ferstar/deseq2-analysis-template.R

## deseq2-analysis-template.R
## RNA-seq analysis with DESeq2
## Stephen Turner, @genetics_blog

# RNA-seq data from GSE52202
# http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=gse52202. All patients with
# ALS, 4 with C9 expansion ("exp"), 4 controls without expansion ("ctl")

# Import & pre-process ----------------------------------------------------

# Import data from featureCounts
## Previously ran at command line something like this:
## featureCounts -a genes.gtf -o counts.txt -T 12 -t exon -g gene_id GSM*.sam
countdata <- read.table("counts.txt", header=TRUE, row.names=1)

# Remove first five columns (chr, start, end, strand, length)
countdata <- countdata[ ,6:ncol(countdata)]

# Remove .bam or .sam from filenames
colnames(countdata) <- gsub("\\.[sb]am$", "", colnames(countdata))

# Convert to matrix
countdata <- as.matrix(countdata)
head(countdata)

# Assign condition (first four are controls, second four contain the expansion)
(condition <- factor(c(rep("ctl", 4), rep("exp", 4))))

# Analysis with DESeq2 ----------------------------------------------------

library(DESeq2)

# Create a coldata frame and instantiate the DESeqDataSet. See ?DESeqDataSetFromMatrix
(coldata <- data.frame(row.names=colnames(countdata), condition))
dds <- DESeqDataSetFromMatrix(countData=countdata, colData=coldata, design=~condition)
dds

# Run the DESeq pipeline
dds <- DESeq(dds)

# Plot dispersions
png("qc-dispersions.png", 1000, 1000, pointsize=20)
plotDispEsts(dds, main="Dispersion plot")
dev.off()

# Regularized log transformation for clustering/heatmaps, etc
rld <- rlogTransformation(dds)
head(assay(rld))
hist(assay(rld))

# Colors for plots below
## Ugly:
## (mycols <- 1:length(unique(condition)))
## Use RColorBrewer, better
library(RColorBrewer)
(mycols <- brewer.pal(8, "Dark2")[1:length(unique(condition))])

# Sample distance heatmap
sampleDists <- as.matrix(dist(t(assay(rld))))
library(gplots)
png("qc-heatmap-samples.png", w=1000, h=1000, pointsize=20)
heatmap.2(as.matrix(sampleDists), key=F, trace="none",
          col=colorpanel(100, "black", "white"),
          ColSideColors=mycols[condition], RowSideColors=mycols[condition],
          margin=c(10, 10), main="Sample Distance Matrix")
dev.off()

# Principal components analysis
## Could do with built-in DESeq2 function:
## DESeq2::plotPCA(rld, intgroup="condition")
## I like mine better:
rld_pca <- function (rld, intgroup = "condition", ntop = 500, colors=NULL, legendpos="bottomleft", main="PCA Biplot", textcx=1, ...) {
  require(genefilter)
  require(calibrate)
  require(RColorBrewer)
  rv = rowVars(assay(rld))
  select = order(rv, decreasing = TRUE)[seq_len(min(ntop, length(rv)))]
  pca = prcomp(t(assay(rld)[select, ]))
  fac = factor(apply(as.data.frame(colData(rld)[, intgroup, drop = FALSE]), 1, paste, collapse = " : "))
  if (is.null(colors)) {
    if (nlevels(fac) >= 3) {
      colors = brewer.pal(nlevels(fac), "Paired")
    }   else {
      colors = c("black", "red")
    }
  }
  pc1var <- round(summary(pca)$importance[2,1]*100, digits=1)
  pc2var <- round(summary(pca)$importance[2,2]*100, digits=1)
  pc1lab <- paste0("PC1 (",as.character(pc1var),"%)")
  pc2lab <- paste0("PC1 (",as.character(pc2var),"%)")
  plot(PC2~PC1, data=as.data.frame(pca$x), bg=colors[fac], pch=21, xlab=pc1lab, ylab=pc2lab, main=main, ...)
  with(as.data.frame(pca$x), textxy(PC1, PC2, labs=rownames(as.data.frame(pca$x)), cex=textcx))
  legend(legendpos, legend=levels(fac), col=colors, pch=20)
  #     rldyplot(PC2 ~ PC1, groups = fac, data = as.data.frame(pca$rld),
  #            pch = 16, cerld = 2, aspect = "iso", col = colours, main = draw.key(key = list(rect = list(col = colours),
  #                                                                                         terldt = list(levels(fac)), rep = FALSE)))
}
png("qc-pca.png", 1000, 1000, pointsize=20)
rld_pca(rld, colors=mycols, intgroup="condition", xlim=c(-75, 35))
dev.off()


# Get differential expression results
res <- results(dds)
table(res$padj<0.05)
## Order by adjusted p-value
res <- res[order(res$padj), ]
## Merge with normalized count data
resdata <- merge(as.data.frame(res), as.data.frame(counts(dds, normalized=TRUE)), by="row.names", sort=FALSE)
names(resdata)[1] <- "Gene"
head(resdata)
## Write results
write.csv(resdata, file="diffexpr-results.csv")

