Mercurial > repos > fubar > differential_count_models
comparison rgedgeRpaired_nocamera.xml @ 36:b8f9b2c64202 draft
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author | fubar |
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date | Sun, 22 Dec 2013 01:48:38 -0500 |
parents | 8051d14cf819 |
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35:375269b30baf | 36:b8f9b2c64202 |
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1 <tool id="rgDifferentialCount" name="Differential_Count" version="0.22"> | |
2 <description>models using BioConductor packages</description> | |
3 <requirements> | |
4 <requirement type="package" version="3.0.1">r3</requirement> | |
5 <requirement type="package" version="1.3.18">graphicsmagick</requirement> | |
6 <requirement type="package" version="9.07">ghostscript</requirement> | |
7 <requirement type="package" version="2.12">biocbasics</requirement> | |
8 </requirements> | |
9 | |
10 <command interpreter="python"> | |
11 rgToolFactory.py --script_path "$runme" --interpreter "Rscript" --tool_name "DifferentialCounts" | |
12 --output_dir "$html_file.files_path" --output_html "$html_file" --make_HTML "yes" | |
13 </command> | |
14 <inputs> | |
15 <param name="input1" type="data" format="tabular" label="Select an input matrix - rows are contigs, columns are counts for each sample" | |
16 help="Use the HTSeq based count matrix preparation tool to create these matrices from BAM/SAM files and a GTF file of genomic features"/> | |
17 <param name="title" type="text" value="Differential Counts" size="80" label="Title for job outputs" | |
18 help="Supply a meaningful name here to remind you what the outputs contain"> | |
19 <sanitizer invalid_char=""> | |
20 <valid initial="string.letters,string.digits"><add value="_" /> </valid> | |
21 </sanitizer> | |
22 </param> | |
23 <param name="treatment_name" type="text" value="Treatment" size="50" label="Treatment Name"/> | |
24 <param name="Treat_cols" label="Select columns containing treatment." type="data_column" data_ref="input1" numerical="True" | |
25 multiple="true" use_header_names="true" size="120" display="checkboxes"> | |
26 <validator type="no_options" message="Please select at least one column."/> | |
27 <sanitizer invalid_char=""> | |
28 <valid initial="string.letters,string.digits"><add value="_" /> </valid> | |
29 </sanitizer> | |
30 </param> | |
31 <param name="control_name" type="text" value="Control" size="50" label="Control Name"/> | |
32 <param name="Control_cols" label="Select columns containing control." type="data_column" data_ref="input1" numerical="True" | |
33 multiple="true" use_header_names="true" size="120" display="checkboxes" optional="true"> | |
34 <validator type="no_options" message="Please select at least one column."/> | |
35 <sanitizer invalid_char=""> | |
36 <valid initial="string.letters,string.digits"><add value="_" /> </valid> | |
37 </sanitizer> <validator type="no_options" message="Please select at least one column."/> | |
38 <sanitizer invalid_char=""> | |
39 <valid initial="string.letters,string.digits"><add value="_" /> </valid> | |
40 </sanitizer> | |
41 | |
42 </param> | |
43 <param name="subjectids" type="text" optional="true" size="120" value = "" | |
44 label="IF SUBJECTS NOT ALL INDEPENDENT! Enter comma separated strings to indicate sample labels for (eg) pairing - must be one for every column in input" | |
45 help="Leave blank if no pairing, but eg if data from sample id A99 is in columns 2,4 and id C21 is in 3,5 then enter 'A99,C21,A99,C21'"> | |
46 <sanitizer> | |
47 <valid initial="string.letters,string.digits"><add value="," /> </valid> | |
48 </sanitizer> | |
49 </param> | |
50 <param name="fQ" type="float" value="0.3" size="5" label="Non-differential contig count quantile threshold - zero to analyze all non-zero read count contigs" | |
51 help="May be a good or a bad idea depending on the biology and the question. EG 0.3 = sparsest 30% of contigs with at least one read are removed before analysis"/> | |
52 <param name="useNDF" type="boolean" truevalue="T" falsevalue="F" checked="false" size="1" | |
53 label="Non differential filter - remove contigs below a threshold (1 per million) for half or more samples" | |
54 help="May be a good or a bad idea depending on the biology and the question. This was the old default. Quantile based is available as an alternative"/> | |
55 | |
56 <conditional name="edgeR"> | |
57 <param name="doedgeR" type="select" | |
58 label="Run this model using edgeR" | |
59 help="edgeR uses a negative binomial model and seems to be powerful, even with few replicates"> | |
60 <option value="F">Do not run edgeR</option> | |
61 <option value="T" selected="true">Run edgeR</option> | |
62 </param> | |
63 <when value="T"> | |
64 <param name="edgeR_priordf" type="integer" value="20" size="3" | |
65 label="prior.df for tagwise dispersion - lower value = more emphasis on each tag's variance. Replaces prior.n and prior.df = prior.n * residual.df" | |
66 help="0 = Use edgeR default. Use a small value to 'smooth' small samples. See edgeR docs and note below"/> | |
67 </when> | |
68 <when value="F"></when> | |
69 </conditional> | |
70 <conditional name="DESeq2"> | |
71 <param name="doDESeq2" type="select" | |
72 label="Run the same model with DESeq2 and compare findings" | |
73 help="DESeq2 is an update to the DESeq package. It uses different assumptions and methods to edgeR"> | |
74 <option value="F" selected="true">Do not run DESeq2</option> | |
75 <option value="T">Run DESeq2</option> | |
76 </param> | |
77 <when value="T"> | |
78 <param name="DESeq_fitType" type="select"> | |
79 <option value="parametric" selected="true">Parametric (default) fit for dispersions</option> | |
80 <option value="local">Local fit - this will automagically be used if parametric fit fails</option> | |
81 <option value="mean">Mean dispersion fit- use this if you really understand what you're doing - read the fine manual linked below in the documentation</option> | |
82 </param> | |
83 </when> | |
84 <when value="F"> </when> | |
85 </conditional> | |
86 <param name="doVoom" type="select" | |
87 label="Run the same model with Voom/limma and compare findings" | |
88 help="Voom uses counts per million and a precise transformation of variance so count data can be analysed using limma"> | |
89 <option value="F" selected="true">Do not run VOOM</option> | |
90 <option value="T">Run VOOM</option> | |
91 </param> | |
92 <!-- | |
93 <conditional name="camera"> | |
94 <param name="doCamera" type="select" label="Run the edgeR implementation of Camera GSEA for up/down gene sets" | |
