R/experimental.R
In AngelCampos/tx_tools: An R package facilitating analysis of RNA modifications, structures, and interactions
Defines functions
tx_generateSingleEndFASTQ
tx_generatePairedEndFASTQ
tx_plot_metaGeneByBins
Documented in
tx_generatePairedEndFASTQ
tx_generateSingleEndFASTQ
tx_plot_metaGeneByBins
#' Plot metagene by bins
#'
#' @param txDT data.table. A table as output by the \code{\link{tx_makeDT_coverage}}(),
#' \code{\link{tx_makeDT_nucFreq}}() or \code{\link{tx_makeDT_covNucFreq}}() functions.
#' @param colName character. Name of the column of numeric (or logical) class to be plot
#' @param nBins integer. Number of bins to divide each gene on
#' @param FUN character. Function to be used to summarize values across bins and genes.
#' @param minTxLength integer. Minimum transcript length to be included in analysis.
#' @param smooth logical. Set to FALSE for not smoothing line.
#' @param na.rm logical. Remove NA values from computations, by default is TRUE.
#'
#' @return ggplot
tx_plot_metaGeneByBins <- function(txDT, colName, nBins = 100, FUN = "mean",
minTxLength = 300, smooth = TRUE, na.rm = TRUE){
if(nBins >= minTxLength){
stop("Number of bins most be smaller than minimum",
"transcript length.")
}
if(!(colName %in% colnames(txDT))){
stop("colName is not a column in txDT.")
}
geneLens <- tx_get_geneLengths(txDT)
txDT <- txDT[txDT$gene %in% names(geneLens)[geneLens > minTxLength]]
GENES <- as.character(unique(txDT$gene))
if(length(GENES) < 1){
stop("No genes after filtering parameters")
}
meanCovBinned <- parallel::mclapply(seq(GENES), function(i){
iGene <- GENES[i]
tmpDT <- txDT[txDT$gene == iGene,]
tmpDT$group <- tmpDT$txcoor %>% ggplot2::cut_number(n = nBins)
out <- tapply(tmpDT[[colName]], tmpDT$group, FUN, na.rm = na.rm)
out[is.nan(out)] <- NA
out
}) %>% do.call(what = "rbind") %>% apply(MARGIN = 2, FUN = FUN, na.rm = na.rm) %>%
magrittr::set_names(NULL)
DF <- data.frame(bins = seq(meanCovBinned) %>% as.numeric(),
score = meanCovBinned)
plotTitle <- paste("METAGENE BY BINS -", FUN, colName) %>% toupper()
plotSub <- paste0("n(genes) =", length(GENES), ", minTxLen =", minTxLength,
", smooth.sp =", smooth)
Y_axis <- paste(FUN, colName)
if(smooth){
DF$smooth <- stats::smooth.spline(DF$score)$y
ggplot2::ggplot(DF, ggplot2::aes(x = .data$bins, y = .data$smooth)) +
ggplot2::geom_line() + ggplot2::theme_classic() +
ggplot2::ggtitle(plotTitle, plotSub) + ggplot2::ylab(Y_axis)
}else{
ggplot2::ggplot(DF, ggplot2::aes(x = .data$bins, y = .data$score)) +
ggplot2::geom_line() + ggplot2::theme_classic() +
ggplot2::ggtitle(plotTitle, plotSub) + ggplot2::ylab(Y_axis)
}
}
# Ideas for functions ##########################################################
# # Apply a function in a binned manner to a data.table column
# tx_DT_bin_function <- function(DT, col, bins = 100, fun = mean){
# tapply(X = DT[[col]], INDEX = cut_interval(1:nrow(DT), bins), FUN = fun) %>% set_names(c())
# }
# # Apply a function in a binned manner to a vector
# tx_bin_function <- function(x, bins = 100, fun = mean){
# tapply(X = x, INDEX = cut_interval(1:length(x), bins), FUN = fun) %>% set_names(c())
# }
#' Generate paired-end FASTQ file
#'
#' Simulates a paired-end FASTQ files from a genome and a gene annotation.
#' The distribution of reads is randomly selected following a negative binomial
#' distribution.
#'
#' @param genome list. The full reference genome sequences, as loaded by
#' \code{\link{tx_load_genome}}() or prepackaged by BSgenome, see ?BSgenome::available.genomes
#' @param geneAnnot GRanges. Gene annotation as loaded by \code{\link{tx_load_bed}}().
