Mercurial > repos > iuc > ruvseq
view ruvseq.R @ 0:61dffb20b6f9 draft
planemo upload for repository https://github.com/galaxyproject/tools-iuc/tree/master/tools/ruvseq commit b95582cea8320d5488056a9576474f79cec53be8
author | iuc |
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date | Wed, 05 Sep 2018 15:54:16 -0400 |
parents | |
children | c24765926774 |
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# setup R error handling to go to stderr library("getopt") options( show.error.messages=F, error = function () { cat( geterrmessage(), file=stderr() ); q( "no", 1, F ) } ) options(stringAsFactors = FALSE, useFancyQuotes = FALSE) setup_cmdline_options <- function() { args <- commandArgs(trailingOnly = TRUE) spec <- matrix(c( "help", "h", 0, "logical", "alpha", "a", 1, "double", "min_mean_count", "min_c", 1, "double", "min_k", "min_k", 1, "double", "max_k", "max_k", 1, "double", "sample_json", "s", 1, "character", "plots" , "p", 1, "character", "header", "H", 0, "logical", "txtype", "y", 1, "character", "tx2gene", "x", 1, "character"), # a space-sep tx-to-gene map or GTF file (auto detect .gtf/.GTF) byrow=TRUE, ncol=4) opt <- getopt(spec) # if help was asked for print a friendly message # and exit with a non-zero error code if (!is.null(opt$help)) { cat(getopt(spec, usage=TRUE)) q(status=1) } else { load_libraries() } return(opt) } load_libraries <- function() { # Allows displaying help without waiting for libraries to load library("tools") library("jsonlite") library("reshape2") library("RUVSeq") library("RColorBrewer") library("tximport") library("DESeq2") library("ggrepel") } source_local <- function(fname){ argv <- commandArgs(trailingOnly = FALSE) base_dir <- dirname(substring(argv[grep("--file=", argv)], 8)) source(paste(base_dir, fname, sep="/")) } # Source get_deseq_dataset.R for getting deseq dataset from htseq/featurecounts/tximport source_local('get_deseq_dataset.R') # RUVseq function definitions plot_pca_rle <- function (set, title) { x <- pData(set)[,1] colors <- brewer.pal(3, "Set2") label <- paste0(' for ', title) plotRLE(set, outline=FALSE, ylim=c(-4, 4), col=colors[x]) title(main=paste0("RLE", label)) plotPCA(set, col=colors[x], cex=1.2) title(main=paste0("PCA", label)) } plot_factors_of_unwanted_variation <- function(set, method, k){ pd <- pData(set) pd['sample'] <- row.names(pd) colnames(pd)[1] <- 'condition' d = melt(pd, id.vars = c('sample', 'condition')) d['x'] <- 1 # There is no information on the X, so we just fake it to be able to do a scatterplot print(ggplot(d, aes(x=x, y=value, color=condition, label=sample)) + geom_point() + ggtitle(paste0('Factors of unwanted variation for method: ', method, ", k=", k)) + facet_wrap( ~ variable, scales = "free_x") + geom_text_repel() + theme(axis.title.x=element_blank(), axis.text.x=element_blank(), axis.ticks.x=element_blank(), plot.title = element_text(hjust = 0.5)) ) } create_seq_expression_set <- function (dds, min_mean_count) { count_values <- counts(dds) filter <- apply(count_values, 1, function(x) mean(x) > min_mean_count) filtered <- count_values[filter,] set = newSeqExpressionSet(as.matrix(count_values), phenoData = data.frame(colData(dds)$condition, row.names=colnames(filtered))) plot_pca_rle(set = set, title = 'raw data') set <- betweenLaneNormalization(set, which="upper") plot_pca_rle(set = set, title = 'upper quartile normalized') return(set) } get_empirical_control_genes <- function(set, cutoff_p) { x <- pData(set)[,1] design <- model.matrix(~x, data=pData(set)) y <- DGEList(counts=counts(set), group=x) y <- calcNormFactors(y, method="upperquartile") y <- estimateGLMCommonDisp(y, design) y <- estimateGLMTagwiseDisp(y, design) fit <- glmFit(y, design) lrt <- glmLRT(fit, coef=2) top <- topTags(lrt, n=nrow(set))$table top_rows <- rownames(top)[which(top$PValue > cutoff_p)] empirical <- rownames(set)[which(!