95 help="If yes, you can choose a set of genesets to test and/or supply a gmt format geneset collection from your history"> | |
96 <option value="F" selected="true">Do not run GSEA tests with the Camera algorithm</option> | |
97 <option value="T">Run GSEA tests with the Camera algorithm</option> | |
98 </param> | |
99 <when value="T"> | |
100 <conditional name="gmtSource"> | |
101 <param name="refgmtSource" type="select" | |
102 label="Use a gene set (.gmt) from your history and/or use a built-in (MSigDB etc) gene set"> | |
103 <option value="indexed" selected="true">Use a built-in gene set</option> | |
104 <option value="history">Use a gene set from my history</option> | |
105 <option value="both">Add a gene set from my history to a built in gene set</option> | |
106 </param> | |
107 <when value="indexed"> | |
108 <param name="builtinGMT" type="select" label="Select a gene set matrix (.gmt) file to use for the analysis"> | |
109 <options from_data_table="gseaGMT_3.1"> | |
110 <filter type="sort_by" column="2" /> | |
111 <validator type="no_options" message="No GMT v3.1 files are available - please install them"/> | |
112 </options> | |
113 </param> | |
114 </when> | |
115 <when value="history"> | |
116 <param name="ownGMT" type="data" format="gmt" label="Select a Gene Set from your history" /> | |
117 </when> | |
118 <when value="both"> | |
119 <param name="ownGMT" type="data" format="gseagmt" label="Select a Gene Set from your history" /> | |
120 <param name="builtinGMT" type="select" label="Select a gene set matrix (.gmt) file to use for the analysis"> | |
121 <options from_data_table="gseaGMT_4"> | |
122 <filter type="sort_by" column="2" /> | |
123 <validator type="no_options" message="No GMT v4 files are available - please fix tool_data_table and loc files"/> | |
124 </options> | |
125 </param> | |
126 </when> | |
127 </conditional> | |
128 </when> | |
129 <when value="F"> | |
130 </when> | |
131 </conditional> | |
132 --> | |
133 <param name="fdrthresh" type="float" value="0.05" size="5" label="P value threshold for FDR filtering for amily wise error rate control" | |
134 help="Conventional default value of 0.05 recommended"/> | |
135 <param name="fdrtype" type="select" label="FDR (Type II error) control method" | |
136 help="Use fdr or bh typically to control for the number of tests in a reliable way"> | |
137 <option value="fdr" selected="true">fdr</option> | |
138 <option value="BH">Benjamini Hochberg</option> | |
139 <option value="BY">Benjamini Yukateli</option> | |
140 <option value="bonferroni">Bonferroni</option> | |
141 <option value="hochberg">Hochberg</option> | |
142 <option value="holm">Holm</option> | |
143 <option value="hommel">Hommel</option> | |
144 <option value="none">no control for multiple tests</option> | |
145 </param> | |
146 </inputs> | |
147 <outputs> | |
148 <data format="tabular" name="out_edgeR" label="${title}_topTable_edgeR.xls"> | |
149 <filter>edgeR['doedgeR'] == "T"</filter> | |
150 </data> | |
151 <data format="tabular" name="out_DESeq2" label="${title}_topTable_DESeq2.xls"> | |
152 <filter>DESeq2['doDESeq2'] == "T"</filter> | |
153 </data> | |
154 <data format="tabular" name="out_VOOM" label="${title}_topTable_VOOM.xls"> | |
155 <filter>doVoom == "T"</filter> | |
156 </data> | |
157 <data format="html" name="html_file" label="${title}.html"/> | |
158 </outputs> | |
159 <stdio> | |
160 <exit_code range="4" level="fatal" description="Number of subject ids must match total number of samples in the input matrix" /> | |
161 </stdio> | |
162 <tests> | |
163 <test> | |
164 <param name='input1' value='test_bams2mx.xls' ftype='tabular' /> | |
165 <param name='treatment_name' value='liver' /> | |
166 <param name='title' value='edgeRtest' /> | |
167 <param name='useNDF' value='' /> | |
168 <param name='doedgeR' value='T' /> | |
169 <param name='doVoom' value='T' /> | |
170 <param name='doDESeq2' value='T' /> | |
171 <param name='fdrtype' value='fdr' /> | |
172 <param name='edgeR_priordf' value="8" /> | |
173 <param name='fdrthresh' value="0.05" /> | |
174 <param name='control_name' value='heart' /> | |
175 <param name='subjectids' value='' /> | |
176 <param name='Control_cols' value='3,4,5,9' /> | |
177 <param name='Treat_cols' value='2,6,7,8' /> | |
178 <output name='out_edgeR' file='edgeRtest1out.xls' compare='diff' /> | |
179 <output name='html_file' file='edgeRtest1out.html' compare='diff' lines_diff='20' /> | |
180 </test> | |
181 </tests> | |
182 | |
183 <configfiles> | |
184 <configfile name="runme"> | |
185 <![CDATA[ | |
186 # | |
187 # edgeR.Rscript | |
188 # updated npv 2011 for R 2.14.0 and edgeR 2.4.0 by ross | |
189 # Performs DGE on a count table containing n replicates of two conditions | |
190 # | |
191 # Parameters | |
192 # | |
193 # 1 - Output Dir | |
194 | |
195 # Original edgeR code by: S.Lunke and A.Kaspi | |
196 reallybig = log10(.Machine\$double.xmax) | |
197 reallysmall = log10(.Machine\$double.xmin) | |
198 library('stringr') | |
199 library('gplots') | |
200 library('edgeR') | |
201 hmap2 = function(cmat,nsamp=100,outpdfname='heatmap2.pdf', TName='Treatment',group=NA,myTitle='title goes here') | |
202 { | |
203 # Perform clustering for significant pvalues after controlling FWER | |
204 samples = colnames(cmat) | |
205 gu = unique(group) | |
206 gn = rownames(cmat) | |
207 if (length(gu) == 2) { | |
208 col.map = function(g) {if (g==gu[1]) "#FF0000" else "#0000FF"} | |
209 pcols = unlist(lapply(group,col.map)) | |
210 } else { | |
211 colours = rainbow(length(gu),start=0,end=4/6) | |
212 pcols = colours[match(group,gu)] } | |
213 dm = cmat[(! is.na(gn)),] | |
214 # remove unlabelled hm rows | |
215 nprobes = nrow(dm) | |
216 # sub = paste('Showing',nprobes,'contigs ranked for evidence of differential abundance') | |
217 if (nprobes > nsamp) { | |
218 dm =dm[1:nsamp,] | |
219 #sub = paste('Showing',nsamp,'contigs ranked for evidence for differential abundance out of',nprobes,'total') | |
220 } | |
221 newcolnames = substr(colnames(dm),1,20) | |
222 colnames(dm) = newcolnames | |
223 pdf(outpdfname) | |
224 heatmap.2(dm,main=myTitle,ColSideColors=pcols,col=topo.colors(100),dendrogram="col",key=T,density.info='none', | |
225 Rowv=F,scale='row',trace='none',margins=c(8,8),cexRow=0.4,cexCol=0.5) | |
226 dev.off() | |
227 } | |
228 | |
229 hmap = function(cmat,nmeans=4,outpdfname="heatMap.pdf",nsamp=250,TName='Treatment',group=NA,myTitle="Title goes here") | |
230 { | |
231 # for 2 groups only was | |
232 #col.map = function(g) {if (g==TName) "#FF0000" else "#0000FF"} | |
