view mutational_patterns.R @ 28:9a33a5a90a2c draft default tip

planemo upload for repository https://github.com/ARTbio/tools-artbio/tree/main/tools/mutational_patterns commit c55e91bc6716a71ee3a3f30da3f4c915f465c1d4
author artbio
date Sun, 11 Feb 2024 01:12:41 +0000
parents af5c65ad5317
children
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# load packages that are provided in the conda env
options(
    show.error.messages = FALSE,
    error = function() {
        cat(geterrmessage(), file = stderr())
        q("no", 1, FALSE)
    }
)
loc <- Sys.setlocale("LC_MESSAGES", "en_US.UTF-8")
warnings()
library(optparse)
library(rjson)
library(grid)
library(gridExtra)
library(scales)
library(RColorBrewer)

# Arguments
option_list <- list(
    make_option(
        "--inputs",
        default = NA,
        type = "character",
        help = "json formatted dictionary of datasets and their paths"
    ),
    make_option(
        "--genome",
        default = NA,
        type = "character",
        help = "genome name in the BSgenome bioconductor package"
    ),
    make_option(
        "--levels",
        default = NA,
        type = "character",
        help = "path to the tab separated file describing the levels in function of datasets"
    ),
    make_option(
        "--cosmic_version",
        default = NA,
        type = "character",
        help = "Version of the Cosmic Signature set to be used to express mutational profiles"
    ),
    make_option(
        "--own_signatures",
        default = NA,
        type = "character",
        help = "Path to the user-defined signature matrix"
    ),
    make_option(
        "--signum",
        default = 2,
        type = "integer",
        help = "selects the N most significant signatures in samples to express mutational profiles"
    ),
    make_option(
        "--nrun",
        default = 2,
        type = "integer",
        help = "Number of runs to fit signatures"
    ),
    make_option(
        "--rank",
        default = 2,
        type = "integer",
        help = "number of ranks to display for parameter optimization"
    ),
    make_option(
        "--newsignum",
        default = 2,
        type = "integer",
        help = "Number of new signatures to be captured"
    ),
    make_option(
        "--cosmic_id_threshold",
        default = 0.85,
        type = "double",
        help = "minimu cosine similarity to rename a new signature according to cosmic v3.2"
    ),
    make_option(
        "--output_spectrum",
        default = NA,
        type = "character",
        help = "path to output dataset"
    ),
    make_option(
        "--output_denovo",
        default = NA,
        type = "character",
        help = "path to output dataset"
    ),
    make_option(
        "--sigmatrix",
        default = NA,
        type = "character",
        help = "path to signature matrix"
    ),
    make_option(
        "--output_sigpattern",
        default = NA,
        type = "character",
        help = "path to output dataset"
    ),
    make_option(
        "--display_signatures",
        default = NA,
        type = "character",
        help = "display input signature profiles if set to yes"
    ),
    make_option(
        "--sig_contrib_matrix",
        default = NA,
        type = "character",
        help = "path to signature contribution matrix"
    ),
    make_option(
        "--colors",
        default = NA,
        type = "character",
        help = "color palette to display signatures"
    ),
    make_option(
        c("-r", "--rdata"),
        type = "character",
        default = NULL,
        help = "Path to RData output file"
    ),
    make_option(
        c("-t", "--tooldir"),
        type = "character",
        default = NULL,
        help = "Path to tool directory, where tool data are stored"
    )
)

opt <- parse_args(OptionParser(option_list = option_list),
    args = commandArgs(trailingOnly = TRUE)
)

################ Manage input data ####################
json_dict <- opt$inputs
parser <- newJSONParser()
parser$addData(json_dict)
fileslist <- parser$getObject()
vcf_paths <- attr(fileslist, "names")
element_identifiers <- unname(unlist(fileslist))
ref_genome <- opt$genome
vcf_table <- data.frame(element_identifier = as.character(element_identifiers), path = vcf_paths)

library(MutationalPatterns)
library(ref_genome, character.only = TRUE)
library(ggplot2)

