDVVND +EDINVAIANAVANVDSQSNNKHDGKDDDATNNNDGQDNNTNNDHNNNSNINNNNVGSHGI +SSHSPSSIRDTSMNLDVFNSATDDIPGPFVVTKIEPYHSHPLEDNLSLGKFILTKIPKIL +QNDLKFDQILESSYNNSNHTVSKFKVSHYVEESGLLDILMQRYGLTAEDFEKRLLSQIAR +RITTYKARFVLKKKKMGEYNDLQPSSSSNNNNNNDGELSGTNLRSNSIDYAKHQEISSAG +TSSNTTKNVNNNKNDSNDDNNGNNNNDASNLMESVLDKTSSHRYQPKKMPSVNKWSKPDQ +ITHSDVSMVGLDESNDGGNENVHPTLAEVDAQEARETAQLAIDKINSYKRSIDDKNGDGH +NNSSRNVVDENLINDMDSEDAHKSKRQHLSDITLEERNEDDKLPHEVAEQLRLLSSHLKE +VENLHQNNDDDVDDVMVDVDVESQYNKNTTHHNNHHSQPHHDEEDVAGLIGKADDEEDLS +DENIQPELRGQ +>sp|Q02486|ABF2_YEAST ARS-binding factor 2, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ABF2 PE=1 SV=1 +MNSYSLLTRSFHESSKPLFNLASTLLKASKRTQLRNELIKQGPKRPTSAYFLYLQDHRSQ +FVKENPTLRPAEISKIAGEKWQNLEADIKEKYISERKKLYSEYQKAKKEFDEKLPPKKPA +GPFIKYANEVRSQVFAQHPDKSQLDLMKIIGDKWQSLDQSIKDKYIQEYKKAIQEYNARY +PLN +>sp|P47146|ABM1_YEAST Aberrant microtubules protein 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ABM1 PE=4 SV=1 +MSWRYSILTVDGSFKIFIPWEIFLTWNFLSAAWLNSTESNTYIHYSTCWGTSDYTLNISV +IEATTEKLVDTRLLTTLENATAWINSNSIDEDEDDMPHATNVADRLDGLSLSKRVYSICH +YEF +>sp|P15891|ABP1_YEAST Actin-binding protein OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ABP1 PE=1 SV=4 +MALEPIDYTTHSREIDAEYLKIVRGSDPDTTWLIISPNAKKEYEPESTGSSFHDFLQLFD +ETKVQYGLARVSPPGSDVEKIIIIGWCPDSAPLKTRASFAANFAAVANNLFKGYHVQVTA +RDEDDLDENELLMKISNAAGARYSIQTSSKQQGKASTPPVKKSFTPSKSPAPVSKKEPVK +TPSPAPAAKISSRVNDNNDDDDWNEPELKERDFDQAPLKPNQSSYKPIGKIDLQKVIAEE +KAKEDPRLVQKPTAAGSKIDPSSDIANLKNESKLKRDSEFNSFLGTTKPPSMTESSLKND +DDKVIKGFRNEKSPAQLWAERKAKQNSGNAETKAEAPKPEVPEDEPEGEPDVKDLKSKFE +GLAASEKEEEEMENKFAPPPKKSEPTIISPKPFSKPQEPVKAEEAEQPKTDYKKIGNPLP +GMHIEADNEEEPEENDDDWDDDEDEAAQPPLPSRNVASGAPVQKEEPEQEEIAPSLPSRN +SIPAPKQEEAPEQAPEEEIEEEAEEAAPQLPSRSSAAPPPPPRRATPEKKPKENPWATAE +YDYDAAEDNELTFVENDKIINIEFVDDDWWLGELEKDGSKGLFPSNYVSLGN +>sp|P39970|ACA1_YEAST ATF/CREB activator 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACA1 PE=2 SV=1 +MDYKHNFATSPDSFLDGRQNPLLYTDFLSSNKELIYKQPSGPGLVDSAYNFHHQNSLHDR +SVQENLGPMFQPFGVDISHLPITNPPIFQSSLPAFDQPVYKRRISISNGQISQLGEDLET +VENLYNCQPPILSSKAQQNPNPQQVANPSAAIYPSFSSNELQNVPQPHEQATVIPEAAPQ +TGSKNIYAAMTPYDSNIKLNIPAVAATCDIPSATPSIPSGDSTMNQAYINMQLRLQAQMQ +TKAWKNAQLNVHPCTPASNSSVSSSSSCQNINDHNIENQSVHSSISHGVNHHTVNNSCQN +AELNISSSLPYESKCPDVNLTHANSKPQYKDATSALKNNINSEKDVHTAPFSSMHTTATF +QIKQEARPQKIENNTAGLKDGAKAWKRARLLERNRIAASKCRQRKKMSQLQLQREFDQIS +KENTMMKKKIENYEKLVQKMKKISRLHMQECTINGGNNSYQSLQNKDSDVNGFLKMIEEM +IRSSSLYDE +>sp|P40535|ACA2_YEAST ATF/CREB activator 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=CST6 PE=1 SV=1 +MFTGQEYHSVDSNSNKQKDNNKRGIDDTSKILNNKIPHSVSDTSAAATTTSTMNNSALSR +SLDPTDINYSTNMAGVVDQIHDYTTSNRNSLTPQYSIAAGNVNSHDRVVKPSANSNYQQA +AYLRQQQQQDQRQQSPSMKTEEESQLYGDILMNSGVVQDMHQNLATHTNLSQLSSTRKSA +PNDSTTAPTNASNIANTASVNKQMYFMNMNMNNNPHALNDPSILETLSPFFQPFGVDVAH +LPMTNPPIFQSSLPGCDEPIRRRRISISNGQISQLGEDIETLENLHNTQPPPMPNFHNYN +GLSQTRNVSNKPVFNQAVPVSSIPQYNAKKVINPTKDSALGDQSVIYSKSQQRNFVNAPS +KNTPAESISDLEGMTTFAPTTGGENRGKSALRESHSNPSFTPKSQGSHLNLAANTQGNPI +PGTTAWKRARLLERNRIAASKCRQRKKVAQLQLQKEFNEIKDENRILLKKLNYYEKLISK +FKKFSKIHLREHEKLNKDSDNNVNGTNSSNKNESMTVDSLKIIEELLMIDSDVTEVDKDT +GKIIAIKHEPYSQRFGSDTDDDDIDLKPVEGGKDPDNQSLPNSEKIK +>sp|Q00955|ACAC_YEAST Acetyl-CoA carboxylase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACC1 PE=1 SV=2 +MSEESLFESSPQKMEYEITNYSERHTELPGHFIGLNTVDKLEESPLRDFVKSHGGHTVIS +KILIANNGIAAVKEIRSVRKWAYETFGDDRTVQFVAMATPEDLEANAEYIRMADQYIEVP +GGTNNNNYANVDLIVDIAERADVDAVWAGWGHASENPLLPEKLSQSKRKVIFIGPPGNAM +RSLGDKISSTIVAQSAKVPCIPWSGTGVDTVHVDEKTGLVSVDDDIYQKGCCTSPEDGLQ +KAKRIGFPVMIKASEGGGGKGIRQVEREEDFIALYHQAANEIPGSPIFIMKLAGRARHLE +VQLLADQYGTNISLFGRDCSVQRRHQKIIEEAPVTIAKAETFHEMEKAAVRLGKLVGYVS +AGTVEYLYSHDDGKFYFLELNPRLQVEHPTTEMVSGVNLPAAQLQIAMGIPMHRISDIRT +LYGMNPHSASEIDFEFKTQDATKKQRRPIPKGHCTACRITSEDPNDGFKPSGGTLHELNF +RSSSNVWGYFSVGNNGNIHSFSDSQFGHIFAFGENRQASRKHMVVALKELSIRGDFRTTV +EYLIKLLETEDFEDNTITTGWLDDLITHKMTAEKPDPTLAVICGAATKAFLASEEARHKY +IESLQKGQVLSKDLLQTMFPVDFIHEGKRYKFTVAKSGNDRYTLFINGSKCDIILRQLSD +GGLLIAIGGKSHTIYWKEEVAATRLSVDSMTTLLEVENDPTQLRTPSPGKLVKFLVENGE +HIIKGQPYAEIEVMKMQMPLVSQENGIVQLLKQPGSTIVAGDIMAIMTLDDPSKVKHALP +FEGMLPDFGSPVIEGTKPAYKFKSLVSTLENILKGYDNQVIMNASLQQLIEVLRNPKLPY +SEWKLHISALHSRLPAKLDEQMEELVARSLRRGAVFPARQLSKLIDMAVKNPEYNPDKLL +GAVVEPLADIAHKYSNGLEAHEHSIFVHFLEEYYEVEKLFNGPNVREENIILKLRDENPK +DLDKVALTVLSHSKVSAKNNLILAILKHYQPLCKLSSKVSAIFSTPLQHIVELESKATAK +VALQAREILIQGALPSVKERTEQIEHILKSSVVKVAYGSSNPKRSEPDLNILKDLIDSNY +VVFDVLLQFLTHQDPVVTAAAAQVYIRRAYRAYTIGDIRVHEGVTVPIVEWKFQLPSAAF +STFPTVKSKMGMNRAVSVSDLSYVANSQSSPLREGILMAVDHLDDVDEILSQSLEVIPRH +QSSSNGPAPDRSGSSASLSNVANVCVASTEGFESEEEILVRLREILDLNKQELINASIRR +ITFMFGFKDGSYPKYYTFNGPNYNENETIRHIEPALAFQLELGRLSNFNIKPIFTDNRNI +HVYEAVSKTSPLDKRFFTRGIIRTGHIRDDISIQEYLTSEANRLMSDILDNLEVTDTSNS +DLNHIFINFIAVFDISPEDVEAAFGGFLERFGKRLLRLRVSSAEIRIIIKDPQTGAPVPL +RALINNVSGYVIKTEMYTEVKNAKGEWVFKSLGKPGSMHLRPIATPYPVKEWLQPKRYKA +HLMGTTYVYDFPELFRQASSSQWKNFSADVKLTDDFFISNELIEDENGELTEVEREPGAN +AIGMVAFKITVKTPEYPRGRQFVVVANDITFKIGSFGPQEDEFFNKVTEYARKRGIPRIY +LAANSGARIGMAEEIVPLFQVAWNDAANPDKGFQYLYLTSEGMETLKKFDKENSVLTERT +VINGEERFVIKTIIGSEDGLGVECLRGSGLIAGATSRAYHDIFTITLVTCRSVGIGAYLV +RLGQRAIQVEGQPIILTGAPAINKMLGREVYTSNLQLGGTQIMYNNGVSHLTAVDDLAGV +EKIVEWMSYVPAKRNMPVPILETKDTWDRPVDFTPTNDETYDVRWMIEGRETESGFEYGL +FDKGSFFETLSGWAKGVVVGRARLGGIPLGVIGVETRTVENLIPADPANPNSAETLIQEP +GQVWHPNSAFKTAQAINDFNNGEQLPMMILANWRGFSGGQRDMFNEVLKYGSFIVDALVD +YKQPIIIYIPPTGELRGGSWVVVDPTINADQMEMYADVNARAGVLEPQGMVGIKFRREKL +LDTMNRLDDKYRELRSQLSNKSLAPEVHQQISKQLADRERELLPIYGQISLQFADLHDRS +SRMVAKGVISKELEWTEARRFFFWRLRRRLNEEYLIKRLSHQVGEASRLEKIARIRSWYP +ASVDHEDDRQVATWIEENYKTLDDKLKGLKLESFAQDLAKKIRSDHDNAIDGLSEVIKML +STDDKEKLLKTLK +>sp|P31787|ACBP_YEAST Acyl-CoA-binding protein OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACB1 PE=1 SV=3 +MVSQLFEEKAKAVNELPTKPSTDELLELYALYKQATVGDNDKEKPGIFNMKDRYKWEAWE +NLKGKSQEDAEKEYIALVDQLIAKYSS +>sp|P21192|ACE2_YEAST Metallothionein expression activator OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACE2 PE=1 SV=1 +MDNVVDPWYINPSGFAKDTQDEEYVQHHDNVNPTIPPPDNYILNNENDDGLDNLLGMDYY +NIDDLLTQELRDLDIPLVPSPKTGDGSSDKKNIDRTWNLGDENNKVSHYSKKSMSSHKRG +LSGTAIFGFLGHNKTLSISSLQQSILNMSKDPQPMELINELGNHNTVKNNNDDFDHIREN +DGENSYLSQVLLKQQEELRIALEKQKEVNEKLEKQLRDNQIQQEKLRKVLEEQEEVAQKL +VSGATNSNSKPGSPVILKTPAMQNGRMKDNAIIVTTNSANGGYQFPPPTLISPRMSNTSI +NGSPSRKYHRQRYPNKSPESNGLNLFSSNSGYLRDSELLSFSPQNYNLNLDGLTYNDHNN +TSDKNNNDKKNSTGDNIFRLFEKTSPGGLSISPRINGNSLRSPFLVGTDKSRDDRYAAGT +FTPRTQLSPIHKKRESVVSTVSTISQLQDDTEPIHMRNTQNPTLRNANALASSSVLPPIP +GSSNNTPIKNSLPQKHVFQHTPVKAPPKNGSNLAPLLNAPDLTDHQLEIKTPIRNNSHCE +VESYPQVPPVTHDIHKSPTLHSTSPLPDEIIPRTTPMKITKKPTTLPPGTIDQYVKELPD +KLFECLYPNCNKVFKRRYNIRSHIQTHLQDRPYSCDFPGCTKAFVRNHDLIRHKISHNAK +KYICPCGKRFNREDALMVHRSRMICTGGKKLEHSINKKLTSPKKSLLDSPHDTSPVKETI +ARDKDGSVLMKMEEQLRDDMRKHGLLDPPPSTAAHEQNSNRTLSNETDAL +>sp|P28240|ACEA_YEAST Isocitrate lyase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ICL1 PE=1 SV=1 +MPIPVGNTKNDFAALQAKLDADAAEIEKWWSDSRWSKTKRNYSARDIAVRRGTFPPIEYP +SSVMARKLFKVLEKHHNEGTVSKTFGALDPVQISQMAKYLDTIYISGWQCSSTASTSNEP +GPDLADYPMDTVPNKVEHLFKAQLFHDRKQLEARSKAKSQEELDEMGAPIDYLTPIVADA +DAGHGGLTAVFKLTKMFIERGAAGIHMEDQTSTNKKCGHMAGRCVIPVQEHVNRLVTIRM +CADIMHSDLIVVARTDSEAATLISSTIDTRDHYFIVGATNPNIEPFAEVLNDAIMSGASG +QELADIEQKWCRDAGLKLFHEAVIDEIERSALSNKQELIKKFTSKVGPLTETSHREAKKL +AKEILGHEIFFDWELPRVREGLYRYRGGTQCSIMRARAFAPYADLVWMESNYPDFQQAKE +FAEGVKEKFPDQWLAYNLSPSFNWPKAMSVDEQHTFIQRLGDLGYIWQFITLAGLHTNAL +AVHNFSRDFAKDGMKAYAQNVQQREMDDGVDVLKHQKWSGAEYIDGLLKLAQGGVSATAA +MGTGVTEDQFKENGVKK +>sp|Q12031|ACEB_YEAST Mitochondrial 2-methylisocitrate lyase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ICL2 PE=1 SV=1 +MITMINNKTFNRKTTGTLKKLVLSSDKSLRRSFNGASSTKDFVFSESSKVEEWWESARFK +NISRPYSATDVVKHRGSLPANTSIYPSSYQARKLFNLLEENFKNGTPLHTLGVIDPVQMS +QLARCRNIKVAYISGWACSSTLVGSTNEVSPDFGDYPYDTVPNQVERIFKAQQLHDRKAF +LEASIKGSTPVDYLKPIIADADMGHGGPTTVMKVAKLFAEKGAAGIHLEDQMVGGKRCGH +LSGAVLVPTATHLMRLISTRFQWDIMGTENLVIARTDSCNGKLLSSSSDPRDHEFIRGII +RDNVVPWSEKLIEMEDKKIPNSAIADMEKEWYHENELFTFEEALEKQFTASEFESYKEKK +EDLMVNKLGRAYLSLREMKLLAQEVTPLKKIIFDWDAPRTKEGYYMFNGCIEAAIRRSLV +FAPYSDMIWLETKTPDLEQARSFSRKIHKQLPATKLVYNLSPSFNWSAHGFDDKALKSFV +WDLAKEGFTLQLVSLAGLHSDGVSFWELANSFQSDGMKAYVEKVQKREKETNCDIMTHQL +WSGAEYVDSLMKVVQNGASSQTLSTSGESFTETQF +>sp|P47129|ACF4_YEAST Assembly-complementing factor 4 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACF4 PE=1 SV=1 +MSEDQRVISQPIELHKLSIVDKHSQGQQQQPHQKQHEVQPESKSPRVTTPLKPKRLAIPI +SSPQRSTTNQSPVSDHASPISTDQDLIYKLAAKHREINELSFKLEVAQKELKQLELQFKD +TLPRNGQQKLGNQNPSEYLSTFTKRIQQTFVDVNNSPNMLKGKKSINDFFSKPNNNVNSN +INNTLPNRKPNPPPNRSQRMQNIAPSRSSESTPTSGPPLLPPRNTMKNANTTATAGENTP +FLQRILNKFNQMNMEEDEFDDLLEKRKSKKDHYYIKENLGYEYDEVRSEDEDDEEFEPMG +DIPVHLFKR +>sp|P32316|ACH1_YEAST Acetyl-CoA hydrolase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACH1 PE=1 SV=2 +MTISNLLKQRVRYAPYLKKVKEAHELIPLFKNGQYLGWSGFTGVGTPKAVPEALIDHVEK +NNLQGKLRFNLFVGASAGPEENRWAEHDMIIKRAPHQVGKPIAKAINQGRIEFFDKHLSM +FPQDLTYGFYTRERKDNKILDYTIIEATAIKEDGSIVPGPSVGGSPEFITVSDKVIIEVN +TATPSFEGIHDIDMPVNPPFRKPYPYLKVDDKCGVDSIPVDPEKVVAIVESTMRDQVPPN +TPSDDMSRAIAGHLVEFFRNEVKHGRLPENLLPLQSGIGNIANAVIEGLAGAQFKHLTVW +TEVLQDSFLDLFENGSLDYATATSVRLTEKGFDRAFANWENFKHRLCLRSQVVSNNPEMI +RRLGVIAMNTPVEVDIYAHANSTNVNGSRMLNGLGGSADFLRNAKLSIMHAPSARPTKVD +PTGISTIVPMASHVDQTEHDLDILVTDQGLADLRGLSPKERAREIINKCAHPDYQALLTD +YLDRAEHYAKKHNCLHEPHMLKNAFKFHTNLAEKGTMKVDSWEPVD +>sp|Q07622|ACK1_YEAST Activator of C kinase protein 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACK1 PE=1 SV=1 +MVNQGQPQPNLYDKHINMFPPARARESSHKLGNANSDRHGLPAQNIVPAPYPVDDSIVEL +TPAIPFTSPSSSSSLSLPLSALNFTDGNADGGQLGTPVTINSNNGMDIFNSKPTGEIGYA +NNGTNSTGSRYELPFNFSSTKESLGSPAVQDASISSGNRISESVRDNSAPPPYEESESRI +LQEKVYRTEEKAPIRPLNNNPVPPQKINQPPTGSAKTDDNGSSGGEDKLSSYSPEALAFY +QVYKKTITDSSKFTPEIQMQWCETLLTYAFNEDFISQYNINAEKLKRSLKPEEMLKNQKV +ILEHSFKVLTKLITLKWPPAMYLMGTLYSHQPYLPIKNKNIVIKNDEKALEYYCKAAKLN +NSDACYRAGVCFEYQRGTSSLDPSPTKEQCIKKAFQYYQHGAEVCSNSACMYKLGMSHLY +GLNMQKTDVLLAIKWFDKAAQKGDSPQTLYELGKIYEFSVLPPEIQNLLFANGIRKDSQL +AIKYYQQCAKDFEYPLAQWKLGNCYEFGDLGLPVVAKKSIYWYSKAAAAQPKGNPMAMLS +LSGWYLTGAPNILKPNNKEAFNWALKSSKCSDGKLARTEFALGFYYEKGVGCEVDLDLAK +QYYQRAARMGFRKAVDALRSLTN +>sp|Q03771|ACL4_YEAST Assembly chaperone of RPL4 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACL4 PE=1 SV=1 +MSELEATIRQAKEALAENNAKKALKILKPFKSSLKKENANNVILNEVFADAYLDNGQVEK +AYPILARACELDPEGQVGGPDKFFTMGQIMGGQDGVSIITRGIMNISNTGGEMLTNVQVE +KIVGGLLSVIEIWMTDLCMEPNAEEQCEELIQKAMELTEGKSPETWSTLGSIKISQQKFG +EAYEAFSQAWNFFELKKQEIGSGINENGDTTQKAGLQSEYVDLLQPLLSLTKMCLEVGAY +EVALKVIAAVRDIDEDNIEGYYLEGFTYYLMSKLEIFKLNNPEVSLRPENIYEFNQLIQE +VPLDLSHEPISQLIYDSRLALSFALQAGVNADSKDEIVQELLGGANALLQEIGGPLDPSE +LTQIKKGDLVNENEDLEELDIEEEYSD +>sp|Q08981|ACM1_YEAST APC/C-CDH1 modulator 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACM1 PE=1 SV=1 +MISPSKKRTILSSKNINQKPRAVVKGNELRSPSKRRSQIDTDYALRRSPIKTIQISKAAQ +FMLYEETAEERNIAVHRHNEIYNNNNSVSNENNPSQVKENLSPAKICPYERAFLREGGRI +ALKDLSVDEFKGYIQDPLTDETIPLTLPLGDKKISLPSFITPPRNSKISIFFTSKHQGQN +PETKISRSTDDVSEKKVVRKLSFHVYEDE +>sp|P21147|ACO1_YEAST Acyl-CoA desaturase 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=OLE1 PE=1 SV=2 +MPTSGTTIELIDDQFPKDDSASSGIVDEVDLTEANILATGLNKKAPRIVNGFGSLMGSKE +MVSVEFDKKGNEKKSNLDRLLEKDNQEKEEAKTKIHISEQPWTLNNWHQHLNWLNMVLVC +GMPMIGWYFALSGKVPLHLNVFLFSVFYYAVGGVSITAGYHRLWSHRSYSAHWPLRLFYA +IFGCASVEGSAKWWGHSHRIHHRYTDTLRDPYDARRGLWYSHMGWMLLKPNPKYKARADI +TDMTDDWTIRFQHRHYILLMLLTAFVIPTLICGYFFNDYMGGLIYAGFIRVFVIQQATFC +INSLAHYIGTQPFDDRRTPRDNWITAIVTFGEGYHNFHHEFPTDYRNAIKWYQYDPTKVI +IYLTSLVGLAYDLKKFSQNAIEEALIQQEQKKINKKKAKINWGPVLTDLPMWDKQTFLAK +SKENKGLVIISGIVHDVSGYISEHPGGETLIKTALGKDATKAFSGGVYRHSNAAQNVLAD +MRVAVIKESKNSAIRMASKRGEIYETGKFF +>sp|P39533|ACON2_YEAST Homocitrate dehydratase, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACO2 PE=1 SV=1 +MLSSANRFYIKRHLATHANMFPSVSKNFQTKVPPYAKLLTNLDKIKQITNNAPLTLAEKI +LYSHLCDPEESITSSDLSTIRGNKYLKLNPDRVAMQDASAQMALLQFMTTGLNQTSVPAS +IHCDHLIVGKDGETKDLPSSIATNQEVFDFLESCAKRYGIQFWGPGSGIIHQIVLENFSA +PGLMMLGTDSHTPNAGGLGAIAIGVGGADAVDALTGTPWELKAPKILGVKLTGKLNGWST +PKDVITKLAGLLTVRGGTGYIVEYFGEGVSTLSCTGMATICNMGAEIGATTSTFPYQEAH +KRYLQATNRAEVAEAADVALNKFNFLRADKDAQYDKVIEIDLSAIEPHVNGPFTPDLSTP +ISQYAEKSLKENWPQKVSAGLIGSCTNSSYQDMSRVVDLVKQASKAGLKPRIPFFVTPGS +EQIRATLERDGIIDIFQENGAKVLANACGPCIGQWNREDVSKTSKETNTIFTSFNRNFRA +RNDGNRNTMNFLTSPEIVTAMSYSGDAQFNPLTDSIKLPNGKDFKFQPPKGDELPKRGFE +HGRDKFYPEMDPKPDSNVEIKVDPNSDRLQLLEPFKPWNGKELKTNVLLKVEGKCTTDHI +SAAGVWLKYKGHLENISYNTLIGAQNKETGEVNKAYDLDGTEYDIPGLMMKWKSDGRPWT +VIAEHNYGEGSAREHAALSPRFLGGEILLVKSFARIHETNLKKQGVLPLTFANESDYDKI +SSGDVLETLNLVDMIAKDGNNGGEIDVKITKPNGESFTIKAKHTMSKDQIDFFKAGSAIN +YIGNIRRNE +>sp|P19414|ACON_YEAST Aconitate hydratase, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACO1 PE=1 SV=2 +MLSARSAIKRPIVRGLATVSNLTRDSKVNQNLLEDHSFINYKQNVETLDIVRKRLNRPFT +YAEKILYGHLDDPHGQDIQRGVSYLKLRPDRVACQDATAQMAILQFMSAGLPQVAKPVTV +HCDHLIQAQVGGEKDLKRAIDLNKEVYDFLASATAKYNMGFWKPGSGIIHQIVLENYAFP +GALIIGTDSHTPNAGGLGQLAIGVGGADAVDVMAGRPWELKAPKILGVKLTGKMNGWTSP +KDIILKLAGITTVKGGTGKIVEYFGDGVDTFSATGMGTICNMGAEIGATTSVFPFNKSMI +EYLEATGRGKIADFAKLYHKDLLSADKDAEYDEVVEIDLNTLEPYINGPFTPDLATPVSK +MKEVAVANNWPLDVRVGLIGSCTNSSYEDMSRSASIVKDAAAHGLKSKTIFTVTPGSEQI +RATIERDGQLETFKEFGGIVLANACGPCIGQWDRRDIKKGDKNTIVSSYNRNFTSRNDGN +PQTHAFVASPELVTAFAIAGDLRFNPLTDKLKDKDGNEFMLKPPHGDGLPQRGYDAGENT +YQAPPADRSTVEVKVSPTSDRLQLLKPFKPWDGKDAKDMPILIKAVGKTTTDHISMAGPW +LKYRGHLENISNNYMIGAINAENKKANCVKNVYTGEYKGVPDTARDYRDQGIKWVVIGDE +NFGEGSSREHAALEPRFLGGFAIITKSFARIHETNLKKQGLLPLNFKNPADYDKINPDDR +IDILGLAELAPGKPVTMRVHPKNGKPWDAVLTHTFNDEQIEWFKYGSALNKIKADEKK +>sp|P13711|ACOX_YEAST Acyl-coenzyme A oxidase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=POX1 PE=1 SV=2 +MTRRTTINPDSVVLNPQKFIQKERADSKIKVDQVNTFLESSPERRTLTHALIDQIVNDPI +LKTDTDYYDAKKMQEREITAKKIARLASYMEHDIKTVRKHFRDTDLMKELQANDPDKASP +LTNKDLFIFDKRLSLVANIDPQLGTRVGVHLGLFGNCIKGNGTDEQIRYWLQERGATLMK +GIYGCFAMTELGHGSNVAQLQTRAVYDKQNDTFVIDTPDLTATKWWIGGAAHSATHAAVY +ARLIVEGKDYGVKTFVVPLRDPSTFQLLAGVSIGDIGAKMGRDGIDNGWIQFRNVVIPRE +FMLSRFTKVVRSPDGSVTVKTEPQLDQISGYSALLSGRVNMVMDSFRFGSKFATIAVRYA +VGRQQFAPRKGLSETQLIDYPLHQYRVLPQLCVPYLVSPVAFKLMDNYYSTLDELYNASS +SAYKAALVTVSKKLKNLFIDSASLKATNTWLIATLIDELRQTCGGHGYSQYNGFGKGYDD +WVVQCTWEGDNNVLSLTSAKSILKKFIDSATKGRFDNTLDVDSFSYLKPQYIGSVVSGEI +KSGLKELGDYTEIWSITLIKLLAHIGTLVEKSRSIDSVSKLLVLVSKFHALRCMLKTYYD +KLNSRDSHISDEITKESMWNVYKLFSLYFIDKHSGEFQQFKIFTPDQISKVVQPQLLALL +PIVRKDCIGLTDSFELPDAMLNSPIGYFDGDIYHNYFNEVCRNNPVEADGAGKPSYHALL +SSMLGRGFEFDQKLGGAANAEILSKINK +>sp|P32463|ACPM_YEAST Acyl carrier protein, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACP1 PE=1 SV=1 +MFRSVCRISSRVAPSAYRTIMGRSVMSNTILAQRFYSANLSKDQVSQRVIDVIKAFDKNS +PNIANKQISSDTQFHKDLGLDSLDTVELLVAIEEEFDIEIPDKVADELRSVGETVDYIAS +NPDAN +>sp|Q01574|ACS1_YEAST Acetyl-coenzyme A synthetase 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACS1 PE=1 SV=2 +MSPSAVQSSKLEEQSSEIDKLKAKMSQSAATAQQKKEHEYEHLTSVKIVPQRPISDRLQP +AIATHYSPHLDGLQDYQRLHKESIEDPAKFFGSKATQFLNWSKPFDKVFIPDPKTGRPSF +QNNAWFLNGQLNACYNCVDRHALKTPNKKAIIFEGDEPGQGYSITYKELLEEVCQVAQVL +TYSMGVRKGDTVAVYMPMVPEAIITLLAISRIGAIHSVVFAGFSSNSLRDRINDGDSKVV +ITTDESNRGGKVIETKRIVDDALRETPGVRHVLVYRKTNNPSVAFHAPRDLDWATEKKKY +KTYYPCTPVDSEDPLFLLYTSGSTGAPKGVQHSTAGYLLGALLTMRYTFDTHQEDVFFTA +GDIGWITGHTYVVYGPLLYGCATLVFEGTPAYPNYSRYWDIIDEHKVTQFYVAPTALRLL +KRAGDSYIENHSLKSLRCLGSVGEPIAAEVWEWYSEKIGKNEIPIVDTYWQTESGSHLVT +PLAGGVTPMKPGSASFPFFGIDAVVLDPNTGEELNTSHAEGVLAVKAAWPSFARTIWKNH +DRYLDTYLNPYPGYYFTGDGAAKDKDGYIWILGRVDDVVNVSGHRLSTAEIEAAIIEDPI +VAECAVVGFNDDLTGQAVAAFVVLKNKSSWSTATDDELQDIKKHLVFTVRKDIGPFAAPK +LIILVDDLPKTRSGKIMRRILRKILAGESDQLGDVSTLSNPGIVRHLIDSVKL +>sp|P52910|ACS2_YEAST Acetyl-coenzyme A synthetase 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACS2 PE=1 SV=1 +MTIKEHKVVYEAHNVKALKAPQHFYNSQPGKGYVTDMQHYQEMYQQSINEPEKFFDKMAK +EYLHWDAPYTKVQSGSLNNGDVAWFLNGKLNASYNCVDRHAFANPDKPALIYEADDESDN +KIITFGELLRKVSQIAGVLKSWGVKKGDTVAIYLPMIPEAVIAMLAVARIGAIHSVVFAG +FSAGSLKDRVVDANSKVVITCDEGKRGGKTINTKKIVDEGLNGVDLVSRILVFQRTGTEG +IPMKAGRDYWWHEEAAKQRTYLPPVSCDAEDPLFLLYTSGSTGSPKGVVHTTGGYLLGAA +LTTRYVFDIHPEDVLFTAGDVGWITGHTYALYGPLTLGTASIIFESTPAYPDYGRYWRII +QRHKATHFYVAPTALRLIKRVGEAEIAKYDTSSLRVLGSVGEPISPDLWEWYHEKVGNKN +CVICDTMWQTESGSHLIAPLAGAVPTKPGSATVPFFGINACIIDPVTGVELEGNDVEGVL +AVKSPWPSMARSVWNHHDRYMDTYLKPYPGHYFTGDGAGRDHDGYYWIRGRVDDVVNVSG +HRLSTSEIEASISNHENVSEAAVVGIPDELTGQTVVAYVSLKDGYLQNNATEGDAEHITP +DNLRRELILQVRGEIGPFASPKTIILVRDLPRTRSGKIMRRVLRKVASNEAEQLGDLTTL +ANPEVVPAIISAVENQFFSQKKK +>sp|P60010|ACT_YEAST Actin OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ACT1 PE=1 SV=1 +MDSEVAALVIDNGSGMCKAGFAGDDAPRAVFPSIVGRPRHQGIMVGMGQKDSYVGDEAQS +KRGILTLRYPIEHGIVTNWDDMEKIWHHTFYNELRVAPEEHPVLLTEAPMNPKSNREKMT +QIMFETFNVPAFYVSIQAVLSLYSSGRTTGIVLDSGDGVTHVVPIYAGFSLPHAILRIDL +AGRDLTDYLMKILSERGYSFSTTAEREIVRDIKEKLCYVALDFEQEMQTAAQSSSIEKSY +ELPDGQVITIGNERFRAPEALFHPSVLGLESAGIDQTTYNSIMKCDVDVRKELYGNIVMS +GGTTMFPGIAERMQKEITALAPSSMKVKIIAPPERKYSVWIGGSILASLTTFQQMWISKQ +EYDESGPSIVHHKCF +>sp|Q02336|ADA2_YEAST Transcriptional adapter 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADA2 PE=1 SV=1 +MSNKFHCDVCSADCTNRVRVSCAICPEYDLCVPCFSQGSYTGKHRPYHDYRIIETNSYPI +LCPDWGADEELQLIKGAQTLGLGNWQDIADHIGSRGKEEVKEHYLKYYLESKYYPIPDIT +QNIHVPQDEFLEQRRHRIESFRERPLEPPRKPMASVPSCHEVQGFMPGRLEFETEFENEA +EGPVKDMVFEPDDQPLDIELKFAILDIYNSRLTTRAEKKRLLFENHLMDYRKLQAIDKKR +SKEAKELYNRIKPFARVMTAQDFEEFSKDILEELHCRARIQQLQEWRSNGLTTLEAGLKY +ERDKQARISSFEKFGASTAASLSEGNSRYRSNSAHRSNAEYSQNYSENGGRKKNMTISDI +QHAPDYALLSNDEQQLCIQLKILPKPYLVLKEVMFRELLKTGGNLSKSACRELLNIDPIK +ANRIYDFFQSQNWM +>sp|Q03233|ADD37_YEAST Alpha1-proteinase inhibitor-degradation deficient protein 37 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADD37 PE=1 SV=1 +MAIKPTKSFQNCLEAEVPGYNDCPTVLFSIDPNSGPRSKSKQRTKSKRCVSGRLATEVLD +LYGNTKTATTPPPVLRRPSVTAAQQESACEGVLVKDQGDRQLQPILCSKEELVAKINDLC +VCGSKLSSKELEFYKKKLDSNITKILQNEHTKTVLSQIFNEKDKNMAVKTIKHWMVTDTT +ISNWCPAFLKIFENAMPN +>sp|Q2V2Q1|ADF1_YEAST Antisense of depressing factor protein 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADF1 PE=3 SV=4 +MGKCSMKKKGVGKNVGVGKKVQKKRSISTAERKRTKLQVEKLNKSSETMIPTLLREASTQ +EPAKLKAETTLKAEELIKDQEKDSKVREQIRTEKSKTNDSMLKQIEMISGFSL +>sp|P53909|ADE_YEAST Adenine deaminase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAH1 PE=1 SV=1 +MVSVEFLQELPKCEHHLHLEGTLEPDLLFPLAKRNDIILPEGFPKSVEELNEKYKKFRDL +QDFLDYYYIGTNVLISEQDFFDLAWAYFKKVHKQGLVHAEVFYDPQSHTSRGISIETVTK +GFQRACDKAFSEFGITSKLIMCLLRHIEPEECLKTIEEATPFIKDGTISALGLDSAEKPF +PPHLFVECYGKAASLNKDLKLTAHAGEEGPAQFVSDALDLLQVTRIDHGINSQYDEELLD +RLSRDQTMLTICPLSNVKLQVVQSVSELPLQKFLDRDVPFSLNSDDPAYFGGYILDVYTQ +VSKDFPHWDHETWGRIAKNAIKGSWCDDKRKNGLLSRVDEVVTKYSH +>sp|P00330|ADH1_YEAST Alcohol dehydrogenase 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADH1 PE=1 SV=5 +MSIPETQKGVIFYESHGKLEYKDIPVPKPKANELLINVKYSGVCHTDLHAWHGDWPLPVK +LPLVGGHEGAGVVVGMGENVKGWKIGDYAGIKWLNGSCMACEYCELGNESNCPHADLSGY +THDGSFQQYATADAVQAAHIPQGTDLAQVAPILCAGITVYKALKSANLMAGHWVAISGAA +GGLGSLAVQYAKAMGYRVLGIDGGEGKEELFRSIGGEVFIDFTKEKDIVGAVLKATDGGA +HGVINVSVSEAAIEASTRYVRANGTTVLVGMPAGAKCCSDVFNQVVKSISIVGSYVGNRA +DTREALDFFARGLVKSPIKVVGLSTLPEIYEKMEKGQIVGRYVVDTSK +>sp|P00331|ADH2_YEAST Alcohol dehydrogenase 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADH2 PE=1 SV=3 +MSIPETQKAIIFYESNGKLEHKDIPVPKPKPNELLINVKYSGVCHTDLHAWHGDWPLPTK +LPLVGGHEGAGVVVGMGENVKGWKIGDYAGIKWLNGSCMACEYCELGNESNCPHADLSGY +THDGSFQEYATADAVQAAHIPQGTDLAEVAPILCAGITVYKALKSANLRAGHWAAISGAA +GGLGSLAVQYAKAMGYRVLGIDGGPGKEELFTSLGGEVFIDFTKEKDIVSAVVKATNGGA +HGIINVSVSEAAIEASTRYCRANGTVVLVGLPAGAKCSSDVFNHVVKSISIVGSYVGNRA +DTREALDFFARGLVKSPIKVVGLSSLPEIYEKMEKGQIAGRYVVDTSK +>sp|P07246|ADH3_YEAST Alcohol dehydrogenase 3, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADH3 PE=1 SV=2 +MLRTSTLFTRRVQPSLFSRNILRLQSTAAIPKTQKGVIFYENKGKLHYKDIPVPEPKPNE +ILINVKYSGVCHTDLHAWHGDWPLPVKLPLVGGHEGAGVVVKLGSNVKGWKVGDLAGIKW +LNGSCMTCEFCESGHESNCPDADLSGYTHDGSFQQFATADAIQAAKIQQGTDLAEVAPIL +CAGVTVYKALKEADLKAGDWVAISGAAGGLGSLAVQYATAMGYRVLGIDAGEEKEKLFKK +LGGEVFIDFTKTKNMVSDIQEATKGGPHGVINVSVSEAAISLSTEYVRPCGTVVLVGLPA +NAYVKSEVFSHVVKSINIKGSYVGNRADTREALDFFSRGLIKSPIKIVGLSELPKVYDLM +EKGKILGRYVVDTSK +>sp|P10127|ADH4_YEAST Alcohol dehydrogenase 4 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADH4 PE=1 SV=3 +MSSVTGFYIPPISFFGEGALEETADYIKNKDYKKALIVTDPGIAAIGLSGRVQKMLEERD +LNVAIYDKTQPNPNIANVTAGLKVLKEQNSEIVVSIGGGSAHDNAKAIALLATNGGEIGD +YEGVNQSKKAALPLFAINTTAGTASEMTRFTIISNEEKKIKMAIIDNNVTPAVAVNDPST +MFGLPPALTAATGLDALTHCIEAYVSTASNPITDACALKGIDLINESLVAAYKDGKDKKA +RTDMCYAEYLAGMAFNNASLGYVHALAHQLGGFYHLPHGVCNAVLLPHVQEANMQCPKAK +KRLGEIALHFGASQEDPEETIKALHVLNRTMNIPRNLKELGVKTEDFEILAEHAMHDACH +LTNPVQFTKEQVVAIIKKAYEY +>sp|P38113|ADH5_YEAST Alcohol dehydrogenase 5 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADH5 PE=1 SV=1 +MPSQVIPEKQKAIVFYETDGKLEYKDVTVPEPKPNEILVHVKYSGVCHSDLHAWHGDWPF +QLKFPLIGGHEGAGVVVKLGSNVKGWKVGDFAGIKWLNGTCMSCEYCEVGNESQCPYLDG +TGFTHDGTFQEYATADAVQAAHIPPNVNLAEVAPILCAGITVYKALKRANVIPGQWVTIS +GACGGLGSLAIQYALAMGYRVIGIDGGNAKRKLFEQLGGEIFIDFTEEKDIVGAIIKATN +GGSHGVINVSVSEAAIEASTRYCRPNGTVVLVGMPAHAYCNSDVFNQVVKSISIVGSCVG +NRADTREALDFFARGLIKSPIHLAGLSDVPEIFAKMEKGEIVGRYVVETSK +>sp|Q04894|ADH6_YEAST NADP-dependent alcohol dehydrogenase 6 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADH6 PE=1 SV=1 +MSYPEKFEGIAIQSHEDWKNPKKTKYDPKPFYDHDIDIKIEACGVCGSDIHCAAGHWGNM +KMPLVVGHEIVGKVVKLGPKSNSGLKVGQRVGVGAQVFSCLECDRCKNDNEPYCTKFVTT +YSQPYEDGYVSQGGYANYVRVHEHFVVPIPENIPSHLAAPLLCGGLTVYSPLVRNGCGPG +KKVGIVGLGGIGSMGTLISKAMGAETYVISRSSRKREDAMKMGADHYIATLEEGDWGEKY +FDTFDLIVVCASSLTDIDFNIMPKAMKVGGRIVSISIPEQHEMLSLKPYGLKAVSISYSA +LGSIKELNQLLKLVSEKDIKIWVETLPVGEAGVHEAFERMEKGDVRYRFTLVGYDKEFSD +>sp|P25377|ADH7_YEAST NADP-dependent alcohol dehydrogenase 7 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADH7 PE=1 SV=1 +MLYPEKFQGIGISNAKDWKHPKLVSFDPKPFGDHDVDVEIEACGICGSDFHIAVGNWGPV +PENQILGHEIIGRVVKVGSKCHTGVKIGDRVGVGAQALACFECERCKSDNEQYCTNDHVL +TMWTPYKDGYISQGGFASHVRLHEHFAIQIPENIPSPLAAPLLCGGITVFSPLLRNGCGP +GKRVGIVGIGGIGHMGILLAKAMGAEVYAFSRGHSKREDSMKLGADHYIAMLEDKGWTEQ +YSNALDLLVVCSSSLSKVNFDSIVKIMKIGGSIVSIAAPEVNEKLVLKPLGLMGVSISSS +AIGSRKEIEQLLKLVSEKNVKIWVEKLPISEEGVSHAFTRMESGDVKYRFTLVDYDKKFH +K +>sp|P47143|ADK_YEAST Adenosine kinase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADO1 PE=1 SV=1 +MTAPLVVLGNPLLDFQADVTAEYLAKYSLKENDAILVDAKSGDAKMAIFDELLQMPETKL +VAGGAAQNTARGAAYVLGAGQVVYFGSVGKDKFSERLLNENEKAGVKSMYQVQNDIGTGK +CAALITGHNRSLVTDLGAANFFTPDHLDKHWDLVEAAKLFYIGGFHLTVSPDAIVKLGQH +AKENSKPFVLNFSAPFIPHVFKDALARVLPYATVIIANESEAEAFCDAFQLDCANTDLEA +IAQRIVKDSPVEKTVIFTHGVEPTVVVSSKGTSTYPVKPLDSSKIVDTNGAGDAFAGGFM +AGLTKGEDLETSIDMGQWLAALSIQEVGPSYPSEKISYSK +>sp|P25371|ADP1_YEAST Probable ATP-dependent permease OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADP1 PE=1 SV=2 +MGSHRRYLYYSILSFLLLSCSVVLAKQDKTPFFEGTSSKNSRLTAQDKGNDTCPPCFNCM +LPIFECKQFSECNSYTGRCECIEGFAGDDCSLPLCGGLSPDESGNKDRPIRAQNDTCHCD +NGWGGINCDVCQEDFVCDAFMPDPSIKGTCYKNGMIVDKVFSGCNVTNEKILQILNGKIP +QITFACDKPNQECNFQFWIDQLESFYCGLSDCAFEYDLEQNTSHYKCNDVQCKCVPDTVL +CGAKGSIDISDFLTETIKGPGDFSCDLETRQCKFSEPSMNDLILTVFGDPYITLKCESGE +CVHYSEIPGYKSPSKDPTVSWQGKLVLALTAVMVLALFTFATFYISKSPLFRNGLGSSKS +PIRLPDEDAVNNFLQNEDDTLATLSFENITYSVPSINSDGVEETVLNEISGIVKPGQILA +IMGGSGAGKTTLLDILAMKRKTGHVSGSIKVNGISMDRKSFSKIIGFVDQDDFLLPTLTV +FETVLNSALLRLPKALSFEAKKARVYKVLEELRIIDIKDRIIGNEFDRGISGGEKRRVSI +ACELVTSPLVLFLDEPTSGLDASNANNVIECLVRLSSDYNRTLVLSIHQPRSNIFYLFDK +LVLLSKGEMVYSGNAKKVSEFLRNEGYICPDNYNIADYLIDITFEAGPQGKRRRIRNISD +LEAGTDTNDIDNTIHQTTFTSSDGTTQREWAHLAAHRDEIRSLLRDEEDVEGTDGRRGAT +EIDLNTKLLHDKYKDSVYYAELSQEIEEVLSEGDEESNVLNGDLPTGQQSAGFLQQLSIL +NSRSFKNMYRNPKLLLGNYLLTILLSLFLGTLYYNVSNDISGFQNRMGLFFFILTYFGFV +TFTGLSSFALERIIFIKERSNNYYSPLAYYISKIMSEVVPLRVVPPILLSLIVYPMTGLN +MKDNAFFKCIGILILFNLGISLEILTIGIIFEDLNNSIILSVLVLLGSLLFSGLFINTKN +ITNVAFKYLKNFSVFYYAYESLLINEVKTLMLKERKYGLNIEVPGATILSTFGFVVQNLV +FDIKILALFNVVFLIMGYLALKWIVVEQK +>sp|Q01976|ADPP_YEAST ADP-ribose pyrophosphatase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=YSA1 PE=1 SV=2 +MFLRNVRVISLNSRRLFRTMSTVKGKPEDAKIIEARHVKETSDCKWIGLQKIIYKDPNGK +EREWDSAVRTTRSSGGVDGIGILTILKYKDGKPDEILLQKQFRPPVEGVCIEMPAGLIDA +GEDIDTAALRELKEETGYSGKIISKSPTVFNDPGFTNTNLCLVTVEVDMSLPENQKPVTQ +LEDNEFIECFSVELHKFPDEMVKLDQQGYKLDARVQNVAQGILMAKQYHIK +>sp|P07248|ADR1_YEAST Regulatory protein ADR1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADR1 PE=1 SV=2 +MANVEKPNDCSGFPVVDLNSCFSNGFNNEKQEIEMETDDSPILLMSSSASRENSNTFSVI +QRTPDGKIITTNNNMNSKINKQLDKLPENLRLNGRTPSGKLRSFVCEVCTRAFARQEHLK +RHYRSHTNEKPYPCGLCNRCFTRRDLLIRHAQKIHSGNLGETISHTKKVSRTITKARKNS +ASSVKFQTPTYGTPDNGNFLNRTTANTRRKASPEANVKRKYLKKLTRRASFSAQSASSYA +LPDQSSLEQHPKDRVKFSTPELVPLDLKNPELDSSFDLNMNLDLNLNLDSNFNIALNRSD +SSGSTMNLDYKLPESANNYTYSSGSPTRAYVGANTNSKNASFNDADLLSSSYWIKAYNDH +LFSVSESDETSPMNSELNDTKLIVPDFKSTIHHLKDSRSSSWTVAIDNNSNNNKVSDNQP +DFVDFQELLDNDTLGNDLLETTAVLKEFELLHDDSVSATATSNEIDLSHLNLSNSPISPH +KLIYKNKEGTNDDMLISFGLDHPSNREDDLDKLCNMTRDVQAIFSQYLKGEESKRSLEDF +LSTSNRKEKPDSGNYTFYGLDCLTLSKISRALPASTVNNNQPSHSIESKLFNEPMRNMCI +KVLRYYEKFSHDSSESVMDSNPNLLSKELLMPAVSELNEYLDLFKNNFLPHFPIIHPSLL +DLDLDSLQRYTNEDGYDDAENAQLFDRLSQGTDKEYDYEHYQILSISKIVCLPLFMATFG +SLHKFGYKSQTIELYEMSRRILHSFLETKRRCRSTTVNDSYQNIWLMQSLILSFMFALVA +DYLEKIDSSLMKRQLSALCSTIRSNCLPTISANSEKSINNNNEPLTFGSPLQYIIFESKI +RCTLMAYDFCQFLKCFFHIKFDLSIKEKDVETIYIPDNESKWASESIICNGHVVQKQNFY +DFRNFYYSFTYGHLHSIPEFLGSSMIYYEYDLRKGTKSHVFLDRIDTKRLERSLDTSSYG +NDNMAATNKNIAILIDDTIILKNNLMSMRFIKQIDRSFTEKVRKGQIAKIYDSFLNSVRL +NFLKNYSVEVLCEFLVALNFSIRNISSLYVEEESDCSQRMNSPELPRIHLNNQALSVFNL +QGYYYCFILIIKFLLDFEATPNFKLLRIFIELRSLANSILLPTLSRLYPQEFSGFPDVVF +TQQFINKDNGMLVPGLSANEHHNGASAAVKTKLAKKINVEGLAMFINEILVNSFNDTSFL +NMEDPIRNEFSFDNGDRAVTDLPRSAHFLSDTGLEGINFSGLNDSHQTVSTLNLLRYGEN +HSSKHKNGGKGQGFAEKYQLSLKYVTIAKLFFTNVKENYIHCHMLDKMASDFHTLENHLK +GNS +>sp|Q12184|ADRX_YEAST Adrenodoxin homolog, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=YAH1 PE=1 SV=1 +MLKIVTRAGHTARISNIAAHLLRTSPSLLTRTTTTTRFLPFSTSSFLNHGHLKKPKPGEE +LKITFILKDGSQKTYEVCEGETILDIAQGHNLDMEGACGGSCACSTCHVIVDPDYYDALP +EPEDDENDMLDLAYGLTETSRLGCQIKMSKDIDGIRVALPQMTRNVNNNDFS +>sp|P48360|ADRO_YEAST Probable NADPH:adrenodoxin oxidoreductase, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ARH1 PE=1 SV=1 +MSFVQIRHISSQINRKTVSIVGSGPSGFYTAYHLLKKSPIPLNVTIWEKLPVPFGLSRYG +VAPDHPEVKNCEETFTTCAEEFSSPTNQKHKFSFVGGITIGKEILLKELLDNQDAVILSY +GCTGDRKLNIPGELGTKGVFSSREFVNWYNGHPDFAKDKRFTDFDWSKVSKVGIIGNGNV +ALDITRVLISNQIDEIWENTDISSLALNLLRRAPVKDVKLIARRDFVHSKFTNKELRELW +ELEKYGIRGRIDPKFFQKEMFDPSKYDRAFNRRVEMCSEYLKPFNERSKKNYKKAPPPSS +GYDKFWELDYLKTPLKINRDDFGAINSLSLCNNRLNEDNSLQPLKDVNNIMTYKVDLLIT +SLGYAGVPMPEFSKLSIGFDKDHIANKQGRVLTSSGEIFPHLYASGWIRKGSQGVIASTM +QDAFEVGDRVIQDLVVSGALSLENSIDLSNIKHTTWKDWERINKKELLRGKKEHKTRSKF +LTFEELWNGVEGI +>sp|P04710|ADT1_YEAST ADP,ATP carrier protein 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAC1 PE=1 SV=1 +MSHTETQTQQSHFGVDFLMGGVSAAIAKTGAAPIERVKLLMQNQEEMLKQGSLDTRYKGI +LDCFKRTATHEGIVSFWRGNTANVLRYFPTQALNFAFKDKIKSLLSYDRERDGYAKWFAG +NLFSGGAAGGLSLLFVYSLDYARTRLAADARGSKSTSQRQFNGLLDVYKKTLKTDGLLGL +YRGFVPSVLGIIVYRGLYFGLYDSFKPVLLTGALEGSFVASFLLGWVITMGASTASYPLD +TVRRRMMMTSGQTIKYDGALDCLRKIVQKEGAYSLFKGCGANIFRGVAAAGVISLYDQLQ +LIMFGKKFK +>sp|P18239|ADT2_YEAST ADP,ATP carrier protein 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=PET9 PE=1 SV=2 +MSSNAQVKTPLPPAPAPKKESNFLIDFLMGGVSAAVAKTAASPIERVKLLIQNQDEMLKQ +GTLDRKYAGILDCFKRTATQEGVISFWRGNTANVIRYFPTQALNFAFKDKIKAMFGFKKE +EGYAKWFAGNLASGGAAGALSLLFVYSLDYARTRLAADSKSSKKGGARQFNGLIDVYKKT +LKSDGVAGLYRGFLPSVVGIVVYRGLYFGMYDSLKPLLLTGSLEGSFLASFLLGWVVTTG +ASTCSYPLDTVRRRMMMTSGQAVKYDGAFDCLRKIVAAEGVGSLFKGCGANILRGVAGAG +VISMYDQLQMILFGKKFK +>sp|P18238|ADT3_YEAST ADP,ATP carrier protein 3 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AAC3 PE=1 SV=1 +MSSDAKQQETNFAINFLMGGVSAAIAKTAASPIERVKILIQNQDEMIKQGTLDKKYSGIV +DCFKRTAKQEGLISFWRGNTANVIRYFPTQALNFAFKDKIKLMFGFKKEEGYGKWFAGNL +ASGGAAGALSLLFVYSLDFARTRLAADAKSSKKGGARQFNGLTDVYKKTLKSDGIAGLYR +GFMPSVVGIVVYRGLYFGMFDSLKPLVLTGSLDGSFLASFLLGWVVTTGASTCSYPLDTV +RRRMMMTSGQAVKYNGAIDCLKKIVASEGVGSLFKGCGANILRSVAGAGVISMYDQLQMI +LFGKKFK +>sp|P25613|ADY2_YEAST Accumulation of dyads protein 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADY2 PE=1 SV=1 +MSDKEQTSGNTDLENAPAGYYSSHDNDVNGVAEDERPSHDSLGKIYTGGDNNEYIYIGRQ +KFLKSDLYQAFGGTLNPGLAPAPVHKFANPAPLGLSAFALTTFVLSMFNARAQGITVPNV +VVGCAMFYGGLVQLIAGIWEIALENTFGGTALCSYGGFWLSFAAIYIPWFGILEAYEDNE +SDLNNALGFYLLGWAIFTFGLTVCTMKSTVMFFLLFFLLALTFLLLSIGHFANRLGVTRA +GGVLGVVVAFIAWYNAYAGVATKQNSYVLARPFPLPSTERVIF +>sp|Q05955|ADY4_YEAST Accumulates dyads protein 4 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADY4 PE=1 SV=1 +MNKDVDYQTFKKSLRKEFKKAVKTILNLQAYNGDLIRDFLALYIPYHVVFYNLSIMKKGS +PLRIQTNNLLKEALAKILNFNLAMGPKHIIKIMKKDKADPETMNKLKLVLYIKLFQGVFG +HVDKNYNLAFQSFRWCLQFIAYSKRTRLFASIADEQIGAFYELCELFISMLCCHCFLIDL +KENEALVGNNLKNFIKRQNPNYSHGFDLNEETKSLQWHWSLDEVDVIEALYCVAFDAMDK +ITLKFSKVNENFVFSQFFQYCAEIEEMLAILRGKIWECECDVFGPRIGLLVDSNHMNETI +QKNILSITFKLKNDPQIICCLNKILEGLLLSSGVQFKVIQFFYVLKLYYMQDNEYTFEAS +SEMDKLTIECLCIIENIIDACDNPDEVTDYQLPKVLLTAMEGKLLVAEKISEDNDCSESL +DDYHPRTYQFRHPRIIIDKMKTKLKQKLRFDSPKDPETDDHWIEYWKYCYQDNIGNLPDI +LSRIYQTFTDPSN +>sp|Q07732|ADY3_YEAST Accumulates dyads protein 3 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ADY3 PE=1 SV=2 +MNHWLAFLNKPESLKEQNSDCDQQGEMRHVTDGTLTKSPESKPFRERRSQTWIDSEVPTS +TEKSNVQESISSDIISKLSNRRSRRNRSESWAGSEASSPSGNISTLENATEKNTLKSPNK +FLQRGGLPTVGIGSQALSPAGKPSTLGNVSPGKFTTYKVHNSIEVNRFSSTPTKLLTNPH +KVAAISNDEHYVVSNESLEENIEVAHLENVFRSSKTPDEEQSEYMKLGEIRLSSSSYGGS +ISKENSLPKVLDELQSQNEEIKALRQKLEEKDDRIQELEELNSMNDAKLQRIEDLQKEFH +NERKAASKRLNIVQDRFRKEIKKIREEKITDFQNKNASKKEKNEVTSAKTKCKAFSQRNI +LVSELYRKQKQILNLQQENDKFLKDINESNNSIVKLRSEVEILKSNLQLSQDENKKLHDN +GSFYEKRLNDVYSYMQNLSLFEKDLGKFILEEMKCGHSPSMFQNGFAKLYPDFQDIKNLE +NMEQYKQLKGKIELLEKNDRIRLEKIISVFKLINERLHFMQQQHSHKIKYLQKEALTKEQ +QFRLEKRRWHDILNLKEENFQKLKSELKEKLILSEKIQKNAEDKLNDYMNEHQEIVEKLQ +NQALIASRWSTQIQESENTHKKITDELAGKQSEILKLEETILSLKEDVFQEKLNLKKLYG +DPSTELNFETVGKSFPHITKEKYDSLGLDILTDLTYVQSQNLIKNLLIVLDIPLKTFLKI +VPTIVIQLRCELTLLTKFANDLNLKVFGKQLDFKSRRKVAMNEFLNNHDIAEVKHPLEYD +LQALFKYFFS +>sp|P38872|ADY1_YEAST Prospore formation at selected spindle poles protein 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=PFS1 PE=1 SV=1 +MNQGYTQLSAPELKETKTSKLNKMNNFRSSPIAEIINKIPPDCGKIQNTTFPEFNPALRR +RQHEQWPAYEKPIRVTDSMSPQLSSINCLPNLYPHGTLPLPNPYLSYLNHIEKVNCQDVK +FSNWSVLHNSNNGFEIPTYFSPRTTQNMPCSEKVESWLERLPIFVGFDGYLFTNCFDYEY +MLDWEETEFTFEKTSCMETDYSKALTDTDIIYIQEKKIEALIRNQYLKEYEFSQKDF +>sp|P32493|AEP1_YEAST ATPase expression protein 1, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AEP1 PE=1 SV=2 +MITTVQEISKWRNLCFIRMQSRKWYPVLKKTPLVADGRKIIKHADKVPHPEEIIHPFYQP +TAIEQFTACATEYNPSLLDGKKIAPSLIKHPVSLKTILVDSKLKFDDIRGVNKWLMEFVA +RRQHQRNIVLTPASKSVRSFHVLHLSSTDIAKLRGLENILSEIENTNDLQSRVESVNNEL +QNIFDRDSKQTRLFCENILAYLIKNYGNSTEKLILLINVTEMQLYSRLDQMKAMNIILYN +ILCKVEANENPPYSPTLVTALENLLAAINNRFFPGRCENSLHPIVIEQLLSYFIKTGNLN +ESKNFLGHLIKKGILPEATIINRYLEAIDVHFDKSTKIFDIRSKFAFIADLAPIIENYGT +IDLFKFLIPMCRHFDELCSLLNIIRKSNNAKRAVDSTLPIFIKKVLTFTKDPMINSGNLS +TVFNIVSPIYGQNVPSEFVEKFILSFALQGNYTMMAHMIDTYKIKLSHKYQLQIIRALKN +SERNHALKNTGAVGYNKEFKKYFIEKYLNCTEREALRP +>sp|Q12089|AEP3_YEAST ATPase expression protein 3 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AEP3 PE=1 SV=1 +MNTLRCLTQALSKSGREAPKLYQKVIFPGLFREGIPIANVKKVDEKIIDSPTSTSVNGEA +KKIVRHGVKYEREQVKEYLSSLPTLTLSRKQIRDDYDEERAKRMYMFSKQTNSSNKFQKL +LTAKSQEFTRELLTLLIDCTSNEKNSGPERFTRKFLKFSNDEIPPLPDFSKNPQLFENYI +GILSHTKFNFRSSSKLNGIVRKMLRHLLHPTNKTTLPLRSAQVYNDSIYFFSEHFDFASC +REIFAQMKAEGTKPNTITFNLLLRNVVKNSHIRKTKHPDDEVLFYLRSMRNHGVFADVIT +WTTCYNFLRDEVSRQLYIVQMGEHLGNFNVNFVYTVLRNGDYRAEDCLKVLAANSLPISR +KTFYLCIERLLNEEQLETASKLLDYGFQHLKSNFKLDSEAMNHFMRVFANKGRSDLAFLC +YNTCRKIYKIKPDSQTFEMLFKALVRNGNTKNFGAVLQYIKDLKVSEGFGLRTSYWRTKA +DSIFKFGSPNTLSEKSIEKARKLLGNLIASEGEFSWKIWKESDSSQKKILRFLGCIPTTL +RCTNTAQDHQKPTNLPSNISQKKREYRNRVKAIATKAALEKRMAYIKDNDVAFKKELVKR +RIVGEV +>sp|P22136|AEP2_YEAST ATPase expression protein 2, mitochondrial OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AEP2 PE=1 SV=3 +MWINRLVKHPSYSVLRFYTKRLCTVSVKSLREFGVLPNSTICHSVYPRRTYVMGRAVIND +ILIKKSYSTHTVCAIDRSKDENNGSAYDKFEAKGIPIDVHTLKRIISSSGMDESEFSKSI +SYLFAKTVDPEPKDVLSLEDLSFLLSKLYTQRFQIRRICRDINAKYSEFWFKLFSLYAEK +VDAKRNQVNLRNTKLDACEIFDANLMIKNFIELGQLGKAQKILSFILDRNPDILLSPKNA +DISTIVHFLQLRCGALAPYWKIPDNSEQKQGFLRKMVRLGAKNTSIRLSSTYKAMDHQTL +LKIADLALQEKKLLNSEDLLSTLIQSFGHLGQTQILERCIEHIWQISPQEFPSHVVIKHR +GCYPSSKILVSILVSFYFNDHDLHRGLSILDSFIKHYPDVKLDALFWRRLFQLSHFAWTP +ANDKKATSVVRCWHLMKQWYASKRLRPSVDYETLRQLYDIMKKTGNFPLGIDVLRSFKPG +IERTRAENAGKVNNIIIKYQKCIIKELVNRGRFSAVREFIDSYGFDRKMTKDLNIFCANR +MFLRSKKMKNKIENKKEREKVRLDSFDDDEDDGMIIGSLW +>sp|P53930|AF9_YEAST Protein AF-9 homolog OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=YAF9 PE=1 SV=1 +MAPTISKRIKTLSVSRPIIYGNTAKKMGSVKPPNAPAEHTHLWTIFVRGPQNEDISYFIK +KVVFKLHDTYPNPVRSIEAPPFELTETGWGEFDINIKVYFVEEANEKVLNFYHRLRLHPY +ANPVPNSDNGNEQNTTDHNSKDAEVSSVYFDEIVFNEPNEEFFKILMSRPGNLLPSNKTD +DCVYSKQLEQEEIDRIEIGIEKVDKEIDELKQKLENLVKQEAINGS +>sp|P32317|AFG1_YEAST Protein AFG1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AFG1 PE=1 SV=1 +MIALKPNAVRTFRQVQHCSFRICRYQSTKSNKCLTPLQEYDRLVKLGKLRDDTYQRGIIS +SLGDLYDSLVKYVPPVVKTPNAVDQVGGWLNGLKSVFSRGKPKNIGAYVDVSKIGNSIPR +GVYLYGDVGCGKTMLMDLFYTTIPNHLTKKRIHFHQFMQYVHKRSHEIVREQNLKELGDA +KGKEIDTVPFLAAEIANNSHVLCFDEFQVTDVADAMILRRLMTALLSDDYGVVLFATSNR +HPDELYINGVQRQSFIPCIELIKHRTKVIFLNSPTDYRKIPRPVSSVYYFPSDTSIKYAS +KECKTRRETHIKEWYNYFAQASHTDDSTDSHTVHKTFYDYPLTIWGREFKVPKCTPPRVA +QFTFKQLCGEPLAAGDYLTLAKNFEAFIVTDIPYLSIYVRDEVRRFITFLDAVYDSGGKL +ATTGAADFSSLFVEPEQILNDFELRPTTKEPDSVDTGMVDEMVEKHGFSKEIAKKSQMFA +LDEERFAFARALSRLSQMSSTDWVTKPTY +>sp|P32794|AFG2_YEAST ATPase family gene 2 protein OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AFG2 PE=1 SV=1 +MAPKSSSSGSKKKSSASSNSADAKASKFKLPAEFITRPHPSKDHGKETCTAYIHPNVLSS +LEINPGSFCTVGKIGENGILVIARAGDEEVHPVNVITLSTTIRSVGNLILGDRLELKKAQ +VQPPYATKVTVGSLQGYNILECMEEKVIQKLLDDSGVIMPGMIFQNLKTKAGDESIDVVI +TDASDDSLPDVSQLDLNMDDMYGGLDNLFYLSPPFIFRKGSTHITFSKETQANRKYNLPE +PLSYAAVGGLDKEIESLKSAIEIPLHQPTLFSSFGVSPPRGILLHGPPGTGKTMLLRVVA +NTSNAHVLTINGPSIVSKYLGETEAALRDIFNEARKYQPSIIFIDEIDSIAPNRANDDSG +EVESRVVATLLTLMDGMGAAGKVVVIAATNRPNSVDPALRRPGRFDQEVEIGIPDVDARF +DILTKQFSRMSSDRHVLDSEAIKYIASKTHGYVGADLTALCRESVMKTIQRGLGTDANID +KFSLKVTLKDVESAMVDIRPSAMREIFLEMPKVYWSDIGGQEELKTKMKEMIQLPLEASE +TFARLGISAPKGVLLYGPPGCSKTLTAKALATESGINFLAVKGPEIFNKYVGESERAIRE +IFRKARSAAPSIIFFDEIDALSPDRDGSSTSAANHVLTSLLNEIDGVEELKGVVIVAATN +RPDEIDAALLRPGRLDRHIYVGPPDVNARLEILKKCTKKFNTEESGVDLHELADRTEGYS +GAEVVLLCQEAGLAAIMEDLDVAKVELRHFEKAFKGIARGITPEMLSYYEEFALRSGSSS +>sp|Q99222|AFI1_YEAST ARF3-interacting protein 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AFI1 PE=1 SV=1 +MLRRELNNSISNRSIENESFPFERPNVSYIISAEFDNKLGPILKHQYPKDIPGFNQFSHE +QRNGNTSVSMNLASLMIPSSIERNPGKQDITVFTLYYNKFTQNYQLFPVPKDPRFSFNLH +HREQSDGSVTNSIYYDAENHQDAKNNRYTIVLEDDELECQEVQNNQKAIDNEPLFFINVA +NTVLDTTNDRGAVIKSIAIGTPLKTFFAFKNIIVLVLDLYMKAPTQAAATDILLDCFNML +NSIDLTLINDIHSKSSIQEVLHSIHDESIITKVFLDPDSTLKKLFCINGFDTKDKYGNIV +TFHDQLIQYHFTRFQPKTLPPFLLKIPLQFNMIRREPIYIENDYNELVLKFLDKFVPYLL +KAGQKVNAWKLVINSTKLSKEDLCAFILSLANITATYASDPQSYFKGNAALIFPYMDISL +VDGLRAYVASNSDFVGCFAIIGTANPIFRYQLDIWDYYYDVDEGVFYENNSPEKEKPDTV +AEVKIGPNPLRKIFNRPHFSTNAVNESQVNLGQKLFSLLIDEYHDSDTIMSVLRRLNVLQ +LENLLDALKRREIPPNIALKDEYIMFYKDFFIFPEFFDYFTLHSIELLSNLDNCLFSLGN +TCQLFSTEQIYSQLSQILDIVKELFRMVSVSRTNIEKFLNACLNYSPFKILPTAQLHGDN +ISRWSFESEVRQGFDNFNSYMGIEKDPHGVIVSAIDLFTQIYSFDILAFFLTFITKESGQ +DLPFTKSLSRRRTYLTRIAQSSSLRQFLQLSTRPNIRILGGNGQGTGNSNYPEFTNASSV +ISPKLRASPLLERRASKICYAITKLLYRLECHPIGMALLKKYLHNQLREAYLESKRHFIS +KKGDSTNTSSTIASSSFAGASVPLSSNESGMLNGLKQINEQQESTLETTQKED +>sp|P39925|AFG3_YEAST Mitochondrial respiratory chain complexes assembly protein AFG3 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AFG3 PE=1 SV=1 +MMMWQRYARGAPRSLTSLSFGKASRISTVKPVLRSRMPVHQRLQTLSGLATRNTIHRSTQ +IRSFHISWTRLNENRPNKEGEGKNNGNKDNNSNKEDGKDKRNEFGSLSEYFRSKEFANTM +FLTIGFTIIFTLLTPSSNNSGDDSNRVLTFQDFKTKYLEKGLVSKIYVVNKFLVEAELVN +TKQVVSFTIGSVDIFEEQMDQIQDLLNIPPRDRIPIKYIERSSPFTFLFPFLPTIILLGG +LYFITRKINSSPPNANGGGGGGLGGMFNVGKSRAKLFNKETDIKISFKNVAGCDEAKQEI +MEFVHFLKNPGKYTKLGAKIPRGAILSGPPGTGKTLLAKATAGEANVPFLSVSGSEFVEM +FVGVGASRVRDLFTQARSMAPSIIFIDEIDAIGKERGKGGALGGANDEREATLNQLLVEM +DGFTTSDQVVVLAGTNRPDVLDNALMRPGRFDRHIQIDSPDVNGRQQIYLVHLKRLNLDP +LLTDDMNNLSGKLATLTPGFTGADIANACNEAALIAARHNDPYITIHHFEQAIERVIAGL +EKKTRVLSKEEKRSVAYHEAGHAVCGWFLKYADPLLKVSIIPRGQGALGYAQYLPPDQYL +ISEEQFRHRMIMALGGRVSEELHFPSVTSGAHDDFKKVTQMANAMVTSLGMSPKIGYLSF +DQNDGNFKVNKPFSNKTARTIDLEVKSIVDDAHRACTELLTKNLDKVDLVAKELLRKEAI +TREDMIRLLGPRPFKERNEAFEKYLDPKSNTEPPEAPAATN +>sp|P33304|AFR1_YEAST Protein AFR1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AFR1 PE=1 SV=1 +MEGSYLSAQENQPIPERLIPRSNSTSNLFALSSTFSKLNVRNDADYNYSNPNKKRHIYSG +EIDCRSVTAARKFPVRSCSMTAAQQRKRTALFTVRERNSYHEGFNNDQDYVSQYQKPQYT +FGVYKELTPYQLQRSKMKRSFQFPNGEIYKPKLDGKCTHSLKKPELNSRDSSLFKFSEKK +GRNLSKDFVGPHNGTSVIHIPPNDTGYGVNSLELNTSVPSTIKSSVSSTSPISAVNTLTS +LPESQTDDDDGYENKTVTISYCFENTVNEKHGSHIEKLDLSTKEKTKPTTNSGLFDRKKK +TILGTEKYRCIKSQSKLKLGSVLKKLWRTSGNSNTKHGKKDTKRRRIPIDDMVTHSDGNS +EAENDIELMDANLDGIEFDDDETLMDTDSIFDDLLSKENDKYDLRRRQLEIRQKLHETSH +NDDGKVSFRDTEKHNVNEGLIDKTIIEEFSKLGEYIIDTRNQPPPRSSKRPSLDDNESAR +YFYNISTDLRQSLSGPISLPMHVGNDMVNRLRNDWEYIRFEDRRNSLPDSSFDKVETPPK +PIKKDVRFAKEVCLASTWSSNAYERANPEFIMNRHRLLWMMKVHPSMNSAMNEIKLELNS +YKKNEMVVHENSKCFTHYLI +>sp|Q08957|AFT2_YEAST Iron-regulated transcriptional activator AFT2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AFT2 PE=1 SV=1 +MKAKSMKSIISVPISVSKTGKMKLTASPDNLASMMSKDQNKLIHLDPVPSFEDRHEIKPW +LQKIFYPQGIDIVIERSDSSKVTFKCRSVRSKVGLNPKSKGSSSRSHACPFRIRAAYSVR +LQKWNVVVMNNIHSHELRFDLITKTDDYKKFKENLRQKNDEKAIKTFDELEYKASLNLPL +VTPIISCDCGLTKEIEAFNNIFLPLSNPPLTSKKNLLKTNKNSVSKIKSRQMDNSKPRPR +LKTKLDADLHDTGFLDNFKTRNSCVKIEKEDSLTNLNEIDFTNMFCNDNFIQNYNQGLME +LLTEPTPGPSSSSCILPSTPTRPLSQSKMDIALSESTTSSPNFMETDAPYGDEIIKVSKD +TKSNAPTADTDIATNLGKERNENFGMLNYNYEALLHFNDEHFNELNSIDPALISKY +>sp|P22149|AFT1_YEAST Iron-regulated transcriptional activator AFT1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AFT1 PE=1 SV=2 +MEGFNPADIEHASPINSSDSHSSSFVYALPKSASEYVVNHNEGRASASGNPAAVPSPIMT +LNLKSTHSLNIDQHVHTSTSPTETIGHIHHVEKLNQNNLIHLDPVPNFEDKSDIKPWLQK +IFYPQGIELVIERSDAFKVVFKCKAAKRGRNARRKRKDKPKGQDHEDEKSKINDDELEYA +SPSNATVTNGPQTSPDQTSSIKPKKKRCVSRFNNCPFRVRATYSLKRKRWSIVVMDNNHS +HQLKFNPDSEEYKKFKEKLRKDNDVDAIKKFDELEYRTLANLPIPTATIPCDCGLTNEIQ +SFNVVLPTNSNVTSSASSSTVSSISLDSSNASKRPCLPSVNNTGSINTNNVRKPKSQCKN +KDTLLKRTTMQNFLTTKSRLRKTGTPTSSQHSSTAFSGYIDDPFNLNEILPLPASDFKLN +TVTNLNEIDFTNIFTKSPHPHSGSTHPRQVFDQLDDCSSILFSPLTTNTNNEFEGESDDF +VHSPYLNSEADFSQILSSAPPVHHDPNETHQENQDIIDRFANSSQEHNEYILQYLTHSDA +ANHNNIGVPNNNSHSLNTQHNVSDLGNSLLRQEALVGSSSTKIFDELKFVQNGPHGSQHP +IDFQHVDHRHLSSNEPQVRSHQYGPQQQPPQQLQYHQNQPHDGHNHEQHQTVQKDMQTHE +SLEIMGNTLLEEFKDIKMVNGELKYVKPED +>sp|P32781|AGA2_YEAST A-agglutinin-binding subunit OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AGA2 PE=1 SV=1 +MQLLRCFSIFSVIASVLAQELTTICEQIPSPTLESTPYSLSTTTILANGKAMQGVFEYYK +SVTFVSNCGSHPSTTSKGSPINTQYVF +>sp|P32323|AGA1_YEAST A-agglutinin anchorage subunit OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AGA1 PE=1 SV=1 +MTLSFAHFTYLFTILLGLTNIALASDPETILVTITKTNDANGVVTTTVSPALVSTSTIVQ +AGTTTLYTTWCPLTVSTSSAAEISPSISYATTLSRFSTLTLSTEVCSHEACPSSSTLPTT +TLSVTSKFTSYICPTCHTTAISSLSEVGTTTVVSSSAIEPSSASIISPVTSTLSSTTSSN +PTTTSLSSTSTSPSSTSTSPSSTSTSSSSTSTSSSSTSTSSSSTSTSPSSTSTSSSLTST +SSSSTSTSQSSTSTSSSSTSTSPSSTSTSSSSTSTSPSSKSTSASSTSTSSYSTSTSPSL +TSSSPTLASTSPSSTSISSTFTDSTSSLGSSIASSSTSVSLYSPSTPVYSVPSTSSNVAT +PSMTSSTVETTVSSQSSSEYITKSSISTTIPSFSMSTYFTTVSGVTTMYTTWCPYSSESE +TSTLTSMHETVTTDATVCTHESCMPSQTTSLITSSIKMSTKNVATSVSTSTVESSYACST +CAETSHSYSSVQTASSSSVTQQTTSTKSWVSSMTTSDEDFNKHATGKYHVTSSGTSTIST +SVSEATSTSSIDSESQEQSSHLLSTSVLSSSSLSATLSSDSTILLFSSVSSLSVEQSPVT +TLQISSTSEILQPTSSTAIATISASTSSLSATSISTPSTSVESTIESSSLTPTVSSIFLS +SSSAPSSLQTSVTTTEVSTTSISIQYQTSSMVTISQYMGSGSQTRLPLGKLVFAIMAVAC +NVIFS +>sp|Q12482|AGC1_YEAST Mitochondrial aspartate-glutamate transporter AGC1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AGC1 PE=3 SV=1 +MEQINSNSRKKKQQLEVFKYFASVLTKEDKPISISNGMLDMPTVNSSKLTAGNGKPDTEK +LTGELILTYDDFIELISSSKTIYSKFTDHSFNLNQIPKNVFGCIFFAIDEQNKGYLTLND +WFYFNNLLEYDNYHLIILYEFFRKFDVENLKAKQKKELGSSSFNLKAADDRIKSINYGNR +FLSFDDLLLNLNQFKDTIRLLHESIDDNFVKDNKLLLDWNDFRFLKFYKCYHENEEYLSL +NSLVTILQNDLKNEKIFIGFDRLAQMDSQGHRLALSKNQLTYLLRLFYSHRVSADIFSSL +NLSNTELLKADNNSIPYNVFKDIFYLFQNFDLLNQIFHKYVTENNLNEQDIREQIVTKND +FMTVLNAQYNKVNNIIEFSPSQINLLFSIVANSKENRRLRKRNQDRDDELLNDHHYDSDI +DFFIHNEYLHGVSRSRKNLESFNDYYHDLSDGFDQDSGVKKASKASTGLFESVFGGKKDK +ATMRSDLTIEDFMKILNPNYLNDLVHQMELQKNQNESLYINYYFYPIFDSLYNFSLGSIA +GCIGATVVYPIDFIKTRMQAQRSLAQYKNSIDCLLKIISREGIKGLYSGLGPQLIGVAPE +KAIKLTVNDFMRNRLTDKNGKLSLFPEIISGASAGACQVIFTNPLEIVKIRLQVQSDYVG +ENIQQANETATQIVKKLGLRGLYNGVAACLMRDVPFSAIYFPTYAHLKKDLFDFDPNDKT +KRNRLKTWELLTAGAIAGMPAAFLTTPFDVIKTRLQIDPRKGETKYNGIFHAIRTILKEE +SFRSFFKGGGARVLRSSPQFGFTLAAYELFKGFIPSPDNKLKSREGRKRFCIDDDAGNEE +TVVHSNGELPQQKFYSDDRKHANYYYKSCQIAKTFIDLDNNFSRFDSSVYKNFQEHLRSI +NG +>sp|Q04412|AGE1_YEAST ADP-ribosylation factor GTPase-activating protein effector protein 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AGE1 PE=1 SV=1 +MDFYTTDINKNVVPLFSKGTVARTASKAQYPSWCNNALKLTNILLKSLRCKFQTNRCEDD +RGFEVYCVILKSIALLMAAKESLILLQIPPSLPSGFPFRSPQLSFTYLSTRLSGSQHKST +HSHHINHQTHPIHSSSSNSNSNNRIPTKTDSSKQHTQHFSFANAGASNRDELLSIVRKID +KSNLKCCDCGSTATVEWVSINLLCILCIKCSGVHRSLGSHISKIRSLTLDNFTSLELMHL +LQNNVSNSNVNAIYESNLRNFPVKKITANSDDSERSKFIIDKYQFKKFVIDSNQGREASL +KSLIKAIHLDSVFMMQRAIAQSKYSLRELTASEKEQNDLNHSSIFQYSLKHYEIVDGTPI +FFITEFLLCNGIHIDNLPKITTNWSPKVLEYWETKLEMYGTFQAVNTSRPRSGPHLNMHS +NVDSASSYNKKHDLRVNIPERSASASKRWSLSSIPKSSQNLMSPTNLLTMHKSLKLAKKD +KK +>sp|P40529|AGE2_YEAST ADP-ribosylation factor GTPase-activating protein effector protein 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AGE2 PE=1 SV=1 +MSTSVPVKKALSALLRDPGNSHCADCKAQLHPRWASWSLGVFICIKCAGIHRSLGTHISK +VKSVDLDTWKEEHLVKLIQFKNNLRANSYYEATLADELKQRKITDTSSLQNFIKNKYEYK +KWIGDLSSIEGLNDSTEPVLHKPSANHSLPASNARLDQSSNSLQKTQTQPPSHLLSTSRS +NTSLLNLQVSSLSKTTSNTSVTSSATSIGAANTKTGNRVGEFGQRNDLKKSILSLYSKPS +AQTQSQNSFFTSTTPQPCNTPSPFVNTGITATNNNSMNSNSSSNISLDDNELFKNVWS +>sp|P38628|AGM1_YEAST Phosphoacetylglucosamine mutase OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=PCM1 PE=1 SV=2 +MKVDYEQLCKLYDDTCRTKNVQFSYGTAGFRTLAKNLDTVMFSTGILAVLRSLKLQGQYV +GVMITASHNPYQDNGVKIVEPDGSMLLATWEPYAMQLANAASFATNFEEFRVELAKLIEH +EKIDLNTTVVPHIVVGRDSRESSPYLLRCLTSSMASVFHAQVLDLGCVTTPQLHYITDLS +NRRKLEGDTAPVATEQDYYSFFIGAFNELFATYQLEKRLSVPKLFIDTANGIGGPQLKKL +LASEDWDVPAEQVEVINDRSDVPELLNFECGADYVKTNQRLPKGLSPSSFDSLYCSFDGD +ADRVVFYYVDSGSKFHLLDGDKISTLFAKFLSKQLELAHLEHSLKIGVVQTAYANGSSTA +YIKNTLHCPVSCTKTGVKHLHHEAATQYDIGIYFEANGHGTIIFSEKFHRTIKSELSKSK +LNGDTLALRTLKCFSELINQTVGDAISDMLAVLATLAILKMSPMDWDEEYTDLPNKLVKC +IVPDRSIFQTTDQERKLLNPVGLQDKIDLVVAKYPMGRSFVRASGTEDAVRVYAECKDSS +KLGQFCDEVVEHVKASA +>sp|P25376|AGP1_YEAST General amino acid permease AGP1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AGP1 PE=1 SV=3 +MSSSKSLYELKDLKNSSTEIHATGQDNEIEYFETGSNDRPSSQPHLGYEQHNTSAVRRFF +DSFKRADQGPQDEVEATQMNDLTSAISPSSRQAQELEKNESSDNIGANTGHKSDSLKKTI +QPRHVLMIALGTGIGTGLLVGNGTALVHAGPAGLLIGYAIMGSILYCIIQACGEMALVYS +NLTGGYNAYPSFLVDDGFGFAVAWVYCLQWLCVCPLELVTASMTIKYWTTSVNPDVFVII +FYVLVITINIFGARGYAEAEFFFNCCKILMMTGFFILGIIIDVGGAGNDGFIGGKYWHDP +GAFNGKHAIDRFKGVAATLVTAAFAFGGSEFIAITTAEQSNPRKAIPGAAKQMIYRILFL +FLATIILLGFLVPYNSDQLLGSTGGGTKASPYVIAVASHGVRVVPHFINAVILLSVLSMA +NSSFYSSARLFLTLSEQGYAPKVFSYIDRAGRPLIAMGVSALFAVIAFCAASPKEEQVFT +WLLAISGLSQLFTWTAICLSHLRFRRAMKVQGRSLGELGFKSQTGVWGSAYACIMMILIL +IAQFWVAIAPIGEGKLDAQAFFENYLAMPILIALYVGYKVWHKDWKLFIRADKIDLDSHR +QIFDEELIKQEDEEYRERLRNGPYWKRVVAFWC +>sp|P38090|AGP2_YEAST General amino acid permease AGP2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AGP2 PE=1 SV=1 +MTKERMTIDYENDGDFEYDKNKYKTITTRIKSIEPSEGWLEPSGSVGHINTIPEAGDVHV +DEHEDRGSSIDDDSRTYLLYFTETRRKLENRHVQLIAISGVIGTALFVAIGKALYRGGPA +SLLLAFALWCVPILCITVSTAEMVCFFPVSSPFLRLATKCVDDSLAVMASWNFWFLECVQ +IPFEIVSVNTIIHYWRDDYSAGIPLAVQVVLYLLISICAVKYYGEMEFWLASFKIILALG +LFTFTFITMLGGNPEHDRYGFRNYGESPFKKYFPDGNDVGKSSGYFQGFLACLIQASFTI +AGGEYISMLAGEVKRPRKVLPKAFKQVFVRLTFLFLGSCLCVGIVCSPNDPDLTAAINEA +RPGAGSSPYVIAMNNLKIRILPDIVNIALITAAFSAGNAYTYCSSRTFYGMALDGYAPKI +FTRCNRHGVPIYSVAISLVWALVSLLQLNSNSAVVLNWLINLITASQLINFVVLCIVYLF +FRRAYHVQQDSLPKLPFRSWGQPYTAIIGLVSCSAMILIQGYTVFFPKLWNTQDFLFSYL +MVFINIGIYVGYKFIWKRGKDHFKNPHEIDFSKELTEIENHEIESSFEKFQYYSKA +>sp|P43548|AGP3_YEAST General amino acid permease AGP3 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AGP3 PE=1 SV=1 +MAVLNLKRETVDIEETAKKDIKPYFASNVEAVDIDEDPDVSRYDPQTGVKRALKNRHISL +LALGGVIGPGCLVGAGNALNKGGPLALLLGFSIIGIIAFSVMESIGEMITLYPSGGGFTT +LARRFHSDALPAVCGYAYVVVFFAVLANEYNTLSSILQFWGPQVPLYGYILIFWFAFEIF +QLVGVGLFGETEYWLAWLKIVGLVAYYIFSIVYISGDIRNRPAFGFHYWNSPGALSHGFK +GIAIVFVFCSTFYSGTESVALAATESKNPGKAVPLAVRQTLWRILVVYIGIAVFYGATVP +FDDPNLSASTKVLKSPIAIAISRAGWAGGAHLVNAFILITCISAINGSLYIGSRTLTHLA +HEGLAPKILAWTDRRGVPIPAITVFNALGLISLMNVSVGAANAYSYIVNLSGVGVFIVWG +VISYTHLRIRKAWVAQGRSIEELPYEALFYPWTPVLSLAANIFLALIQGWSYFVPFDAGN +FVDAYILLPVGILLYIGICVFKSNHFRTVDLRSINLDEGRRKDMEADLSDQESSLASSET +MKDYKSATFFRYLSNIFT +>sp|P43567|AGX1_YEAST Alanine--glyoxylate aminotransferase 1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AGX1 PE=1 SV=1 +MTKSVDTLLIPGPIILSGAVQKALDVPSLGHTSPEFVSIFQRVLKNTRAVFKSAAASKSQ +PFVLAGSGTLGWDIFASNFILSKAPNKNVLVVSTGTFSDRFADCLRSYGAQVDVVRPLKI +GESVPLELITEKLSQNSYGAVTVTHVDTSTAVLSDLKAISQAIKQTSPETFFVVDAVCSI +GCEEFEFDEWGVDFALTASQKAIGAPAGLSISLCSSRFMDYALNDSKNGHVHGYFSSLRR +WTPIMENYEAGKGAYFATPPVQLINSLDVALKEILEEGLHKRWDLHREMSDWFKDSLVNG +LQLTSVSRYPSNMSAHGLTAVYVADPPDVIAFLKSHGVVIAGGIHKDIGPKYIRIGHMGV +TACNKNLPYMKNCFDLIKLALQRKK +>sp|Q12449|AHA1_YEAST Hsp90 co-chaperone AHA1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AHA1 PE=1 SV=1 +MVVNNPNNWHWVDKNCIGWAKEYFKQKLVGVEAGSVKDKKYAKIKSVSSIEGDCEVNQRK +GKVISLFDLKITVLIEGHVDSKDGSALPFEGSINVPEVAFDSEASSYQFDISIFKETSEL +SEAKPLIRSELLPKLRQIFQQFGKDLLATHGNDIQVPESQVKSNYTRGNQKSSFTEIKDS +ASKPKKNALPSSTSTSAPVSSTNKVPQNGSGNSTSIYLEPTFNVPSSELYETFLDKQRIL +AWTRSAQFFNSGPKLETKEKFELFGGNVISELVSCEKDKKLVFHWKLKDWSAPFNSTIEM +TFHESQEFHETKLQVKWTGIPVGEEDRVRANFEEYYVRSIKLTFGFGAVL +>sp|Q12433|AHC1_YEAST Protein AHC1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AHC1 PE=1 SV=1 +MMSPAQDKLQHQHHNPNSSSSSSSKMTNVYQVTTPKSPQDLENNMDEPFKMDTATSNPDK +DSENTQRLKYECAKGEIQNVLNLHIMLNHKHVRHLRRNVQKVNAKLALLETLHKDTGLLN +KIERTYQLKIKQHQQHSVLGGHFHDSTATENTNASNYNLSYPVLSDYNINCQPLSSSSNR +NLSTTRIPHHHYHTRSKSNGLLLEPSALRPANSNIIDYRLTGSKSLSEAITKPTPVSLPH +SNSDGISSPRSSSISPLDEQPGFQILPFKPSQMHLNHRRNYSSTCLTSNSGIIGKTENNE +PIFRRYDGILVIITCSKCDRSGFTSAQGIVNHTRLKHSKLYSSQPLAVLNNQKLLPNDKQ +DPEILSKFKKLNLDPNKDYLPSDIAIPKPQSPINHSENHTRAPKTVKNTPHLEKLYQNKE +DFKKLIDMVNETPDDLNEYLKQREIQLRYQKEQEEESSKSDDEASYVPSPSLSATATTTT +TTDPPSPPVLSSSLQRKLLRKRKLSLNSSTPMEDLPLRERLRANPTDKKPRKAALLTNEL +EGPDPAAKSSSYYNLRSKSRLRGSHT +>sp|P25649|AHC2_YEAST ADA histone acetyltransferase complex component 2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AHC2 PE=1 SV=1 +MITPKGTHDAVAKFQKTDLHQDLDYIVLQQRRTQLETLINERESFVKNLCSLFHKIQNTK +NYQEFVDVLAENRDLLREIFTVENGFQKQKWISNDDIPQIDWDKFALDINAYIAENDQLL +ALYEDGLL +>sp|P38013|AHP1_YEAST Peroxiredoxin type-2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AHP1 PE=1 SV=4 +MSDLVNKKFPAGDYKFQYIAISQSDADSESCKMPQTVEWSKLISENKKVIITGAPAAFSP +TCTVSHIPGYINYLDELVKEKEVDQVIVVTVDNPFANQAWAKSLGVKDTTHIKFASDPGC +AFTKSIGFELAVGDGVYWSGRWAMVVENGIVTYAAKETNPGTDVTVSSVESVLAHL +>sp|P29589|AHT1_YEAST Putative hexose transport activator protein OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AHT1 PE=5 SV=1 +MDCKIKAAGKNSGIFHEGGTKSSKSFLTVFIRSVFPLSPSFPAGGGIWGPMEKKPGGVGK +KKGSEKKTAQGNIFFSTERDAGQEKCGILYKHCFSILYGFFWKKADKPKEKTGNGSGLGI +VFPIGQKKIPEPADSDIFLPCFRYAAASDFTKAKRFLVEITAVYWVSLEAQPSSASCLFI +LI +>sp|P03876|AI2M_YEAST Putative COX1/OXI3 intron 2 protein OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AI2 PE=3 SV=2 +MVQRWLYSTNAKDIAVLYFMLAIFSGMAGTAMSLIIRLELAAPGSQYLHGNSQLFNVLVV +GHAVLMIFCAPFRLIYHCIEVLIDKHISVYSINENFTVSFWFWLLVVTYMVFRYVNHMAY +PVGANSTGTMACHKSAGVKQPAQGKNCPMARLTNSCKECLGFSLTPSHLGIVIHAYVLEE +EVHELTKNESLALSKSWHLEGCTSSNGKLRNTGLSERGNPGDNGVFMVPKFNLNKVRYFS +TLSKLNARKEDSLAYLTKINTTDFSELNKLMENNHNKTETINTRILKLMSDIRMLLIAYN +KIKSKKGNMSKGSNNITLDGINISYLNKLSKDINTNMFKFSPVRRVEIPKTSGGFRPLSV +GNPREKIVQESMRMMLEIIYNNSFSYYSHGFRPNLSCLTAIIQCKNYMQYCNWFIKVDLN +KCFDTIPHNMLINVLNERIKDKGFMDLLYKLLRAGYVDKNNNYHNTTLGIPQGSVVSPIL +CNIFLDKLDKYLENKFENEFNTGNMSNRGRNPIYNSLSSKIYRCKLLSEKLKLIRLRDHY +QRNMGSDKSFKRAYFVRYADDIIIGVMGSHNDCKNILNDINNFLKENLGMSINMDKSVIK +HSKEGVSFLGYDVKVTPWEKRPYRMIKKGDNFIRVRHHTSLVVNAPIRSIVMKLNKHGYC +SHGILGKPRGVGRLIHEEMKTILMHYLAVGRGIMNYYRLATNFTTLRGRITYILFYSCCL +TLARKFKLNTVKKVILKFGKVLVDPHSKVSFSIDDFKIRHKMNMTDSNYTPDEILDRYKY +MLPRSLSLFSGICQICGSKHDLEVHHVRTLNNAANKIKDDYLLGRMIKMNRKQITICKTC +HFKVHQGKYNGPGL +>sp|Q9ZZX0|AI5B_YEAST Intron-encoded DNA endonuclease aI5 beta OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=AI5_BETA PE=3 SV=1 +MLMLLMMILTNNKVFMETLYYYLMFNFQLMSPFGVPVPGPAPETKDIKNLYESIMNNYIN +ILNKYTININKDNINKLKFLDNYTEEEKGYYLSGLFEGDGNIYTRCFSITFSLEDVLLAN +YLCTYFKIGHITAKYNFNKELTAVKWNIMKKKEQEVFMNYINGKLLTYKRYDQYFKYNFN +NRLNIKLLKPKEFDLTLNPWLTGFNDADGYFYTGFQKHKNSQWLKFHLELSQKDSYILDI +IKKYFKTGGILKRDYKSGATAYIYKAQSSKAMKPFIEYFNNYQPLSTRRYKQYLLLNIAY +LLKLNKLHMLTNSLLMLKELMLLQSVKNMSLEMKNELNNRVKIIINKTHYNNIE \ No newline at end of file
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/test-data/uniprot-proteome_UP000002311Condensed-first100entries.xml Thu Nov 05 08:59:15 2015 -0500 @@ -0,0 +1,3817 @@ +<uniprot xmlns="http://uniprot.org/uniprot" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://uniprot.org/uniprot http://www.uniprot.org/support/docs/uniprot.xsd"> +<entry dataset="Swiss-Prot" created="1995-02-01" modified="2015-10-14" version="136"> +<accession>P38903</accession> +<accession>D6W281</accession> +<name>2A5D_YEAST</name> +<protein> +<recommendedName> +<fullName>Serine/threonine-protein phosphatase 2A 56 kDa regulatory subunit delta isoform</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">RTS1</name> +<name type="synonym">SCS1</name> +<name type="ordered locus">YOR014W</name> +<name type="ORF">OR26.04</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphothreonine" evidence="1"> +<location> +<position position="242"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="2"> +<location> +<position position="257"/> +</location> +</feature> +<sequence length="757" mass="85335" checksum="5A7476C30140331C" modified="1996-10-01" version="2"> +MMRGFKQRLIKKTTGSSSSSSSKKKDKEKEKEKSSTTSSTSKKPASASSSSHGTTHSSAS +STGSKSTTEKGKQSGSVPSQGKHHSSSTSKTKTATTPSSSSSSSRSSSVSRSGSSSTKKT +SSRKGQEQSKQSQQPSQSQKQGSSSSSAAIMNPTPVLTVTKDDKSTSGEDHAHPTLLGAV +SAVPSSPISNASGTAVSSDVENGNSNNNNMNINTSNTQDANHASSQSIDIPRSSHSFERL +PTPTKLNPDTDLELIKTPQRHSSSRFEPSRYTPLTKLPNFNEVSPEERIPLFIAKVDQCN +TMFDFNDPSFDIQGKEIKRSTLDELIEFLVTNRFTYTNEMYAHVVNMFKINLFRPIPPPV +NPVGDIYDPDEDEPVNELAWPHMQAVYEFFLRFVESPDFNHQIAKQYIDQDFILKLLELF +DSEDIRERDCLKTTLHRIYGKFLSLRSFIRRSMNNIFLQFIYETEKFNGVAELLEILGSI +INGFALPLKEEHKVFLVRILIPLHKVRCLSLYHPQLAYCIVQFLEKDPLLTEEVVMGLLR +YWPKINSTKEIMFLNEIEDIFEVIEPLEFIKVEVPLFVQLAKCISSPHFQVAEKVLSYWN +NEYFLNLCIENAEVILPIIFPALYELTSQLELDTANGEDSISDPYMLVEQAINSGSWNRA +IHAMAFKALKIFLETNPVLYENCNALYLSSVKETQQRKVQREENWSKLEEYVKNLRINND +KDQYTIKNPELRNSFNTASENNTLNEENENDCDSEIQ +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-07-01" modified="2015-10-14" version="133"> +<accession>P31383</accession> +<accession>D6VPK2</accession> +<name>2AAA_YEAST</name> +<protein> +<recommendedName> +<fullName>Protein phosphatase PP2A regulatory subunit A</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">TPD3</name> +<name type="ordered locus">YAL016W</name> +<name type="ORF">FUN32</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="635" mass="70907" checksum="7ED350FB20633DC8" modified="2010-10-05" version="3"> +MSGARSTTAGAVPSAATTSTTSTTSNSKDSDSNESLYPLALLMDELKHDDIANRVEAMKK +LDTIALALGPERTRNELIPFLTEVAQDDEDEVFAVLAEQLGKFVPYIGGPQYATILLPVL +EILASAEETLVREKAVDSLNNVAQELSQEQLFSDFVPLIEHLATADWFSSKVSACGLFKS +VIVRIKDDSLRKNILALYLQLAQDDTPMVKRAVGKNLPILIDLLTQNLGLSTDEDWDYIS +NIFQKIINDNQDSVKFLAVDCLISILKFFNAKGDESHTQDLLNSAVKLIGDEAWRVRYMA +ADRFSDLASQFSSNQAYIDELVQPFLNLCEDNEGDVREAVAKQVSGFAKFLNDPSIILNK +ILPAVQNLSMDESETVRSALASKITNIVLLLNKDQVINNFLPILLNMLRDEFPDVRLNII +ASLKVVNDVIGIELLSDSLLPAITELAKDVNWRVRMAIIEYIPILAEQLGMQFFDQQLSD +LCLSWLWDTVYSIREAAVNNLKRLTEIFGSDWCRDEIISRLLKFDLQLLENFVSRFTILS +ALTTLVPVVSLDVVTEQLLPFISHLADDGVPNIRFNVAKSYAVIVKVLIKDEAKYDALIK +NTILPSLQTLCQDEDVDVKYFAKKSLAECQELLKN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-04-01" modified="2015-10-14" version="147"> +<accession>Q00362</accession> +<accession>D6VTW4</accession> +<name>2ABA_YEAST</name> +<protein> +<recommendedName> +<fullName>Protein phosphatase PP2A regulatory subunit B</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">CDC55</name> +<name type="ordered locus">YGL190C</name> +<name type="ORF">G1345</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="124"/> +</location> +</feature> +<sequence length="526" mass="59662" checksum="6DA12C2805FA6A82" modified="1996-10-01" version="2"> +MAQNNFDFKFSQCFGDKADIVVTEADLITAVEFDYTGNYLATGDKGGRVVLFERSNSRHC +EYKFLTEFQSHDAEFDYLKSLEIEEKINEIKWLRPTQRSHFLLSTNDKTIKLWKVYEKNI +KLVSQNNLTEGVTFAKKGKPDNHNSRGGSVRAVLSLQSLKLPQLSQHDKIIAATPKRIYS +NAHTYHINSISLNSDQETFLSADDLRINLWNLDIPDQSFNIVDIKPTNMEELTEVITSAE +FHPQECNLFMYSSSKGTIKLCDMRQNSLCDNKTKTFEEYLDPINHNFFTEITSSISDIKF +SPNGRYIASRDYLTVKIWDVNMDNKPLKTINIHEQLKERLSDTYENDAIFDKFEVNFSGD +SSSVMTGSYNNNFMIYPNVVTSGDNDNGIVKTFDEHNAPNSNSNKNIHNSIQNKDSSSSG +NSHKRRSNGRNTGMVGSSNSSRSSIAGGEGANSEDSGTEMNEIVLQADKTAFRNKRYGSL +AQRSARNKDWGDDIDFKKNILHFSWHPRENSIAVAATNNLFIFSAL +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-02-01" modified="2015-10-14" version="111"> +<accession>P47177</accession> +<accession>D6VWW7</accession> +<name>2NDP_YEAST</name> +<protein> +<recommendedName> +<fullName>Putative nitronate monooxygenase</fullName> +<ecNumber>1.13.12.16</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="ordered locus">YJR149W</name> +<name type="ORF">J2213</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="404" mass="45159" checksum="E3FEE0E6C76ED7FA" modified="2011-09-21" version="2"> +MYFLNQLIFQDVSVMSVDKREDMSRSFQKCLNLRYPIIQAPMAGVTTIEMAAKACIAGAI +ASLPLSHLDFRKVNDIEKLKLMVSQFRDQVADESLEGNLNLNFFCHDIVDKPTDLQTANW +AKLYRKSMNVPIDMNEIKFDNGNVSFKAFEKENALQDFFQYLSDGFRPKIISFHFGHPSK +STIEYLQKIGILIFVTATSVREVRLLARLGINGIVCQGYEAGGHRGNFLVNDPKDDENLS +TVQLVKRTVDELAEMKNKGLIHATPFVIAAGGIMDSKDISYMLSQQADAVQVGTAFLGCS +ESNASKNFSSPFTRETTTKMVNIISGKPARTISTPFIEKVIANFQGEELPPYGYMYSAFK +QVRKKYPELANFILAGQGFQNVQSGITTDKKIETMGARLKIDGK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-02-01" modified="2015-10-14" version="135"> +<accession>P47096</accession> +<accession>D6VWJ8</accession> +<name>3HAO_YEAST</name> +<protein> +<recommendedName> +<fullName evidence="5">3-hydroxyanthranilate 3,4-dioxygenase</fullName> +<ecNumber evidence="5">1.13.11.6</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary" evidence="5">BNA1</name> +<name type="synonym">HAD1</name> +<name type="ordered locus">YJR025C</name> +<name type="ORF">J1550</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="2 3 4"> +<location> +<position position="176"/> +</location> +</feature> +<sequence length="177" mass="20235" checksum="930D69F486632417" modified="1996-02-01" version="1"> +MFNTTPINIDKWLKENEGLLKPPVNNYCLHKGGFTVMIVGGPNERTGYHINPTPEWFYQK +KGSMLLKVVDETDAEPKFIDIIINEGDSYLLPGNVPHSPVRFADTVGIVVEQDRPGGEND +KIRWYCSHCRQVVHESELQMLDLGTQVKEAILDFENDVEKRTCFHCKTLNYARPQSN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-02-01" modified="2015-10-14" version="145"> +<accession>P40433</accession> +<accession>D6VVI0</accession> +<name>6P21_YEAST</name> +<protein> +<recommendedName> +<fullName>6-phosphofructo-2-kinase 1</fullName> +<shortName>6PF-2-K 1</shortName> +<ecNumber>2.7.1.105</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">PFK26</name> +<name type="ordered locus">YIL107C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="92"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="2"> +<location> +<position position="157"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="644"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="652"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="659"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="667"/> +</location> +</feature> +<sequence length="827" mass="93417" checksum="9FA7BCBA08C9F0E3" modified="1995-02-01" version="1"> +MFKPVDFSETSPVPPDIDLAPTQSPHHVAPSQDSSYDLLSRSSDDKIDAEKGPHDELSKH +LPLFQKRPLSDTPISSNWNSPGITEENTPSDSPENSATNLKSLHRLHINDETQLKNAKIP +TNDTTDYMPPSDGANEVTRIDLKDIKSPTRHHKRRPTTIDVPGLTKSKTSPDGLISKEDS +GSKLVIVMVGLPATGKSFITNKLSRFLNYSLYYCKVFNVGNTRRKFAKEHGLKDQDSKFF +EPKNADSTRLRDKWAMDTLDELLDYLLEGSGSVGIFDATNTSRERRKNVLARIRKRSPHL +KVLFLESVCSDHALVQKNIRLKLFGPDYKGKDPESSLKDFKSRLANYLKAYEPIEDDENL +QYIKMIDVGKKVIAYNIQGFLASQTVYYLLNFNLADRQIWITRSGESEDNVSGRIGGNSH +LTPRGLRFAKSLPKFIARQREIFYQNLMQQKKNNENTDGNIYNDFFVWTSMRARTIGTAQ +YFNEDDYPIKQMKMLDELSAGDYDGMTYPEIKNNFPEEFEKRQKDKLRYRYPGIGGESYM +DVINRLRPVITELERIEDNVLIITHRVVARALLGYFMNLSMGIIANLDVPLHCVYCLEPK +PYGITWSLWEYDEASDSFSKVPQTDLNTTRVKEVGLVYNERRYSVIPTAPPSARSSFASD +FLSRKRSNPTSASSSQSELSEQPKNSVSAQTGSNNTTLIGSNFNIKNENGDSRIPLSAPL +MATNTSNNILDGGGTSISIHRPRVVPNQNNVNPLLANNNKAASNVPNVKKSAATPRQIFE +IDKVDEKLSMLKNKSFLLHGKDYPNNADNNDNEDIRAKTMNRSQSHV +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1997-11-01" modified="2015-10-14" version="105"> +<accession>Q12471</accession> +<accession>D6W1T3</accession> +<name>6P22_YEAST</name> +<protein> +<recommendedName> +<fullName>6-phosphofructo-2-kinase 2</fullName> +<shortName>6PF-2-K 2</shortName> +<ecNumber>2.7.1.105</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">PFK27</name> +<name type="ordered locus">YOL136C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="397" mass="45318" checksum="F8A36E8BE135A55C" modified="1997-11-01" version="1"> +MGGSSDSDSHDGYLTSEYNSSNSLFSLNTGNSYSSASLDRATLDCQDSVFFDNHKSSLLS +TEVPRFISNDPLHLPITLNYKRDNADPTYTNGKVNKFMIVLIGLPATGKSTISSHLIQCL +KNNPLTNSLRCKVFNAGKIRRQISCATISKPLLLSNTSSEDLFNPKNNDKKETYARITLQ +KLFHEINNDECDVGIFDATNSTIERRRFIFEEVCSFNTDELSSFNLVPIILQVSCFNRSF +IKYNIHNKSFNEDYLDKPYELAIKDFAKRLKHYYSQFTPFSLDEFNQIHRYISQHEEIDT +SLFFFNVINAGVVEPHSLNQSHYPSTCGKQIRDTIMVIENFINHYSQMFGFEYIEAVKLF +FESFGNSSEETLTTLDSVVNDKFFDDLQSLIESNGFA +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-02-01" modified="2015-10-14" version="145"> +<accession>P38720</accession> +<accession>D3DLD1</accession> +<name>6PGD1_YEAST</name> +<protein> +<recommendedName> +<fullName>6-phosphogluconate dehydrogenase, decarboxylating 1</fullName> +<ecNumber>1.1.1.44</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">GND1</name> +<name type="ordered locus">YHR183W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="50"/> +</location> +</feature> +<sequence length="489" mass="53543" checksum="55CAE5DACDC6A00B" modified="1995-02-01" version="1"> +MSADFGLIGLAVMGQNLILNAADHGFTVCAYNRTQSKVDHFLANEAKGKSIIGATSIEDF +ISKLKRPRKVMLLVKAGAPVDALINQIVPLLEKGDIIIDGGNSHFPDSNRRYEELKKKGI +LFVGSGVSGGEEGARYGPSLMPGGSEEAWPHIKNIFQSISAKSDGEPCCEWVGPAGAGHY +VKMVHNGIEYGDMQLICEAYDIMKRLGGFTDKEISDVFAKWNNGVLDSFLVEITRDILKF +DDVDGKPLVEKIMDTAGQKGTGKWTAINALDLGMPVTLIGEAVFARCLSALKNERIRASK +VLPGPEVPKDAVKDREQFVDDLEQALYASKIISYAQGFMLIREAAATYGWKLNNPAIALM +WRGGCIIRSVFLGQITKAYREEPDLENLLFNKFFADAVTKAQSGWRKSIALATTYGIPTP +AFSTALSFYDGYRSERLPANLLQAQRDYFGAHTFRVLPECASDNLPVDKDIHINWTGHGG +NVSSSTYQA +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-10-01" modified="2015-10-14" version="139"> +<accession>P53319</accession> +<accession>D6VV36</accession> +<name>6PGD2_YEAST</name> +<protein> +<recommendedName> +<fullName>6-phosphogluconate dehydrogenase, decarboxylating 2</fullName> +<ecNumber>1.1.1.44</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">GND2</name> +<name type="ordered locus">YGR256W</name> +<name type="ORF">G9170</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="492" mass="53923" checksum="3D75D53563987735" modified="1996-10-01" version="1"> +MSKAVGDLGLVGLAVMGQNLILNAADHGFTVVAYNRTQSKVDRFLANEAKGKSIIGATSI +EDLVAKLKKPRKIMLLIKAGAPVDTLIKELVPHLDKGDIIIDGGNSHFPDTNRRYEELTK +QGILFVGSGVSGGEDGARFGPSLMPGGSAEAWPHIKNIFQSIAAKSNGEPCCEWVGPAGS +GHYVKMVHNGIEYGDMQLICEAYDIMKRIGRFTDKEISEVFDKWNTGVLDSFLIEITRDI +LKFDDVDGKPLVEKIMDTAGQKGTGKWTAINALDLGMPVTLIGEAVFARCLSAIKDERKR +ASKLLAGPTVPKDAIHDREQFVYDLEQALYASKIISYAQGFMLIREAARSYGWKLNNPAI +ALMWRGGCIIRSVFLAEITKAYRDDPDLENLLFNEFFASAVTKAQSGWRRTIALAATYGI +PTPAFSTALAFYDGYRSERLPANLLQAQRDYFGAHTFRILPECASAHLPVDKDIHINWTG +HGGNISSSTYQA +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-02-01" modified="2015-10-14" version="109"> +<accession>P47182</accession> +<accession>D6VWX4</accession> +<name>AAD10_YEAST</name> +<protein> +<recommendedName> +<fullName>Putative aryl-alcohol dehydrogenase AAD10</fullName> +<ecNumber>1.1.1.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AAD10</name> +<name type="ordered locus">YJR155W</name> +<name type="ORF">J2245</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="inferred from homology"/> +<sequence length="288" mass="32570" checksum="4E963216BE0600E2" modified="1996-02-01" version="1"> +MASRKLRDQIVIATKFTTDYKGYDVGKGKSANFCGNHKRSLHVSVRDSLRKLQTDWIDIL +YVHWWDYMSSIEEVMDSLHILVQQGKVLYLGVSDTPAWVVSAANYYATSHGKTPFSIYQG +KWNVLNRDFERDIIPMARHFGMALAPWDVMGGGRFQSKKAVEERKKKGEGLRTFFGTSEQ +TDMEVKISEALLKVAEEHGTESVTAIAIAYVRSKAKHVFPLVGGRKIEHLKQNIEALSIK +LTPEQIKYLESIVPFDVGFPTNFIGDDPAVTKKPSFLTEMSAKISFED +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2005-10-25" modified="2015-10-14" version="96"> +<accession>Q08361</accession> +<accession>D6W1Q4</accession> +<name>AAD15_YEAST</name> +<protein> +<recommendedName> +<fullName>Putative aryl-alcohol dehydrogenase AAD15</fullName> +<ecNumber>1.1.1.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AAD15</name> +<name type="ordered locus">YOL165C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="inferred from homology"/> +<sequence length="143" mass="15722" checksum="B1D8F0399364F354" modified="1996-11-01" version="1"> +MARHFGMALAPWDVMGGGRFQSKKAMEERRKNGECIRSFVGASEQTDAEIKISEALAKVA +EEHGTESVTAIAIAYVRSKAKNVFPSVEGGKIEDLKENIKALSIDLTPDNIKYLENVVPF +DIGFPNTFIVLNSLTQKYGTNNV +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2006-05-30" modified="2015-10-14" version="109"> +<accession>Q02895</accession> +<accession>D6W3S9</accession> +<name>AAD16_YEAST</name> +<protein> +<recommendedName> +<fullName evidence="4">Putative aryl-alcohol dehydrogenase AAD16</fullName> +<ecNumber>1.1.1.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary" evidence="4">AAD16</name> +<name type="ordered locus" evidence="6">YPL088W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="342" mass="39683" checksum="E99B1EB62FC880B1" modified="1996-11-01" version="1"> +MVLVKQVRLGNSGLKISPIVIGCMSYGSKKWADWVIEDKTQIFKIMKHCYDKGLRTFDTA +DFYSNGLSERIIKEFLEYYSIKRETVVIMTKIYFPVDETLDLHHNFTLNEFEELDLSNQR +GLSRKHIIAGVENSVKRLGTYIDLLQIHRLDHETPMKEIMKALNDVVEAGHVRYIGASSM +LATEFAELQFTADKYGWFQFISSQSYYNLLYREDERELIPFAKRHNIGLLPWSPNARGML +TRPLNQSTDRIKSDPTFKSLHLDNLEEEQKEIINRVEKVSKDKKVSMAMLSIAWVLHKGC +HPIVGLNTTARVDEAIAALQVTLTEEEIKYLEEPYKPQRQRC +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1992-05-01" modified="2015-10-14" version="107"> +<accession>P25612</accession> +<accession>D6VRA7</accession> +<name>AAD3_YEAST</name> +<protein> +<recommendedName> +<fullName>Putative aryl-alcohol dehydrogenase AAD3</fullName> +<ecNumber>1.1.1.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AAD3</name> +<name type="ordered locus">YCR107W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="inferred from homology"/> +<sequence length="363" mass="40911" checksum="FFC74519895671DC" modified="1992-05-01" version="1"> +MIGSASDSSSKLGRLRFLSETAAIKVSPLILGEVSYDGARSDFLKSMNKNRAFELLDTFY +EAGGNFIDAANNCQNEQSEEWIGEWIQSRRLRDQIVIATKFIKSDKKYKAGESNTANYCG +NHKRSLHVSVRDSLRKLQTDWIDILYVHWWDYMSSIEEFMDSLHILVQQGKVLYLGVSDT +PAWVVSAANYYATSYGKTPFSIYQGKWNVLNRDFERDIIPMARHFGMALAPWDVMGGGRF +QSKKAMEERRKNGEGIRSFVGASEQTDAEIKISEALAKIAEEHGTESVTAIAIAYVRSKA +KNFFPSVEGGKIEDLKENIKALSIDLTPDNIKYLESIVPFDIGFPNNFIVLNSLTQKYGT +NNV +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1999-07-15" modified="2015-10-14" version="109"> +<accession>Q07747</accession> +<accession>D6VRB4</accession> +<name>AAD4_YEAST</name> +<protein> +<recommendedName> +<fullName>Probable aryl-alcohol dehydrogenase AAD4</fullName> +<ecNumber>1.1.1.