233 #pcols = unlist(lapply(group,col.map)) | |
234 gu = unique(group) | |
235 colours = rainbow(length(gu),start=0.3,end=0.6) | |
236 pcols = colours[match(group,gu)] | |
237 nrows = nrow(cmat) | |
238 mtitle = paste(myTitle,'Heatmap: n contigs =',nrows) | |
239 if (nrows > nsamp) { | |
240 cmat = cmat[c(1:nsamp),] | |
241 mtitle = paste('Heatmap: Top ',nsamp,' DE contigs (of ',nrows,')',sep='') | |
242 } | |
243 newcolnames = substr(colnames(cmat),1,20) | |
244 colnames(cmat) = newcolnames | |
245 pdf(outpdfname) | |
246 heatmap(cmat,scale='row',main=mtitle,cexRow=0.3,cexCol=0.4,Rowv=NA,ColSideColors=pcols) | |
247 dev.off() | |
248 } | |
249 | |
250 qqPlot = function(descr='qqplot',pvector, outpdf='qqplot.pdf',...) | |
251 # stolen from https://gist.github.com/703512 | |
252 { | |
253 o = -log10(sort(pvector,decreasing=F)) | |
254 e = -log10( 1:length(o)/length(o) ) | |
255 o[o==-Inf] = reallysmall | |
256 o[o==Inf] = reallybig | |
257 maint = descr | |
258 pdf(outpdf) | |
259 plot(e,o,pch=19,cex=1, main=maint, ..., | |
260 xlab=expression(Expected~~-log[10](italic(p))), | |
261 ylab=expression(Observed~~-log[10](italic(p))), | |
262 xlim=c(0,max(e)), ylim=c(0,max(o))) | |
263 lines(e,e,col="red") | |
264 grid(col = "lightgray", lty = "dotted") | |
265 dev.off() | |
266 } | |
267 | |
268 smearPlot = function(DGEList,deTags, outSmear, outMain) | |
269 { | |
270 pdf(outSmear) | |
271 plotSmear(DGEList,de.tags=deTags,main=outMain) | |
272 grid(col="lightgray", lty="dotted") | |
273 dev.off() | |
274 } | |
275 | |
276 boxPlot = function(rawrs,cleanrs,maint,myTitle,pdfname) | |
277 { # | |
278 nc = ncol(rawrs) | |
279 for (i in c(1:nc)) {rawrs[(rawrs[,i] < 0),i] = NA} | |
280 fullnames = colnames(rawrs) | |
281 newcolnames = substr(colnames(rawrs),1,20) | |
282 colnames(rawrs) = newcolnames | |
283 newcolnames = substr(colnames(cleanrs),1,20) | |
284 colnames(cleanrs) = newcolnames | |
285 defpar = par(no.readonly=T) | |
286 print.noquote('raw contig counts by sample:') | |
287 print.noquote(summary(rawrs)) | |
288 print.noquote('normalised contig counts by sample:') | |
289 print.noquote(summary(cleanrs)) | |
290 pdf(pdfname) | |
291 par(mfrow=c(1,2)) | |
292 boxplot(rawrs,varwidth=T,notch=T,ylab='log contig count',col="maroon",las=3,cex.axis=0.35,main=paste('Raw:',maint)) | |
293 grid(col="lightgray",lty="dotted") | |
294 boxplot(cleanrs,varwidth=T,notch=T,ylab='log contig count',col="maroon",las=3,cex.axis=0.35,main=paste('After ',maint)) | |
295 grid(col="lightgray",lty="dotted") | |
296 dev.off() | |
297 pdfname = "sample_counts_histogram.pdf" | |
298 nc = ncol(rawrs) | |
299 print.noquote(paste('Using ncol rawrs=',nc)) | |
300 ncroot = round(sqrt(nc)) | |
301 if (ncroot*ncroot < nc) { ncroot = ncroot + 1 } | |
302 m = c() | |
303 for (i in c(1:nc)) { | |
304 rhist = hist(rawrs[,i],breaks=100,plot=F) | |
305 m = append(m,max(rhist\$counts)) | |
306 } | |
307 ymax = max(m) | |
308 ncols = length(fullnames) | |
309 if (ncols > 20) | |
310 { | |
311 scale = 7*ncols/20 | |
312 pdf(pdfname,width=scale,height=scale) | |
313 } else { | |
314 pdf(pdfname) | |
315 } | |
316 par(mfrow=c(ncroot,ncroot)) | |
317 for (i in c(1:nc)) { | |
318 hist(rawrs[,i], main=paste("Contig logcount",i), xlab='log raw count', col="maroon", | |
319 breaks=100,sub=fullnames[i],cex=0.8,ylim=c(0,ymax)) | |
320 } | |
321 dev.off() | |
322 par(defpar) | |
323 | |
324 } | |
325 | |
326 cumPlot = function(rawrs,cleanrs,maint,myTitle) | |
327 { # updated to use ecdf | |
328 pdfname = "Filtering_rowsum_bar_charts.pdf" | |
329 defpar = par(no.readonly=T) | |
330 lrs = log(rawrs,10) | |
331 lim = max(lrs) | |
332 pdf(pdfname) | |
333 par(mfrow=c(2,1)) | |
334 hist(lrs,breaks=100,main=paste('Before:',maint),xlab="# Reads (log)", | |
335 ylab="Count",col="maroon",sub=myTitle, xlim=c(0,lim),las=1) | |
336 grid(col="lightgray", lty="dotted") | |
337 lrs = log(cleanrs,10) | |
338 hist(lrs,breaks=100,main=paste('After:',maint),xlab="# Reads (log)", | |
339 ylab="Count",col="maroon",sub=myTitle,xlim=c(0,lim),las=1) | |
340 grid(col="lightgray", lty="dotted") | |
341 dev.off() | |
342 par(defpar) | |
343 } | |
344 | |
345 cumPlot1 = function(rawrs,cleanrs,maint,myTitle) | |
346 { # updated to use ecdf | |
347 pdfname = paste(gsub(" ","", myTitle , fixed=TRUE),"RowsumCum.pdf",sep='_') | |
348 pdf(pdfname) | |
349 par(mfrow=c(2,1)) | |
350 lastx = max(rawrs) | |
351 rawe = knots(ecdf(rawrs)) | |
352 cleane = knots(ecdf(cleanrs)) | |
353 cy = 1:length(cleane)/length(cleane) | |
354 ry = 1:length(rawe)/length(rawe) | |
355 plot(rawe,ry,type='l',main=paste('Before',maint),xlab="Log Contig Total Reads", | |
356 ylab="Cumulative proportion",col="maroon",log='x',xlim=c(1,lastx),sub=myTitle) | |
357 grid(col="blue") | |
358 plot(cleane,cy,type='l',main=paste('After',maint),xlab="Log Contig Total Reads", | |
359 ylab="Cumulative proportion",col="maroon",log='x',xlim=c(1,lastx),sub=myTitle) | |
360 grid(col="blue") | |
361 dev.off() | |
362 } | |
363 | |
364 | |
365 | |
366 doGSEA = function(y=NULL,design=NULL,histgmt="", | |
367 bigmt="/data/genomes/gsea/3.1/Abetterchoice_nocgp_c2_c3_c5_symbols_all.gmt", | |
368 ntest=0, myTitle="myTitle", outfname="GSEA.xls", minnin=5, maxnin=2000,fdrthresh=0.05,fdrtype="BH") | |
369 { | |
370 sink('Camera.log') | |
371 genesets = c() | |
372 if (bigmt > "") | |
373 { | |
374 bigenesets = readLines(bigmt) | |
375 genesets = bigenesets | |
376 } | |
377 if (histgmt > "") | |
378 { | |
379 hgenesets = readLines(histgmt) | |
380 if (bigmt > "") { | |
381 genesets = rbind(genesets,hgenesets) | |
382 } else { | |
383 genesets = hgenesets | |
384 } # use only history if no bi | |
385 } | |
386 print.noquote(paste("@@@read",length(genesets), 'genesets from',histgmt,bigmt)) | |
387 genesets = strsplit(genesets,'\t') # tabular. genesetid\tURLorwhatever\tgene_1\t..\tgene_n | |
388 outf = outfname | |
389 head=paste(myTitle,'edgeR GSEA') | |
390 write(head,file=outfname,append=F) | |
391 ntest=length(genesets) | |
392 urownames = toupper(rownames(y)) | |
393 upcam = c() | |
394 downcam = c() | |
395 for (i in 1:ntest) { | |
396 gs = unlist(genesets[i]) | |
397 g = gs[1] # geneset_id | |
398 u = gs[2] | |
399 if (u > "") { u = paste("<a href=\'",u,"\'>",u,"</a>",sep="") } | |
400 glist = gs[3:length(gs)] # member gene symbols | |
401 glist = toupper(glist) | |
402 inglist = urownames %in% glist | |
403 nin = sum(inglist) | |
404 if ((nin > minnin) && (nin < maxnin)) { | |
405 ### print(paste('@@found',sum(inglist),'genes in glist')) | |
406 camres = camera(y=y,index=inglist,design=design) | |