# Load the VCF files into a GRangesList:
vcfs <- read_vcfs_as_granges(vcf_paths, element_identifiers, ref_genome)
library(plyr)
if (!is.na(opt$levels)[1]) { # manage levels if there are
    levels_table <- read.delim(opt$levels,
        header = FALSE,
        col.names = c("element_identifier", "level")
    )
} else {
    levels_table <- data.frame(
        element_identifier = vcf_table$element_identifier,
        level = rep("nolabels", length(vcf_table$element_identifier))
    )
}
metadata_table <- join(vcf_table, levels_table, by = "element_identifier")
tissue <- as.vector(metadata_table$level)
detach(package:plyr)

##### This is done for any section ######
mut_mat <- mut_matrix(vcf_list = vcfs, ref_genome = ref_genome)
qual_col_pals <- brewer.pal.info[brewer.pal.info$category == "qual", ]

###### Section 1 Mutation characteristics and spectrums #############
if (!is.na(opt$output_spectrum)[1]) {
    pdf(opt$output_spectrum, paper = "special", width = 11.69, height = 11.69)
    type_occurrences <- mut_type_occurrences(vcfs, ref_genome)

    # mutation spectrum, total or by sample

    if (length(levels(factor(levels_table$level))) == 1) {
        p1 <- plot_spectrum(type_occurrences, CT = TRUE, legend = TRUE)
        plot(p1)
    } else {
        p2 <- plot_spectrum(type_occurrences, by = tissue, CT = TRUE) # by levels
        p3 <- plot_spectrum(type_occurrences, CT = TRUE, legend = TRUE) # total
        grid.arrange(p2, p3, ncol = 2, widths = c(4, 2.3), heights = c(4, 1))
    }
    plot_96_profile(mut_mat, condensed = TRUE)
    dev.off()
}

###### Section 2: De novo mutational signature extraction using NMF #######
# opt$rank cannot be higher than the number of samples and
# likewise, opt$signum cannot be higher thant the number of samples
if (!is.na(opt$output_denovo)[1]) {
    if (opt$rank > length(element_identifiers)) {
        opt$rank <- length(element_identifiers)
    }
    if (opt$signum > length(element_identifiers)) {
        opt$signum <- length(element_identifiers)
    }
    pseudo_mut_mat <- mut_mat + 0.0001 # First add a small pseudocount to the mutation count matrix
    # Use the NMF package to generate an estimate rank plot
    library("NMF")
    estimate <- nmf(pseudo_mut_mat, rank = 1:opt$rank, method = "brunet", nrun = opt$nrun, seed = 123456)
    # And plot it
    pdf(opt$output_denovo, paper = "special", width = 11.69, height = 11.69)
    p4 <- plot(estimate)
    grid.arrange(p4)
    # Extract 4 (PARAMETIZE) mutational signatures from the mutation count matrix with extract_signatures
    # (For larger datasets it is wise to perform more iterations by changing the nrun parameter
    # to achieve stability and avoid local minima)
    nmf_res <- extract_signatures(pseudo_mut_mat, rank = opt$newsignum, nrun = opt$nrun)
    # Assign signature COSMICv3.2 names
    cosmic_signatures <- get_known_signatures()
    nmf_res <- rename_nmf_signatures(nmf_res, cosmic_signatures, cutoff = opt$cosmic_id_threshold)
    sim_matrix <- cos_sim_matrix(cosmic_signatures, nmf_res$signatures)
    plot_cosine_sim <- plot_cosine_heatmap(sim_matrix)
    grid.arrange(plot_cosine_sim)
    # Plot the 96-profile of the signatures:
    p5 <- plot_96_profile(nmf_res$signatures, condensed = TRUE)
    grid.arrange(p5)
    # write matrix of deno signatures for user
    new_sig_matrix <- reshape2::dcast(p5$data, substitution + context ~ sample, value.var = "freq")
    new_sig_matrix <- format(new_sig_matrix, scientific = TRUE)
    newcol <- paste0(
        gsub("\\..", "", new_sig_matrix$context, perl = TRUE),
        "[", new_sig_matrix$substitution, "]",
        gsub("^.\\.", "", new_sig_matrix$context, perl = TRUE)
    )
    new_sig_matrix <- cbind(Type = newcol, new_sig_matrix[, seq_along(new_sig_matrix)[-c(1, 2)]])
    write.table(new_sig_matrix, file = opt$sigmatrix, quote = FALSE, row.names = FALSE, sep = "\t")
    # Visualize the contribution of the signatures in a barplot
    pc1 <- plot_contribution(nmf_res$contribution, nmf_res$signature, mode = "relative", coord_flip = TRUE)
    # Visualize the contribution of the signatures in absolute number of mutations
    pc2 <- plot_contribution(nmf_res$contribution, nmf_res$signature, mode = "absolute", coord_flip = TRUE)
    # Combine the two plots:
    grid.arrange(pc1, pc2)