## Examine plot of p-values
hist(res$pvalue, breaks=50, col="grey")

## Examine independent filtering
attr(res, "filterThreshold")
plot(attr(res,"filterNumRej"), type="b", xlab="quantiles of baseMean", ylab="number of rejections")

## MA plot
## Could do with built-in DESeq2 function:
## DESeq2::plotMA(dds, ylim=c(-1,1), cex=1)
## I like mine better:
maplot <- function (res, thresh=0.05, labelsig=TRUE, textcx=1, ...) {
  with(res, plot(baseMean, log2FoldChange, pch=20, cex=.5, log="x", ...))
  with(subset(res, padj<thresh), points(baseMean, log2FoldChange, col="red", pch=20, cex=1.5))
  if (labelsig) {
    require(calibrate)
    with(subset(res, padj<thresh), textxy(baseMean, log2FoldChange, labs=Gene, cex=textcx, col=2))
  }
}
png("diffexpr-maplot.png", 1500, 1000, pointsize=20)
maplot(resdata, main="MA Plot")
dev.off()

## Volcano plot with "significant" genes labeled
volcanoplot <- function (res, lfcthresh=2, sigthresh=0.05, main="Volcano Plot", legendpos="bottomright", labelsig=TRUE, textcx=1, ...) {
  with(res, plot(log2FoldChange, -log10(pvalue), pch=20, main=main, ...))
  with(subset(res, padj<sigthresh ), points(log2FoldChange, -log10(pvalue), pch=20, col="red", ...))
  with(subset(res, abs(log2FoldChange)>lfcthresh), points(log2FoldChange, -log10(pvalue), pch=20, col="orange", ...))
  with(subset(res, padj<sigthresh & abs(log2FoldChange)>lfcthresh), points(log2FoldChange, -log10(pvalue), pch=20, col="green", ...))
  if (labelsig) {
    require(calibrate)
    with(subset(res, padj<sigthresh & abs(log2FoldChange)>lfcthresh), textxy(log2FoldChange, -log10(pvalue), labs=Gene, cex=textcx, ...))
  }
  legend(legendpos, xjust=1, yjust=1, legend=c(paste("FDR<",sigthresh,sep=""), paste("|LogFC|>",lfcthresh,sep=""), "both"), pch=20, col=c("red","orange","green"))
}
png("diffexpr-volcanoplot.png", 1200, 1000, pointsize=20)
volcanoplot(resdata, lfcthresh=1, sigthresh=0.05, textcx=.8, xlim=c(-2.3, 2))
dev.off()
	## RNA-seq analysis with DESeq2
	## Stephen Turner, @genetics_blog

	# RNA-seq data from GSE52202
	# http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=gse52202. All patients with
	# ALS, 4 with C9 expansion ("exp"), 4 controls without expansion ("ctl")

	# Import & pre-process ----------------------------------------------------

	# Import data from featureCounts
	## Previously ran at command line something like this:
	## featureCounts -a genes.gtf -o counts.txt -T 12 -t exon -g gene_id GSM*.sam
	countdata <- read.table("counts.txt", header=TRUE, row.names=1)

	# Remove first five columns (chr, start, end, strand, length)
	countdata <- countdata[ ,6:ncol(countdata)]

	# Remove .bam or .sam from filenames
	colnames(countdata) <- gsub("\\.[sb]am$", "", colnames(countdata))

	# Convert to matrix
	countdata <- as.matrix(countdata)
	head(countdata)

	# Assign condition (first four are controls, second four contain the expansion)
	(condition <- factor(c(rep("ctl", 4), rep("exp", 4))))

	# Analysis with DESeq2 ----------------------------------------------------

	library(DESeq2)

	# Create a coldata frame and instantiate the DESeqDataSet. See ?DESeqDataSetFromMatrix
	(coldata <- data.frame(row.names=colnames(countdata), condition))
	dds <- DESeqDataSetFromMatrix(countData=countdata, colData=coldata, design=~condition)
	dds

	# Run the DESeq pipeline
	dds <- DESeq(dds)

	# Plot dispersions
	png("qc-dispersions.png", 1000, 1000, pointsize=20)
	plotDispEsts(dds, main="Dispersion plot")
	dev.off()

	# Regularized log transformation for clustering/heatmaps, etc
	rld <- rlogTransformation(dds)
	head(assay(rld))
	hist(assay(rld))

	# Colors for plots below
	## Ugly:
	## (mycols <- 1:length(unique(condition)))
	## Use RColorBrewer, better
	library(RColorBrewer)
	(mycols <- brewer.pal(8, "Dark2")[1:length(unique(condition))])

	# Sample distance heatmap
	sampleDists <- as.matrix(dist(t(assay(rld))))
	library(gplots)
	png("qc-heatmap-samples.png", w=1000, h=1000, pointsize=20)
	heatmap.2(as.matrix(sampleDists), key=F, trace="none",
	col=colorpanel(100, "black", "white"),
	ColSideColors=mycols[condition], RowSideColors=mycols[condition],
	margin=c(10, 10), main="Sample Distance Matrix")
	dev.off()