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AAD4</name> +<name type="ordered locus">YDL243C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at transcript level"/> +<sequence length="329" mass="36977" checksum="62DBDD0C889610E0" modified="1996-11-01" version="1"> +MGSMNKEQAFELLDAFYEAGGNCIDTANSYQNEESEIWIGEWMKSRKLRDQIVIATKFTG +DYKKYEVGGGKSANYCGNHKHSLHVSVRDSLRKLQTDWIDILYVHWWDYMSSIEEVMDSL +HILVQQGKVLYLGVSDTPAWVVSAANYYATSHGKTPFSIYQGKWNVLNRDFERDIIPMAR +HFGMALAPWDVMGGGRFQSKKAMEERKKNGEGLRTVSGTSKQTDKEVKISEALAKVAEEH +GTESVTAIAIAYVRSKAKNVFPLVGGRKIEHLKQNIEALSIKLTPEQIEYLESIIPFDVG +FPTNFIGDDPAVTKKASLLTAMSAQISFD +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-11-01" modified="2015-10-14" version="117"> +<accession>P42884</accession> +<accession>D6W0L6</accession> +<name>AAD14_YEAST</name> +<protein> +<recommendedName> +<fullName>Putative aryl-alcohol dehydrogenase AAD14</fullName> +<ecNumber>1.1.1.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AAD14</name> +<name type="ordered locus">YNL331C</name> +<name type="ORF">N0300</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="376" mass="41991" checksum="2265406386938313" modified="1995-11-01" version="1"> +MTDLFKPLPEPPTELGRLRVLSKTAGIRVSPLILGGASIGDAWSGFMGSMNKEQAFELLD +AFYEAGGNCIDTANSYQNEESEIWIGEWMASRKLRDQIVIATKFTGDYKKYEVGGGKSAN +YCGNHKRSLHVSVRDSLRKLQTDWIDILYIHWWDYMSSIEEVMDSLHILVQQGKVLYLGV +SDTPAWVVSAANYYATSHGKTPFSVYQGKWNVLNRDFERDIIPMARHFGMALAPWDVMGG +GRFQSKKAMEERKKNGEGLRTFVGGPEQTELEVKISEALTKIAEEHGTESVTAIAIAYVR +SKAKNVFPLIGGRKIEHLKQNIEALSIKLTPEQIEYLESIVPFDVGFPKSLIGDDPAVTK +KLSPLTSMSARIAFDN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-11-01" modified="2015-10-14" version="113"> +<accession>P43547</accession> +<accession>D6VTH4</accession> +<accession>E9P925</accession> +<name>AAD6_YEAST</name> +<protein> +<recommendedName> +<fullName evidence="2">Putative aryl-alcohol dehydrogenase AAD6</fullName> +<ecNumber>1.1.1.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary" evidence="2">AAD6</name> +<name type="ordered locus" evidence="5">YFL056C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="uncertain"/> +<sequence length="212" mass="23919" checksum="C3FF042B12C91580" modified="1995-11-01" version="1"> +MADLFAPAPEPSTELGRLRVLSKSAGIRVSPLILGGMSIGDAWSEILGSMSKERAFELLD +AFYEAGGNFIDTANNYQNEQSEAWIGEWMVSRKLRDQIVIATKFTTDYKKYDVGGGKSAN +YCGNHKRSLHVSVRDSLRKLQTDWIDILYVHWWDYMSSIEEVMDSLHILVQQARSSIWVC +LIRLPGLFLRQITTLNLMVKPLLASIKVNGTC +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1989-10-01" modified="2015-10-14" version="141"> +<accession>P12904</accession> +<accession>D6VU32</accession> +<name>AAKG_YEAST</name> +<protein> +<recommendedName> +<fullName>5'-AMP-activated protein kinase subunit gamma</fullName> +<shortName>AMPK gamma</shortName> +<shortName>AMPK subunit gamma</shortName> +</recommendedName> +</protein> +<gene> +<name type="primary">SNF4</name> +<name type="synonym">CAT3</name> +<name type="synonym">SCI1</name> +<name type="ordered locus">YGL115W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="322" mass="36401" checksum="51B387E346EE9561" modified="1989-10-01" version="1"> +MKPTQDSQEKVSIEQQLAVESIRKFLNSKTSYDVLPVSYRLIVLDTSLLVKKSLNVLLQN +SIVSAPLWDSKTSRFAGLLTTTDFINVIQYYFSNPDKFELVDKLQLDGLKDIERALGVDQ +LDTASIHPSRPLFEACLKMLESRSGRIPLIDQDEETHREIVVSVLTQYRILKFVALNCRE +THFLKIPIGDLNIITQDNMKSCQMTTPVIDVIQMLTQGRVSSVPIIDENGYLINVYEAYD +VLGLIKGGIYNDLSLSVGEALMRRSDDFEGVYTCTKNDKLSTIMDNIRKARVHRFFVVDD +VGRLVGVLTLSDILKYILLGSN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1994-10-01" modified="2015-10-14" version="135"> +<accession>P37898</accession> +<accession>D3DKZ5</accession> +<name>AAP1_YEAST</name> +<protein> +<recommendedName> +<fullName>Alanine/arginine aminopeptidase</fullName> +<ecNumber>3.4.11.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AAP1</name> +<name type="ordered locus">YHR047C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="856" mass="97663" checksum="0209F9E0298DF9DB" modified="1995-02-01" version="2"> +MSREVLPNNVTPLHYDITLEPNFRAFTFEGSLKIDLQINDHSINSVQINYLEIDFHSARI +EGVNAIEVNKNENQQKATLVFPNGTFENLGPSAKLEIIFSGILNDQMAGFYRAKYTDKVT +GETKYMATTQMEATDARRAFPCFDEPNLKATFAVTLVSESFLTHLSNMDVRNETIKEGKK +YTTFNTTPKMSTYLVAFIVADLRYVESNNFRIPVRVYSTPGDEKFGQFAANLAARTLRFF +EDTFNIEYPLPKMDMVAVHEFSAGAMENWGLVTYRVIDLLLDIENSSLDRIQRVAEVIQH +ELAHQWFGNLVTMDWWEGLWLNEGFATWMSWYSCNKFQPEWKVWEQYVTDNLQRALNLDS +LRSSHPIEVPVNNADEINQIFDAISYSKGSSLLRMISKWLGEETFIKGVSQYLNKFKYGN +AKTGDLWDALADASGKDVCSVMNIWTKRVGFPVLSVKEHKNKITLTQHRYLSTGDVKEEE +DTTIYPILLALKDSTGIDNTLVLNEKSATFELKNEEFFKINGDQSGIFITSYSDERWAKL +SKQANLLSVEDRVGLVADAKALSASGYTSTTNFLNLISNWKNEDSFVVWEQIINSLSALK +STWVFEPEDILNALDKFTLDLVLNKLSELGWNIGEDDSFAIQRLKVTLFSAACTSGNEKM +QSIAVEMFEEYANGNKQAIPALFKAVVFNTVARLGGENNYEKIFNIYQNPVSSEEKIIAL +RALGRFEDKELLERTLSYLLDGTVLNQDFYIPMQGIRVHKKGIERLWAWMQEHWDEIAKR +LQPGSPVLGGVLTLGLTNFTSFEALEKISAFYSRKVTKGFDQTLAQALDTIRSKAQWVSR +DREIVATYLREHEYDQ +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1988-08-01" modified="2015-10-14" version="86"> +<accession>P08521</accession> +<accession>D6W301</accession> +<name>AAP_YEAST</name> +<protein> +<recommendedName> +<fullName>Arginine attenuator peptide</fullName> +<shortName>AAP</shortName> +</recommendedName> +</protein> +<gene> +<name type="ordered locus">YOR302W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="25" mass="2979" checksum="01D494C8AFEAE4AA" modified="1988-08-01" version="1"> +MFSLSNSQYTCQDYISDHIWKTSSH +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-10-01" modified="2015-10-14" version="117"> +<accession>P32357</accession> +<accession>D6VPS8</accession> +<name>AAR2_YEAST</name> +<protein> +<recommendedName> +<fullName>A1 cistron-splicing factor AAR2</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AAR2</name> +<name type="ordered locus">YBL074C</name> +<name type="ORF">YBL06.06</name> +<name type="ORF">YBL0611</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="9"> +<location> +<position position="253"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="9"> +<location> +<position position="274"/> +</location> +</feature> +<feature type="modified residue" description="Phosphotyrosine" evidence="9"> +<location> +<position position="328"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="9"> +<location> +<position position="331"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="9"> +<location> +<position position="345"/> +</location> +</feature> +<sequence length="355" mass="41688" checksum="1F030D821D974131" modified="1993-10-01" version="1"> +MNTVPFTSAPIEVTIGIDQYSFNVKENQPFHGIKDIPIGHVHVIHFQHADNSSMRYGYWF +DCRMGNFYIQYDPKDGLYKMMEERDGAKFENIVHNFKERQMMVSYPKIDEDDTWYNLTEF +VQMDKIRKIVRKDENQFSYVDSSMTTVQENELLKSSLQKAGSKMEAKNEDDPAHSLNYTV +INFKSREAIRPGHEMEDFLDKSYYLNTVMLQGIFKNSSNYFGELQFAFLNAMFFGNYGSS +LQWHAMIELICSSATVPKHMLDKLDEILYYQIKTLPEQYSDILLNERVWNICLYSSFQKN +SLHNTEKIMENKYPELLGKDNEDDALIYGISDEERDDEDDEHNPTIVGGLYYQRP +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1991-11-01" modified="2015-10-14" version="156"> +<accession>P23542</accession> +<accession>D6VY29</accession> +<name>AATC_YEAST</name> +<protein> +<recommendedName> +<fullName>Aspartate aminotransferase, cytoplasmic</fullName> +<ecNumber>2.6.1.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AAT2</name> +<name type="synonym">ASP5</name> +<name type="ordered locus">YLR027C</name> +<name type="ORF">L1746</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N-acetylserine" evidence="3 5"> +<location> +<position position="2"/> +</location> +</feature> +<feature type="modified residue" description="N6-(pyridoxal phosphate)lysine" evidence="9"> +<location> +<position position="255"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="389"/> +</location> +</feature> +<sequence length="418" mass="46058" checksum="D25F40F6C6DD2B33" modified="2007-01-23" version="3"> +MSATLFNNIELLPPDALFGIKQRYGQDQRATKVDLGIGAYRDDNGKPWVLPSVKAAEKLI +HNDSSYNHEYLGITGLPSLTSNAAKIIFGTQSDAFQEDRVISVQSLSGTGALHISAKFFS +KFFPDKLVYLSKPTWANHMAIFENQGLKTATYPYWANETKSLDLNGFLNAIQKAPEGSIF +VLHSCAHNPTGLDPTSEQWVQIVDAIASKNHIALFDTAYQGFATGDLDKDAYAVRLGVEK +LSTVSPVFVCQSFAKNAGMYGERVGCFHLALTKQAQNKTIKPAVTSQLAKIIRSEVSNPP +AYGAKIVAKLLETPELTEQWHKDMVTMSSRITKMRHALRDHLVKLGTPGNWDHIVNQCGM +FSFTGLTPQMVKRLEETHAVYLVASGRASIAGLNQGNVEYVAKAIDEVVRFYTIEAKL +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-07-01" modified="2015-10-14" version="135"> +<accession>Q01802</accession> +<accession>D6VXI2</accession> +<name>AATM_YEAST</name> +<protein> +<recommendedName> +<fullName>Aspartate aminotransferase, mitochondrial</fullName> +<ecNumber>2.6.1.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AAT1</name> +<name type="ordered locus">YKL106W</name> +<name type="ORF">YKL461</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N6-(pyridoxal phosphate)lysine" evidence="1"> +<location> +<position position="286"/> +</location> +</feature> +<sequence length="451" mass="51795" checksum="758A90434CDBAA7A" modified="2005-12-06" version="2" precursor="true"> +MLRTRLTNCSLWRPYYTSSLSRVPRAPPDKVLGLSEHFKKVKNVNKIDLTVGIYKDGWGK +VTTFPSVAKAQKLIESHLELNKNLSYLPITGSKEFQENVMKFLFKESCPQFGPFYLAHDR +ISFVQTLSGTGALAVAAKFLALFISRDIWIPDPSWANHKNIFQNNGFENIYRYSYYKDGQ +IDIDGWIEQLKTFAYNNQQENNKNPPCIILHACCHNPTGLDPTKEQWEKIIDTIYELKMV +PIVDMAYQGLESGNLLKDAYLLRLCLNVNKYPNWSNGIFLCQSFAKNMGLYGERVGSLSV +ITPATANNGKFNPLQQKNSLQQNIDSQLKKIVRGMYSSPPGYGSRVVNVVLSDFKLKQQW +FKDVDFMVQRLHHVRQEMFDRLGWPDLVNFAQQHGMFYYTRFSPKQVEILRNNYFVYLTG +DGRLSLSGVNDSNVDYLCESLEAVSKMDKLA +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2001-09-26" modified="2015-09-16" version="134"> +<accession>Q08641</accession> +<accession>D6W2U2</accession> +<accession>Q08644</accession> +<name>AB140_YEAST</name> +<protein> +<recommendedName> +<fullName>tRNA(Thr) (cytosine(32)-N(3))-methyltransferase</fullName> +<ecNumber>2.1.1.268</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ABP140</name> +<name type="synonym">TRM140</name> +<name type="ordered locus">YOR239W</name> +<name type="ORF">YOR240W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="1 3"> +<location> +<position position="93"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="2"> +<location> +<position position="150"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1 3"> +<location> +<position position="321"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1 2 3"> +<location> +<position position="326"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="3"> +<location> +<position position="347"/> +</location> +</feature> +<sequence length="628" mass="71486" checksum="74F9CA30BC5BCABF" modified="2007-01-23" version="3"> +MGVADLIKKFESISKEEGDATVDTNSSSKPLKSNDETKELHQQESTAVPQEVDVNEEFEN +EPETINSSRTAEKPLETNLPKPETNEEDEEEGSMSENKIYSKGENADINVNDFQEYKEME +NTGAEVLASSVEESDAIQEGVAEETEGIATPKQKENEKNDESEEESANNASEPAEEYSQS +EEDADIEQSNGKETENAENASQQANDGSTSTTTSKNKKKKNKKKNKKKRNGNVNTNANVD +DSTKTGENDDTTGDTTSSTTSAIQEVNDLEVVDDSCLGIDQQHNREHLKALTQDVKEETL +ENIAHEGRGDNTGDQNAVEKSDFEKSDTEGSRIGRDLPFEFGKRNLTEESDVWDHNAWDN +VEWGEEQVQQAEEKIKEQFKHPVPEFDKKLYNENPARYWDIFYKNNKENFFKDRKWLQIE +FPILYASTRKDAEPVTIFEIGCGAGNTFFPILKDNENENLRIIAADFAPRAVELVKNSEQ +FNPKYGHATVWDLANPDGNLPDGVEPHSVDIAVMIFVFSALAPNQWDQAMDNLHKILKPG +GKIIFRDYGAYDLTQVRFKKNRILEENFYVRGDGTRVYFFSEEKLREIFTKKYFLENKIG +TDRRLLVNRKRQLKMYRCWVQAVFDVPQ +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1990-01-01" modified="2015-10-14" version="138"> +<accession>P14164</accession> +<accession>D6VXH6</accession> +<name>ABF1_YEAST</name> +<protein> +<recommendedName> +<fullName>ARS-binding factor 1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ABF1</name> +<name type="synonym">BAF1</name> +<name type="synonym">OBF1</name> +<name type="synonym">REB2</name> +<name type="synonym">SBF1</name> +<name type="ordered locus">YKL112W</name> +<name type="ORF">YKL505</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphothreonine" evidence="2"> +<location> +<position position="189"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="193"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="467"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="554"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="618"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine; by PKC" evidence="4"> +<location> +<position position="624"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine; by CK2" evidence="1 2 3 21"> +<location> +<position position="720"/> +</location> +</feature> +<sequence length="731" mass="81753" checksum="BE338DA7C9514DC3" modified="2010-10-05" version="4"> +MDKLVVNYYEYKHPIINKDLAIGAHGGKKFPTLGAWYDVINEYEFQTRCPIILKNSHRNK +HFTFACHLKNCPFKVLLSYAGNAASSETSSPSANNNTNPPGTPDHIHHHSNNMNNEDNDN +NNGSNNKVSNDSKLDFVTDDLEYHLANTHPDDTNDKVESRSNEVNGNNDDDADANNIFKQ +QGVTIKNDTEDDSINKASIDRGLDDESGPTHGNDSGNHRHNEEDDVHTQMTKNYSDVVND +EDINVAIANAVANVDSQSNNKHDGKDDDATNNNDGQDNNTNNDHNNNSNINNNNVGSHGI +SSHSPSSIRDTSMNLDVFNSATDDIPGPFVVTKIEPYHSHPLEDNLSLGKFILTKIPKIL +QNDLKFDQILESSYNNSNHTVSKFKVSHYVEESGLLDILMQRYGLTAEDFEKRLLSQIAR +RITTYKARFVLKKKKMGEYNDLQPSSSSNNNNNNDGELSGTNLRSNSIDYAKHQEISSAG +TSSNTTKNVNNNKNDSNDDNNGNNNNDASNLMESVLDKTSSHRYQPKKMPSVNKWSKPDQ +ITHSDVSMVGLDESNDGGNENVHPTLAEVDAQEARETAQLAIDKINSYKRSIDDKNGDGH +NNSSRNVVDENLINDMDSEDAHKSKRQHLSDITLEERNEDDKLPHEVAEQLRLLSSHLKE +VENLHQNNDDDVDDVMVDVDVESQYNKNTTHHNNHHSQPHHDEEDVAGLIGKADDEEDLS +DENIQPELRGQ +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-07-01" modified="2015-10-14" version="137"> +<accession>Q02486</accession> +<accession>D6VZP6</accession> +<accession>Q712M5</accession> +<name>ABF2_YEAST</name> +<protein> +<recommendedName> +<fullName>ARS-binding factor 2, mitochondrial</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ABF2</name> +<name type="synonym">HIM1</name> +<name type="ordered locus">YMR072W</name> +<name type="ORF">YM9916.11</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="183" mass="21562" checksum="D280A7D2B675B5B1" modified="1993-07-01" version="1" precursor="true"> +MNSYSLLTRSFHESSKPLFNLASTLLKASKRTQLRNELIKQGPKRPTSAYFLYLQDHRSQ +FVKENPTLRPAEISKIAGEKWQNLEADIKEKYISERKKLYSEYQKAKKEFDEKLPPKKPA +GPFIKYANEVRSQVFAQHPDKSQLDLMKIIGDKWQSLDQSIKDKYIQEYKKAIQEYNARY +PLN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-02-01" modified="2015-10-14" version="84"> +<accession>P47146</accession> +<accession>D6VWS7</accession> +<name>ABM1_YEAST</name> +<protein> +<recommendedName> +<fullName>Aberrant microtubules protein 1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ABM1</name> +<name type="ordered locus">YJR108W</name> +<name type="ORF">J1988</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="predicted"/> +<sequence length="123" mass="14204" checksum="6BADF1E0D50FB3CE" modified="1996-02-01" version="1"> +MSWRYSILTVDGSFKIFIPWEIFLTWNFLSAAWLNSTESNTYIHYSTCWGTSDYTLNISV +IEATTEKLVDTRLLTTLENATAWINSNSIDEDEDDMPHATNVADRLDGLSLSKRVYSICH +YEF +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1990-04-01" modified="2015-10-14" version="160"> +<accession>P15891</accession> +<accession>D6VR88</accession> +<name>ABP1_YEAST</name> +<protein> +<recommendedName> +<fullName>Actin-binding protein</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ABP1</name> +<name type="ordered locus">YCR088W</name> +<name type="ORF">YCR88W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N-acetylalanine" evidence="8 20"> +<location> +<position position="2"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="7"> +<location> +<position position="165"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="7"> +<location> +<position position="167"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4 6 7"> +<location> +<position position="169"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="4 5 6 7"> +<location> +<position position="181"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4 6"> +<location> +<position position="183"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="6 7"> +<location> +<position position="313"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="5 6 7"> +<location> +<position position="365"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4 6"> +<location> +<position position="389"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="6"> +<location> +<position position="458"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="5 6"> +<location> +<position position="481"/> +</location> +</feature> +<sequence length="592" mass="65576" checksum="39523510704D94AA" modified="2007-01-23" version="4"> +MALEPIDYTTHSREIDAEYLKIVRGSDPDTTWLIISPNAKKEYEPESTGSSFHDFLQLFD +ETKVQYGLARVSPPGSDVEKIIIIGWCPDSAPLKTRASFAANFAAVANNLFKGYHVQVTA +RDEDDLDENELLMKISNAAGARYSIQTSSKQQGKASTPPVKKSFTPSKSPAPVSKKEPVK +TPSPAPAAKISSRVNDNNDDDDWNEPELKERDFDQAPLKPNQSSYKPIGKIDLQKVIAEE +KAKEDPRLVQKPTAAGSKIDPSSDIANLKNESKLKRDSEFNSFLGTTKPPSMTESSLKND +DDKVIKGFRNEKSPAQLWAERKAKQNSGNAETKAEAPKPEVPEDEPEGEPDVKDLKSKFE +GLAASEKEEEEMENKFAPPPKKSEPTIISPKPFSKPQEPVKAEEAEQPKTDYKKIGNPLP +GMHIEADNEEEPEENDDDWDDDEDEAAQPPLPSRNVASGAPVQKEEPEQEEIAPSLPSRN +SIPAPKQEEAPEQAPEEEIEEEAEEAAPQLPSRSSAAPPPPPRRATPEKKPKENPWATAE +YDYDAAEDNELTFVENDKIINIEFVDDDWWLGELEKDGSKGLFPSNYVSLGN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-02-01" modified="2015-10-14" version="124"> +<accession>P39970</accession> +<accession>D3DLU6</accession> +<name>ACA1_YEAST</name> +<protein> +<recommendedName> +<fullName>ATF/CREB activator 1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ACA1</name> +<name type="ordered locus">YER045C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at transcript level"/> +<sequence length="489" mass="54592" checksum="2850D6C3DDF5C29D" modified="1995-02-01" version="1"> +MDYKHNFATSPDSFLDGRQNPLLYTDFLSSNKELIYKQPSGPGLVDSAYNFHHQNSLHDR +SVQENLGPMFQPFGVDISHLPITNPPIFQSSLPAFDQPVYKRRISISNGQISQLGEDLET +VENLYNCQPPILSSKAQQNPNPQQVANPSAAIYPSFSSNELQNVPQPHEQATVIPEAAPQ +TGSKNIYAAMTPYDSNIKLNIPAVAATCDIPSATPSIPSGDSTMNQAYINMQLRLQAQMQ +TKAWKNAQLNVHPCTPASNSSVSSSSSCQNINDHNIENQSVHSSISHGVNHHTVNNSCQN +AELNISSSLPYESKCPDVNLTHANSKPQYKDATSALKNNINSEKDVHTAPFSSMHTTATF +QIKQEARPQKIENNTAGLKDGAKAWKRARLLERNRIAASKCRQRKKMSQLQLQREFDQIS +KENTMMKKKIENYEKLVQKMKKISRLHMQECTINGGNNSYQSLQNKDSDVNGFLKMIEEM +IRSSSLYDE +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-02-01" modified="2015-10-14" version="125"> +<accession>P40535</accession> +<accession>D6VVP6</accession> +<name>ACA2_YEAST</name> +<protein> +<recommendedName> +<fullName>ATF/CREB activator 2</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">CST6</name> +<name type="synonym">ACA2</name> +<name type="ordered locus">YIL036W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="171"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="179"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="399"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2 3 4"> +<location> +<position position="557"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="1 2 3 4"> +<location> +<position position="559"/> +</location> +</feature> +<sequence length="587" mass="65264" checksum="1B98DC38BC8CAE94" modified="1995-02-01" version="1"> +MFTGQEYHSVDSNSNKQKDNNKRGIDDTSKILNNKIPHSVSDTSAAATTTSTMNNSALSR +SLDPTDINYSTNMAGVVDQIHDYTTSNRNSLTPQYSIAAGNVNSHDRVVKPSANSNYQQA +AYLRQQQQQDQRQQSPSMKTEEESQLYGDILMNSGVVQDMHQNLATHTNLSQLSSTRKSA +PNDSTTAPTNASNIANTASVNKQMYFMNMNMNNNPHALNDPSILETLSPFFQPFGVDVAH +LPMTNPPIFQSSLPGCDEPIRRRRISISNGQISQLGEDIETLENLHNTQPPPMPNFHNYN +GLSQTRNVSNKPVFNQAVPVSSIPQYNAKKVINPTKDSALGDQSVIYSKSQQRNFVNAPS +KNTPAESISDLEGMTTFAPTTGGENRGKSALRESHSNPSFTPKSQGSHLNLAANTQGNPI +PGTTAWKRARLLERNRIAASKCRQRKKVAQLQLQKEFNEIKDENRILLKKLNYYEKLISK +FKKFSKIHLREHEKLNKDSDNNVNGTNSSNKNESMTVDSLKIIEELLMIDSDVTEVDKDT +GKIIAIKHEPYSQRFGSDTDDDDIDLKPVEGGKDPDNQSLPNSEKIK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-04-01" modified="2015-10-14" version="170"> +<accession>Q00955</accession> +<accession>D6W1J1</accession> +<name>ACAC_YEAST</name> +<protein> +<recommendedName> +<fullName>Acetyl-CoA carboxylase</fullName> +<shortName>ACC</shortName> +<ecNumber evidence="22 26">6.4.1.2</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ACC1</name> +<name type="synonym">ABP2</name> +<name type="synonym">FAS3</name> +<name type="synonym">MTR7</name> +<name type="ordered locus">YNR016C</name> +<name type="ORF">N3175</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N-acetylserine" evidence="11 15"> +<location> +<position position="2"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="11"> +<location> +<position position="2"/> +</location> +</feature> +<feature type="modified residue" description="N6-biotinyllysine" evidence="16 20"> +<location> +<position position="735"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="14"> +<location> +<position position="790"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="11 13 14"> +<location> +<position position="1148"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="11 12 13 14"> +<location> +<position position="1157"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="14"> +<location> +<position position="1162"/> +</location> +</feature> +<sequence length="2233" mass="250353" checksum="0A335AAD9B1F8308" modified="1996-10-01" version="2"> +MSEESLFESSPQKMEYEITNYSERHTELPGHFIGLNTVDKLEESPLRDFVKSHGGHTVIS +KILIANNGIAAVKEIRSVRKWAYETFGDDRTVQFVAMATPEDLEANAEYIRMADQYIEVP +GGTNNNNYANVDLIVDIAERADVDAVWAGWGHASENPLLPEKLSQSKRKVIFIGPPGNAM +RSLGDKISSTIVAQSAKVPCIPWSGTGVDTVHVDEKTGLVSVDDDIYQKGCCTSPEDGLQ +KAKRIGFPVMIKASEGGGGKGIRQVEREEDFIALYHQAANEIPGSPIFIMKLAGRARHLE +VQLLADQYGTNISLFGRDCSVQRRHQKIIEEAPVTIAKAETFHEMEKAAVRLGKLVGYVS +AGTVEYLYSHDDGKFYFLELNPRLQVEHPTTEMVSGVNLPAAQLQIAMGIPMHRISDIRT +LYGMNPHSASEIDFEFKTQDATKKQRRPIPKGHCTACRITSEDPNDGFKPSGGTLHELNF +RSSSNVWGYFSVGNNGNIHSFSDSQFGHIFAFGENRQASRKHMVVALKELSIRGDFRTTV +EYLIKLLETEDFEDNTITTGWLDDLITHKMTAEKPDPTLAVICGAATKAFLASEEARHKY +IESLQKGQVLSKDLLQTMFPVDFIHEGKRYKFTVAKSGNDRYTLFINGSKCDIILRQLSD +GGLLIAIGGKSHTIYWKEEVAATRLSVDSMTTLLEVENDPTQLRTPSPGKLVKFLVENGE +HIIKGQPYAEIEVMKMQMPLVSQENGIVQLLKQPGSTIVAGDIMAIMTLDDPSKVKHALP +FEGMLPDFGSPVIEGTKPAYKFKSLVSTLENILKGYDNQVIMNASLQQLIEVLRNPKLPY +SEWKLHISALHSRLPAKLDEQMEELVARSLRRGAVFPARQLSKLIDMAVKNPEYNPDKLL +GAVVEPLADIAHKYSNGLEAHEHSIFVHFLEEYYEVEKLFNGPNVREENIILKLRDENPK +DLDKVALTVLSHSKVSAKNNLILAILKHYQPLCKLSSKVSAIFSTPLQHIVELESKATAK +VALQAREILIQGALPSVKERTEQIEHILKSSVVKVAYGSSNPKRSEPDLNILKDLIDSNY +VVFDVLLQFLTHQDPVVTAAAAQVYIRRAYRAYTIGDIRVHEGVTVPIVEWKFQLPSAAF +STFPTVKSKMGMNRAVSVSDLSYVANSQSSPLREGILMAVDHLDDVDEILSQSLEVIPRH +QSSSNGPAPDRSGSSASLSNVANVCVASTEGFESEEEILVRLREILDLNKQELINASIRR +ITFMFGFKDGSYPKYYTFNGPNYNENETIRHIEPALAFQLELGRLSNFNIKPIFTDNRNI +HVYEAVSKTSPLDKRFFTRGIIRTGHIRDDISIQEYLTSEANRLMSDILDNLEVTDTSNS +DLNHIFINFIAVFDISPEDVEAAFGGFLERFGKRLLRLRVSSAEIRIIIKDPQTGAPVPL +RALINNVSGYVIKTEMYTEVKNAKGEWVFKSLGKPGSMHLRPIATPYPVKEWLQPKRYKA +HLMGTTYVYDFPELFRQASSSQWKNFSADVKLTDDFFISNELIEDENGELTEVEREPGAN +AIGMVAFKITVKTPEYPRGRQFVVVANDITFKIGSFGPQEDEFFNKVTEYARKRGIPRIY +LAANSGARIGMAEEIVPLFQVAWNDAANPDKGFQYLYLTSEGMETLKKFDKENSVLTERT +VINGEERFVIKTIIGSEDGLGVECLRGSGLIAGATSRAYHDIFTITLVTCRSVGIGAYLV +RLGQRAIQVEGQPIILTGAPAINKMLGREVYTSNLQLGGTQIMYNNGVSHLTAVDDLAGV +EKIVEWMSYVPAKRNMPVPILETKDTWDRPVDFTPTNDETYDVRWMIEGRETESGFEYGL +FDKGSFFETLSGWAKGVVVGRARLGGIPLGVIGVETRTVENLIPADPANPNSAETLIQEP +GQVWHPNSAFKTAQAINDFNNGEQLPMMILANWRGFSGGQRDMFNEVLKYGSFIVDALVD +YKQPIIIYIPPTGELRGGSWVVVDPTINADQMEMYADVNARAGVLEPQGMVGIKFRREKL +LDTMNRLDDKYRELRSQLSNKSLAPEVHQQISKQLADRERELLPIYGQISLQFADLHDRS +SRMVAKGVISKELEWTEARRFFFWRLRRRLNEEYLIKRLSHQVGEASRLEKIARIRSWYP +ASVDHEDDRQVATWIEENYKTLDDKLKGLKLESFAQDLAKKIRSDHDNAIDGLSEVIKML +STDDKEKLLKTLK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-07-01" modified="2015-07-22" version="132"> +<accession>P31787</accession> +<accession>D6VUH4</accession> +<accession>Q45U46</accession> +<name>ACBP_YEAST</name> +<protein> +<recommendedName> +<fullName>Acyl-CoA-binding protein</fullName> +<shortName>ACBP</shortName> +</recommendedName> +</protein> +<gene> +<name type="primary">ACB1</name> +<name type="synonym">ACB</name> +<name type="ordered locus">YGR037C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="87" mass="10061" checksum="686B186195EA02FC" modified="2007-01-23" version="3"> +MVSQLFEEKAKAVNELPTKPSTDELLELYALYKQATVGDNDKEKPGIFNMKDRYKWEAWE +NLKGKSQEDAEKEYIALVDQLIAKYSS +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1991-05-01" modified="2015-10-14" version="158"> +<accession>P21192</accession> +<accession>D6VYC6</accession> +<name>ACE2_YEAST</name> +<protein> +<recommendedName> +<fullName>Metallothionein expression activator</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ACE2</name> +<name type="ordered locus">YLR131C</name> +<name type="ORF">L3123</name> +<name type="ORF">L9606.10</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="1 2 4"> +<location> +<position position="80"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="122"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="247"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="249"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="253"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="4"> +<location> +<position position="259"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="385"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="392"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="483"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="4"> +<location> +<position position="486"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="4"> +<location> +<position position="501"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="564"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="709"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="714"/> +</location> +</feature> +<sequence length="770" mass="86634" checksum="A7FCA8C506A2FD75" modified="1991-05-01" version="1"> +MDNVVDPWYINPSGFAKDTQDEEYVQHHDNVNPTIPPPDNYILNNENDDGLDNLLGMDYY +NIDDLLTQELRDLDIPLVPSPKTGDGSSDKKNIDRTWNLGDENNKVSHYSKKSMSSHKRG +LSGTAIFGFLGHNKTLSISSLQQSILNMSKDPQPMELINELGNHNTVKNNNDDFDHIREN +DGENSYLSQVLLKQQEELRIALEKQKEVNEKLEKQLRDNQIQQEKLRKVLEEQEEVAQKL +VSGATNSNSKPGSPVILKTPAMQNGRMKDNAIIVTTNSANGGYQFPPPTLISPRMSNTSI +NGSPSRKYHRQRYPNKSPESNGLNLFSSNSGYLRDSELLSFSPQNYNLNLDGLTYNDHNN +TSDKNNNDKKNSTGDNIFRLFEKTSPGGLSISPRINGNSLRSPFLVGTDKSRDDRYAAGT +FTPRTQLSPIHKKRESVVSTVSTISQLQDDTEPIHMRNTQNPTLRNANALASSSVLPPIP +GSSNNTPIKNSLPQKHVFQHTPVKAPPKNGSNLAPLLNAPDLTDHQLEIKTPIRNNSHCE +VESYPQVPPVTHDIHKSPTLHSTSPLPDEIIPRTTPMKITKKPTTLPPGTIDQYVKELPD +KLFECLYPNCNKVFKRRYNIRSHIQTHLQDRPYSCDFPGCTKAFVRNHDLIRHKISHNAK +KYICPCGKRFNREDALMVHRSRMICTGGKKLEHSINKKLTSPKKSLLDSPHDTSPVKETI +ARDKDGSVLMKMEEQLRDDMRKHGLLDPPPSTAAHEQNSNRTLSNETDAL +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1992-12-01" modified="2015-10-14" version="136"> +<accession>P28240</accession> +<accession>D3DLX0</accession> +<name>ACEA_YEAST</name> +<protein> +<recommendedName> +<fullName evidence="24">Isocitrate lyase</fullName> +<shortName evidence="26">ICL</shortName> +<ecNumber evidence="5 11 15 17">4.1.3.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary" evidence="24">ICL1</name> +<name type="ordered locus" evidence="29">YER065C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphothreonine" evidence="2"> +<location> +<position position="53"/> +</location> +</feature> +<sequence length="557" mass="62409" checksum="15CC5A169CCEBE8B" modified="1992-12-01" version="1"> +MPIPVGNTKNDFAALQAKLDADAAEIEKWWSDSRWSKTKRNYSARDIAVRRGTFPPIEYP +SSVMARKLFKVLEKHHNEGTVSKTFGALDPVQISQMAKYLDTIYISGWQCSSTASTSNEP +GPDLADYPMDTVPNKVEHLFKAQLFHDRKQLEARSKAKSQEELDEMGAPIDYLTPIVADA +DAGHGGLTAVFKLTKMFIERGAAGIHMEDQTSTNKKCGHMAGRCVIPVQEHVNRLVTIRM +CADIMHSDLIVVARTDSEAATLISSTIDTRDHYFIVGATNPNIEPFAEVLNDAIMSGASG +QELADIEQKWCRDAGLKLFHEAVIDEIERSALSNKQELIKKFTSKVGPLTETSHREAKKL +AKEILGHEIFFDWELPRVREGLYRYRGGTQCSIMRARAFAPYADLVWMESNYPDFQQAKE +FAEGVKEKFPDQWLAYNLSPSFNWPKAMSVDEQHTFIQRLGDLGYIWQFITLAGLHTNAL +AVHNFSRDFAKDGMKAYAQNVQQREMDDGVDVLKHQKWSGAEYIDGLLKLAQGGVSATAA +MGTGVTEDQFKENGVKK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1997-11-01" modified="2015-10-14" version="124"> +<accession>Q12031</accession> +<accession>D6W417</accession> +<name>ACEB_YEAST</name> +<protein> +<recommendedName> +<fullName>Mitochondrial 2-methylisocitrate lyase</fullName> +<shortName>Methylisocitrate lyase</shortName> +<ecNumber>4.1.3.30</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ICL2</name> +<name type="ordered locus">YPR006C</name> +<name type="ORF">LPZ6C</name> +<name type="ORF">YP9723.06C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="575" mass="64976" checksum="C29A9A62A02BD291" modified="1997-11-01" version="1"> +MITMINNKTFNRKTTGTLKKLVLSSDKSLRRSFNGASSTKDFVFSESSKVEEWWESARFK +NISRPYSATDVVKHRGSLPANTSIYPSSYQARKLFNLLEENFKNGTPLHTLGVIDPVQMS +QLARCRNIKVAYISGWACSSTLVGSTNEVSPDFGDYPYDTVPNQVERIFKAQQLHDRKAF +LEASIKGSTPVDYLKPIIADADMGHGGPTTVMKVAKLFAEKGAAGIHLEDQMVGGKRCGH +LSGAVLVPTATHLMRLISTRFQWDIMGTENLVIARTDSCNGKLLSSSSDPRDHEFIRGII +RDNVVPWSEKLIEMEDKKIPNSAIADMEKEWYHENELFTFEEALEKQFTASEFESYKEKK +EDLMVNKLGRAYLSLREMKLLAQEVTPLKKIIFDWDAPRTKEGYYMFNGCIEAAIRRSLV +FAPYSDMIWLETKTPDLEQARSFSRKIHKQLPATKLVYNLSPSFNWSAHGFDDKALKSFV +WDLAKEGFTLQLVSLAGLHSDGVSFWELANSFQSDGMKAYVEKVQKREKETNCDIMTHQL +WSGAEYVDSLMKVVQNGASSQTLSTSGESFTETQF +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-02-01" modified="2015-10-14" version="102"> +<accession>P47129</accession> +<accession>D6VWQ2</accession> +<name>ACF4_YEAST</name> +<protein> +<recommendedName> +<fullName>Assembly-complementing factor 4</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ACF4</name> +<name type="ordered locus">YJR083C</name> +<name type="ORF">J1857</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="44"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2 3"> +<location> +<position position="71"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2 3 4"> +<location> +<position position="74"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2 4"> +<location> +<position position="78"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2 3 4"> +<location> +<position position="165"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2 3 4"> +<location> +<position position="288"/> +</location> +</feature> +<sequence length="309" mass="35521" checksum="FE29E8D0192B2113" modified="1996-02-01" version="1"> +MSEDQRVISQPIELHKLSIVDKHSQGQQQQPHQKQHEVQPESKSPRVTTPLKPKRLAIPI +SSPQRSTTNQSPVSDHASPISTDQDLIYKLAAKHREINELSFKLEVAQKELKQLELQFKD +TLPRNGQQKLGNQNPSEYLSTFTKRIQQTFVDVNNSPNMLKGKKSINDFFSKPNNNVNSN +INNTLPNRKPNPPPNRSQRMQNIAPSRSSESTPTSGPPLLPPRNTMKNANTTATAGENTP +FLQRILNKFNQMNMEEDEFDDLLEKRKSKKDHYYIKENLGYEYDEVRSEDEDDEEFEPMG +DIPVHLFKR +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-10-01" modified="2015-10-14" version="128"> +<accession>P32316</accession> +<accession>D6VPY5</accession> +<name>ACH1_YEAST</name> +<protein> +<recommendedName> +<fullName>Acetyl-CoA hydrolase</fullName> +<ecNumber>3.1.2.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ACH1</name> +<name type="ordered locus">YBL015W</name> +<name type="ORF">YBL03.18</name> +<name type="ORF">YBL0304</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Blocked amino end (Thr)"> +<location> +<position position="2"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="350"/> +</location> +</feature> +<sequence length="526" mass="58712" checksum="7133A291F18AA1E4" modified="2005-01-04" version="2"> +MTISNLLKQRVRYAPYLKKVKEAHELIPLFKNGQYLGWSGFTGVGTPKAVPEALIDHVEK +NNLQGKLRFNLFVGASAGPEENRWAEHDMIIKRAPHQVGKPIAKAINQGRIEFFDKHLSM +FPQDLTYGFYTRERKDNKILDYTIIEATAIKEDGSIVPGPSVGGSPEFITVSDKVIIEVN +TATPSFEGIHDIDMPVNPPFRKPYPYLKVDDKCGVDSIPVDPEKVVAIVESTMRDQVPPN +TPSDDMSRAIAGHLVEFFRNEVKHGRLPENLLPLQSGIGNIANAVIEGLAGAQFKHLTVW +TEVLQDSFLDLFENGSLDYATATSVRLTEKGFDRAFANWENFKHRLCLRSQVVSNNPEMI +RRLGVIAMNTPVEVDIYAHANSTNVNGSRMLNGLGGSADFLRNAKLSIMHAPSARPTKVD +PTGISTIVPMASHVDQTEHDLDILVTDQGLADLRGLSPKERAREIINKCAHPDYQALLTD +YLDRAEHYAKKHNCLHEPHMLKNAFKFHTNLAEKGTMKVDSWEPVD +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2006-06-27" modified="2015-10-14" version="113"> +<accession>Q07622</accession> +<accession>D6VRF1</accession> +<name>ACK1_YEAST</name> +<protein> +<recommendedName> +<fullName>Activator of C kinase protein 1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ACK1</name> +<name type="ordered locus">YDL203C</name> +<name type="ORF">D1066</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="623" mass="69371" checksum="5CBB9D907443EC2E" modified="1996-11-01" version="1"> +MVNQGQPQPNLYDKHINMFPPARARESSHKLGNANSDRHGLPAQNIVPAPYPVDDSIVEL +TPAIPFTSPSSSSSLSLPLSALNFTDGNADGGQLGTPVTINSNNGMDIFNSKPTGEIGYA +NNGTNSTGSRYELPFNFSSTKESLGSPAVQDASISSGNRISESVRDNSAPPPYEESESRI +LQEKVYRTEEKAPIRPLNNNPVPPQKINQPPTGSAKTDDNGSSGGEDKLSSYSPEALAFY +QVYKKTITDSSKFTPEIQMQWCETLLTYAFNEDFISQYNINAEKLKRSLKPEEMLKNQKV +ILEHSFKVLTKLITLKWPPAMYLMGTLYSHQPYLPIKNKNIVIKNDEKALEYYCKAAKLN +NSDACYRAGVCFEYQRGTSSLDPSPTKEQCIKKAFQYYQHGAEVCSNSACMYKLGMSHLY +GLNMQKTDVLLAIKWFDKAAQKGDSPQTLYELGKIYEFSVLPPEIQNLLFANGIRKDSQL +AIKYYQQCAKDFEYPLAQWKLGNCYEFGDLGLPVVAKKSIYWYSKAAAAQPKGNPMAMLS +LSGWYLTGAPNILKPNNKEAFNWALKSSKCSDGKLARTEFALGFYYEKGVGCEVDLDLAK +QYYQRAARMGFRKAVDALRSLTN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2006-10-17" modified="2015-10-14" version="101"> +<accession>Q03771</accession> +<accession>D6VSE1</accession> +<name>ACL4_YEAST</name> +<protein> +<recommendedName> +<fullName evidence="5">Assembly chaperone of RPL4</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary" evidence="5">ACL4</name> +<name type="ordered locus" evidence="7">YDR161W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N-acetylserine" evidence="1"> +<location> +<position position="2"/> +</location> +</feature> +<sequence length="387" mass="42943" checksum="539F5C1AB133614E" modified="1996-11-01" version="1"> +MSELEATIRQAKEALAENNAKKALKILKPFKSSLKKENANNVILNEVFADAYLDNGQVEK +AYPILARACELDPEGQVGGPDKFFTMGQIMGGQDGVSIITRGIMNISNTGGEMLTNVQVE +KIVGGLLSVIEIWMTDLCMEPNAEEQCEELIQKAMELTEGKSPETWSTLGSIKISQQKFG +EAYEAFSQAWNFFELKKQEIGSGINENGDTTQKAGLQSEYVDLLQPLLSLTKMCLEVGAY +EVALKVIAAVRDIDEDNIEGYYLEGFTYYLMSKLEIFKLNNPEVSLRPENIYEFNQLIQE +VPLDLSHEPISQLIYDSRLALSFALQAGVNADSKDEIVQELLGGANALLQEIGGPLDPSE +LTQIKKGDLVNENEDLEELDIEEEYSD +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2006-12-12" modified="2015-10-14" version="100"> +<accession>Q08981</accession> +<accession>D6W3A3</accession> +<name>ACM1_YEAST</name> +<protein> +<recommendedName> +<fullName>APC/C-CDH1 modulator 1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ACM1</name> +<name type="ordered locus">YPL267W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="48"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="2 3"> +<location> +<position position="161"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2 3 4"> +<location> +<position position="202"/> +</location> +</feature> +<sequence length="209" mass="23870" checksum="0646D4E3AD41758C" modified="1996-11-01" version="1"> +MISPSKKRTILSSKNINQKPRAVVKGNELRSPSKRRSQIDTDYALRRSPIKTIQISKAAQ +FMLYEETAEERNIAVHRHNEIYNNNNSVSNENNPSQVKENLSPAKICPYERAFLREGGRI +ALKDLSVDEFKGYIQDPLTDETIPLTLPLGDKKISLPSFITPPRNSKISIFFTSKHQGQN +PETKISRSTDDVSEKKVVRKLSFHVYEDE +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1991-05-01" modified="2015-10-14" version="154"> +<accession>P21147</accession> +<accession>D6VU86</accession> +<accession>E9P911</accession> +<name>ACO1_YEAST</name> +<protein> +<recommendedName> +<fullName>Acyl-CoA desaturase 1</fullName> +<ecNumber evidence="6 7">1.14.19.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">OLE1</name> +<name type="ordered locus">YGL055W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="510" mass="58403" checksum="A6CC78DD4210ECCA" modified="1996-10-01" version="2"> +MPTSGTTIELIDDQFPKDDSASSGIVDEVDLTEANILATGLNKKAPRIVNGFGSLMGSKE +MVSVEFDKKGNEKKSNLDRLLEKDNQEKEEAKTKIHISEQPWTLNNWHQHLNWLNMVLVC +GMPMIGWYFALSGKVPLHLNVFLFSVFYYAVGGVSITAGYHRLWSHRSYSAHWPLRLFYA +IFGCASVEGSAKWWGHSHRIHHRYTDTLRDPYDARRGLWYSHMGWMLLKPNPKYKARADI +TDMTDDWTIRFQHRHYILLMLLTAFVIPTLICGYFFNDYMGGLIYAGFIRVFVIQQATFC +INSLAHYIGTQPFDDRRTPRDNWITAIVTFGEGYHNFHHEFPTDYRNAIKWYQYDPTKVI +IYLTSLVGLAYDLKKFSQNAIEEALIQQEQKKINKKKAKINWGPVLTDLPMWDKQTFLAK +SKENKGLVIISGIVHDVSGYISEHPGGETLIKTALGKDATKAFSGGVYRHSNAAQNVLAD +MRVAVIKESKNSAIRMASKRGEIYETGKFF +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-02-01" modified="2015-10-14" version="124"> +<accession>P39533</accession> +<accession>D6VVZ3</accession> +<name>ACON2_YEAST</name> +<protein> +<recommendedName> +<fullName>Homocitrate dehydratase, mitochondrial</fullName> +<ecNumber>4.2.1.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ACO2</name> +<name type="ordered locus">YJL200C</name> +<name type="ORF">J0327</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="789" mass="86583" checksum="FABA4FE482D3F993" modified="1995-02-01" version="1" precursor="true"> +MLSSANRFYIKRHLATHANMFPSVSKNFQTKVPPYAKLLTNLDKIKQITNNAPLTLAEKI +LYSHLCDPEESITSSDLSTIRGNKYLKLNPDRVAMQDASAQMALLQFMTTGLNQTSVPAS +IHCDHLIVGKDGETKDLPSSIATNQEVFDFLESCAKRYGIQFWGPGSGIIHQIVLENFSA +PGLMMLGTDSHTPNAGGLGAIAIGVGGADAVDALTGTPWELKAPKILGVKLTGKLNGWST +PKDVITKLAGLLTVRGGTGYIVEYFGEGVSTLSCTGMATICNMGAEIGATTSTFPYQEAH +KRYLQATNRAEVAEAADVALNKFNFLRADKDAQYDKVIEIDLSAIEPHVNGPFTPDLSTP +ISQYAEKSLKENWPQKVSAGLIGSCTNSSYQDMSRVVDLVKQASKAGLKPRIPFFVTPGS +EQIRATLERDGIIDIFQENGAKVLANACGPCIGQWNREDVSKTSKETNTIFTSFNRNFRA +RNDGNRNTMNFLTSPEIVTAMSYSGDAQFNPLTDSIKLPNGKDFKFQPPKGDELPKRGFE +HGRDKFYPEMDPKPDSNVEIKVDPNSDRLQLLEPFKPWNGKELKTNVLLKVEGKCTTDHI +SAAGVWLKYKGHLENISYNTLIGAQNKETGEVNKAYDLDGTEYDIPGLMMKWKSDGRPWT +VIAEHNYGEGSAREHAALSPRFLGGEILLVKSFARIHETNLKKQGVLPLTFANESDYDKI +SSGDVLETLNLVDMIAKDGNNGGEIDVKITKPNGESFTIKAKHTMSKDQIDFFKAGSAIN +YIGNIRRNE +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1990-11-01" modified="2015-10-14" version="154"> +<accession>P19414</accession> +<accession>D6VYU7</accession> +<name>ACON_YEAST</name> +<protein> +<recommendedName> +<fullName>Aconitate hydratase, mitochondrial</fullName> +<shortName>Aconitase</shortName> +<ecNumber>4.2.1.3</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ACO1</name> +<name type="synonym">GLU1</name> +<name type="ordered locus">YLR304C</name> +<name type="ORF">L8003.22</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="391"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="2"> +<location> +<position position="409"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="556"/> +</location> +</feature> +<sequence length="778" mass="85368" checksum="AA9EB9A24388090E" modified="1995-11-01" version="2" precursor="true"> +MLSARSAIKRPIVRGLATVSNLTRDSKVNQNLLEDHSFINYKQNVETLDIVRKRLNRPFT +YAEKILYGHLDDPHGQDIQRGVSYLKLRPDRVACQDATAQMAILQFMSAGLPQVAKPVTV +HCDHLIQAQVGGEKDLKRAIDLNKEVYDFLASATAKYNMGFWKPGSGIIHQIVLENYAFP +GALIIGTDSHTPNAGGLGQLAIGVGGADAVDVMAGRPWELKAPKILGVKLTGKMNGWTSP +KDIILKLAGITTVKGGTGKIVEYFGDGVDTFSATGMGTICNMGAEIGATTSVFPFNKSMI +EYLEATGRGKIADFAKLYHKDLLSADKDAEYDEVVEIDLNTLEPYINGPFTPDLATPVSK +MKEVAVANNWPLDVRVGLIGSCTNSSYEDMSRSASIVKDAAAHGLKSKTIFTVTPGSEQI +RATIERDGQLETFKEFGGIVLANACGPCIGQWDRRDIKKGDKNTIVSSYNRNFTSRNDGN +PQTHAFVASPELVTAFAIAGDLRFNPLTDKLKDKDGNEFMLKPPHGDGLPQRGYDAGENT +YQAPPADRSTVEVKVSPTSDRLQLLKPFKPWDGKDAKDMPILIKAVGKTTTDHISMAGPW +LKYRGHLENISNNYMIGAINAENKKANCVKNVYTGEYKGVPDTARDYRDQGIKWVVIGDE +NFGEGSSREHAALEPRFLGGFAIITKSFARIHETNLKKQGLLPLNFKNPADYDKINPDDR +IDILGLAELAPGKPVTMRVHPKNGKPWDAVLTHTFNDEQIEWFKYGSALNKIKADEKK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1990-01-01" modified="2015-10-14" version="148"> +<accession>P13711</accession> +<accession>D6VTV0</accession> +<name>ACOX_YEAST</name> +<protein> +<recommendedName> +<fullName>Acyl-coenzyme A oxidase</fullName> +<shortName>Acyl-CoA oxidase</shortName> +<ecNumber>1.3.3.6</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">POX1</name> +<name type="synonym">FOX1</name> +<name type="ordered locus">YGL205W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="748" mass="84042" checksum="5C0664455A050BDA" modified="1996-10-01" version="2"> +MTRRTTINPDSVVLNPQKFIQKERADSKIKVDQVNTFLESSPERRTLTHALIDQIVNDPI +LKTDTDYYDAKKMQEREITAKKIARLASYMEHDIKTVRKHFRDTDLMKELQANDPDKASP +LTNKDLFIFDKRLSLVANIDPQLGTRVGVHLGLFGNCIKGNGTDEQIRYWLQERGATLMK +GIYGCFAMTELGHGSNVAQLQTRAVYDKQNDTFVIDTPDLTATKWWIGGAAHSATHAAVY +ARLIVEGKDYGVKTFVVPLRDPSTFQLLAGVSIGDIGAKMGRDGIDNGWIQFRNVVIPRE +FMLSRFTKVVRSPDGSVTVKTEPQLDQISGYSALLSGRVNMVMDSFRFGSKFATIAVRYA +VGRQQFAPRKGLSETQLIDYPLHQYRVLPQLCVPYLVSPVAFKLMDNYYSTLDELYNASS +SAYKAALVTVSKKLKNLFIDSASLKATNTWLIATLIDELRQTCGGHGYSQYNGFGKGYDD +WVVQCTWEGDNNVLSLTSAKSILKKFIDSATKGRFDNTLDVDSFSYLKPQYIGSVVSGEI +KSGLKELGDYTEIWSITLIKLLAHIGTLVEKSRSIDSVSKLLVLVSKFHALRCMLKTYYD +KLNSRDSHISDEITKESMWNVYKLFSLYFIDKHSGEFQQFKIFTPDQISKVVQPQLLALL +PIVRKDCIGLTDSFELPDAMLNSPIGYFDGDIYHNYFNEVCRNNPVEADGAGKPSYHALL +SSMLGRGFEFDQKLGGAANAEILSKINK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-10-01" modified="2015-10-14" version="146"> +<accession>P32463</accession> +<accession>D6VX08</accession> +<name>ACPM_YEAST</name> +<protein> +<recommendedName> +<fullName>Acyl carrier protein, mitochondrial</fullName> +<shortName>ACP</shortName> +</recommendedName> +</protein> +<gene> +<name type="primary">ACP1</name> +<name type="ordered locus">YKL192C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="O-(pantetheine 4'-phosphoryl)serine" evidence="1"> +<location> +<position position="82"/> +</location> +</feature> +<sequence length="125" mass="13943" checksum="A0C64C5B796A5DDF" modified="1993-10-01" version="1" precursor="true"> +MFRSVCRISSRVAPSAYRTIMGRSVMSNTILAQRFYSANLSKDQVSQRVIDVIKAFDKNS +PNIANKQISSDTQFHKDLGLDSLDTVELLVAIEEEFDIEIPDKVADELRSVGETVDYIAS +NPDAN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-07-01" modified="2015-09-16" version="146"> +<accession>Q01574</accession> +<accession>D6VPG4</accession> +<accession>Q66RJ0</accession> +<name>ACS1_YEAST</name> +<protein> +<recommendedName> +<fullName>Acetyl-coenzyme A synthetase 1</fullName> +<ecNumber>6.2.1.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ACS1</name> +<name type="ordered locus">YAL054C</name> +<name type="ORF">FUN44</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="713" mass="79141" checksum="F282218B9A6CA3B2" modified="2009-09-01" version="2"> +MSPSAVQSSKLEEQSSEIDKLKAKMSQSAATAQQKKEHEYEHLTSVKIVPQRPISDRLQP +AIATHYSPHLDGLQDYQRLHKESIEDPAKFFGSKATQFLNWSKPFDKVFIPDPKTGRPSF +QNNAWFLNGQLNACYNCVDRHALKTPNKKAIIFEGDEPGQGYSITYKELLEEVCQVAQVL +TYSMGVRKGDTVAVYMPMVPEAIITLLAISRIGAIHSVVFAGFSSNSLRDRINDGDSKVV +ITTDESNRGGKVIETKRIVDDALRETPGVRHVLVYRKTNNPSVAFHAPRDLDWATEKKKY +KTYYPCTPVDSEDPLFLLYTSGSTGAPKGVQHSTAGYLLGALLTMRYTFDTHQEDVFFTA +GDIGWITGHTYVVYGPLLYGCATLVFEGTPAYPNYSRYWDIIDEHKVTQFYVAPTALRLL +KRAGDSYIENHSLKSLRCLGSVGEPIAAEVWEWYSEKIGKNEIPIVDTYWQTESGSHLVT +PLAGGVTPMKPGSASFPFFGIDAVVLDPNTGEELNTSHAEGVLAVKAAWPSFARTIWKNH +DRYLDTYLNPYPGYYFTGDGAAKDKDGYIWILGRVDDVVNVSGHRLSTAEIEAAIIEDPI +VAECAVVGFNDDLTGQAVAAFVVLKNKSSWSTATDDELQDIKKHLVFTVRKDIGPFAAPK +LIILVDDLPKTRSGKIMRRILRKILAGESDQLGDVSTLSNPGIVRHLIDSVKL +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-10-01" modified="2015-10-14" version="127"> +<accession>P52910</accession> +<accession>D6VYE8</accession> +<name>ACS2_YEAST</name> +<protein> +<recommendedName> +<fullName>Acetyl-coenzyme A synthetase 2</fullName> +<ecNumber>6.2.1.