    # The relative contribution of each signature for each sample can also be plotted as a heatmap with
    # plot_contribution_heatmap, which might be easier to interpret and compare than stacked barplots.
    # The samples can be hierarchically clustered based on their euclidean dis- tance. The signatures
    # can be plotted in a user-specified order.
    # Plot signature contribution as a heatmap with sample clustering dendrogram and a specified signature order:
    pch1 <- plot_contribution_heatmap(nmf_res$contribution, cluster_samples = TRUE)
    # Plot signature contribution as a heatmap without sample clustering:
    pch2 <- plot_contribution_heatmap(nmf_res$contribution, cluster_samples = FALSE)
    # Combine the plots into one figure:
    grid.arrange(pch1, pch2, ncol = 2, widths = c(2, 1.6))

    # Compare the reconstructed mutational profile with the original mutational profile:
    pch3 <- plot_original_vs_reconstructed(pseudo_mut_mat, nmf_res$reconstructed, y_intercept = 0.95)
    grid.arrange(pch3)
    dev.off()
}

##### Section 3: Find optimal contribution of known signatures: COSMIC or OWN mutational signatures ####

if (!is.na(opt$output_sigpattern)[1]) {
    # Prepare cosmic signatures
    if (!is.na(opt$cosmic_version)) {
        cosmic_urls <- read.delim(paste0(opt$tooldir, "cosmic_urls.tsv"), sep = "\t", header = TRUE)
        cosmic_sbs_file <- cosmic_urls$url[cosmic_urls$genome == opt$genome &
                                               cosmic_urls$cosmic_version == opt$cosmic_version]
        sbs_signatures <- read.table(paste0(opt$tooldir, cosmic_sbs_file),
            sep = "\t", header = TRUE
        )
        tag <- paste(gsub("BSgenome.Hsapiens.UCSC.", "", opt$genome), "COSMIC", opt$cosmic_version, sep = " ")
    }
    # Prepare user-defined signatures
    if (!is.na(opt$own_signatures)) {
        sbs_signatures <- read.table(opt$own_signatures, sep = "\t", header = TRUE)
        tag <- paste(gsub("BSgenome.Hsapiens.UCSC.", "", opt$genome), "User-Defined Signatures", sep = " ")
    }
    row.names(sbs_signatures) <- sbs_signatures$Type
    # drop column Type of sbs_signatures
    sbs_signatures <- subset(sbs_signatures, select = -c(Type))
    # reorder substitutions of sbs_signatures to match mut_mat
    sbs_signatures <- sbs_signatures[match(row.names(mut_mat), row.names(sbs_signatures)), ]
    # arrange signature colors
    if (opt$colors == "intense") {
        signature_colors <- c(
            "#3f4100", "#6f53ff", "#6dc400", "#9d1fd7", "#009c06", "#001fae", "#c4bedf", "#8adb4d", "#5a67ff", "#d8c938", "#024bc3",
            "#d2ab00", "#e36eff", "#cad5b3", "#00ac44", "#d000b0", "#01b071", "#ff64e2", "#006b21", "#b70090", "#60dc9f", "#5f0083",