	# Principal components analysis
	## Could do with built-in DESeq2 function:
	## DESeq2::plotPCA(rld, intgroup="condition")
	## I like mine better:
	rld_pca <- function (rld, intgroup = "condition", ntop = 500, colors=NULL, legendpos="bottomleft", main="PCA Biplot", textcx=1, ...) {
	require(genefilter)
	require(calibrate)
	require(RColorBrewer)
	rv = rowVars(assay(rld))
	select = order(rv, decreasing = TRUE)[seq_len(min(ntop, length(rv)))]
	pca = prcomp(t(assay(rld)[select, ]))
	fac = factor(apply(as.data.frame(colData(rld)[, intgroup, drop = FALSE]), 1, paste, collapse = " : "))
	if (is.null(colors)) {
	if (nlevels(fac) >= 3) {
	colors = brewer.pal(nlevels(fac), "Paired")
	} else {
	colors = c("black", "red")
	}
	}
	pc1var <- round(summary(pca)$importance[2,1]*100, digits=1)
	pc2var <- round(summary(pca)$importance[2,2]*100, digits=1)
	pc1lab <- paste0("PC1 (",as.character(pc1var),"%)")
	pc2lab <- paste0("PC1 (",as.character(pc2var),"%)")
	plot(PC2~PC1, data=as.data.frame(pca$x), bg=colors[fac], pch=21, xlab=pc1lab, ylab=pc2lab, main=main, ...)
	with(as.data.frame(pca$x), textxy(PC1, PC2, labs=rownames(as.data.frame(pca$x)), cex=textcx))
	legend(legendpos, legend=levels(fac), col=colors, pch=20)
	# rldyplot(PC2 ~ PC1, groups = fac, data = as.data.frame(pca$rld),
	# pch = 16, cerld = 2, aspect = "iso", col = colours, main = draw.key(key = list(rect = list(col = colours),
	# terldt = list(levels(fac)), rep = FALSE)))
	}
	png("qc-pca.png", 1000, 1000, pointsize=20)
	rld_pca(rld, colors=mycols, intgroup="condition", xlim=c(-75, 35))
	dev.off()


	# Get differential expression results
	res <- results(dds)
	table(res$padj<0.05)
	## Order by adjusted p-value
	res <- res[order(res$padj), ]
	## Merge with normalized count data
	resdata <- merge(as.data.frame(res), as.data.frame(counts(dds, normalized=TRUE)), by="row.names", sort=FALSE)
	names(resdata)[1] <- "Gene"
	head(resdata)
	## Write results
	write.csv(resdata, file="diffexpr-results.csv")

	## Examine plot of p-values
	hist(res$pvalue, breaks=50, col="grey")

	## Examine independent filtering
	attr(res, "filterThreshold")
	plot(attr(res,"filterNumRej"), type="b", xlab="quantiles of baseMean", ylab="number of rejections")

	## MA plot
	## Could do with built-in DESeq2 function:
	## DESeq2::plotMA(dds, ylim=c(-1,1), cex=1)
	## I like mine better:
	maplot <- function (res, thresh=0.05, labelsig=TRUE, textcx=1, ...) {
	with(res, plot(baseMean, log2FoldChange, pch=20, cex=.5, log="x", ...))
	with(subset(res, padj<thresh), points(baseMean, log2FoldChange, col="red", pch=20, cex=1.5))
	if (labelsig) {
	require(calibrate)
	with(subset(res, padj<thresh), textxy(baseMean, log2FoldChange, labs=Gene, cex=textcx, col=2))
	}
	}
	png("diffexpr-maplot.png", 1500, 1000, pointsize=20)
	maplot(resdata, main="MA Plot")
	dev.off()

	## Volcano plot with "significant" genes labeled
	volcanoplot <- function (res, lfcthresh=2, sigthresh=0.05, main="Volcano Plot", legendpos="bottomright", labelsig=TRUE, textcx=1, ...) {
	with(res, plot(log2FoldChange, -log10(pvalue), pch=20, main=main, ...))
	with(subset(res, padj<sigthresh ), points(log2FoldChange, -log10(pvalue), pch=20, col="red", ...))
	with(subset(res, abs(log2FoldChange)>lfcthresh), points(log2FoldChange, -log10(pvalue), pch=20, col="orange", ...))
	with(subset(res, padj<sigthresh & abs(log2FoldChange)>lfcthresh), points(log2FoldChange, -log10(pvalue), pch=20, col="green", ...))
	if (labelsig) {
	require(calibrate)
	with(subset(res, padj<sigthresh & abs(log2FoldChange)>lfcthresh), textxy(log2FoldChange, -log10(pvalue), labs=Gene, cex=textcx, ...))
	}
	legend(legendpos, xjust=1, yjust=1, legend=c(paste("FDR<",sigthresh,sep=""), paste("\|LogFC\|>",lfcthresh,sep=""), "both"), pch=20, col=c("red","orange","green"))
	}
	png("diffexpr-volcanoplot.png", 1200, 1000, pointsize=20)
	volcanoplot(resdata, lfcthresh=1, sigthresh=0.05, textcx=.8, xlim=c(-2.3, 2))
	dev.off()