407 if (! is.null(camres)) { | |
408 rownames(camres) = g # gene set name | |
409 camres = cbind(GeneSet=g,URL=u,camres) | |
410 if (camres\$Direction == "Up") | |
411 { | |
412 upcam = rbind(upcam,camres) } else { | |
413 downcam = rbind(downcam,camres) | |
414 } | |
415 } | |
416 } | |
417 } | |
418 uscam = upcam[order(upcam\$PValue),] | |
419 unadjp = uscam\$PValue | |
420 uscam\$adjPValue = p.adjust(unadjp,method=fdrtype) | |
421 nup = max(10,sum((uscam\$adjPValue < fdrthresh))) | |
422 dscam = downcam[order(downcam\$PValue),] | |
423 unadjp = dscam\$PValue | |
424 dscam\$adjPValue = p.adjust(unadjp,method=fdrtype) | |
425 ndown = max(10,sum((dscam\$adjPValue < fdrthresh))) | |
426 write.table(uscam,file=paste('camera_up',outfname,sep='_'),quote=F,sep='\t',row.names=F) | |
427 write.table(dscam,file=paste('camera_down',outfname,sep='_'),quote=F,sep='\t',row.names=F) | |
428 print.noquote(paste('@@@@@ Camera up top',nup,'gene sets:')) | |
429 write.table(head(uscam,nup),file="",quote=F,sep='\t',row.names=F) | |
430 print.noquote(paste('@@@@@ Camera down top',ndown,'gene sets:')) | |
431 write.table(head(dscam,ndown),file="",quote=F,sep='\t',row.names=F) | |
432 sink() | |
433 } | |
434 | |
435 | |
436 | |
437 | |
438 doGSEAatonce = function(y=NULL,design=NULL,histgmt="", | |
439 bigmt="/data/genomes/gsea/3.1/Abetterchoice_nocgp_c2_c3_c5_symbols_all.gmt", | |
440 ntest=0, myTitle="myTitle", outfname="GSEA.xls", minnin=5, maxnin=2000,fdrthresh=0.05,fdrtype="BH") | |
441 { | |
442 sink('Camera.log') | |
443 genesets = c() | |
444 if (bigmt > "") | |
445 { | |
446 bigenesets = readLines(bigmt) | |
447 genesets = bigenesets | |
448 } | |
449 if (histgmt > "") | |
450 { | |
451 hgenesets = readLines(histgmt) | |
452 if (bigmt > "") { | |
453 genesets = rbind(genesets,hgenesets) | |
454 } else { | |
455 genesets = hgenesets | |
456 } # use only history if no bi | |
457 } | |
458 print.noquote(paste("@@@read",length(genesets), 'genesets from',histgmt,bigmt)) | |
459 genesets = strsplit(genesets,'\t') # tabular. genesetid\tURLorwhatever\tgene_1\t..\tgene_n | |
460 outf = outfname | |
461 head=paste(myTitle,'edgeR GSEA') | |
462 write(head,file=outfname,append=F) | |
463 ntest=length(genesets) | |
464 urownames = toupper(rownames(y)) | |
465 upcam = c() | |
466 downcam = c() | |
467 incam = c() | |
468 urls = c() | |
469 gsids = c() | |
470 for (i in 1:ntest) { | |
471 gs = unlist(genesets[i]) | |
472 gsid = gs[1] # geneset_id | |
473 url = gs[2] | |
474 if (url > "") { url = paste("<a href=\'",url,"\'>",url,"</a>",sep="") } | |
475 glist = gs[3:length(gs)] # member gene symbols | |
476 glist = toupper(glist) | |
477 inglist = urownames %in% glist | |
478 nin = sum(inglist) | |
479 if ((nin > minnin) && (nin < maxnin)) { | |
480 incam = c(incam,inglist) | |
481 gsids = c(gsids,gsid) | |
482 urls = c(urls,url) | |
483 } | |
484 } | |
485 incam = as.list(incam) | |
486 names(incam) = gsids | |
487 allcam = camera(y=y,index=incam,design=design) | |
488 allcamres = cbind(geneset=gsids,allcam,URL=urls) | |
489 for (i in 1:ntest) { | |
490 camres = allcamres[i] | |
491 res = try(test = (camres\$Direction == "Up")) | |
492 if ("try-error" %in% class(res)) { | |
493 cat("test failed, camres = :") | |
494 print.noquote(camres) | |
495 } else { if (camres\$Direction == "Up") | |
496 { upcam = rbind(upcam,camres) | |
497 } else { downcam = rbind(downcam,camres) | |
498 } | |
499 | |
500 } | |
501 } | |
502 uscam = upcam[order(upcam\$PValue),] | |
503 unadjp = uscam\$PValue | |
504 uscam\$adjPValue = p.adjust(unadjp,method=fdrtype) | |
505 nup = max(10,sum((uscam\$adjPValue < fdrthresh))) | |
506 dscam = downcam[order(downcam\$PValue),] | |
507 unadjp = dscam\$PValue | |
508 dscam\$adjPValue = p.adjust(unadjp,method=fdrtype) | |
509 ndown = max(10,sum((dscam\$adjPValue < fdrthresh))) | |
510 write.table(uscam,file=paste('camera_up',outfname,sep='_'),quote=F,sep='\t',row.names=F) | |
511 write.table(dscam,file=paste('camera_down',outfname,sep='_'),quote=F,sep='\t',row.names=F) | |
512 print.noquote(paste('@@@@@ Camera up top',nup,'gene sets:')) | |
513 write.table(head(uscam,nup),file="",quote=F,sep='\t',row.names=F) | |
514 print.noquote(paste('@@@@@ Camera down top',ndown,'gene sets:')) | |
515 write.table(head(dscam,ndown),file="",quote=F,sep='\t',row.names=F) | |
516 sink() | |
517 } | |
518 | |
519 | |
520 edgeIt = function (Count_Matrix=c(),group=c(),out_edgeR=F,out_VOOM=F,out_DESeq2=F,fdrtype='fdr',priordf=5, | |
521 fdrthresh=0.05,outputdir='.', myTitle='Differential Counts',libSize=c(),useNDF=F, | |
522 filterquantile=0.2, subjects=c(),mydesign=NULL, | |
523 doDESeq2=T,doVoom=T,doCamera=T,doedgeR=T,org='hg19', | |
524 histgmt="", bigmt="/data/genomes/gsea/3.1/Abetterchoice_nocgp_c2_c3_c5_symbols_all.gmt", | |
525 doCook=F,DESeq_fitType="parameteric") | |
526 { | |
527 # Error handling | |
528 if (length(unique(group))!=2){ | |
529 print("Number of conditions identified in experiment does not equal 2") | |
530 q() | |
531 } | |
532 require(edgeR) | |
533 options(width = 512) | |
534 mt = paste(unlist(strsplit(myTitle,'_')),collapse=" ") | |
535 allN = nrow(Count_Matrix) | |
536 nscut = round(ncol(Count_Matrix)/2) | |
537 colTotmillionreads = colSums(Count_Matrix)/1e6 | |
538 counts.dataframe = as.data.frame(c()) | |
539 rawrs = rowSums(Count_Matrix) | |
540 nonzerod = Count_Matrix[(rawrs > 0),] # remove all zero count genes | |
541 nzN = nrow(nonzerod) | |
542 nzrs = rowSums(nonzerod) | |
543 zN = allN - nzN | |
544 print('# Quantiles for non-zero row counts:',quote=F) | |
545 print(quantile(nzrs,probs=seq(0,1,0.1)),quote=F) | |
546 if (useNDF == T) | |
547 { | |
548 gt1rpin3 = rowSums(Count_Matrix/expandAsMatrix(colTotmillionreads,dim(Count_Matrix)) >= 1) >= nscut | |
549 lo = colSums(Count_Matrix[!gt1rpin3,]) | |
550 workCM = Count_Matrix[gt1rpin3,] | |
551 cleanrs = rowSums(workCM) | |
552 cleanN = length(cleanrs) | |
553 meth = paste( "After removing",length(lo),"contigs with fewer than ",nscut," sample read counts >= 1 per million, there are",sep="") | |
554 print(paste("Read",allN,"contigs. Removed",zN,"contigs with no reads.",meth,cleanN,"contigs"),quote=F) | |
555 maint = paste('Filter >=1/million reads in >=',nscut,'samples') | |
556 } else { | |
557 useme = (nzrs > quantile(nzrs,filterquantile)) | |
558 workCM = nonzerod[useme,] | |
559 lo = colSums(nonzerod[!useme,]) | |
560 cleanrs = rowSums(workCM) | |
561 cleanN = length(cleanrs) | |
562 meth = paste("After filtering at count quantile =",filterquantile,", there are",sep="") | |