            "#c0ce67", "#002981", "#e6b8b3", "#ffb53e", "#44005f", "#b59600", "#7d95ff", "#f47600", "#017bc4", "#ff2722", "#02cfec",
            "#ff233f", "#01b7b4", "#fd005c", "#019560", "#ff57a9", "#88d896", "#b80067", "#abd27f", "#dc8eff", "#667b00", "#fba3ff",
            "#093f00", "#ff6494", "#009791", "#c93200", "#4ac8ff", "#a60005", "#8fd4b6", "#ce0036", "#00634d", "#ff6035", "#2d1956",
            "#f0be6d", "#6a0058", "#957a00", "#e4b4ff", "#4a5500", "#abc7fe", "#c95900", "#003d27", "#b10043", "#d5c68e", "#3e163e",
            "#b36b00", "#debaeb", "#605400", "#7a0044", "#ffa06d", "#4c0d21", "#ff9cb5", "#3f1d02", "#ff958f", "#634a66", "#775500",
            "#6e0028", "#717653", "#6c1000", "#693600"
        )
    } else {
        signature_colors <- c(
            "#7FC97F", "#BEAED4", "#FDC086", "#FFFF99", "#386CB0", "#F0027F", "#c4bedf", "#BF5B17", "#666666", "#1B9E77", "#D95F02",
            "#7570B3", "#E7298A", "#cad5b3", "#66A61E", "#E6AB02", "#A6761D", "#A6CEE3", "#1F78B4", "#B2DF8A", "#33A02C", "#FB9A99",
            "#E31A1C", "#B3E2CD", "#e6b8b3", "#FF7F00", "#CAB2D6", "#6A3D9A", "#B15928", "#FBB4AE", "#B3CDE3", "#CCEBC5", "#DECBE4",
            "#FED9A6", "#FFFFCC", "#E5D8BD", "#FDDAEC", "#F2F2F2", "#B3E2CD", "#FDCDAC", "#CBD5E8", "#F4CAE4", "#E6F5C9", "#FFF2AE",
            "#F1E2CC", "#CCCCCC", "#E41A1C", "#377EB8", "#4DAF4A", "#984EA3", "#FFFF33", "#A65628", "#F781BF", "#999999", "#66C2A5",
            "#FC8D62", "#8DA0CB", "#E78AC3", "#A6D854", "#FFD92F", "#E5C494", "#B3B3B3", "#8DD3C7", "#FFFFB3", "#BEBADA", "#FB8072",
            "#80B1D3", "#FDB462", "#B3DE69", "#FCCDE5", "#D9D9D9", "#BC80BD", "#FFED6F", "#3f1d02", "#ff958f", "#634a66", "#775500",
            "#6e0028", "#717653", "#6c1000", "#693600"
        )
    }
    names(signature_colors) <- c(
        "SBS1", "SBS2", "SBS3", "SBS4", "SBS5", "SBS6", "SBS7", "SBS7a", "SBS7b", "SBS7c", "SBS7d",
        "SBS8", "SBS9", "SBS10", "SBS10a", "SBS10b", "SBS10c", "SBS10d", "SBS11", "SBS12", "SBS13", "SBS14",
        "SBS15", "SBS16", "SBS17", "SBS17a", "SBS17b", "SBS18", "SBS19", "SBS20", "SBS21", "SBS22", "SBS23",
        "SBS24", "SBS25", "SBS26", "SBS27", "SBS28", "SBS29", "SBS30", "SBS31", "SBS32", "SBS33", "SBS34",
        "SBS35", "SBS36", "SBS37", "SBS38", "SBS39", "SBS40", "SBS41", "SBS42", "SBS43", "SBS44", "SBS45",
        "SBS46", "SBS47", "SBS48", "SBS49", "SBS50", "SBS51", "SBS52", "SBS53", "SBS54", "SBS55", "SBS56",
        "SBS57", "SBS58", "SBS59", "SBS60", "SBS84", "SBS85", "SBS86", "SBS87", "SBS88", "SBS89", "SBS90",
        "SBS91", "SBS92", "SBS93", "SBS94"
    )

