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planemo upload for repository https://github.com/ARTbio/tools-artbio/tree/main/tools/pathifier commit f7363f7c391bd501fc4d1c10aaf372ec2bd82732
| author | artbio |
|---|---|
| date | Mon, 12 Feb 2024 23:57:01 +0000 |
| parents | fec313f5c889 |
| children |
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################################################################################################## # Running PATHIFIER (Drier et al., 2013) # Based on the work of Author: Miguel Angel Garcia-Campos - Github: https://github.com/AngelCampos ################################################################################################## options(show.error.messages = FALSE, error = function() { cat(geterrmessage(), file = stderr()) q("no", 1, FALSE) }) # we need that to not crash galaxy with an UTF8 error on German LC settings. loc <- Sys.setlocale("LC_MESSAGES", "en_US.UTF-8") library(pathifier) library(optparse) library(pheatmap) library(scatterplot3d) library(circlize) option_list <- list( make_option( "--exp", type = "character", help = "Expression matrix" ), make_option( "--sep", type = "character", default = "\t", help = "File separator [default : '%default']" ), make_option( "--genes", type = "character", help = "Gene sets Pathways : gmt format (one pathway per line : Name, description, genes (one by column), tab separated)" ), make_option( "--is_normal", default = FALSE, type = "logical", help = "Define normals cells in your data" ), make_option( "--normals", type = "character", help = "A vector of sample status : 1 = Healthy, 0 = Tumor. Must be in the same order as in expression data" ), make_option( "--logfile", type = "character", default = "log.txt", help = "Log file name [default : '%default']" ), make_option( "--max_stability", type = "logical", default = TRUE, help = "If true, throw away components leading to low stability of sampling noise [default : '%default']" ), make_option( "--attempts", type = "integer", default = 10, help = "Number of runs to determine stability. [default : '%default']" ), make_option( "--min_std", type = "character", default = "0.4", help = "Minimum of standard deviation to filter out low variable genes. Use --min.std data, to use the minimum std of your data [default : '%default']" ), make_option( "--min_exp", type = "character", default = "4", help = "Minimum of gene expression to filter out low expressed genes. Use --min.exp data, to use the minimum expression of your data [default : '%default']" ), make_option( "--pds", type = "character", default = "PDS.tsv", help = "Output PDS (Pathway deregulation score) of Pathifier in tabular file [default : '%default']" ), make_option( "--heatmap_cluster_cells", type = "logical", default = TRUE, help = "Cluster columns (cells) in the heatmap [default : '%default']" ), make_option( "--heatmap_cluster_pathways", type = "logical", default = TRUE, help = "Cluster rows (pathways) in the heatmap [default : '%default']" ), make_option( "--heatmap_show_cell_labels", type = "logical", default = FALSE, help = "Print column names (cells) on the heatmap [default : '%default']" ), make_option( "--heatmap_show_pathway_labels", type = "logical", default = FALSE, help = "Print row names (pathways) on the heatmap [default : '%default']" ), make_option( "--plot", type = "character", default = "./plot.pdf", help = "Pathifier visualization [default : '%default']" ), make_option( "--rdata", type = "character", default = "./results.rdata", help = "Pathifier object (S4) [default : '%default']" ) ) parser <- OptionParser(usage = "%prog [options] file", option_list = option_list) args <- parse_args(parser) if (args$sep == "tab") { args$sep <- "\t" } # set seed for reproducibility set.seed(123) # Load expression data for PATHIFIER exp_matrix <- as.matrix(read.delim( file = args$exp, as.is = TRUE, row.names = 1, sep = args$sep, check.names = FALSE )) # Load Genesets annotation gene_sets_file <- file(args$genes, open = "r") gene_sets <- readLines(gene_sets_file) close(gene_sets_file) # Generate a list that contains genes in genesets gs <- strsplit(gene_sets, "\t") names(gs) <- lapply(gs, function(x) x[1]) gs <- lapply(gs, function(x) x[-c(1:2)]) # Generate a list that contains the names of the genesets used pathwaynames <- names(gs) # Prepare data and parameters ################################################## # Extract information from binary phenotypes. 