563 print(paste('Read',allN,"contigs. Removed",zN,"with no reads.",meth,cleanN,"contigs"),quote=F) | |
564 maint = paste('Filter below',filterquantile,'quantile') | |
565 } | |
566 cumPlot(rawrs=rawrs,cleanrs=cleanrs,maint=maint,myTitle=myTitle) | |
567 allgenes = rownames(workCM) | |
568 reg = "^chr([0-9]+):([0-9]+)-([0-9]+)" | |
569 genecards="<a href=\'http://www.genecards.org/index.php?path=/Search/keyword/" | |
570 ucsc = paste("<a href=\'http://genome.ucsc.edu/cgi-bin/hgTracks?db=",org,sep='') | |
571 testreg = str_match(allgenes,reg) | |
572 if (sum(!is.na(testreg[,1]))/length(testreg[,1]) > 0.8) # is ucsc style string | |
573 { | |
574 print("@@ using ucsc substitution for urls") | |
575 contigurls = paste0(ucsc,"&position=chr",testreg[,2],":",testreg[,3],"-",testreg[,4],"\'>",allgenes,"</a>") | |
576 } else { | |
577 print.noquote("@@ using genecards substitution for urls") | |
578 contigurls = paste0(genecards,allgenes,"\'>",allgenes,"</a>") | |
579 } | |
580 print(paste("# Total low count contigs per sample = ",paste(lo,collapse=',')),quote=F) | |
581 cmrowsums = rowSums(workCM) | |
582 TName=unique(group)[1] | |
583 CName=unique(group)[2] | |
584 if (is.null(mydesign)) { | |
585 if (length(subjects) == 0) | |
586 { | |
587 mydesign = model.matrix(~group) | |
588 } | |
589 else { | |
590 subjf = factor(subjects) | |
591 mydesign = model.matrix(~subjf+group) # we block on subject so make group last to simplify finding it | |
592 } | |
593 } | |
594 print.noquote(paste('Using samples:',paste(colnames(workCM),collapse=','))) | |
595 print.noquote('Using design matrix:') | |
596 print.noquote(mydesign) | |
597 if (doedgeR) { | |
598 sink('edgeR.log') | |
599 #### Setup DGEList object | |
600 DGEList = DGEList(counts=workCM, group = group) | |
601 DGEList = calcNormFactors(DGEList) | |
602 | |
603 DGEList = estimateGLMCommonDisp(DGEList,mydesign) | |
604 comdisp = DGEList\$common.dispersion | |
605 DGEList = estimateGLMTrendedDisp(DGEList,mydesign) | |
606 if (edgeR_priordf > 0) { | |
607 print.noquote(paste("prior.df =",edgeR_priordf)) | |
608 DGEList = estimateGLMTagwiseDisp(DGEList,mydesign,prior.df = edgeR_priordf) | |
609 } else { | |
610 DGEList = estimateGLMTagwiseDisp(DGEList,mydesign) | |
611 } | |
612 DGLM = glmFit(DGEList,design=mydesign) | |
613 DE = glmLRT(DGLM,coef=ncol(DGLM\$design)) # always last one - subject is first if needed | |
614 efflib = DGEList\$samples\$lib.size*DGEList\$samples\$norm.factors | |
615 normData = (1e+06*DGEList\$counts/efflib) | |
616 uoutput = cbind( | |
617 Name=as.character(rownames(DGEList\$counts)), | |
618 DE\$table, | |
619 adj.p.value=p.adjust(DE\$table\$PValue, method=fdrtype), | |
620 Dispersion=DGEList\$tagwise.dispersion,totreads=cmrowsums,normData, | |
621 DGEList\$counts | |
622 ) | |
623 soutput = uoutput[order(DE\$table\$PValue),] # sorted into p value order - for quick toptable | |
624 goodness = gof(DGLM, pcutoff=fdrthresh) | |
625 if (sum(goodness\$outlier) > 0) { | |
626 print.noquote('GLM outliers:') | |
627 print(paste(rownames(DGLM)[(goodness\$outlier)],collapse=','),quote=F) | |
628 } else { | |
629 print('No GLM fit outlier genes found\n') | |
630 } | |
631 z = limma::zscoreGamma(goodness\$gof.statistic, shape=goodness\$df/2, scale=2) | |
632 pdf("edgeR_GoodnessofFit.pdf") | |
633 qq = qqnorm(z, panel.first=grid(), main="tagwise dispersion") | |
634 abline(0,1,lwd=3) | |
635 points(qq\$x[goodness\$outlier],qq\$y[goodness\$outlier], pch=16, col="maroon") | |
636 dev.off() | |
637 estpriorn = getPriorN(DGEList) | |
638 print(paste("Common Dispersion =",comdisp,"CV = ",sqrt(comdisp),"getPriorN = ",estpriorn),quote=F) | |
639 efflib = DGEList\$samples\$lib.size*DGEList\$samples\$norm.factors | |
640 normData = (1e+06*DGEList\$counts/efflib) | |
641 uniqueg = unique(group) | |
642 #### Plot MDS | |
643 sample_colors = match(group,levels(group)) | |
644 sampleTypes = levels(factor(group)) | |
645 print.noquote(sampleTypes) | |
646 pdf("edgeR_MDSplot.pdf") | |
647 plotMDS.DGEList(DGEList,main=paste("edgeR MDS for",myTitle),cex=0.5,col=sample_colors,pch=sample_colors) | |
648 legend(x="topleft", legend = sampleTypes,col=c(1:length(sampleTypes)), pch=19) | |
649 grid(col="blue") | |
650 dev.off() | |
651 colnames(normData) = paste( colnames(normData),'N',sep="_") | |
652 print(paste('Raw sample read totals',paste(colSums(nonzerod,na.rm=T),collapse=','))) | |
653 nzd = data.frame(log(nonzerod + 1e-2,10)) | |
654 try( boxPlot(rawrs=nzd,cleanrs=log(normData,10),maint='TMM Normalisation',myTitle=myTitle,pdfname="edgeR_raw_norm_counts_box.pdf") ) | |
655 write.table(soutput,file=out_edgeR, quote=FALSE, sep="\t",row.names=F) | |
656 tt = cbind( | |
657 Name=as.character(rownames(DGEList\$counts)), | |
658 DE\$table, | |
659 adj.p.value=p.adjust(DE\$table\$PValue, method=fdrtype), | |
660 Dispersion=DGEList\$tagwise.dispersion,totreads=cmrowsums | |
661 ) | |
662 print.noquote("# edgeR Top tags\n") | |
663 tt = cbind(tt,URL=contigurls) # add to end so table isn't laid out strangely | |
664 tt = tt[order(DE\$table\$PValue),] | |
665 print.noquote(tt[1:50,]) | |
666 deTags = rownames(uoutput[uoutput\$adj.p.value < fdrthresh,]) | |
667 nsig = length(deTags) | |
668 print(paste('#',nsig,'tags significant at adj p=',fdrthresh),quote=F) | |
669 deColours = ifelse(deTags,'red','black') | |
670 pdf("edgeR_BCV_vs_abundance.pdf") | |
671 plotBCV(DGEList, cex=0.3, main="Biological CV vs abundance") | |
672 dev.off() | |
673 dg = DGEList[order(DE\$table\$PValue),] | |
674 #normData = (1e+06 * dg\$counts/expandAsMatrix(dg\$samples\$lib.size, dim(dg))) | |
675 efflib = dg\$samples\$lib.size*dg\$samples\$norm.factors | |
676 normData = (1e+06*dg\$counts/efflib) | |
677 outpdfname="edgeR_top_100_heatmap.pdf" | |
678 hmap2(normData,nsamp=100,TName=TName,group=group,outpdfname=outpdfname,myTitle=paste('edgeR Heatmap',myTitle)) | |
679 outSmear = "edgeR_smearplot.pdf" | |
680 outMain = paste("Smear Plot for ",TName,' Vs ',CName,' (FDR@',fdrthresh,' N = ',nsig,')',sep='') | |
681 smearPlot(DGEList=DGEList,deTags=deTags, outSmear=outSmear, outMain = outMain) | |
682 qqPlot(descr=paste(myTitle,'edgeR adj p QQ plot'),pvector=tt\$adj.p.value,outpdf='edgeR_qqplot.pdf') | |
683 norm.factor = DGEList\$samples\$norm.factors | |
684 topresults.edgeR = soutput[which(soutput\$adj.p.value < fdrthresh), ] | |
685 edgeRcountsindex = which(allgenes %in% rownames(topresults.edgeR)) | |
686 edgeRcounts = rep(0, length(allgenes)) | |
687 edgeRcounts[edgeRcountsindex] = 1 # Create venn diagram of hits | |
688 sink() | |
689 } ### doedgeR | |