    # if signature names provided are not compliant with cosmic nomenclature,
    # we attribute these names to the active signature_colors vector, adjusted to the length
    # of the signature names.

    if (!all(colnames(sbs_signatures) %in% names(signature_colors))) { # provided signature are not all included in cosmic names
        signature_colors <- signature_colors[seq_along(sbs_signatures)]
        names(signature_colors) <- colnames(sbs_signatures)
    }

    # This is IMPORTANT since in Galaxy we do not use the embeded function get_known_signatures()
    sbs_signatures <- as.matrix(sbs_signatures)


    # Plot mutational profiles of the COSMIC signatures

    pdf(opt$output_sigpattern, paper = "special", width = 11.69, height = 11.69)
    if (opt$display_signatures == "yes") {
        for (i in head(seq(1, ncol(sbs_signatures), by = 20), -1)) {
            p6 <- plot_96_profile(sbs_signatures[, i:(i + 19)], condensed = TRUE, ymax = 0.3)
            grid.arrange(p6, top = textGrob(
                paste0(
                    tag, " profiles (", trunc((i + 1) / 20) + 1, " of ",
                    trunc(ncol(sbs_signatures) / 20) + 1, " pages)"
                ),
                gp = gpar(fontsize = 12, font = 3)
            ))
        }
        p6 <- plot_96_profile(sbs_signatures[, (trunc(ncol(sbs_signatures) / 20) * 20):(ncol(sbs_signatures))],
            condensed = TRUE, ymax = 0.3
        )
        grid.arrange(p6, top = textGrob(
            paste0(
                tag, " profiles (", trunc(ncol(sbs_signatures) / 20) + 1, " of ",
                trunc(ncol(sbs_signatures) / 20) + 1, " pages)"
            ),
            gp = gpar(fontsize = 12, font = 3)
        ))
    }


    # Find optimal contribution of COSMIC signatures to reconstruct 96 mutational profiles
    pseudo_mut_mat <- mut_mat + 0.0001 # First add a small pseudocount to the mutation count matrix
    fit_res <- fit_to_signatures(pseudo_mut_mat, sbs_signatures)