(rownames(set) %in% top_rows))] return(empirical) } ruv_control_gene_method <- function(set, k, control_genes='empirical', cutoff_p=0.2) { if (control_genes == 'empirical') { control_genes = get_empirical_control_genes(set, cutoff_p=cutoff_p) } set <- RUVg(set, control_genes, k=k) plot_pca_rle(set, paste0("RUVg with empirical control genes, k=", k)) plot_factors_of_unwanted_variation(set, method="RUVg with empirical control genes", k=k) return(set) } ruv_residual_method <- function(set, k) { genes <- rownames(counts(set)) x <- pData(set)[,1] # Initial edger residuals design <- model.matrix(~x, data=pData(set)) y <- DGEList(counts=counts(set), group=x) y <- calcNormFactors(y, method="upperquartile") y <- estimateGLMCommonDisp(y, design) y <- estimateGLMTagwiseDisp(y, design) fit <- glmFit(y, design) res <- residuals(fit, type="deviance") set <- RUVr(set, genes, k=k, res) plot_pca_rle(set = set, title = paste0('RUVr using residuals, k=', k)) plot_factors_of_unwanted_variation(set, method="RUVr using residuals", k=k) return(set) } ruv_replicate_method <- function (set, k) { genes <- rownames(counts(set)) x <- pData(set)[,1] differences <- makeGroups(x) set <- RUVs(set, genes, k=k, differences) plot_pca_rle(set, paste0('RUVs with replicate samples, k=', k)) plot_factors_of_unwanted_variation(set, method="RUVs using replicates", k=k) return(set) } get_differentially_expressed_genes <- function(dds, contrast, alpha=0.01) { r <- results(dds, contrast=contrast, alpha=alpha) return(rownames(r[which(r$padj < alpha),])) } opt <- setup_cmdline_options() alpha <- opt$alpha min_k <- opt$min_k max_k <- opt$max_k sample_json <- fromJSON(opt$sample_json) sample_paths <- sample_json$path sample_names <- sample_json$label condition <- as.factor(sample_json$condition) sampleTable <- data.frame(samplename=sample_names, filename = sample_paths, condition=condition) rownames(sampleTable) <- sample_names dds <- get_deseq_dataset(sampleTable, header=opt$header, designFormula= ~ condition, tximport=opt$txtype, txtype=opt$txtype, tx2gene=opt$tx2gene) if (!is.null(opt$plots)) { pdf(opt$plots) } # Run through the ruvseq variants set <- create_seq_expression_set(dds, min_mean_count = opt$min_mean_count) result <- list(no_correction = set) for (k in seq(min_k, max_k)) { result[[paste0('residual_method_k', k)]] <- ruv_residual_method(set, k=k) result[[paste0('replicate_method_k', k)]] <- ruv_replicate_method(set, k=k) result[[paste0('control_method_k', k)]] <- ruv_control_gene_method(set, k=k, cutoff_p=0.5) } for (name in names(result)) { if (!startsWith(name, "no_correction")) { set <- result[[name]] unwanted_variation <- pData(set) df <- data.frame(identifier = rownames(unwanted_variation)) df <- cbind(df, unwanted_variation) colnames(df)[2] <- 'condition' write.table(df, file=paste0("batch_effects_", name, ".tabular"), sep="\t", quote=F, row.names=F) } } # close the plot device if (!is.null(opt$plots)) { cat("closing plot device\n") dev.off() } cat("Session information:\n\n") sessionInfo()