690 if (doDESeq2 == T) | |
691 { | |
692 sink("DESeq2.log") | |
693 # DESeq2 | |
694 require('DESeq2') | |
695 library('RColorBrewer') | |
696 if (length(subjects) == 0) | |
697 { | |
698 pdata = data.frame(Name=colnames(workCM),Rx=group,row.names=colnames(workCM)) | |
699 deSEQds = DESeqDataSetFromMatrix(countData = workCM, colData = pdata, design = formula(~ Rx)) | |
700 } else { | |
701 pdata = data.frame(Name=colnames(workCM),Rx=group,subjects=subjects,row.names=colnames(workCM)) | |
702 deSEQds = DESeqDataSetFromMatrix(countData = workCM, colData = pdata, design = formula(~ subjects + Rx)) | |
703 } | |
704 #DESeq2 = DESeq(deSEQds,fitType='local',pAdjustMethod=fdrtype) | |
705 #rDESeq = results(DESeq2) | |
706 #newCountDataSet(workCM, group) | |
707 deSeqDatsizefac = estimateSizeFactors(deSEQds) | |
708 deSeqDatdisp = estimateDispersions(deSeqDatsizefac,fitType=DESeq_fitType) | |
709 resDESeq = nbinomWaldTest(deSeqDatdisp, pAdjustMethod=fdrtype) | |
710 rDESeq = as.data.frame(results(resDESeq)) | |
711 rDESeq = cbind(Contig=rownames(workCM),rDESeq,NReads=cmrowsums) | |
712 srDESeq = rDESeq[order(rDESeq\$pvalue),] | |
713 write.table(srDESeq,file=out_DESeq2, quote=FALSE, sep="\t",row.names=F) | |
714 qqPlot(descr=paste(myTitle,'DESeq2 adj p qq plot'),pvector=rDESeq\$padj,outpdf='DESeq2_qqplot.pdf') | |
715 cat("# DESeq top 50\n") | |
716 rDESeq = cbind(Contig=rownames(workCM),rDESeq,NReads=cmrowsums,URL=contigurls) | |
717 srDESeq = rDESeq[order(rDESeq\$pvalue),] | |
718 print.noquote(srDESeq[1:50,]) | |
719 topresults.DESeq = rDESeq[which(rDESeq\$padj < fdrthresh), ] | |
720 DESeqcountsindex = which(allgenes %in% rownames(topresults.DESeq)) | |
721 DESeqcounts = rep(0, length(allgenes)) | |
722 DESeqcounts[DESeqcountsindex] = 1 | |
723 pdf("DESeq2_dispersion_estimates.pdf") | |
724 plotDispEsts(resDESeq) | |
725 dev.off() | |
726 ysmall = abs(min(rDESeq\$log2FoldChange)) | |
727 ybig = abs(max(rDESeq\$log2FoldChange)) | |
728 ylimit = min(4,ysmall,ybig) | |
729 pdf("DESeq2_MA_plot.pdf") | |
730 plotMA(resDESeq,main=paste(myTitle,"DESeq2 MA plot"),ylim=c(-ylimit,ylimit)) | |
731 dev.off() | |
732 rlogres = rlogTransformation(resDESeq) | |
733 sampledists = dist( t( assay(rlogres) ) ) | |
734 sdmat = as.matrix(sampledists) | |
735 pdf("DESeq2_sample_distance_plot.pdf") | |
736 heatmap.2(sdmat,trace="none",main=paste(myTitle,"DESeq2 sample distances"), | |
737 col = colorRampPalette( rev(brewer.pal(9, "RdBu")) )(255)) | |
738 dev.off() | |
739 ###outpdfname="DESeq2_top50_heatmap.pdf" | |
740 ###hmap2(sresDESeq,nsamp=50,TName=TName,group=group,outpdfname=outpdfname,myTitle=paste('DESeq2 vst rlog Heatmap',myTitle)) | |
741 sink() | |
742 result = try( (ppca = plotPCA( varianceStabilizingTransformation(deSeqDatdisp,blind=T), intgroup=c("Rx","Name")) ) ) | |
743 if ("try-error" %in% class(result)) { | |
744 print.noquote('DESeq2 plotPCA failed.') | |
745 } else { | |
746 pdf("DESeq2_PCA_plot.pdf") | |
747 #### wtf - print? Seems needed to get this to work | |
748 print(ppca) | |
749 dev.off() | |
750 } | |
751 } | |
752 | |
753 if (doVoom == T) { | |
754 sink('Voom.log') | |
755 if (doedgeR == F) { | |
756 #### Setup DGEList object | |
757 DGEList = DGEList(counts=workCM, group = group) | |
758 DGEList = calcNormFactors(DGEList) | |
759 DGEList = estimateGLMCommonDisp(DGEList,mydesign) | |
760 DGEList = estimateGLMTrendedDisp(DGEList,mydesign) | |
761 DGEList = estimateGLMTagwiseDisp(DGEList,mydesign) | |
762 DGEList = estimateGLMTagwiseDisp(DGEList,mydesign) | |
763 norm.factor = DGEList\$samples\$norm.factors | |
764 } | |
765 pdf("Voom_mean_variance_plot.pdf") | |
766 dat.voomed = voom(DGEList, mydesign, plot = TRUE, lib.size = colSums(workCM) * norm.factor) | |
767 dev.off() | |
768 # Use limma to fit data | |
769 fit = lmFit(dat.voomed, mydesign) | |
770 fit = eBayes(fit) | |
771 rvoom = topTable(fit, coef = length(colnames(mydesign)), adj = fdrtype, n = Inf, sort="none") | |
772 qqPlot(descr=paste(myTitle,'Voom-limma adj p QQ plot'),pvector=rvoom\$adj.P.Val,outpdf='Voom_qqplot.pdf') | |
773 rownames(rvoom) = rownames(workCM) | |
774 rvoom = cbind(rvoom,NReads=cmrowsums) | |
775 srvoom = rvoom[order(rvoom\$P.Value),] | |
776 write.table(srvoom,file=out_VOOM, quote=FALSE, sep="\t",row.names=F) | |
777 rvoom = cbind(rvoom,NReads=cmrowsums,URL=contigurls) | |
778 srvoom = rvoom[order(rvoom\$P.Value),] | |
779 cat("# Voom top 50\n") | |
780 print(srvoom[1:50,]) | |
781 # Use an FDR cutoff to find interesting samples for edgeR, DESeq and voom/limma | |
782 topresults.voom = rvoom[which(rvoom\$adj.P.Val < fdrthresh), ] | |
783 voomcountsindex = which(allgenes %in% topresults.voom\$ID) | |
784 voomcounts = rep(0, length(allgenes)) | |
785 voomcounts[voomcountsindex] = 1 | |
786 sink() | |
787 } | |
788 | |
789 if (doCamera) { | |
790 doGSEA(y=DGEList,design=mydesign,histgmt=histgmt,bigmt=bigmt,ntest=20,myTitle=myTitle, | |
791 outfname=paste(mt,"GSEA.xls",sep="_"),fdrthresh=fdrthresh,fdrtype=fdrtype) | |
792 } | |
793 | |
794 if ((doDESeq2==T) || (doVoom==T) || (doedgeR==T)) { | |
795 if ((doVoom==T) && (doDESeq2==T) && (doedgeR==T)) { | |
796 vennmain = paste(mt,'Voom,edgeR and DESeq2 overlap at FDR=',fdrthresh) | |
797 counts.dataframe = data.frame(edgeR = edgeRcounts, DESeq2 = DESeqcounts, | |
798 VOOM_limma = voomcounts, row.names = allgenes) | |
799 } else if ((doDESeq2==T) && (doedgeR==T)) { | |
800 vennmain = paste(mt,'DESeq2 and edgeR overlap at FDR=',fdrthresh) | |
801 counts.dataframe = data.frame(edgeR = edgeRcounts, DESeq2 = DESeqcounts, row.names = allgenes) | |
802 } else if ((doVoom==T) && (doedgeR==T)) { | |
803 vennmain = paste(mt,'Voom and edgeR overlap at FDR=',fdrthresh) | |
804 counts.dataframe = data.frame(edgeR = edgeRcounts, VOOM_limma = voomcounts, row.names = allgenes) | |
805 } | |
806 | |
807 if (nrow(counts.dataframe > 1)) { | |
808 counts.venn = vennCounts(counts.dataframe) | |
809 vennf = "Venn_significant_genes_overlap.pdf" | |
810 pdf(vennf) | |
811 vennDiagram(counts.venn,main=vennmain,col="maroon") | |
812 dev.off() | |
813 } | |
814 } #### doDESeq2 or doVoom | |
815 | |
816 } | |
817 #### Done | |
818 | |
819 ###sink(stdout(),append=T,type="message") | |
820 builtin_gmt = "" | |
821 history_gmt = "" | |
822 history_gmt_name = "" | |
823 out_edgeR = F | |
824 out_DESeq2 = F | |
825 out_VOOM = "$out_VOOM" | |
826 doDESeq2 = $DESeq2.doDESeq2 # make these T or F | |
827 doVoom = $doVoom | |
828 doCamera = F | |
829 doedgeR = $edgeR.doedgeR | |
830 edgeR_priordf = 0 | |
831 | |
832 | |
833 #if $doVoom == "T": | |