    # Plot contribution barplots
    pc3 <- plot_contribution(fit_res$contribution, sbs_signatures, coord_flip = TRUE, mode = "absolute")
    pc4 <- plot_contribution(fit_res$contribution, sbs_signatures, coord_flip = TRUE, mode = "relative")
    if (is.na(opt$levels)[1]) { # if there are NO levels to display in graphs
        pc3_data <- pc3$data
        pc3 <- ggplot(pc3_data, aes(x = Sample, y = Contribution, fill = as.factor(Signature))) +
            geom_bar(stat = "identity", position = "stack") +
            coord_flip() +
            scale_fill_manual(name = tag, values = signature_colors[colnames(sbs_signatures)]) +
            labs(x = "Samples", y = "Absolute contribution") +
            theme_bw() +
            theme(
                panel.grid.minor.x = element_blank(),
                panel.grid.major.x = element_blank(),
                legend.position = "right",
                text = element_text(size = 8),
                axis.text.x = element_text(angle = 90, hjust = 1)
            )
        pc4_data <- pc4$data
        pc4 <- ggplot(pc4_data, aes(x = Sample, y = Contribution, fill = as.factor(Signature))) +
            geom_bar(stat = "identity", position = "fill") +
            coord_flip() +
            scale_fill_manual(name = tag, values = signature_colors[colnames(sbs_signatures)]) +
            scale_y_continuous(labels = scales::percent_format(accuracy = 1)) +
            labs(x = "Samples", y = "Relative contribution") +
            theme_bw() +
            theme(
                panel.grid.minor.x = element_blank(), panel.grid.major.x = element_blank(), legend.position = "right",
                text = element_text(size = 8),
                axis.text.x = element_text(angle = 90, hjust = 1)
            )
    }
    #####
    # ggplot2 alternative
    if (!is.na(opt$levels)[1]) { # if there are levels to display in graphs
        pc3_data <- pc3$data
        pc3_data <- merge(pc3_data, metadata_table[, c(1, 3)], by.x = "Sample", by.y = "element_identifier")
        pc3 <- ggplot(pc3_data, aes(x = Sample, y = Contribution, fill = as.factor(Signature))) +
            geom_bar(stat = "identity", position = "stack") +
            scale_fill_manual(name = tag, values = signature_colors[colnames(sbs_signatures)]) +
            labs(x = "Samples", y = "Absolute contribution") +
            theme_bw() +
            theme(
                panel.grid.minor.x = element_blank(),
                panel.grid.major.x = element_blank(),
                legend.position = "right",
                text = element_text(size = 8),
                axis.text.x = element_text(angle = 90, hjust = 1)
            ) +
            facet_grid(~level, scales = "free_x", space = "free")
        pc4_data <- pc4$data
        pc4_data <- merge(pc4_data, metadata_table[, c(1, 3)], by.x = "Sample", by.y = "element_identifier")
        pc4 <- ggplot(pc4_data, aes(x = Sample, y = Contribution, fill = as.factor(Signature))) +
            geom_bar(stat = "identity", position = "fill") +
            scale_fill_manual(name = tag, values = signature_colors[colnames(sbs_signatures)]) +
            scale_y_continuous(labels = scales::percent_format(accuracy = 1)) +
            labs(x = "Samples", y = "Relative contribution") +
            theme_bw() +
            theme(
                panel.grid.minor.x = element_blank(),
                panel.grid.major.x = element_blank(),
                legend.position = "right",
                text = element_text(size = 8),
                axis.text.x = element_text(angle = 90, hjust = 1)
            ) +
            facet_grid(~level, scales = "free_x", space = "free")
    }
    # Combine the two plots:
    grid.arrange(pc3, pc4,
        top = textGrob("Absolute and Relative Contributions of elementary signatures to mutational profiles",
            gp = gpar(fontsize = 12, font = 3)
        )
    )

    #### pie charts of comic signatures contributions in samples ###
    library(reshape2)
    library(dplyr)
    if (length(levels(factor(levels_table$level))) < 2) {
        fit_res_contrib <- as.data.frame(fit_res$contribution)
        worklist <- cbind(
            signature = rownames(fit_res$contribution),
            level = rep("nolabels", length(fit_res_contrib[, 1])),
            fit_res_contrib,
            sum = rowSums(fit_res_contrib)
        )
        worklist <- worklist[order(worklist[, "sum"], decreasing = TRUE), ]
        worklist <- worklist[1:opt$signum, ]
        worklist <- worklist[, -length(worklist[1, ])]
        worklist <- melt(worklist)
        worklist <- worklist[, c(1, 3, 4, 2)]
    } else {
        worklist <- list()
        for (i in levels(factor(levels_table$level))) {
            worklist[[i]] <- fit_res$contribution[, levels_table$element_identifier[levels_table$level == i]]
            sum <- rowSums(as.data.frame(worklist[[i]]))
            worklist[[i]] <- cbind(worklist[[i]], sum)
            worklist[[i]] <- worklist[[i]][order(worklist[[i]][, "sum"], decreasing = TRUE), ]
            worklist[[i]] <- worklist[[i]][1:opt$signum, ]
            worklist[[i]] <- worklist[[i]][, -length(as.data.frame(worklist[[i]]))]
        }
        worklist <- as.data.frame(melt(worklist))
        worklist[, 2] <- paste0(worklist[, 4], " - ", worklist[, 2])
    }