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ACS2</name> +<name type="ordered locus">YLR153C</name> +<name type="ORF">L9634.10</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="679"/> +</location> +</feature> +<sequence length="683" mass="75492" checksum="418439EDCDF308F3" modified="1996-10-01" version="1"> +MTIKEHKVVYEAHNVKALKAPQHFYNSQPGKGYVTDMQHYQEMYQQSINEPEKFFDKMAK +EYLHWDAPYTKVQSGSLNNGDVAWFLNGKLNASYNCVDRHAFANPDKPALIYEADDESDN +KIITFGELLRKVSQIAGVLKSWGVKKGDTVAIYLPMIPEAVIAMLAVARIGAIHSVVFAG +FSAGSLKDRVVDANSKVVITCDEGKRGGKTINTKKIVDEGLNGVDLVSRILVFQRTGTEG +IPMKAGRDYWWHEEAAKQRTYLPPVSCDAEDPLFLLYTSGSTGSPKGVVHTTGGYLLGAA +LTTRYVFDIHPEDVLFTAGDVGWITGHTYALYGPLTLGTASIIFESTPAYPDYGRYWRII +QRHKATHFYVAPTALRLIKRVGEAEIAKYDTSSLRVLGSVGEPISPDLWEWYHEKVGNKN +CVICDTMWQTESGSHLIAPLAGAVPTKPGSATVPFFGINACIIDPVTGVELEGNDVEGVL +AVKSPWPSMARSVWNHHDRYMDTYLKPYPGHYFTGDGAGRDHDGYYWIRGRVDDVVNVSG +HRLSTSEIEASISNHENVSEAAVVGIPDELTGQTVVAYVSLKDGYLQNNATEGDAEHITP +DNLRRELILQVRGEIGPFASPKTIILVRDLPRTRSGKIMRRVLRKVASNEAEQLGDLTTL +ANPEVVPAIISAVENQFFSQKKK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1986-07-21" modified="2015-10-14" version="136"> +<accession>P60010</accession> +<accession>D6VTJ1</accession> +<accession>P02579</accession> +<accession>Q9P3X6</accession> +<accession>Q9P3X7</accession> +<name>ACT_YEAST</name> +<protein> +<recommendedName> +<fullName>Actin</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ACT1</name> +<name type="synonym">ABY1</name> +<name type="synonym">END7</name> +<name type="ordered locus">YFL039C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N-acetylmethionine" evidence="3 4"> +<location> +<position position="1"/> +</location> +</feature> +<sequence length="375" mass="41690" checksum="87AC19B0B0BC9E71" modified="1986-07-21" version="1"> +MDSEVAALVIDNGSGMCKAGFAGDDAPRAVFPSIVGRPRHQGIMVGMGQKDSYVGDEAQS +KRGILTLRYPIEHGIVTNWDDMEKIWHHTFYNELRVAPEEHPVLLTEAPMNPKSNREKMT +QIMFETFNVPAFYVSIQAVLSLYSSGRTTGIVLDSGDGVTHVVPIYAGFSLPHAILRIDL +AGRDLTDYLMKILSERGYSFSTTAEREIVRDIKEKLCYVALDFEQEMQTAAQSSSIEKSY +ELPDGQVITIGNERFRAPEALFHPSVLGLESAGIDQTTYNSIMKCDVDVRKELYGNIVMS +GGTTMFPGIAERMQKEITALAPSSMKVKIIAPPERKYSVWIGGSILASLTTFQQMWISKQ +EYDESGPSIVHHKCF +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-07-01" modified="2015-10-14" version="158"> +<accession>Q02336</accession> +<accession>D6VT73</accession> +<name>ADA2_YEAST</name> +<protein> +<recommendedName> +<fullName>Transcriptional adapter 2</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ADA2</name> +<name type="ordered locus">YDR448W</name> +<name type="ORF">D9461.33</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="434" mass="50569" checksum="9637E1EDBBED0AC3" modified="1993-07-01" version="1"> +MSNKFHCDVCSADCTNRVRVSCAICPEYDLCVPCFSQGSYTGKHRPYHDYRIIETNSYPI +LCPDWGADEELQLIKGAQTLGLGNWQDIADHIGSRGKEEVKEHYLKYYLESKYYPIPDIT +QNIHVPQDEFLEQRRHRIESFRERPLEPPRKPMASVPSCHEVQGFMPGRLEFETEFENEA +EGPVKDMVFEPDDQPLDIELKFAILDIYNSRLTTRAEKKRLLFENHLMDYRKLQAIDKKR +SKEAKELYNRIKPFARVMTAQDFEEFSKDILEELHCRARIQQLQEWRSNGLTTLEAGLKY +ERDKQARISSFEKFGASTAASLSEGNSRYRSNSAHRSNAEYSQNYSENGGRKKNMTISDI +QHAPDYALLSNDEQQLCIQLKILPKPYLVLKEVMFRELLKTGGNLSKSACRELLNIDPIK +ANRIYDFFQSQNWM +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1997-11-01" modified="2015-10-14" version="95"> +<accession>Q03233</accession> +<accession>D6W008</accession> +<name>ADD37_YEAST</name> +<protein> +<recommendedName> +<fullName>Alpha1-proteinase inhibitor-degradation deficient protein 37</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ADD37</name> +<name type="ordered locus">YMR184W</name> +<name type="ORF">YM8010.14</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="1 2"> +<location> +<position position="79"/> +</location> +</feature> +<sequence length="198" mass="22110" checksum="2716B90391A82092" modified="1997-11-01" version="1"> +MAIKPTKSFQNCLEAEVPGYNDCPTVLFSIDPNSGPRSKSKQRTKSKRCVSGRLATEVLD +LYGNTKTATTPPPVLRRPSVTAAQQESACEGVLVKDQGDRQLQPILCSKEELVAKINDLC +VCGSKLSSKELEFYKKKLDSNITKILQNEHTKTVLSQIFNEKDKNMAVKTIKHWMVTDTT +ISNWCPAFLKIFENAMPN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2006-09-05" modified="2015-07-22" version="64"> +<accession>Q2V2Q1</accession> +<accession>D6VQV8</accession> +<name>ADF1_YEAST</name> +<protein> +<recommendedName> +<fullName>Antisense of depressing factor protein 1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ADF1</name> +<name type="ordered locus">YCL058W-A</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="inferred from homology"/> +<sequence length="113" mass="12739" checksum="0D5F95141CB29BFF" modified="2009-06-16" version="4"> +MGKCSMKKKGVGKNVGVGKKVQKKRSISTAERKRTKLQVEKLNKSSETMIPTLLREASTQ +EPAKLKAETTLKAEELIKDQEKDSKVREQIRTEKSKTNDSMLKQIEMISGFSL +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-10-01" modified="2015-10-14" version="129"> +<accession>P53909</accession> +<accession>D6W141</accession> +<name>ADE_YEAST</name> +<protein> +<recommendedName> +<fullName evidence="1">Adenine deaminase</fullName> +<shortName evidence="1">ADE</shortName> +<ecNumber evidence="1">3.5.4.2</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary" evidence="1">AAH1</name> +<name type="ordered locus">YNL141W</name> +<name type="ORF">N1208</name> +<name type="ORF">N1825</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="347" mass="39635" checksum="E25573A9F9EB7BB6" modified="1996-10-01" version="1"> +MVSVEFLQELPKCEHHLHLEGTLEPDLLFPLAKRNDIILPEGFPKSVEELNEKYKKFRDL +QDFLDYYYIGTNVLISEQDFFDLAWAYFKKVHKQGLVHAEVFYDPQSHTSRGISIETVTK +GFQRACDKAFSEFGITSKLIMCLLRHIEPEECLKTIEEATPFIKDGTISALGLDSAEKPF +PPHLFVECYGKAASLNKDLKLTAHAGEEGPAQFVSDALDLLQVTRIDHGINSQYDEELLD +RLSRDQTMLTICPLSNVKLQVVQSVSELPLQKFLDRDVPFSLNSDDPAYFGGYILDVYTQ +VSKDFPHWDHETWGRIAKNAIKGSWCDDKRKNGLLSRVDEVVTKYSH +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1986-07-21" modified="2015-09-16" version="170"> +<accession>P00330</accession> +<accession>D6W1Y3</accession> +<name>ADH1_YEAST</name> +<protein> +<recommendedName> +<fullName>Alcohol dehydrogenase 1</fullName> +<ecNumber>1.1.1.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ADH1</name> +<name type="synonym">ADC1</name> +<name type="ordered locus">YOL086C</name> +<name type="ORF">O0947</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N-acetylserine" evidence="7"> +<location> +<position position="2"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="213"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="3"> +<location> +<position position="223"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="5"> +<location> +<position position="279"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2 4 5"> +<location> +<position position="316"/> +</location> +</feature> +<sequence length="348" mass="36849" checksum="F14AE24B5D8D12A5" modified="2010-10-05" version="5"> +MSIPETQKGVIFYESHGKLEYKDIPVPKPKANELLINVKYSGVCHTDLHAWHGDWPLPVK +LPLVGGHEGAGVVVGMGENVKGWKIGDYAGIKWLNGSCMACEYCELGNESNCPHADLSGY +THDGSFQQYATADAVQAAHIPQGTDLAQVAPILCAGITVYKALKSANLMAGHWVAISGAA +GGLGSLAVQYAKAMGYRVLGIDGGEGKEELFRSIGGEVFIDFTKEKDIVGAVLKATDGGA +HGVINVSVSEAAIEASTRYVRANGTTVLVGMPAGAKCCSDVFNQVVKSISIVGSYVGNRA +DTREALDFFARGLVKSPIKVVGLSTLPEIYEKMEKGQIVGRYVVDTSK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1986-07-21" modified="2015-09-16" version="156"> +<accession>P00331</accession> +<accession>D6W0D0</accession> +<name>ADH2_YEAST</name> +<protein> +<recommendedName> +<fullName>Alcohol dehydrogenase 2</fullName> +<ecNumber>1.1.1.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ADH2</name> +<name type="synonym">ADR2</name> +<name type="ordered locus">YMR303C</name> +<name type="ORF">YM9952.05C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N-acetylserine" evidence="4"> +<location> +<position position="2"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="213"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="2"> +<location> +<position position="223"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="279"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="316"/> +</location> +</feature> +<sequence length="348" mass="36732" checksum="54535FC3258B10EA" modified="2007-01-23" version="3"> +MSIPETQKAIIFYESNGKLEHKDIPVPKPKPNELLINVKYSGVCHTDLHAWHGDWPLPTK +LPLVGGHEGAGVVVGMGENVKGWKIGDYAGIKWLNGSCMACEYCELGNESNCPHADLSGY +THDGSFQEYATADAVQAAHIPQGTDLAEVAPILCAGITVYKALKSANLRAGHWAAISGAA +GGLGSLAVQYAKAMGYRVLGIDGGPGKEELFTSLGGEVFIDFTKEKDIVSAVVKATNGGA +HGIINVSVSEAAIEASTRYCRANGTVVLVGLPAGAKCSSDVFNHVVKSISIVGSYVGNRA +DTREALDFFARGLVKSPIKVVGLSSLPEIYEKMEKGQIAGRYVVDTSK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1988-04-01" modified="2015-10-14" version="148"> +<accession>P07246</accession> +<accession>D6VZQ6</accession> +<name>ADH3_YEAST</name> +<protein> +<recommendedName> +<fullName>Alcohol dehydrogenase 3, mitochondrial</fullName> +<ecNumber>1.1.1.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ADH3</name> +<name type="ordered locus">YMR083W</name> +<name type="ORF">YM9582.08</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="375" mass="40370" checksum="AB849BC4E9D4EB8A" modified="1996-02-01" version="2" precursor="true"> +MLRTSTLFTRRVQPSLFSRNILRLQSTAAIPKTQKGVIFYENKGKLHYKDIPVPEPKPNE +ILINVKYSGVCHTDLHAWHGDWPLPVKLPLVGGHEGAGVVVKLGSNVKGWKVGDLAGIKW +LNGSCMTCEFCESGHESNCPDADLSGYTHDGSFQQFATADAIQAAKIQQGTDLAEVAPIL +CAGVTVYKALKEADLKAGDWVAISGAAGGLGSLAVQYATAMGYRVLGIDAGEEKEKLFKK +LGGEVFIDFTKTKNMVSDIQEATKGGPHGVINVSVSEAAISLSTEYVRPCGTVVLVGLPA +NAYVKSEVFSHVVKSINIKGSYVGNRADTREALDFFSRGLIKSPIKIVGLSELPKVYDLM +EKGKILGRYVVDTSK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1989-07-01" modified="2015-10-14" version="137"> +<accession>P10127</accession> +<accession>D6VV79</accession> +<name>ADH4_YEAST</name> +<protein> +<recommendedName> +<fullName>Alcohol dehydrogenase 4</fullName> +<ecNumber>1.1.1.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ADH4</name> +<name type="synonym">ZRG5</name> +<name type="ordered locus">YGL256W</name> +<name type="ORF">NRC465</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="382" mass="41142" checksum="7DFFD43830FB269B" modified="2008-07-22" version="3"> +MSSVTGFYIPPISFFGEGALEETADYIKNKDYKKALIVTDPGIAAIGLSGRVQKMLEERD +LNVAIYDKTQPNPNIANVTAGLKVLKEQNSEIVVSIGGGSAHDNAKAIALLATNGGEIGD +YEGVNQSKKAALPLFAINTTAGTASEMTRFTIISNEEKKIKMAIIDNNVTPAVAVNDPST +MFGLPPALTAATGLDALTHCIEAYVSTASNPITDACALKGIDLINESLVAAYKDGKDKKA +RTDMCYAEYLAGMAFNNASLGYVHALAHQLGGFYHLPHGVCNAVLLPHVQEANMQCPKAK +KRLGEIALHFGASQEDPEETIKALHVLNRTMNIPRNLKELGVKTEDFEILAEHAMHDACH +LTNPVQFTKEQVVAIIKKAYEY +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1994-10-01" modified="2015-10-14" version="129"> +<accession>P38113</accession> +<accession>D6VQE0</accession> +<name>ADH5_YEAST</name> +<protein> +<recommendedName> +<fullName>Alcohol dehydrogenase 5</fullName> +<ecNumber>1.1.1.1</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ADH5</name> +<name type="ordered locus">YBR145W</name> +<name type="ORF">YBR1122</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphothreonine" evidence="2"> +<location> +<position position="226"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="282"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="319"/> +</location> +</feature> +<sequence length="351" mass="37648" checksum="F4084DAD1E3C19DE" modified="1994-10-01" version="1"> +MPSQVIPEKQKAIVFYETDGKLEYKDVTVPEPKPNEILVHVKYSGVCHSDLHAWHGDWPF +QLKFPLIGGHEGAGVVVKLGSNVKGWKVGDFAGIKWLNGTCMSCEYCEVGNESQCPYLDG +TGFTHDGTFQEYATADAVQAAHIPPNVNLAEVAPILCAGITVYKALKRANVIPGQWVTIS +GACGGLGSLAIQYALAMGYRVIGIDGGNAKRKLFEQLGGEIFIDFTEEKDIVGAIIKATN +GGSHGVINVSVSEAAIEASTRYCRPNGTVVLVGMPAHAYCNSDVFNQVVKSISIVGSCVG +NRADTREALDFFARGLIKSPIHLAGLSDVPEIFAKMEKGEIVGRYVVETSK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1997-11-01" modified="2015-10-14" version="133"> +<accession>Q04894</accession> +<accession>D6W0E6</accession> +<name>ADH6_YEAST</name> +<protein> +<recommendedName> +<fullName>NADP-dependent alcohol dehydrogenase 6</fullName> +<ecNumber>1.1.1.2</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ADH6</name> +<name type="ordered locus">YMR318C</name> +<name type="ORF">YM9924.10C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="131"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="7"> +<location> +<position position="315"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4 5"> +<location> +<position position="359"/> +</location> +</feature> +<sequence length="360" mass="39618" checksum="3F785BE0C5ED8CF1" modified="1997-11-01" version="1"> +MSYPEKFEGIAIQSHEDWKNPKKTKYDPKPFYDHDIDIKIEACGVCGSDIHCAAGHWGNM +KMPLVVGHEIVGKVVKLGPKSNSGLKVGQRVGVGAQVFSCLECDRCKNDNEPYCTKFVTT +YSQPYEDGYVSQGGYANYVRVHEHFVVPIPENIPSHLAAPLLCGGLTVYSPLVRNGCGPG +KKVGIVGLGGIGSMGTLISKAMGAETYVISRSSRKREDAMKMGADHYIATLEEGDWGEKY +FDTFDLIVVCASSLTDIDFNIMPKAMKVGGRIVSISIPEQHEMLSLKPYGLKAVSISYSA +LGSIKELNQLLKLVSEKDIKIWVETLPVGEAGVHEAFERMEKGDVRYRFTLVGYDKEFSD +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1992-05-01" modified="2015-10-14" version="125"> +<accession>P25377</accession> +<accession>D6VRA5</accession> +<name>ADH7_YEAST</name> +<protein> +<recommendedName> +<fullName>NADP-dependent alcohol dehydrogenase 7</fullName> +<ecNumber>1.1.1.2</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ADH7</name> +<name type="ordered locus">YCR105W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="132"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="316"/> +</location> +</feature> +<sequence length="361" mass="39348" checksum="BFB0E6C5F93D3F07" modified="1992-05-01" version="1"> +MLYPEKFQGIGISNAKDWKHPKLVSFDPKPFGDHDVDVEIEACGICGSDFHIAVGNWGPV +PENQILGHEIIGRVVKVGSKCHTGVKIGDRVGVGAQALACFECERCKSDNEQYCTNDHVL +TMWTPYKDGYISQGGFASHVRLHEHFAIQIPENIPSPLAAPLLCGGITVFSPLLRNGCGP +GKRVGIVGIGGIGHMGILLAKAMGAEVYAFSRGHSKREDSMKLGADHYIAMLEDKGWTEQ +YSNALDLLVVCSSSLSKVNFDSIVKIMKIGGSIVSIAAPEVNEKLVLKPLGLMGVSISSS +AIGSRKEIEQLLKLVSEKNVKIWVEKLPISEEGVSHAFTRMESGDVKYRFTLVDYDKKFH +K +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-02-01" modified="2015-10-14" version="140"> +<accession>P47143</accession> +<accession>D6VWS4</accession> +<name>ADK_YEAST</name> +<protein> +<recommendedName> +<fullName>Adenosine kinase</fullName> +<ecNumber>2.7.1.20</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ADO1</name> +<name type="ordered locus">YJR105W</name> +<name type="ORF">J1973</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="340" mass="36372" checksum="F0F18B5831F025A5" modified="1996-02-01" version="1"> +MTAPLVVLGNPLLDFQADVTAEYLAKYSLKENDAILVDAKSGDAKMAIFDELLQMPETKL +VAGGAAQNTARGAAYVLGAGQVVYFGSVGKDKFSERLLNENEKAGVKSMYQVQNDIGTGK +CAALITGHNRSLVTDLGAANFFTPDHLDKHWDLVEAAKLFYIGGFHLTVSPDAIVKLGQH +AKENSKPFVLNFSAPFIPHVFKDALARVLPYATVIIANESEAEAFCDAFQLDCANTDLEA +IAQRIVKDSPVEKTVIFTHGVEPTVVVSSKGTSTYPVKPLDSSKIVDTNGAGDAFAGGFM +AGLTKGEDLETSIDMGQWLAALSIQEVGPSYPSEKISYSK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1992-05-01" modified="2015-10-14" version="154"> +<accession>P25371</accession> +<accession>D6VR20</accession> +<name>ADP1_YEAST</name> +<protein> +<recommendedName> +<fullName>Probable ATP-dependent permease</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ADP1</name> +<name type="ordered locus">YCR011C</name> +<name type="ORF">YCR105</name> +<name type="ORF">YCR11C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="1 2"> +<location> +<position position="659"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1 2"> +<location> +<position position="702"/> +</location> +</feature> +<sequence length="1049" mass="117231" checksum="A3E9CE54BC28407B" modified="2004-03-15" version="2" precursor="true"> +MGSHRRYLYYSILSFLLLSCSVVLAKQDKTPFFEGTSSKNSRLTAQDKGNDTCPPCFNCM +LPIFECKQFSECNSYTGRCECIEGFAGDDCSLPLCGGLSPDESGNKDRPIRAQNDTCHCD +NGWGGINCDVCQEDFVCDAFMPDPSIKGTCYKNGMIVDKVFSGCNVTNEKILQILNGKIP +QITFACDKPNQECNFQFWIDQLESFYCGLSDCAFEYDLEQNTSHYKCNDVQCKCVPDTVL +CGAKGSIDISDFLTETIKGPGDFSCDLETRQCKFSEPSMNDLILTVFGDPYITLKCESGE +CVHYSEIPGYKSPSKDPTVSWQGKLVLALTAVMVLALFTFATFYISKSPLFRNGLGSSKS +PIRLPDEDAVNNFLQNEDDTLATLSFENITYSVPSINSDGVEETVLNEISGIVKPGQILA +IMGGSGAGKTTLLDILAMKRKTGHVSGSIKVNGISMDRKSFSKIIGFVDQDDFLLPTLTV +FETVLNSALLRLPKALSFEAKKARVYKVLEELRIIDIKDRIIGNEFDRGISGGEKRRVSI +ACELVTSPLVLFLDEPTSGLDASNANNVIECLVRLSSDYNRTLVLSIHQPRSNIFYLFDK +LVLLSKGEMVYSGNAKKVSEFLRNEGYICPDNYNIADYLIDITFEAGPQGKRRRIRNISD +LEAGTDTNDIDNTIHQTTFTSSDGTTQREWAHLAAHRDEIRSLLRDEEDVEGTDGRRGAT +EIDLNTKLLHDKYKDSVYYAELSQEIEEVLSEGDEESNVLNGDLPTGQQSAGFLQQLSIL +NSRSFKNMYRNPKLLLGNYLLTILLSLFLGTLYYNVSNDISGFQNRMGLFFFILTYFGFV +TFTGLSSFALERIIFIKERSNNYYSPLAYYISKIMSEVVPLRVVPPILLSLIVYPMTGLN +MKDNAFFKCIGILILFNLGISLEILTIGIIFEDLNNSIILSVLVLLGSLLFSGLFINTKN +ITNVAFKYLKNFSVFYYAYESLLINEVKTLMLKERKYGLNIEVPGATILSTFGFVVQNLV +FDIKILALFNVVFLIMGYLALKWIVVEQK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-10-01" modified="2015-10-14" version="125"> +<accession>Q01976</accession> +<accession>D6VQB0</accession> +<name>ADPP_YEAST</name> +<protein> +<recommendedName> +<fullName>ADP-ribose pyrophosphatase</fullName> +<ecNumber>3.6.1.13</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">YSA1</name> +<name type="ordered locus">YBR111C</name> +<name type="ORF">YBR0907</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="231" mass="26087" checksum="512DE7446A39EFBA" modified="1994-10-01" version="2"> +MFLRNVRVISLNSRRLFRTMSTVKGKPEDAKIIEARHVKETSDCKWIGLQKIIYKDPNGK +EREWDSAVRTTRSSGGVDGIGILTILKYKDGKPDEILLQKQFRPPVEGVCIEMPAGLIDA +GEDIDTAALRELKEETGYSGKIISKSPTVFNDPGFTNTNLCLVTVEVDMSLPENQKPVTQ +LEDNEFIECFSVELHKFPDEMVKLDQQGYKLDARVQNVAQGILMAKQYHIK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1988-04-01" modified="2015-10-14" version="174"> +<accession>P07248</accession> +<accession>D6VSJ9</accession> +<accession>Q04919</accession> +<name>ADR1_YEAST</name> +<protein> +<recommendedName> +<fullName>Regulatory protein ADR1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ADR1</name> +<name type="ordered locus">YDR216W</name> +<name type="ORF">YD8142.16</name> +<name type="ORF">YD8142B.08</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="7"> +<location> +<position position="54"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="7"> +<location> +<position position="188"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="7"> +<location> +<position position="193"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine; by PKA; in vitro" evidence="5 7 9"> +<location> +<position position="230"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="7"> +<location> +<position position="258"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="7"> +<location> +<position position="259"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="7"> +<location> +<position position="299"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="6"> +<location> +<position position="323"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="7"> +<location> +<position position="325"/> +</location> +</feature> +<feature type="modified residue" description="Phosphothreonine" evidence="6"> +<location> +<position position="327"/> +</location> +</feature> +<sequence length="1323" mass="150941" checksum="EE807290EA6CC5C2" modified="2004-12-21" version="2"> +MANVEKPNDCSGFPVVDLNSCFSNGFNNEKQEIEMETDDSPILLMSSSASRENSNTFSVI +QRTPDGKIITTNNNMNSKINKQLDKLPENLRLNGRTPSGKLRSFVCEVCTRAFARQEHLK +RHYRSHTNEKPYPCGLCNRCFTRRDLLIRHAQKIHSGNLGETISHTKKVSRTITKARKNS +ASSVKFQTPTYGTPDNGNFLNRTTANTRRKASPEANVKRKYLKKLTRRASFSAQSASSYA +LPDQSSLEQHPKDRVKFSTPELVPLDLKNPELDSSFDLNMNLDLNLNLDSNFNIALNRSD +SSGSTMNLDYKLPESANNYTYSSGSPTRAYVGANTNSKNASFNDADLLSSSYWIKAYNDH +LFSVSESDETSPMNSELNDTKLIVPDFKSTIHHLKDSRSSSWTVAIDNNSNNNKVSDNQP +DFVDFQELLDNDTLGNDLLETTAVLKEFELLHDDSVSATATSNEIDLSHLNLSNSPISPH +KLIYKNKEGTNDDMLISFGLDHPSNREDDLDKLCNMTRDVQAIFSQYLKGEESKRSLEDF +LSTSNRKEKPDSGNYTFYGLDCLTLSKISRALPASTVNNNQPSHSIESKLFNEPMRNMCI +KVLRYYEKFSHDSSESVMDSNPNLLSKELLMPAVSELNEYLDLFKNNFLPHFPIIHPSLL +DLDLDSLQRYTNEDGYDDAENAQLFDRLSQGTDKEYDYEHYQILSISKIVCLPLFMATFG +SLHKFGYKSQTIELYEMSRRILHSFLETKRRCRSTTVNDSYQNIWLMQSLILSFMFALVA +DYLEKIDSSLMKRQLSALCSTIRSNCLPTISANSEKSINNNNEPLTFGSPLQYIIFESKI +RCTLMAYDFCQFLKCFFHIKFDLSIKEKDVETIYIPDNESKWASESIICNGHVVQKQNFY +DFRNFYYSFTYGHLHSIPEFLGSSMIYYEYDLRKGTKSHVFLDRIDTKRLERSLDTSSYG +NDNMAATNKNIAILIDDTIILKNNLMSMRFIKQIDRSFTEKVRKGQIAKIYDSFLNSVRL +NFLKNYSVEVLCEFLVALNFSIRNISSLYVEEESDCSQRMNSPELPRIHLNNQALSVFNL +QGYYYCFILIIKFLLDFEATPNFKLLRIFIELRSLANSILLPTLSRLYPQEFSGFPDVVF +TQQFINKDNGMLVPGLSANEHHNGASAAVKTKLAKKINVEGLAMFINEILVNSFNDTSFL +NMEDPIRNEFSFDNGDRAVTDLPRSAHFLSDTGLEGINFSGLNDSHQTVSTLNLLRYGEN +HSSKHKNGGKGQGFAEKYQLSLKYVTIAKLFFTNVKENYIHCHMLDKMASDFHTLENHLK +GNS +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2002-10-10" modified="2015-10-14" version="129"> +<accession>Q12184</accession> +<accession>D6W3B9</accession> +<name>ADRX_YEAST</name> +<protein> +<recommendedName> +<fullName>Adrenodoxin homolog, mitochondrial</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">YAH1</name> +<name type="ordered locus">YPL252C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="172" mass="18932" checksum="D7DB9CFACBED1BFC" modified="1996-11-01" version="1" precursor="true"> +MLKIVTRAGHTARISNIAAHLLRTSPSLLTRTTTTTRFLPFSTSSFLNHGHLKKPKPGEE +LKITFILKDGSQKTYEVCEGETILDIAQGHNLDMEGACGGSCACSTCHVIVDPDYYDALP +EPEDDENDMLDLAYGLTETSRLGCQIKMSKDIDGIRVALPQMTRNVNNNDFS +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-02-01" modified="2015-10-14" version="129"> +<accession>P48360</accession> +<accession>D6VT08</accession> +<accession>P32840</accession> +<name>ADRO_YEAST</name> +<protein> +<recommendedName> +<fullName>Probable NADPH:adrenodoxin oxidoreductase, mitochondrial</fullName> +<shortName>AR</shortName> +<shortName>Adrenodoxin reductase</shortName> +<ecNumber>1.18.1.6</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">ARH1</name> +<name type="ordered locus">YDR376W</name> +<name type="ORF">D9481.5</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="493" mass="56237" checksum="9B0600BEA5A18CF3" modified="1996-02-01" version="1" precursor="true"> +MSFVQIRHISSQINRKTVSIVGSGPSGFYTAYHLLKKSPIPLNVTIWEKLPVPFGLSRYG +VAPDHPEVKNCEETFTTCAEEFSSPTNQKHKFSFVGGITIGKEILLKELLDNQDAVILSY +GCTGDRKLNIPGELGTKGVFSSREFVNWYNGHPDFAKDKRFTDFDWSKVSKVGIIGNGNV +ALDITRVLISNQIDEIWENTDISSLALNLLRRAPVKDVKLIARRDFVHSKFTNKELRELW +ELEKYGIRGRIDPKFFQKEMFDPSKYDRAFNRRVEMCSEYLKPFNERSKKNYKKAPPPSS +GYDKFWELDYLKTPLKINRDDFGAINSLSLCNNRLNEDNSLQPLKDVNNIMTYKVDLLIT +SLGYAGVPMPEFSKLSIGFDKDHIANKQGRVLTSSGEIFPHLYASGWIRKGSQGVIASTM +QDAFEVGDRVIQDLVVSGALSLENSIDLSNIKHTTWKDWERINKKELLRGKKEHKTRSKF +LTFEELWNGVEGI +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1987-08-13" modified="2015-10-14" version="140"> +<accession>P04710</accession> +<accession>D6VZN1</accession> +<name>ADT1_YEAST</name> +<protein> +<recommendedName> +<fullName>ADP,ATP carrier protein 1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AAC1</name> +<name type="ordered locus">YMR056C</name> +<name type="ORF">YM9796.09C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="309" mass="34121" checksum="BEC8999DFBB1CA51" modified="1987-08-13" version="1"> +MSHTETQTQQSHFGVDFLMGGVSAAIAKTGAAPIERVKLLMQNQEEMLKQGSLDTRYKGI +LDCFKRTATHEGIVSFWRGNTANVLRYFPTQALNFAFKDKIKSLLSYDRERDGYAKWFAG +NLFSGGAAGGLSLLFVYSLDYARTRLAADARGSKSTSQRQFNGLLDVYKKTLKTDGLLGL +YRGFVPSVLGIIVYRGLYFGLYDSFKPVLLTGALEGSFVASFLLGWVITMGASTASYPLD +TVRRRMMMTSGQTIKYDGALDCLRKIVQKEGAYSLFKGCGANIFRGVAAAGVISLYDQLQ +LIMFGKKFK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1990-11-01" modified="2015-10-14" version="142"> +<accession>P18239</accession> +<accession>D6VPW9</accession> +<name>ADT2_YEAST</name> +<protein> +<recommendedName> +<fullName>ADP,ATP carrier protein 2</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">PET9</name> +<name type="synonym">AAC2</name> +<name type="ordered locus">YBL030C</name> +<name type="ORF">YBL0421</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="318" mass="34426" checksum="A9805DC33D9E24AC" modified="1994-10-01" version="2"> +MSSNAQVKTPLPPAPAPKKESNFLIDFLMGGVSAAVAKTAASPIERVKLLIQNQDEMLKQ +GTLDRKYAGILDCFKRTATQEGVISFWRGNTANVIRYFPTQALNFAFKDKIKAMFGFKKE +EGYAKWFAGNLASGGAAGALSLLFVYSLDYARTRLAADSKSSKKGGARQFNGLIDVYKKT +LKSDGVAGLYRGFLPSVVGIVVYRGLYFGMYDSLKPLLLTGSLEGSFLASFLLGWVVTTG +ASTCSYPLDTVRRRMMMTSGQAVKYDGAFDCLRKIVAAEGVGSLFKGCGANILRGVAGAG +VISMYDQLQMILFGKKFK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1990-11-01" modified="2015-10-14" version="139"> +<accession>P18238</accession> +<accession>D6VQ85</accession> +<name>ADT3_YEAST</name> +<protein> +<recommendedName> +<fullName>ADP,ATP carrier protein 3</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AAC3</name> +<name type="ordered locus">YBR085W</name> +<name type="ORF">YBR0753</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="307" mass="33313" checksum="D0C1329FEC1B4DC8" modified="1990-11-01" version="1"> +MSSDAKQQETNFAINFLMGGVSAAIAKTAASPIERVKILIQNQDEMIKQGTLDKKYSGIV +DCFKRTAKQEGLISFWRGNTANVIRYFPTQALNFAFKDKIKLMFGFKKEEGYGKWFAGNL +ASGGAAGALSLLFVYSLDFARTRLAADAKSSKKGGARQFNGLTDVYKKTLKSDGIAGLYR +GFMPSVVGIVVYRGLYFGMFDSLKPLVLTGSLDGSFLASFLLGWVVTTGASTCSYPLDTV +RRRMMMTSGQAVKYNGAIDCLKKIVASEGVGSLFKGCGANILRSVAGAGVISMYDQLQMI +LFGKKFK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1992-05-01" modified="2015-10-14" version="109"> +<accession>P25613</accession> +<accession>D6VR19</accession> +<name>ADY2_YEAST</name> +<protein> +<recommendedName> +<fullName>Accumulation of dyads protein 2</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ADY2</name> +<name type="synonym">ATO1</name> +<name type="ordered locus">YCR010C</name> +<name type="ORF">YCR10C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="283" mass="30726" checksum="36DE421B09D8BB40" modified="1992-05-01" version="1"> +MSDKEQTSGNTDLENAPAGYYSSHDNDVNGVAEDERPSHDSLGKIYTGGDNNEYIYIGRQ +KFLKSDLYQAFGGTLNPGLAPAPVHKFANPAPLGLSAFALTTFVLSMFNARAQGITVPNV +VVGCAMFYGGLVQLIAGIWEIALENTFGGTALCSYGGFWLSFAAIYIPWFGILEAYEDNE +SDLNNALGFYLLGWAIFTFGLTVCTMKSTVMFFLLFFLLALTFLLLSIGHFANRLGVTRA +GGVLGVVVAFIAWYNAYAGVATKQNSYVLARPFPLPSTERVIF +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2003-10-10" modified="2015-10-14" version="101"> +<accession>Q05955</accession> +<accession>D6VYM7</accession> +<name>ADY4_YEAST</name> +<protein> +<recommendedName> +<fullName>Accumulates dyads protein 4</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ADY4</name> +<name type="ordered locus">YLR227C</name> +<name type="ORF">L8083.11</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="493" mass="57833" checksum="33A6E36B76181927" modified="1996-11-01" version="1"> +MNKDVDYQTFKKSLRKEFKKAVKTILNLQAYNGDLIRDFLALYIPYHVVFYNLSIMKKGS +PLRIQTNNLLKEALAKILNFNLAMGPKHIIKIMKKDKADPETMNKLKLVLYIKLFQGVFG +HVDKNYNLAFQSFRWCLQFIAYSKRTRLFASIADEQIGAFYELCELFISMLCCHCFLIDL +KENEALVGNNLKNFIKRQNPNYSHGFDLNEETKSLQWHWSLDEVDVIEALYCVAFDAMDK +ITLKFSKVNENFVFSQFFQYCAEIEEMLAILRGKIWECECDVFGPRIGLLVDSNHMNETI +QKNILSITFKLKNDPQIICCLNKILEGLLLSSGVQFKVIQFFYVLKLYYMQDNEYTFEAS +SEMDKLTIECLCIIENIIDACDNPDEVTDYQLPKVLLTAMEGKLLVAEKISEDNDCSESL +DDYHPRTYQFRHPRIIIDKMKTKLKQKLRFDSPKDPETDDHWIEYWKYCYQDNIGNLPDI +LSRIYQTFTDPSN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2003-10-10" modified="2015-10-14" version="107"> +<accession>Q07732</accession> +<accession>D6VRB7</accession> +<name>ADY3_YEAST</name> +<protein> +<recommendedName> +<fullName>Accumulates dyads protein 3</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">ADY3</name> +<name type="ordered locus">YDL239C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="790" mass="91812" checksum="46F17474F30FD3D9" modified="2011-07-27" version="2"> +MNHWLAFLNKPESLKEQNSDCDQQGEMRHVTDGTLTKSPESKPFRERRSQTWIDSEVPTS +TEKSNVQESISSDIISKLSNRRSRRNRSESWAGSEASSPSGNISTLENATEKNTLKSPNK +FLQRGGLPTVGIGSQALSPAGKPSTLGNVSPGKFTTYKVHNSIEVNRFSSTPTKLLTNPH +KVAAISNDEHYVVSNESLEENIEVAHLENVFRSSKTPDEEQSEYMKLGEIRLSSSSYGGS +ISKENSLPKVLDELQSQNEEIKALRQKLEEKDDRIQELEELNSMNDAKLQRIEDLQKEFH +NERKAASKRLNIVQDRFRKEIKKIREEKITDFQNKNASKKEKNEVTSAKTKCKAFSQRNI +LVSELYRKQKQILNLQQENDKFLKDINESNNSIVKLRSEVEILKSNLQLSQDENKKLHDN +GSFYEKRLNDVYSYMQNLSLFEKDLGKFILEEMKCGHSPSMFQNGFAKLYPDFQDIKNLE +NMEQYKQLKGKIELLEKNDRIRLEKIISVFKLINERLHFMQQQHSHKIKYLQKEALTKEQ +QFRLEKRRWHDILNLKEENFQKLKSELKEKLILSEKIQKNAEDKLNDYMNEHQEIVEKLQ +NQALIASRWSTQIQESENTHKKITDELAGKQSEILKLEETILSLKEDVFQEKLNLKKLYG +DPSTELNFETVGKSFPHITKEKYDSLGLDILTDLTYVQSQNLIKNLLIVLDIPLKTFLKI +VPTIVIQLRCELTLLTKFANDLNLKVFGKQLDFKSRRKVAMNEFLNNHDIAEVKHPLEYD +LQALFKYFFS +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-02-01" modified="2015-10-14" version="98"> +<accession>P38872</accession> +<accession>D3DLD3</accession> +<name>ADY1_YEAST</name> +<protein> +<recommendedName> +<fullName>Prospore formation at selected spindle poles protein 1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">PFS1</name> +<name type="synonym">ADY1</name> +<name type="ordered locus">YHR185C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="237" mass="27884" checksum="027F01058C0CFE6E" modified="1995-02-01" version="1"> +MNQGYTQLSAPELKETKTSKLNKMNNFRSSPIAEIINKIPPDCGKIQNTTFPEFNPALRR +RQHEQWPAYEKPIRVTDSMSPQLSSINCLPNLYPHGTLPLPNPYLSYLNHIEKVNCQDVK +FSNWSVLHNSNNGFEIPTYFSPRTTQNMPCSEKVESWLERLPIFVGFDGYLFTNCFDYEY +MLDWEETEFTFEKTSCMETDYSKALTDTDIIYIQEKKIEALIRNQYLKEYEFSQKDF +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-10-01" modified="2015-10-14" version="105"> +<accession>P32493</accession> +<accession>D6VZN8</accession> +<accession>P32446</accession> +<name>AEP1_YEAST</name> +<protein> +<recommendedName> +<fullName>ATPase expression protein 1, mitochondrial</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AEP1</name> +<name type="synonym">NCA1</name> +<name type="ordered locus">YMR064W</name> +<name type="ORF">YM9916.03</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="518" mass="59748" checksum="DE1F10728D288C9B" modified="1996-10-01" version="2" precursor="true"> +MITTVQEISKWRNLCFIRMQSRKWYPVLKKTPLVADGRKIIKHADKVPHPEEIIHPFYQP +TAIEQFTACATEYNPSLLDGKKIAPSLIKHPVSLKTILVDSKLKFDDIRGVNKWLMEFVA +RRQHQRNIVLTPASKSVRSFHVLHLSSTDIAKLRGLENILSEIENTNDLQSRVESVNNEL +QNIFDRDSKQTRLFCENILAYLIKNYGNSTEKLILLINVTEMQLYSRLDQMKAMNIILYN +ILCKVEANENPPYSPTLVTALENLLAAINNRFFPGRCENSLHPIVIEQLLSYFIKTGNLN +ESKNFLGHLIKKGILPEATIINRYLEAIDVHFDKSTKIFDIRSKFAFIADLAPIIENYGT +IDLFKFLIPMCRHFDELCSLLNIIRKSNNAKRAVDSTLPIFIKKVLTFTKDPMINSGNLS +TVFNIVSPIYGQNVPSEFVEKFILSFALQGNYTMMAHMIDTYKIKLSHKYQLQIIRALKN +SERNHALKNTGAVGYNKEFKKYFIEKYLNCTEREALRP +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2005-10-25" modified="2015-10-14" version="96"> +<accession>Q12089</accession> +<accession>D6W407</accession> +<name>AEP3_YEAST</name> +<protein> +<recommendedName> +<fullName>ATPase expression protein 3</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AEP3</name> +<name type="ordered locus">YPL005W</name> +<name type="ORF">YP8132.08</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="606" mass="70310" checksum="B7F93D1FD22677F4" modified="1996-11-01" version="1"> +MNTLRCLTQALSKSGREAPKLYQKVIFPGLFREGIPIANVKKVDEKIIDSPTSTSVNGEA +KKIVRHGVKYEREQVKEYLSSLPTLTLSRKQIRDDYDEERAKRMYMFSKQTNSSNKFQKL +LTAKSQEFTRELLTLLIDCTSNEKNSGPERFTRKFLKFSNDEIPPLPDFSKNPQLFENYI +GILSHTKFNFRSSSKLNGIVRKMLRHLLHPTNKTTLPLRSAQVYNDSIYFFSEHFDFASC +REIFAQMKAEGTKPNTITFNLLLRNVVKNSHIRKTKHPDDEVLFYLRSMRNHGVFADVIT +WTTCYNFLRDEVSRQLYIVQMGEHLGNFNVNFVYTVLRNGDYRAEDCLKVLAANSLPISR +KTFYLCIERLLNEEQLETASKLLDYGFQHLKSNFKLDSEAMNHFMRVFANKGRSDLAFLC +YNTCRKIYKIKPDSQTFEMLFKALVRNGNTKNFGAVLQYIKDLKVSEGFGLRTSYWRTKA +DSIFKFGSPNTLSEKSIEKARKLLGNLIASEGEFSWKIWKESDSSQKKILRFLGCIPTTL +RCTNTAQDHQKPTNLPSNISQKKREYRNRVKAIATKAALEKRMAYIKDNDVAFKKELVKR +RIVGEV +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1991-08-01" modified="2015-10-14" version="108"> +<accession>P22136</accession> +<accession>D6W0A9</accession> +<accession>P23115</accession> +<name>AEP2_YEAST</name> +<protein> +<recommendedName> +<fullName>ATPase expression protein 2, mitochondrial</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AEP2</name> +<name type="synonym">ATP13</name> +<name type="ordered locus">YMR282C</name> +<name type="ORF">YM8021.08C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="580" mass="67523" checksum="BC0AB10EABCDA4AA" modified="1996-02-01" version="3" precursor="true"> +MWINRLVKHPSYSVLRFYTKRLCTVSVKSLREFGVLPNSTICHSVYPRRTYVMGRAVIND +ILIKKSYSTHTVCAIDRSKDENNGSAYDKFEAKGIPIDVHTLKRIISSSGMDESEFSKSI +SYLFAKTVDPEPKDVLSLEDLSFLLSKLYTQRFQIRRICRDINAKYSEFWFKLFSLYAEK +VDAKRNQVNLRNTKLDACEIFDANLMIKNFIELGQLGKAQKILSFILDRNPDILLSPKNA +DISTIVHFLQLRCGALAPYWKIPDNSEQKQGFLRKMVRLGAKNTSIRLSSTYKAMDHQTL +LKIADLALQEKKLLNSEDLLSTLIQSFGHLGQTQILERCIEHIWQISPQEFPSHVVIKHR +GCYPSSKILVSILVSFYFNDHDLHRGLSILDSFIKHYPDVKLDALFWRRLFQLSHFAWTP +ANDKKATSVVRCWHLMKQWYASKRLRPSVDYETLRQLYDIMKKTGNFPLGIDVLRSFKPG +IERTRAENAGKVNNIIIKYQKCIIKELVNRGRFSAVREFIDSYGFDRKMTKDLNIFCANR +MFLRSKKMKNKIENKKEREKVRLDSFDDDEDDGMIIGSLW +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1996-10-01" modified="2015-10-14" version="125"> +<accession>P53930</accession> +<accession>D6W173</accession> +<accession>Q6B1N1</accession> +<name>AF9_YEAST</name> +<protein> +<recommendedName> +<fullName>Protein AF-9 homolog</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">YAF9</name> +<name type="ordered locus">YNL107W</name> +<name type="ORF">N1966</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="226" mass="25981" checksum="1FE08F72942061D1" modified="1996-10-01" version="1"> +MAPTISKRIKTLSVSRPIIYGNTAKKMGSVKPPNAPAEHTHLWTIFVRGPQNEDISYFIK +KVVFKLHDTYPNPVRSIEAPPFELTETGWGEFDINIKVYFVEEANEKVLNFYHRLRLHPY +ANPVPNSDNGNEQNTTDHNSKDAEVSSVYFDEIVFNEPNEEFFKILMSRPGNLLPSNKTD +DCVYSKQLEQEEIDRIEIGIEKVDKEIDELKQKLENLVKQEAINGS +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-10-01" modified="2015-10-14" version="115"> +<accession>P32317</accession> +<accession>D3DLJ8</accession> +<accession>E9P923</accession> +<name>AFG1_YEAST</name> +<protein> +<recommendedName> +<fullName>Protein AFG1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AFG1</name> +<name type="synonym">AFG</name> +<name type="ordered locus">YEL052W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="509" mass="58265" checksum="630315D29D5A9924" modified="1993-10-01" version="1"> +MIALKPNAVRTFRQVQHCSFRICRYQSTKSNKCLTPLQEYDRLVKLGKLRDDTYQRGIIS +SLGDLYDSLVKYVPPVVKTPNAVDQVGGWLNGLKSVFSRGKPKNIGAYVDVSKIGNSIPR +GVYLYGDVGCGKTMLMDLFYTTIPNHLTKKRIHFHQFMQYVHKRSHEIVREQNLKELGDA +KGKEIDTVPFLAAEIANNSHVLCFDEFQVTDVADAMILRRLMTALLSDDYGVVLFATSNR +HPDELYINGVQRQSFIPCIELIKHRTKVIFLNSPTDYRKIPRPVSSVYYFPSDTSIKYAS +KECKTRRETHIKEWYNYFAQASHTDDSTDSHTVHKTFYDYPLTIWGREFKVPKCTPPRVA +QFTFKQLCGEPLAAGDYLTLAKNFEAFIVTDIPYLSIYVRDEVRRFITFLDAVYDSGGKL +ATTGAADFSSLFVEPEQILNDFELRPTTKEPDSVDTGMVDEMVEKHGFSKEIAKKSQMFA +LDEERFAFARALSRLSQMSSTDWVTKPTY +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-10-01" modified="2015-10-14" version="127"> +<accession>P32794</accession> +<accession>D6VZ32</accession> +<name>AFG2_YEAST</name> +<protein> +<recommendedName> +<fullName>ATPase family gene 2 protein</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AFG2</name> +<name type="ordered locus">YLR397C</name> +<name type="ORF">L8084.16</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="780" mass="84748" checksum="75094DFA3D401D4E" modified="1993-10-01" version="1"> +MAPKSSSSGSKKKSSASSNSADAKASKFKLPAEFITRPHPSKDHGKETCTAYIHPNVLSS +LEINPGSFCTVGKIGENGILVIARAGDEEVHPVNVITLSTTIRSVGNLILGDRLELKKAQ +VQPPYATKVTVGSLQGYNILECMEEKVIQKLLDDSGVIMPGMIFQNLKTKAGDESIDVVI +TDASDDSLPDVSQLDLNMDDMYGGLDNLFYLSPPFIFRKGSTHITFSKETQANRKYNLPE +PLSYAAVGGLDKEIESLKSAIEIPLHQPTLFSSFGVSPPRGILLHGPPGTGKTMLLRVVA +NTSNAHVLTINGPSIVSKYLGETEAALRDIFNEARKYQPSIIFIDEIDSIAPNRANDDSG +EVESRVVATLLTLMDGMGAAGKVVVIAATNRPNSVDPALRRPGRFDQEVEIGIPDVDARF +DILTKQFSRMSSDRHVLDSEAIKYIASKTHGYVGADLTALCRESVMKTIQRGLGTDANID +KFSLKVTLKDVESAMVDIRPSAMREIFLEMPKVYWSDIGGQEELKTKMKEMIQLPLEASE +TFARLGISAPKGVLLYGPPGCSKTLTAKALATESGINFLAVKGPEIFNKYVGESERAIRE +IFRKARSAAPSIIFFDEIDALSPDRDGSSTSAANHVLTSLLNEIDGVEELKGVVIVAATN +RPDEIDAALLRPGRLDRHIYVGPPDVNARLEILKKCTKKFNTEESGVDLHELADRTEGYS +GAEVVLLCQEAGLAAIMEDLDVAKVELRHFEKAFKGIARGITPEMLSYYEEFALRSGSSS +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2003-10-10" modified="2015-10-14" version="114"> +<accession>Q99222</accession> +<accession>D6W2I7</accession> +<accession>Q92274</accession> +<name>AFI1_YEAST</name> +<protein> +<recommendedName> +<fullName>ARF3-interacting protein 1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AFI1</name> +<name type="ordered locus">YOR129C</name> +<name type="ORF">YOR3296C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="893" mass="102250" checksum="EFAEBE618FBDD989" modified="1996-11-01" version="1"> +MLRRELNNSISNRSIENESFPFERPNVSYIISAEFDNKLGPILKHQYPKDIPGFNQFSHE +QRNGNTSVSMNLASLMIPSSIERNPGKQDITVFTLYYNKFTQNYQLFPVPKDPRFSFNLH +HREQSDGSVTNSIYYDAENHQDAKNNRYTIVLEDDELECQEVQNNQKAIDNEPLFFINVA +NTVLDTTNDRGAVIKSIAIGTPLKTFFAFKNIIVLVLDLYMKAPTQAAATDILLDCFNML +NSIDLTLINDIHSKSSIQEVLHSIHDESIITKVFLDPDSTLKKLFCINGFDTKDKYGNIV +TFHDQLIQYHFTRFQPKTLPPFLLKIPLQFNMIRREPIYIENDYNELVLKFLDKFVPYLL +KAGQKVNAWKLVINSTKLSKEDLCAFILSLANITATYASDPQSYFKGNAALIFPYMDISL +VDGLRAYVASNSDFVGCFAIIGTANPIFRYQLDIWDYYYDVDEGVFYENNSPEKEKPDTV +AEVKIGPNPLRKIFNRPHFSTNAVNESQVNLGQKLFSLLIDEYHDSDTIMSVLRRLNVLQ +LENLLDALKRREIPPNIALKDEYIMFYKDFFIFPEFFDYFTLHSIELLSNLDNCLFSLGN +TCQLFSTEQIYSQLSQILDIVKELFRMVSVSRTNIEKFLNACLNYSPFKILPTAQLHGDN +ISRWSFESEVRQGFDNFNSYMGIEKDPHGVIVSAIDLFTQIYSFDILAFFLTFITKESGQ +DLPFTKSLSRRRTYLTRIAQSSSLRQFLQLSTRPNIRILGGNGQGTGNSNYPEFTNASSV +ISPKLRASPLLERRASKICYAITKLLYRLECHPIGMALLKKYLHNQLREAYLESKRHFIS +KKGDSTNTSSTIASSSFAGASVPLSSNESGMLNGLKQINEQQESTLETTQKED +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-02-01" modified="2015-10-14" version="154"> +<accession>P39925</accession> +<accession>D3DLR5</accession> +<name>AFG3_YEAST</name> +<protein> +<recommendedName> +<fullName>Mitochondrial respiratory chain complexes assembly protein AFG3</fullName> +<ecNumber>3.4.24.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AFG3</name> +<name type="synonym">YTA10</name> +<name type="ordered locus">YER017C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="761" mass="84544" checksum="517C1F0E81ABE841" modified="1995-02-01" version="1"> +MMMWQRYARGAPRSLTSLSFGKASRISTVKPVLRSRMPVHQRLQTLSGLATRNTIHRSTQ +IRSFHISWTRLNENRPNKEGEGKNNGNKDNNSNKEDGKDKRNEFGSLSEYFRSKEFANTM +FLTIGFTIIFTLLTPSSNNSGDDSNRVLTFQDFKTKYLEKGLVSKIYVVNKFLVEAELVN +TKQVVSFTIGSVDIFEEQMDQIQDLLNIPPRDRIPIKYIERSSPFTFLFPFLPTIILLGG +LYFITRKINSSPPNANGGGGGGLGGMFNVGKSRAKLFNKETDIKISFKNVAGCDEAKQEI +MEFVHFLKNPGKYTKLGAKIPRGAILSGPPGTGKTLLAKATAGEANVPFLSVSGSEFVEM +FVGVGASRVRDLFTQARSMAPSIIFIDEIDAIGKERGKGGALGGANDEREATLNQLLVEM +DGFTTSDQVVVLAGTNRPDVLDNALMRPGRFDRHIQIDSPDVNGRQQIYLVHLKRLNLDP +LLTDDMNNLSGKLATLTPGFTGADIANACNEAALIAARHNDPYITIHHFEQAIERVIAGL +EKKTRVLSKEEKRSVAYHEAGHAVCGWFLKYADPLLKVSIIPRGQGALGYAQYLPPDQYL +ISEEQFRHRMIMALGGRVSEELHFPSVTSGAHDDFKKVTQMANAMVTSLGMSPKIGYLSF +DQNDGNFKVNKPFSNKTARTIDLEVKSIVDDAHRACTELLTKNLDKVDLVAKELLRKEAI +TREDMIRLLGPRPFKERNEAFEKYLDPKSNTEPPEAPAATN +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1994-02-01" modified="2015-10-14" version="110"> +<accession>P33304</accession> +<accession>D6VS72</accession> +<name>AFR1_YEAST</name> +<protein> +<recommendedName> +<fullName>Protein AFR1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AFR1</name> +<name type="ordered locus">YDR085C</name> +<name type="ORF">D4471</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="472"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="526"/> +</location> +</feature> +<sequence length="620" mass="71364" checksum="A9ABFBC9A26E62E5" modified="1994-02-01" version="1"> +MEGSYLSAQENQPIPERLIPRSNSTSNLFALSSTFSKLNVRNDADYNYSNPNKKRHIYSG +EIDCRSVTAARKFPVRSCSMTAAQQRKRTALFTVRERNSYHEGFNNDQDYVSQYQKPQYT +FGVYKELTPYQLQRSKMKRSFQFPNGEIYKPKLDGKCTHSLKKPELNSRDSSLFKFSEKK +GRNLSKDFVGPHNGTSVIHIPPNDTGYGVNSLELNTSVPSTIKSSVSSTSPISAVNTLTS +LPESQTDDDDGYENKTVTISYCFENTVNEKHGSHIEKLDLSTKEKTKPTTNSGLFDRKKK +TILGTEKYRCIKSQSKLKLGSVLKKLWRTSGNSNTKHGKKDTKRRRIPIDDMVTHSDGNS +EAENDIELMDANLDGIEFDDDETLMDTDSIFDDLLSKENDKYDLRRRQLEIRQKLHETSH +NDDGKVSFRDTEKHNVNEGLIDKTIIEEFSKLGEYIIDTRNQPPPRSSKRPSLDDNESAR +YFYNISTDLRQSLSGPISLPMHVGNDMVNRLRNDWEYIRFEDRRNSLPDSSFDKVETPPK +PIKKDVRFAKEVCLASTWSSNAYERANPEFIMNRHRLLWMMKVHPSMNSAMNEIKLELNS +YKKNEMVVHENSKCFTHYLI +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2006-03-21" modified="2015-10-14" version="88"> +<accession>Q08957</accession> +<accession>D6W3G7</accession> +<name>AFT2_YEAST</name> +<protein> +<recommendedName> +<fullName>Iron-regulated transcriptional activator AFT2</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AFT2</name> +<name type="ordered locus">YPL202C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="416" mass="47105" checksum="0DAC56291EE56EFA" modified="1996-11-01" version="1"> +MKAKSMKSIISVPISVSKTGKMKLTASPDNLASMMSKDQNKLIHLDPVPSFEDRHEIKPW +LQKIFYPQGIDIVIERSDSSKVTFKCRSVRSKVGLNPKSKGSSSRSHACPFRIRAAYSVR +LQKWNVVVMNNIHSHELRFDLITKTDDYKKFKENLRQKNDEKAIKTFDELEYKASLNLPL +VTPIISCDCGLTKEIEAFNNIFLPLSNPPLTSKKNLLKTNKNSVSKIKSRQMDNSKPRPR +LKTKLDADLHDTGFLDNFKTRNSCVKIEKEDSLTNLNEIDFTNMFCNDNFIQNYNQGLME +LLTEPTPGPSSSSCILPSTPTRPLSQSKMDIALSESTTSSPNFMETDAPYGDEIIKVSKD +TKSNAPTADTDIATNLGKERNENFGMLNYNYEALLHFNDEHFNELNSIDPALISKY +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1991-08-01" modified="2015-10-14" version="121"> +<accession>P22149</accession> +<accession>D6VU71</accession> +<accession>Q06993</accession> +<name>AFT1_YEAST</name> +<protein> +<recommendedName> +<fullName>Iron-regulated transcriptional activator AFT1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AFT1</name> +<name type="synonym">RCS1</name> +<name type="ordered locus">YGL071W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="690" mass="77683" checksum="38641F26B76FCBDD" modified="1995-11-01" version="2"> +MEGFNPADIEHASPINSSDSHSSSFVYALPKSASEYVVNHNEGRASASGNPAAVPSPIMT +LNLKSTHSLNIDQHVHTSTSPTETIGHIHHVEKLNQNNLIHLDPVPNFEDKSDIKPWLQK +IFYPQGIELVIERSDAFKVVFKCKAAKRGRNARRKRKDKPKGQDHEDEKSKINDDELEYA +SPSNATVTNGPQTSPDQTSSIKPKKKRCVSRFNNCPFRVRATYSLKRKRWSIVVMDNNHS +HQLKFNPDSEEYKKFKEKLRKDNDVDAIKKFDELEYRTLANLPIPTATIPCDCGLTNEIQ +SFNVVLPTNSNVTSSASSSTVSSISLDSSNASKRPCLPSVNNTGSINTNNVRKPKSQCKN +KDTLLKRTTMQNFLTTKSRLRKTGTPTSSQHSSTAFSGYIDDPFNLNEILPLPASDFKLN +TVTNLNEIDFTNIFTKSPHPHSGSTHPRQVFDQLDDCSSILFSPLTTNTNNEFEGESDDF +VHSPYLNSEADFSQILSSAPPVHHDPNETHQENQDIIDRFANSSQEHNEYILQYLTHSDA +ANHNNIGVPNNNSHSLNTQHNVSDLGNSLLRQEALVGSSSTKIFDELKFVQNGPHGSQHP +IDFQHVDHRHLSSNEPQVRSHQYGPQQQPPQQLQYHQNQPHDGHNHEQHQTVQKDMQTHE +SLEIMGNTLLEEFKDIKMVNGELKYVKPED +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-10-01" modified="2015-10-14" version="99"> +<accession>P32781</accession> +<accession>D6VUA6</accession> +<name>AGA2_YEAST</name> +<protein> +<recommendedName> +<fullName>A-agglutinin-binding