834 out_VOOM = "$out_VOOM" | |
835 #end if | |
836 | |
837 #if $DESeq2.doDESeq2 == "T": | |
838 out_DESeq2 = "$out_DESeq2" | |
839 DESeq_fitType = "$DESeq2.DESeq_fitType" | |
840 #end if | |
841 | |
842 #if $edgeR.doedgeR == "T": | |
843 out_edgeR = "$out_edgeR" | |
844 edgeR_priordf = $edgeR.edgeR_priordf | |
845 #end if | |
846 | |
847 | |
848 if (sum(c(doedgeR,doVoom,doDESeq2)) == 0) | |
849 { | |
850 write("No methods chosen - nothing to do! Please try again after choosing one or more methods", stderr()) | |
851 quit(save="no",status=2) | |
852 } | |
853 | |
854 Out_Dir = "$html_file.files_path" | |
855 Input = "$input1" | |
856 TreatmentName = "$treatment_name" | |
857 TreatmentCols = "$Treat_cols" | |
858 ControlName = "$control_name" | |
859 ControlCols= "$Control_cols" | |
860 org = "$input1.dbkey" | |
861 if (org == "") { org = "hg19"} | |
862 fdrtype = "$fdrtype" | |
863 fdrthresh = $fdrthresh | |
864 useNDF = $useNDF | |
865 fQ = $fQ # non-differential centile cutoff | |
866 myTitle = "$title" | |
867 sids = strsplit("$subjectids",',') | |
868 subjects = unlist(sids) | |
869 nsubj = length(subjects) | |
870 TCols = as.numeric(strsplit(TreatmentCols,",")[[1]])-1 | |
871 CCols = as.numeric(strsplit(ControlCols,",")[[1]])-1 | |
872 cat('Got TCols=') | |
873 cat(TCols) | |
874 cat('; CCols=') | |
875 cat(CCols) | |
876 cat('\n') | |
877 useCols = c(TCols,CCols) | |
878 if (file.exists(Out_Dir) == F) dir.create(Out_Dir) | |
879 Count_Matrix = read.table(Input,header=T,row.names=1,sep='\t') #Load tab file assume header | |
880 snames = colnames(Count_Matrix) | |
881 nsamples = length(snames) | |
882 if (nsubj > 0 & nsubj != nsamples) { | |
883 options("show.error.messages"=T) | |
884 mess = paste('Fatal error: Supplied subject id list',paste(subjects,collapse=','), | |
885 'has length',nsubj,'but there are',nsamples,'samples',paste(snames,collapse=',')) | |
886 write(mess, stderr()) | |
887 quit(save="no",status=4) | |
888 } | |
889 if (length(subjects) != 0) {subjects = subjects[useCols]} | |
890 Count_Matrix = Count_Matrix[,useCols] ### reorder columns | |
891 rn = rownames(Count_Matrix) | |
892 islib = rn %in% c('librarySize','NotInBedRegions') | |
893 LibSizes = Count_Matrix[subset(rn,islib),][1] # take first | |
894 Count_Matrix = Count_Matrix[subset(rn,! islib),] | |
895 group = c(rep(TreatmentName,length(TCols)), rep(ControlName,length(CCols)) ) #Build a group descriptor | |
896 group = factor(group, levels=c(ControlName,TreatmentName)) | |
897 colnames(Count_Matrix) = paste(group,colnames(Count_Matrix),sep="_") #Relable columns | |
898 results = edgeIt(Count_Matrix=Count_Matrix,group=group, out_edgeR=out_edgeR, out_VOOM=out_VOOM, out_DESeq2=out_DESeq2, | |
899 fdrtype='BH',mydesign=NULL,priordf=edgeR_priordf,fdrthresh=fdrthresh,outputdir='.', | |
900 myTitle=myTitle,useNDF=F,libSize=c(),filterquantile=fQ,subjects=subjects, | |
901 doDESeq2=doDESeq2,doVoom=doVoom,doCamera=doCamera,doedgeR=doedgeR,org=org, | |
902 histgmt=history_gmt,bigmt=builtin_gmt,DESeq_fitType=DESeq_fitType) | |
903 sessionInfo() | |
904 ]]> | |
905 </configfile> | |
906 </configfiles> | |
907 <help> | |
908 | |
909 **What it does** | |
910 | |
911 Allows short read sequence counts from controlled experiments to be analysed for differentially expressed genes. | |
912 Optionally adds a term for subject if not all samples are independent or if some other factor needs to be blocked in the design. | |
913 | |
914 **Input** | |
915 | |
916 Requires a count matrix as a tabular file. These are best made using the companion HTSeq_ based counter Galaxy wrapper | |
917 and your fave gene model to generate inputs. Each row is a genomic feature (gene or exon eg) and each column the | |
918 non-negative integer count of reads from one sample overlapping the feature. | |
919 The matrix must have a header row uniquely identifying the source samples, and unique row names in | |
920 the first column. Typically the row names are gene symbols or probe ids for downstream use in GSEA and other methods. | |
921 | |
922 **Specifying comparisons** | |
923 | |
924 This is basically dumbed down for two factors - case vs control. | |
925 | |
926 More complex interfaces are possible but painful at present. | |
927 Probably need to specify a phenotype file to do this better. | |
928 Work in progress. Send code. | |
929 | |
930 If you have (eg) paired samples and wish to include a term in the GLM to account for some other factor (subject in the case of paired samples), | |
931 put a comma separated list of indicators for every sample (whether modelled or not!) indicating (eg) the subject number or | |
932 A list of integers, one for each subject or an empty string if samples are all independent. | |
933 If not empty, there must be exactly as many integers in the supplied integer list as there are columns (samples) in the count matrix. | |
934 Integers for samples that are not in the analysis *must* be present in the string as filler even if not used. | |
935 | |
936 So if you have 2 pairs out of 6 samples, you need to put in unique integers for the unpaired ones | |
937 eg if you had 6 samples with the first two independent but the second and third pairs each being from independent subjects. you might use | |
938 8,9,1,1,2,2 | |
939 as subject IDs to indicate two paired samples from the same subject in columns 3/4 and 5/6 | |
940 | |
941 **Methods available** | |
942 | |
943 You can run 3 popular Bioconductor packages available for count data. | |
944 | |
945 edgeR - see edgeR_ for details | |
946 | |
947 VOOM/limma - see limma_VOOM_ for details | |
948 | |
949 DESeq2 - see DESeq2_ for details | |
950 | |
951 and optionally camera in edgeR which works better if MSigDB is installed. | |
952 | |
953 **Outputs** | |
954 | |
955 Some helpful plots and analysis results. Note that most of these are produced using R code | |
956 suggested by the excellent documentation and vignettes for the Bioconductor | |
957 packages invoked. The Tool Factory is used to automatically lay these out for you to enjoy. | |
958 | |
959 **Note on Voom** | |
960 | |
961 The voom from limma version 3.16.6 help in R includes this from the authors - but you should read the paper to interpret this method. | |
962 | |
963 This function is intended to process RNA-Seq or ChIP-Seq data prior to linear modelling in limma. | |
964 | |
965 voom is an acronym for mean-variance modelling at the observational level. | |
966 The key concern is to estimate the mean-variance relationship in the data, then use this to compute appropriate weights for each observation. | |