    colnames(worklist) <- c("signature", "sample", "value", "level")
    worklist <- as.data.frame(worklist %>% group_by(sample) %>% mutate(value = value / sum(value) * 100))
    worklist$pos <- cumsum(worklist$value) - worklist$value / 2
    worklist$label <- factor(gsub("SBS", "", worklist$signature))
    worklist$signature <- factor(worklist$signature)
    p7 <- ggplot(worklist, aes(x = "", y = value, group = signature, fill = signature)) +
        geom_bar(width = 1, stat = "identity") +
        geom_text(aes(label = label), position = position_stack(vjust = 0.5), color = "white", size = 3) +
        coord_polar("y", start = 0) +
        facet_wrap(. ~ sample) +
        labs(x = "", y = "Samples", fill = tag) +
        scale_fill_manual(
            name = paste0(opt$signum, " most contributing\nsignatures\n(in each label/tissue)"),
            values = signature_colors[levels(worklist$signature)],
            labels = names(signature_colors[levels(worklist$signature)])
        ) +
        theme(
            axis.text = element_blank(),
            axis.ticks = element_blank(),
            panel.grid = element_blank()
        )
    grid.arrange(p7)

    # Plot relative contribution of the cancer signatures in each sample as a heatmap with sample clustering
    if (length(vcf_paths) > 1) {
        p8 <- plot_contribution_heatmap(fit_res$contribution, cluster_samples = TRUE, method = "complete")
        grid.arrange(p8)
    }

    # export relative contribution matrix
    if (!is.na(opt$sig_contrib_matrix)) {
        output_table <- t(fit_res$contribution) / rowSums(t(fit_res$contribution))
        if (length(levels(factor(levels_table$level))) > 1) {
            output_table <- data.frame(
                sample = paste0(metadata_table[
                    metadata_table$element_identifier == colnames(fit_res$contribution),
                    3
                ], "-", colnames(fit_res$contribution)),
                output_table
            )
            colnames(output_table) <- gsub("X", "SBS", colnames(output_table))
        } else {
            output_table <- data.frame(sample = rownames(output_table), output_table)
            colnames(output_table) <- gsub("X", "SBS", colnames(output_table))
        }
        write.table(output_table, file = opt$sig_contrib_matrix, sep = "\t", quote = FALSE, row.names = FALSE)
    }

    # calculate all pairwise cosine similarities
    cos_sim_ori_rec <- cos_sim_matrix(pseudo_mut_mat, fit_res$reconstructed)
    # extract cosine similarities per sample between original and reconstructed
    cos_sim_ori_rec <- as.data.frame(diag(cos_sim_ori_rec))

    # We can use ggplot to make a barplot of the cosine similarities between the original and
    # reconstructed mutational profile of each sample. This clearly shows how well each mutational
    # profile can be reconstructed with the COSMIC mutational signatures. Two identical profiles
    # have a cosine similarity of 1. The lower the cosine similarity between original and
    # reconstructed, the less well the original mutational profile can be reconstructed with
    # the COSMIC signatures. You could use, for example, cosine similarity of 0.95 as a cutoff.

    # Adjust data frame for plotting with gpplot
    colnames(cos_sim_ori_rec) <- "cos_sim"
    cos_sim_ori_rec$sample <- row.names(cos_sim_ori_rec)
    # Make barplot
    p9 <- ggplot(cos_sim_ori_rec, aes(y = cos_sim, x = sample)) +
        geom_bar(stat = "identity", fill = "skyblue4") +
        coord_cartesian(ylim = c(0.8, 1)) +
        # coord_flip(ylim=c(0.8,1)) +
        ylab("Cosine similarity\n original VS reconstructed") +
        xlab("") +
        # Reverse order of the samples such that first is up
        # xlim(rev(levels(factor(cos_sim_ori_rec$sample)))) +
        theme_bw() +
        theme(
            panel.grid.minor.y = element_blank(),
            panel.grid.major.y = element_blank(),
            axis.text.x = element_text(angle = 90, vjust = 0.5, hjust = 1)
        ) +
        # Add cut.off line
        geom_hline(aes(yintercept = .95))
    grid.arrange(p9, top = textGrob("Similarity between true profiles and profiles reconstructed with elementary signatures", gp = gpar(fontsize = 12, font = 3)))
    dev.off()
}


# Output RData file
if (!is.null(opt$rdata)) {
    save.image(file = opt$rdata)
}