subunit</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AGA2</name> +<name type="ordered locus">YGL032C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="87" mass="9464" checksum="EA7DA943FAD743C3" modified="1993-10-01" version="1" precursor="true"> +MQLLRCFSIFSVIASVLAQELTTICEQIPSPTLESTPYSLSTTTILANGKAMQGVFEYYK +SVTFVSNCGSHPSTTSKGSPINTQYVF +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-10-01" modified="2015-10-14" version="100"> +<accession>P32323</accession> +<accession>D6W1L9</accession> +<name>AGA1_YEAST</name> +<protein> +<recommendedName> +<fullName>A-agglutinin anchorage subunit</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AGA1</name> +<name type="ordered locus">YNR044W</name> +<name type="ORF">N3431</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="725" mass="73354" checksum="70420C853B0B01F8" modified="1993-10-01" version="1" precursor="true"> +MTLSFAHFTYLFTILLGLTNIALASDPETILVTITKTNDANGVVTTTVSPALVSTSTIVQ +AGTTTLYTTWCPLTVSTSSAAEISPSISYATTLSRFSTLTLSTEVCSHEACPSSSTLPTT +TLSVTSKFTSYICPTCHTTAISSLSEVGTTTVVSSSAIEPSSASIISPVTSTLSSTTSSN +PTTTSLSSTSTSPSSTSTSPSSTSTSSSSTSTSSSSTSTSSSSTSTSPSSTSTSSSLTST +SSSSTSTSQSSTSTSSSSTSTSPSSTSTSSSSTSTSPSSKSTSASSTSTSSYSTSTSPSL +TSSSPTLASTSPSSTSISSTFTDSTSSLGSSIASSSTSVSLYSPSTPVYSVPSTSSNVAT +PSMTSSTVETTVSSQSSSEYITKSSISTTIPSFSMSTYFTTVSGVTTMYTTWCPYSSESE +TSTLTSMHETVTTDATVCTHESCMPSQTTSLITSSIKMSTKNVATSVSTSTVESSYACST +CAETSHSYSSVQTASSSSVTQQTTSTKSWVSSMTTSDEDFNKHATGKYHVTSSGTSTIST +SVSEATSTSSIDSESQEQSSHLLSTSVLSSSSLSATLSSDSTILLFSSVSSLSVEQSPVT +TLQISSTSEILQPTSSTAIATISASTSSLSATSISTPSTSVESTIESSSLTPTVSSIFLS +SSSAPSSLQTSVTTTEVSTTSISIQYQTSSMVTISQYMGSGSQTRLPLGKLVFAIMAVAC +NVIFS +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2006-03-21" modified="2015-10-14" version="122"> +<accession>Q12482</accession> +<accession>D6W431</accession> +<name>AGC1_YEAST</name> +<protein> +<recommendedName> +<fullName>Mitochondrial aspartate-glutamate transporter AGC1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AGC1</name> +<name type="ordered locus">YPR021C</name> +<name type="ORF">YP9367.01C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="inferred from homology"/> +<sequence length="902" mass="104304" checksum="07D6F831E2CD15CF" modified="1996-11-01" version="1"> +MEQINSNSRKKKQQLEVFKYFASVLTKEDKPISISNGMLDMPTVNSSKLTAGNGKPDTEK +LTGELILTYDDFIELISSSKTIYSKFTDHSFNLNQIPKNVFGCIFFAIDEQNKGYLTLND +WFYFNNLLEYDNYHLIILYEFFRKFDVENLKAKQKKELGSSSFNLKAADDRIKSINYGNR +FLSFDDLLLNLNQFKDTIRLLHESIDDNFVKDNKLLLDWNDFRFLKFYKCYHENEEYLSL +NSLVTILQNDLKNEKIFIGFDRLAQMDSQGHRLALSKNQLTYLLRLFYSHRVSADIFSSL +NLSNTELLKADNNSIPYNVFKDIFYLFQNFDLLNQIFHKYVTENNLNEQDIREQIVTKND +FMTVLNAQYNKVNNIIEFSPSQINLLFSIVANSKENRRLRKRNQDRDDELLNDHHYDSDI +DFFIHNEYLHGVSRSRKNLESFNDYYHDLSDGFDQDSGVKKASKASTGLFESVFGGKKDK +ATMRSDLTIEDFMKILNPNYLNDLVHQMELQKNQNESLYINYYFYPIFDSLYNFSLGSIA +GCIGATVVYPIDFIKTRMQAQRSLAQYKNSIDCLLKIISREGIKGLYSGLGPQLIGVAPE +KAIKLTVNDFMRNRLTDKNGKLSLFPEIISGASAGACQVIFTNPLEIVKIRLQVQSDYVG +ENIQQANETATQIVKKLGLRGLYNGVAACLMRDVPFSAIYFPTYAHLKKDLFDFDPNDKT +KRNRLKTWELLTAGAIAGMPAAFLTTPFDVIKTRLQIDPRKGETKYNGIFHAIRTILKEE +SFRSFFKGGGARVLRSSPQFGFTLAAYELFKGFIPSPDNKLKSREGRKRFCIDDDAGNEE +TVVHSNGELPQQKFYSDDRKHANYYYKSCQIAKTFIDLDNNFSRFDSSVYKNFQEHLRSI +NG +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2005-10-25" modified="2015-10-14" version="108"> +<accession>Q04412</accession> +<accession>D6VTE4</accession> +<name>AGE1_YEAST</name> +<protein> +<recommendedName> +<fullName>ADP-ribosylation factor GTPase-activating protein effector protein 1</fullName> +<shortName>ARF GAP effector protein 1</shortName> +</recommendedName> +</protein> +<gene> +<name type="primary">AGE1</name> +<name type="synonym">SAT1</name> +<name type="ordered locus">YDR524C</name> +<name type="ORF">D9719.28</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="482" mass="54494" checksum="3F7682F91EA21EDD" modified="1996-11-01" version="1"> +MDFYTTDINKNVVPLFSKGTVARTASKAQYPSWCNNALKLTNILLKSLRCKFQTNRCEDD +RGFEVYCVILKSIALLMAAKESLILLQIPPSLPSGFPFRSPQLSFTYLSTRLSGSQHKST +HSHHINHQTHPIHSSSSNSNSNNRIPTKTDSSKQHTQHFSFANAGASNRDELLSIVRKID +KSNLKCCDCGSTATVEWVSINLLCILCIKCSGVHRSLGSHISKIRSLTLDNFTSLELMHL +LQNNVSNSNVNAIYESNLRNFPVKKITANSDDSERSKFIIDKYQFKKFVIDSNQGREASL +KSLIKAIHLDSVFMMQRAIAQSKYSLRELTASEKEQNDLNHSSIFQYSLKHYEIVDGTPI +FFITEFLLCNGIHIDNLPKITTNWSPKVLEYWETKLEMYGTFQAVNTSRPRSGPHLNMHS +NVDSASSYNKKHDLRVNIPERSASASKRWSLSSIPKSSQNLMSPTNLLTMHKSLKLAKKD +KK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-02-01" modified="2015-10-14" version="127"> +<accession>P40529</accession> +<accession>D6VVN8</accession> +<name>AGE2_YEAST</name> +<protein> +<recommendedName> +<fullName>ADP-ribosylation factor GTPase-activating protein effector protein 2</fullName> +<shortName>ARF GAP effector protein 2</shortName> +</recommendedName> +</protein> +<gene> +<name type="primary">AGE2</name> +<name type="ordered locus">YIL044C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N-acetylserine" evidence="3"> +<location> +<position position="2"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1 2"> +<location> +<position position="180"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="183"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="207"/> +</location> +</feature> +<sequence length="298" mass="32638" checksum="7E22245F35290ACF" modified="1995-02-01" version="1"> +MSTSVPVKKALSALLRDPGNSHCADCKAQLHPRWASWSLGVFICIKCAGIHRSLGTHISK +VKSVDLDTWKEEHLVKLIQFKNNLRANSYYEATLADELKQRKITDTSSLQNFIKNKYEYK +KWIGDLSSIEGLNDSTEPVLHKPSANHSLPASNARLDQSSNSLQKTQTQPPSHLLSTSRS +NTSLLNLQVSSLSKTTSNTSVTSSATSIGAANTKTGNRVGEFGQRNDLKKSILSLYSKPS +AQTQSQNSFFTSTTPQPCNTPSPFVNTGITATNNNSMNSNSSSNISLDDNELFKNVWS +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1994-10-01" modified="2015-10-14" version="147"> +<accession>P38628</accession> +<accession>D3DLJ2</accession> +<name>AGM1_YEAST</name> +<protein> +<recommendedName> +<fullName evidence="9">Phosphoacetylglucosamine mutase</fullName> +<shortName>PAGM</shortName> +<ecNumber evidence="6">5.4.2.3</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary" evidence="7">PCM1</name> +<name type="synonym" evidence="8">AGM1</name> +<name type="ordered locus" evidence="11">YEL058W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="1"> +<location> +<position position="67"/> +</location> +</feature> +<sequence length="557" mass="62067" checksum="76F17D47D07C920A" modified="1995-02-01" version="2"> +MKVDYEQLCKLYDDTCRTKNVQFSYGTAGFRTLAKNLDTVMFSTGILAVLRSLKLQGQYV +GVMITASHNPYQDNGVKIVEPDGSMLLATWEPYAMQLANAASFATNFEEFRVELAKLIEH +EKIDLNTTVVPHIVVGRDSRESSPYLLRCLTSSMASVFHAQVLDLGCVTTPQLHYITDLS +NRRKLEGDTAPVATEQDYYSFFIGAFNELFATYQLEKRLSVPKLFIDTANGIGGPQLKKL +LASEDWDVPAEQVEVINDRSDVPELLNFECGADYVKTNQRLPKGLSPSSFDSLYCSFDGD +ADRVVFYYVDSGSKFHLLDGDKISTLFAKFLSKQLELAHLEHSLKIGVVQTAYANGSSTA +YIKNTLHCPVSCTKTGVKHLHHEAATQYDIGIYFEANGHGTIIFSEKFHRTIKSELSKSK +LNGDTLALRTLKCFSELINQTVGDAISDMLAVLATLAILKMSPMDWDEEYTDLPNKLVKC +IVPDRSIFQTTDQERKLLNPVGLQDKIDLVVAKYPMGRSFVRASGTEDAVRVYAECKDSS +KLGQFCDEVVEHVKASA +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1992-05-01" modified="2015-10-14" version="138"> +<accession>P25376</accession> +<accession>D6VQZ1</accession> +<name>AGP1_YEAST</name> +<protein> +<recommendedName> +<fullName>General amino acid permease AGP1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AGP1</name> +<name type="ordered locus">YCL025C</name> +<name type="ORF">YCL25C</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="2"> +<location> +<position position="6"/> +</location> +</feature> +<sequence length="633" mass="69671" checksum="8E19A836C2F6C50F" modified="2008-04-29" version="3"> +MSSSKSLYELKDLKNSSTEIHATGQDNEIEYFETGSNDRPSSQPHLGYEQHNTSAVRRFF +DSFKRADQGPQDEVEATQMNDLTSAISPSSRQAQELEKNESSDNIGANTGHKSDSLKKTI +QPRHVLMIALGTGIGTGLLVGNGTALVHAGPAGLLIGYAIMGSILYCIIQACGEMALVYS +NLTGGYNAYPSFLVDDGFGFAVAWVYCLQWLCVCPLELVTASMTIKYWTTSVNPDVFVII +FYVLVITINIFGARGYAEAEFFFNCCKILMMTGFFILGIIIDVGGAGNDGFIGGKYWHDP +GAFNGKHAIDRFKGVAATLVTAAFAFGGSEFIAITTAEQSNPRKAIPGAAKQMIYRILFL +FLATIILLGFLVPYNSDQLLGSTGGGTKASPYVIAVASHGVRVVPHFINAVILLSVLSMA +NSSFYSSARLFLTLSEQGYAPKVFSYIDRAGRPLIAMGVSALFAVIAFCAASPKEEQVFT +WLLAISGLSQLFTWTAICLSHLRFRRAMKVQGRSLGELGFKSQTGVWGSAYACIMMILIL +IAQFWVAIAPIGEGKLDAQAFFENYLAMPILIALYVGYKVWHKDWKLFIRADKIDLDSHR +QIFDEELIKQEDEEYRERLRNGPYWKRVVAFWC +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1994-10-01" modified="2015-10-14" version="126"> +<accession>P38090</accession> +<accession>D6VQC9</accession> +<name>AGP2_YEAST</name> +<protein> +<recommendedName> +<fullName>General amino acid permease AGP2</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AGP2</name> +<name type="ordered locus">YBR132C</name> +<name type="ORF">YBR1007</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="596" mass="67262" checksum="8658DCDA5A7D6B64" modified="1994-10-01" version="1"> +MTKERMTIDYENDGDFEYDKNKYKTITTRIKSIEPSEGWLEPSGSVGHINTIPEAGDVHV +DEHEDRGSSIDDDSRTYLLYFTETRRKLENRHVQLIAISGVIGTALFVAIGKALYRGGPA +SLLLAFALWCVPILCITVSTAEMVCFFPVSSPFLRLATKCVDDSLAVMASWNFWFLECVQ +IPFEIVSVNTIIHYWRDDYSAGIPLAVQVVLYLLISICAVKYYGEMEFWLASFKIILALG +LFTFTFITMLGGNPEHDRYGFRNYGESPFKKYFPDGNDVGKSSGYFQGFLACLIQASFTI +AGGEYISMLAGEVKRPRKVLPKAFKQVFVRLTFLFLGSCLCVGIVCSPNDPDLTAAINEA +RPGAGSSPYVIAMNNLKIRILPDIVNIALITAAFSAGNAYTYCSSRTFYGMALDGYAPKI +FTRCNRHGVPIYSVAISLVWALVSLLQLNSNSAVVLNWLINLITASQLINFVVLCIVYLF +FRRAYHVQQDSLPKLPFRSWGQPYTAIIGLVSCSAMILIQGYTVFFPKLWNTQDFLFSYL +MVFINIGIYVGYKFIWKRGKDHFKNPHEIDFSKELTEIENHEIESSFEKFQYYSKA +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-11-01" modified="2015-10-14" version="126"> +<accession>P43548</accession> +<accession>D6VTH5</accession> +<name>AGP3_YEAST</name> +<protein> +<recommendedName> +<fullName>General amino acid permease AGP3</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AGP3</name> +<name type="ordered locus">YFL055W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="558" mass="61052" checksum="D7AE03BE36ADA1A1" modified="1995-11-01" version="1"> +MAVLNLKRETVDIEETAKKDIKPYFASNVEAVDIDEDPDVSRYDPQTGVKRALKNRHISL +LALGGVIGPGCLVGAGNALNKGGPLALLLGFSIIGIIAFSVMESIGEMITLYPSGGGFTT +LARRFHSDALPAVCGYAYVVVFFAVLANEYNTLSSILQFWGPQVPLYGYILIFWFAFEIF +QLVGVGLFGETEYWLAWLKIVGLVAYYIFSIVYISGDIRNRPAFGFHYWNSPGALSHGFK +GIAIVFVFCSTFYSGTESVALAATESKNPGKAVPLAVRQTLWRILVVYIGIAVFYGATVP +FDDPNLSASTKVLKSPIAIAISRAGWAGGAHLVNAFILITCISAINGSLYIGSRTLTHLA +HEGLAPKILAWTDRRGVPIPAITVFNALGLISLMNVSVGAANAYSYIVNLSGVGVFIVWG +VISYTHLRIRKAWVAQGRSIEELPYEALFYPWTPVLSLAANIFLALIQGWSYFVPFDAGN +FVDAYILLPVGILLYIGICVFKSNHFRTVDLRSINLDEGRRKDMEADLSDQESSLASSET +MKDYKSATFFRYLSNIFT +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1995-11-01" modified="2015-10-14" version="130"> +<accession>P43567</accession> +<accession>D6VTK0</accession> +<name>AGX1_YEAST</name> +<protein> +<recommendedName> +<fullName>Alanine--glyoxylate aminotransferase 1</fullName> +<ecNumber>2.6.1.44</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AGX1</name> +<name type="ordered locus">YFL030W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N6-(pyridoxal phosphate)lysine"> +<location> +<position position="201"/> +</location> +</feature> +<sequence length="385" mass="41907" checksum="460D5DCCA8FDF79F" modified="1995-11-01" version="1"> +MTKSVDTLLIPGPIILSGAVQKALDVPSLGHTSPEFVSIFQRVLKNTRAVFKSAAASKSQ +PFVLAGSGTLGWDIFASNFILSKAPNKNVLVVSTGTFSDRFADCLRSYGAQVDVVRPLKI +GESVPLELITEKLSQNSYGAVTVTHVDTSTAVLSDLKAISQAIKQTSPETFFVVDAVCSI +GCEEFEFDEWGVDFALTASQKAIGAPAGLSISLCSSRFMDYALNDSKNGHVHGYFSSLRR +WTPIMENYEAGKGAYFATPPVQLINSLDVALKEILEEGLHKRWDLHREMSDWFKDSLVNG +LQLTSVSRYPSNMSAHGLTAVYVADPPDVIAFLKSHGVVIAGGIHKDIGPKYIRIGHMGV +TACNKNLPYMKNCFDLIKLALQRKK +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2004-11-23" modified="2015-10-14" version="119"> +<accession>Q12449</accession> +<accession>D6VSJ8</accession> +<accession>Q02565</accession> +<accession>Q7LIE3</accession> +<name>AHA1_YEAST</name> +<protein> +<recommendedName> +<fullName>Hsp90 co-chaperone AHA1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AHA1</name> +<name type="ordered locus">YDR214W</name> +<name type="ORF">YD8142.16</name> +<name type="ORF">YD8142B.06</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="350" mass="39436" checksum="06DF6B40EB5050BE" modified="1996-11-01" version="1"> +MVVNNPNNWHWVDKNCIGWAKEYFKQKLVGVEAGSVKDKKYAKIKSVSSIEGDCEVNQRK +GKVISLFDLKITVLIEGHVDSKDGSALPFEGSINVPEVAFDSEASSYQFDISIFKETSEL +SEAKPLIRSELLPKLRQIFQQFGKDLLATHGNDIQVPESQVKSNYTRGNQKSSFTEIKDS +ASKPKKNALPSSTSTSAPVSSTNKVPQNGSGNSTSIYLEPTFNVPSSELYETFLDKQRIL +AWTRSAQFFNSGPKLETKEKFELFGGNVISELVSCEKDKKLVFHWKLKDWSAPFNSTIEM +TFHESQEFHETKLQVKWTGIPVGEEDRVRANFEEYYVRSIKLTFGFGAVL +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2006-03-21" modified="2015-10-14" version="116"> +<accession>Q12433</accession> +<accession>D6W290</accession> +<name>AHC1_YEAST</name> +<protein> +<recommendedName> +<fullName>Protein AHC1</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AHC1</name> +<name type="ordered locus">YOR023C</name> +<name type="ORF">OR26.13</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="282"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="1 2 3"> +<location> +<position position="505"/> +</location> +</feature> +<sequence length="566" mass="63869" checksum="C18AFA10E4334764" modified="1996-11-01" version="1"> +MMSPAQDKLQHQHHNPNSSSSSSSKMTNVYQVTTPKSPQDLENNMDEPFKMDTATSNPDK +DSENTQRLKYECAKGEIQNVLNLHIMLNHKHVRHLRRNVQKVNAKLALLETLHKDTGLLN +KIERTYQLKIKQHQQHSVLGGHFHDSTATENTNASNYNLSYPVLSDYNINCQPLSSSSNR +NLSTTRIPHHHYHTRSKSNGLLLEPSALRPANSNIIDYRLTGSKSLSEAITKPTPVSLPH +SNSDGISSPRSSSISPLDEQPGFQILPFKPSQMHLNHRRNYSSTCLTSNSGIIGKTENNE +PIFRRYDGILVIITCSKCDRSGFTSAQGIVNHTRLKHSKLYSSQPLAVLNNQKLLPNDKQ +DPEILSKFKKLNLDPNKDYLPSDIAIPKPQSPINHSENHTRAPKTVKNTPHLEKLYQNKE +DFKKLIDMVNETPDDLNEYLKQREIQLRYQKEQEEESSKSDDEASYVPSPSLSATATTTT +TTDPPSPPVLSSSLQRKLLRKRKLSLNSSTPMEDLPLRERLRANPTDKKPRKAALLTNEL +EGPDPAAKSSSYYNLRSKSRLRGSHT +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1992-05-01" modified="2015-10-14" version="91"> +<accession>P25649</accession> +<accession>D6VR83</accession> +<name>AHC2_YEAST</name> +<protein> +<recommendedName> +<fullName>ADA histone acetyltransferase complex component 2</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AHC2</name> +<name type="ordered locus">YCR082W</name> +<name type="ORF">YCR82W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<sequence length="128" mass="15117" checksum="6603BD42877E0526" modified="1992-05-01" version="1"> +MITPKGTHDAVAKFQKTDLHQDLDYIVLQQRRTQLETLINERESFVKNLCSLFHKIQNTK +NYQEFVDVLAENRDLLREIFTVENGFQKQKWISNDDIPQIDWDKFALDINAYIAENDQLL +ALYEDGLL +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1994-10-01" modified="2015-09-16" version="157"> +<accession>P38013</accession> +<accession>D6VYA9</accession> +<name>AHP1_YEAST</name> +<protein> +<recommendedName> +<fullName>Peroxiredoxin type-2</fullName> +<ecNumber>1.11.1.15</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AHP1</name> +<name type="ordered locus">YLR109W</name> +<name type="ORF">L2916</name> +<name type="ORF">L9354.5</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="evidence at protein level"/> +<feature type="modified residue" description="N-acetylserine" evidence="10"> +<location> +<position position="2"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="28"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="3"> +<location> +<position position="59"/> +</location> +</feature> +<feature type="modified residue" description="Phosphoserine" evidence="4"> +<location> +<position position="116"/> +</location> +</feature> +<sequence length="176" mass="19115" checksum="11B730781306A015" modified="2007-01-23" version="4"> +MSDLVNKKFPAGDYKFQYIAISQSDADSESCKMPQTVEWSKLISENKKVIITGAPAAFSP +TCTVSHIPGYINYLDELVKEKEVDQVIVVTVDNPFANQAWAKSLGVKDTTHIKFASDPGC +AFTKSIGFELAVGDGVYWSGRWAMVVENGIVTYAAKETNPGTDVTVSSVESVLAHL +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1993-04-01" modified="2015-07-22" version="64"> +<accession>P29589</accession> +<accession>P38807</accession> +<name>AHT1_YEAST</name> +<protein> +<recommendedName> +<fullName>Putative hexose transport activator protein</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AHT1</name> +<name type="ordered locus">YHR093W</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="uncertain"/> +<sequence length="182" mass="19776" checksum="7B0723BAA1066713" modified="1993-04-01" version="1"> +MDCKIKAAGKNSGIFHEGGTKSSKSFLTVFIRSVFPLSPSFPAGGGIWGPMEKKPGGVGK +KKGSEKKTAQGNIFFSTERDAGQEKCGILYKHCFSILYGFFWKKADKPKEKTGNGSGLGI +VFPIGQKKIPEPADSDIFLPCFRYAAASDFTKAKRFLVEITAVYWVSLEAQPSSASCLFI +LI +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1986-07-21" modified="2015-10-14" version="118"> +<accession>P03876</accession> +<accession>A0A0A7NYJ2</accession> +<accession>Q9ZZX4</accession> +<name>AI2M_YEAST</name> +<protein> +<recommendedName> +<fullName>Putative COX1/OXI3 intron 2 protein</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AI2</name> +<name type="ordered locus">Q0055</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="inferred from homology"/> +<sequence length="854" mass="98008" checksum="6E22D9B5ABCD43F2" modified="2005-12-20" version="2"> +MVQRWLYSTNAKDIAVLYFMLAIFSGMAGTAMSLIIRLELAAPGSQYLHGNSQLFNVLVV +GHAVLMIFCAPFRLIYHCIEVLIDKHISVYSINENFTVSFWFWLLVVTYMVFRYVNHMAY +PVGANSTGTMACHKSAGVKQPAQGKNCPMARLTNSCKECLGFSLTPSHLGIVIHAYVLEE +EVHELTKNESLALSKSWHLEGCTSSNGKLRNTGLSERGNPGDNGVFMVPKFNLNKVRYFS +TLSKLNARKEDSLAYLTKINTTDFSELNKLMENNHNKTETINTRILKLMSDIRMLLIAYN +KIKSKKGNMSKGSNNITLDGINISYLNKLSKDINTNMFKFSPVRRVEIPKTSGGFRPLSV +GNPREKIVQESMRMMLEIIYNNSFSYYSHGFRPNLSCLTAIIQCKNYMQYCNWFIKVDLN +KCFDTIPHNMLINVLNERIKDKGFMDLLYKLLRAGYVDKNNNYHNTTLGIPQGSVVSPIL +CNIFLDKLDKYLENKFENEFNTGNMSNRGRNPIYNSLSSKIYRCKLLSEKLKLIRLRDHY +QRNMGSDKSFKRAYFVRYADDIIIGVMGSHNDCKNILNDINNFLKENLGMSINMDKSVIK +HSKEGVSFLGYDVKVTPWEKRPYRMIKKGDNFIRVRHHTSLVVNAPIRSIVMKLNKHGYC +SHGILGKPRGVGRLIHEEMKTILMHYLAVGRGIMNYYRLATNFTTLRGRITYILFYSCCL +TLARKFKLNTVKKVILKFGKVLVDPHSKVSFSIDDFKIRHKMNMTDSNYTPDEILDRYKY +MLPRSLSLFSGICQICGSKHDLEVHHVRTLNNAANKIKDDYLLGRMIKMNRKQITICKTC +HFKVHQGKYNGPGL +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="2007-01-09" modified="2015-10-14" version="81"> +<accession>Q9ZZX0</accession> +<accession>A0A0A7NYD5</accession> +<name>AI5B_YEAST</name> +<protein> +<recommendedName> +<fullName>Intron-encoded DNA endonuclease aI5 beta</fullName> +<ecNumber>3.1.-.-</ecNumber> +</recommendedName> +</protein> +<gene> +<name type="primary">AI5_BETA</name> +<name type="ordered locus">Q0075</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="inferred from homology"/> +<sequence length="354" mass="42279" checksum="FA9175E5748AD798" modified="1999-05-01" version="1"> +MLMLLMMILTNNKVFMETLYYYLMFNFQLMSPFGVPVPGPAPETKDIKNLYESIMNNYIN +ILNKYTININKDNINKLKFLDNYTEEEKGYYLSGLFEGDGNIYTRCFSITFSLEDVLLAN +YLCTYFKIGHITAKYNFNKELTAVKWNIMKKKEQEVFMNYINGKLLTYKRYDQYFKYNFN +NRLNIKLLKPKEFDLTLNPWLTGFNDADGYFYTGFQKHKNSQWLKFHLELSQKDSYILDI +IKKYFKTGGILKRDYKSGATAYIYKAQSSKAMKPFIEYFNNYQPLSTRRYKQYLLLNIAY +LLKLNKLHMLTNSLLMLKELMLLQSVKNMSLEMKNELNNRVKIIINKTHYNNIE +</sequence> +</entry> +<entry dataset="Swiss-Prot" created="1986-07-21" modified="2015-10-14" version="122"> +<accession>P03875</accession> +<accession>A0A0A7NYG1</accession> +<accession>Q9ZZX5</accession> +<name>AI1M_YEAST</name> +<protein> +<recommendedName> +<fullName>Putative COX1/OXI3 intron 1 protein</fullName> +</recommendedName> +</protein> +<gene> +<name type="primary">AI1</name> +<name type="ordered locus">Q0050</name> +</gene> +<organism> +<name type="scientific">Saccharomyces cerevisiae (strain ATCC 204508 / S288c)</name> +<name type="common">Baker's yeast</name> +</organism> +<proteinExistence type="inferred from homology"/> +<sequence length="834" mass="96079" checksum="BFB64B6F36416A5A" modified="2005-12-20" version="2"> +MVQRWLYSTNAKDIAVLYFMLAIFSGMAGTAMSLIIRLELAAPGSQYLHGNSQLFNGAPT +SAYISLMRTALVLWIINRYLKHMTNSVGANFTGTMACHKTPMISVGGVKCYMVRLTNFLQ +VFIRITISSYHLDMVKQVWLFYVEVIRLWFIVLDSTGSVKKMKDTNNTKGNTKSEGSTER +GNSGVDRGMVVPNTQMKMRFLNQVRYYSVNNNLKMGKDTNIELSKDTSTSDLLEFEKLVM +DNMNEENMNNNLLSIMKNVDMLMLAYNRIKSKPGNMTPGTTLETLDGMNMMYLNKLSNEL +GTGKFKFKPMRMVNIPKPKGGMRPLSVGNPRDKIVQEVMRMILDTIFDKKMSTHSHGFRK +NMSCQTAIWEVRNMFGGSNWFIEVDLKKCFDTISHDLIIKELKRYISDKGFIDLVYKLLR +AGYIDEKGTYHKPMLGLPQGSLISPILCNIVMTLVDNWLEDYINLYNKGKVKKQHPTYKK +LSRMIAKAKMFSTRLKLHKERAKGPTFIYNDPNFKRMKYVRYADDILIGVLGSKNDCKMI +KRDLNNFLNSLGLTMNEEKTLITCATETPARFLGYNISITPLKRMPTVTKTIRGKTIRSR +NTTRPIINAPIRDIINKLATNGYCKHNKNGRMGVPTRVGRWTYEEPRTIINNYKALGRGI +LNYYKLATNYKRLRERIYYVLYYSCVLTLASKYRLKTMSKTIKKFGYNLNIIENDKLIAN +FPRNTFDNIKKIENHGMFMYMSEAKVTDPFEYIDSIKYMLPTAKANFNKPCSICNSTIDV +EMHHVKQLHRGMLKATKDYITGRMITMNRKQIPLCKQCHIKTHKNKFKNMGPGM +</sequence> +</entry> +</uniprot> \ No newline at end of file
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/tool_dependencies.xml Thu Nov 05 08:59:15 2015 -0500 @@ -0,0 +1,9 @@ +<?xml version="1.0"?> +<tool_dependency> + <package name="mono" version="4.0"> + <repository changeset_revision="d081ac7d12d1" name="package_mono_4_0" owner="iuc" toolshed="https://testtoolshed.g2.bx.psu.edu" /> + </package> + <package name="morpheus" version="171"> + <repository changeset_revision="a8e9d3b708f2" name="package_morpheus_171" owner="iuc" toolshed="https://testtoolshed.g2.bx.psu.edu" /> + </package> +</tool_dependency>