967 Count data almost show non-trivial mean-variance relationships. Raw counts show increasing variance with increasing count size, while log-counts typically show a decreasing mean-variance trend. | |
968 This function estimates the mean-variance trend for log-counts, then assigns a weight to each observation based on its predicted variance. | |
969 The weights are then used in the linear modelling process to adjust for heteroscedasticity. | |
970 | |
971 In an experiment, a count value is observed for each tag in each sample. A tag-wise mean-variance trend is computed using lowess. | |
972 The tag-wise mean is the mean log2 count with an offset of 0.5, across samples for a given tag. | |
973 The tag-wise variance is the quarter-root-variance of normalized log2 counts per million values with an offset of 0.5, across samples for a given tag. | |
974 Tags with zero counts across all samples are not included in the lowess fit. Optional normalization is performed using normalizeBetweenArrays. | |
975 Using fitted values of log2 counts from a linear model fit by lmFit, variances from the mean-variance trend were interpolated for each observation. | |
976 This was carried out by approxfun. Inverse variance weights can be used to correct for mean-variance trend in the count data. | |
977 | |
978 | |
979 Author(s) | |
980 | |
981 Charity Law and Gordon Smyth | |
982 | |
983 References | |
984 | |
985 Law, CW (2013). Precision weights for gene expression analysis. PhD Thesis. University of Melbourne, Australia. | |
986 | |
987 Law, CW, Chen, Y, Shi, W, Smyth, GK (2013). Voom! Precision weights unlock linear model analysis tools for RNA-seq read counts. | |
988 Technical Report 1 May 2013, Bioinformatics Division, Walter and Eliza Hall Institute of Medical Reseach, Melbourne, Australia. | |
989 http://www.statsci.org/smyth/pubs/VoomPreprint.pdf | |
990 | |
991 See Also | |
992 | |
993 A voom case study is given in the edgeR User's Guide. | |
994 | |
995 vooma is a similar function but for microarrays instead of RNA-seq. | |
996 | |
997 | |
998 ***old rant on changes to Bioconductor package variable names between versions*** | |
999 | |
1000 The edgeR authors made a small cosmetic change in the name of one important variable (from p.value to PValue) | |
1001 breaking this and all other code that assumed the old name for this variable, | |
1002 between edgeR2.4.4 and 2.4.6 (the version for R 2.14 as at the time of writing). | |
1003 This means that all code using edgeR is sensitive to the version. I think this was a very unwise thing | |
1004 to do because it wasted hours of my time to track down and will similarly cost other edgeR users dearly | |
1005 when their old scripts break. This tool currently now works with 2.4.6. | |
1006 | |
1007 **Note on prior.N** | |
1008 | |
1009 http://seqanswers.com/forums/showthread.php?t=5591 says: | |
1010 | |
1011 *prior.n* | |
1012 | |
1013 The value for prior.n determines the amount of smoothing of tagwise dispersions towards the common dispersion. | |
1014 You can think of it as like a "weight" for the common value. (It is actually the weight for the common likelihood | |
1015 in the weighted likelihood equation). The larger the value for prior.n, the more smoothing, i.e. the closer your | |
1016 tagwise dispersion estimates will be to the common dispersion. If you use a prior.n of 1, then that gives the | |
1017 common likelihood the weight of one observation. | |
1018 | |
1019 In answer to your question, it is a good thing to squeeze the tagwise dispersions towards a common value, | |
1020 or else you will be using very unreliable estimates of the dispersion. I would not recommend using the value that | |
1021 you obtained from estimateSmoothing()---this is far too small and would result in virtually no moderation | |
1022 (squeezing) of the tagwise dispersions. How many samples do you have in your experiment? | |
1023 What is the experimental design? If you have few samples (less than 6) then I would suggest a prior.n of at least 10. | |
1024 If you have more samples, then the tagwise dispersion estimates will be more reliable, | |
1025 so you could consider using a smaller prior.n, although I would hesitate to use a prior.n less than 5. | |
1026 | |
1027 | |
1028 From Bioconductor Digest, Vol 118, Issue 5, Gordon writes: | |
1029 | |
1030 Dear Dorota, | |
1031 | |
1032 The important settings are prior.df and trend. | |
1033 | |
1034 prior.n and prior.df are related through prior.df = prior.n * residual.df, | |
1035 and your experiment has residual.df = 36 - 12 = 24. So the old setting of | |
1036 prior.n=10 is equivalent for your data to prior.df = 240, a very large | |
1037 value. Going the other way, the new setting of prior.df=10 is equivalent | |
1038 to prior.n=10/24. | |
1039 | |
1040 To recover old results with the current software you would use | |
1041 | |
1042 estimateTagwiseDisp(object, prior.df=240, trend="none") | |
1043 | |
1044 To get the new default from old software you would use | |
1045 | |
1046 estimateTagwiseDisp(object, prior.n=10/24, trend=TRUE) | |
1047 | |
1048 Actually the old trend method is equivalent to trend="loess" in the new | |
1049 software. You should use plotBCV(object) to see whether a trend is | |
1050 required. | |
1051 | |
1052 Note you could also use | |
1053 | |
1054 prior.n = getPriorN(object, prior.df=10) | |
1055 | |
1056 to map between prior.df and prior.n. | |
1057 | |
1058 ---- | |
1059 | |
1060 **Attributions** | |
1061 | |
1062 edgeR - edgeR_ | |
1063 | |
1064 VOOM/limma - limma_VOOM_ | |
1065 | |
1066 DESeq2 - DESeq2_ for details | |
1067 | |
1068 See above for Bioconductor package documentation for packages exposed in Galaxy by this tool and app store package. | |
1069 | |
1070 Galaxy_ (that's what you are using right now!) for gluing everything together | |
1071 | |
1072 Otherwise, all code and documentation comprising this tool was written by Ross Lazarus and is | |
1073 licensed to you under the LGPL_ like other rgenetics artefacts | |
1074 | |
1075 .. _LGPL: http://www.gnu.org/copyleft/lesser.html | |
1076 .. _HTSeq: http://www-huber.embl.de/users/anders/HTSeq/doc/index.html | |
1077 .. _edgeR: http://www.bioconductor.org/packages/release/bioc/html/edgeR.html | |
1078 .. _DESeq2: http://www.bioconductor.org/packages/release/bioc/html/DESeq2.html | |
1079 .. _limma_VOOM: http://www.bioconductor.org/packages/release/bioc/html/limma.html | |
1080 .. _Galaxy: http://getgalaxy.org | |
1081 </help> | |
1082 | |
1083 </tool> | |
1084 | |
1085 |