1 = Normal, 0 = Tumor if (args$is_normal == TRUE) { normals <- read.delim(file = args$normals, h = FALSE) normals <- as.logical(normals[, 2]) n_exp_matrix <- exp_matrix[, normals] } else { n_exp_matrix <- exp_matrix } # Calculate MIN_STD rsd <- apply(n_exp_matrix, 1, sd) min_std <- quantile(rsd, 0.25) # Calculate MIN_EXP min_exp <- quantile( as.vector(as.matrix(exp_matrix)), 0.1 ) # Percentile 10 of data # Filter low value genes. At least 10% of samples with values over min_exp # Set expression levels < MIN_EXP to MIN_EXP over <- apply(exp_matrix, 1, function(x) x > min_exp) g_over <- apply(over, 2, mean) g_over <- names(g_over)[g_over > 0.1] exp_matrix_filtered <- exp_matrix[g_over, ] exp_matrix_filtered[exp_matrix_filtered < min_exp] <- min_exp # Set maximum 5000 genes with more variance variable_genes <- names(sort(apply(exp_matrix_filtered, 1, var), decreasing = TRUE))[1:5000] variable_genes <- variable_genes[!is.na(variable_genes)] exp_matrix_filtered <- exp_matrix_filtered[variable_genes, ] allgenes <- as.vector(rownames(exp_matrix_filtered)) if (args$min_std == "data") { args$min_std <- min_std } else { args$min_std <- as.numeric(args$min_std) } if (args$min_exp == "data") { args$min_exp <- min_exp } else { args$min_exp <- as.numeric(args$min_exp) } # Open pdf pdf(args$plot) # Construct continuous color scale col_score_fun <- colorRamp2(c(0, 0.5, 1), c("#4575B4", "#FFFFBF", "#D73027")) # Run Pathifier if (args$is_normal == TRUE) { pds <- quantify_pathways_deregulation(exp_matrix_filtered, allgenes, gs, pathwaynames, normals, maximize_stability = args$max_stability, attempts = args$attempts, logfile = args$logfile, min_std = args$min_std, min_exp = args$min_exp ) for (i in pathwaynames) { df <- data.frame(pds$curves[[i]][, 1:3], normal = normals, PDS = as.numeric(pds$scores[[i]]), curve_order = as.vector(pds$curves_order[[i]]) ) ordered <- df[df$curve_order, ] layout(cbind(1:2, 1:2), heights = c(7, 1)) sc3 <- scatterplot3d(ordered[, 1:3], main = paste("Principal curve of", i), box = FALSE, pch = 19, type = "l" ) sc3$points3d(ordered[, 1:3], box = FALSE, pch = 19, col = col_score_fun(ordered$PDS) ) # Plot color scale legend par(mar = c(5, 3, 0, 3)) plot(seq(min(ordered$PDS), max(ordered$PDS), length = 100), rep(0, 100), pch = 15, axes = TRUE, yaxt = "n", xlab = "Color scale of PDS", ylab = "", bty = "n", col = col_score_fun(seq(min(ordered$PDS), max(ordered$PDS), length = 100)) ) cols_status <- ifelse(ordered$normal, "blue", "red") sc3 <- scatterplot3d(ordered[, 1:3], main = paste("Principal curve of", i), box = FALSE, pch = "", type = "l" ) sc3$points3d(ordered[, 1:3], box = FALSE, pch = ifelse(ordered$normal, 19, 8), col = ifelse(ordered$normal, "blue", "red") ) legend("topright", pch = c(19, 8), yjust = 0, legend = c("normal", "cancer"), col = c("blue", "red"), cex = 1.1 ) ## annotation for heatmap sample_status <- data.frame(Status = factor(ifelse(df$normal, "normal", "tumor"))) rownames(sample_status) <- colnames(exp_matrix_filtered) color_status_heatmap <- list(Status = c(normal = "blue", tumor = "red")) } } else { pds <- quantify_pathways_deregulation(exp_matrix_filtered, allgenes, gs, pathwaynames, maximize_stability = args$max_stability, attempts = args$attempts, logfile = args$logfile, min_std = args$min_std, min_exp = args$min_exp ) for (i in pathwaynames) { df <- data.frame(pds$curves[[i]][, 1:3], PDS = as.numeric(pds$scores[[i]]), curve_order = as.vector(pds$curves_order[[i]]) ) ordered <- df[df$curve_order, ] layout(cbind(1:2, 1:2), heights = c(7, 1)) sc3 <- scatterplot3d(ordered[, 1:3], main = paste("Principal curve of", i), box = FALSE, pch = 19, type = "l" ) sc3$points3d(ordered[, 1:3], box = FALSE, pch = 19, col = col_score_fun(ordered$PDS) ) # Plot color scale legend par(mar = c(5, 3, 0, 3)) plot(seq(min(ordered$PDS), max(ordered$PDS), length = 100), rep(0, 100), pch = 15, axes = TRUE, yaxt = "n", xlab = "Color scale of PDS", ylab = "", bty = "n", col = col_score_fun(seq(min(ordered$PDS), max(ordered$PDS), length = 100)) ) ## annotation for heatmap (for the moment none for this situation) sample_status <- NA color_status_heatmap <- NA } } ## Create dataframe from Pathifier list and round score to 4 digits pds_scores <- mapply(FUN = function(x) cbind(round(x, 4)), pds$scores) dimnames(pds_scores) <- list(colnames(exp_matrix_filtered), names(pds$scores)) ## plot heatmap if (ncol(pds_scores) > 1) { pheatmap(t(pds_scores), main = "Heatmap of Pathway Deregulation Score", # heat map title cluster_rows = args$heatmap_cluster_pathways, # apply clustering method cluster_cols = args$heatmap_cluster_cells, # apply clustering method # Additional Options ## Color labeled columns annotation_col = sample_status, annotation_colors = color_status_heatmap, show_rownames = args$heatmap_show_pathway_labels, show_colnames = args$heatmap_show_cell_labels, border_color = NA, legend = TRUE ) } dev.off() ## write table write.table(pds_scores, args$pds, row.names = TRUE, col.names = TRUE, quote = FALSE, sep = "\t" ) ## write S4 pathifier object save(pds, file = args$rdata)