#' @param readLen_1 integer. Length of simulated reads1
#' @param readLen_2 integer. Length of simulated reads2
#' @param insertSize integer. Length of simulated insert (gap between reads)
#' @param libSize integer. Size of simulated FASTQ file
#' @param TPM numeric. Proportion of reads per gene in gene annotation.
#' Overrides negative binomial distribution generation.
#' @param NB_r numeric. Target r dispersion parameter. Bigger values of r tend
#' to generate a normal distribution. See ?stats::rnbinom()
#' @param NB_mu numeric. Target mean of the resulting distribution
#' @param nCores integer. Number of cores to run the function with. Multicore
#' capability not available in Windows OS.
#' @param fileName_r1 character. Name of output file reads1.
#' @param fileName_r2 character. Name of output file reads2.
#'
#' @return Writes FASTQ files fileName_r1 and fileName_r2
#'
tx_generatePairedEndFASTQ <- function(genome, geneAnnot, readLen_1, readLen_2,
insertSize, libSize, fileName_r1,
fileName_r2, TPM = NULL, NB_r = 5, NB_mu = 500, nCores){
# filter transcripts by size
totReadLen <- (readLen_1 + readLen_2 + insertSize)
txOME_seqs <- tx_get_transcriptSeqs(genome = genome, geneAnnot = geneAnnot,
nCores = nCores)
txOME_seqs <- txOME_seqs[BiocGenerics::width(txOME_seqs) >= totReadLen]
if(length(txOME_seqs) != length(geneAnnot)){
stop("Some genes in gene annotation are shorter than total read length\n")
}
if(!is.null(TPM)){
if(length(TPM) != length(geneAnnot)){
stop("If TPM is provided, its length must be equal to geneAnnot's length")
}
}
# Random starts
metaTX <- list(seqs = txOME_seqs, width = BiocGenerics::width(txOME_seqs))
if(is.null(TPM)){
metaTX$TPM <- stats::rnbinom(n = length(txOME_seqs), size = NB_r, mu = NB_mu)
metaTX$TPM <- round(metaTX$TPM * (libSize / sum(metaTX$TPM)))
}else{
metaTX$TPM <- TPM
metaTX$TPM <- round(metaTX$TPM * (libSize / sum(metaTX$TPM)))
}
metaTX$range1 <- metaTX$width - (totReadLen) + 1
metaTX$starts_1 <- lapply(seq_along(metaTX$TPM), function(i){
sample(seq(1, metaTX$range1[i]), size = metaTX$TPM[i], replace = TRUE)
})
#Extract sequences
metaTX$reads1 <- lapply(seq_along(metaTX$seqs), function(i){
stringr::str_sub(metaTX$seqs[i], metaTX$starts_1[[i]],
metaTX$starts_1[[i]] + readLen_1 - 1) %>%
Biostrings::DNAStringSet()
}) %>% do.call(what = "c")
metaTX$reads2 <- lapply(seq_along(metaTX$seqs), function(i){
stringr::str_sub(metaTX$seqs[i], metaTX$starts_1[[i]] + readLen_1 + insertSize,
metaTX$starts_1[[i]] + totReadLen - 1) %>%
Biostrings::DNAStringSet() %>% Biostrings::reverseComplement()
}) %>% do.call(what = "c")
names(metaTX$reads1) <- paste0("R1_", 1:length(metaTX$reads1))
names(metaTX$reads2) <- paste0("R2_", 1:length(metaTX$reads2))
qualStr_1 <- paste(rep("H", readLen_1), collapse = "")
qualStr_2 <- paste(rep("H", readLen_2), collapse = "")
# Writing FASTQS
Biostrings::writeXStringSet(x = metaTX$reads1,
quali = Biostrings::BStringSet(
rep(qualStr_1, each = length(metaTX$reads1))),
filepath = fileName_r1,
format = "fastq",
compress = TRUE)
Biostrings::writeXStringSet(x = metaTX$reads2,
quali = Biostrings::BStringSet(
rep(qualStr_2, each = length(metaTX$reads2))),
filepath = fileName_r2,
format = "fastq",
compress = TRUE)
}
#' Generate single-end FASTQ file
#'
#' Simulates a single-end FASTQ file from a genome and a gene annotation.
#' The distribution of reads is randomly selected following a negative binomial
#' distribution.
#'
#' @param genome list. The full reference genome sequences, as loaded by
#' \code{\link{tx_load_genome}}() or prepackaged by BSgenome, see ?BSgenome::available.genomes
#' @param geneAnnot GRanges. Gene annotation as loaded by \code{\link{tx_load_bed}}().
#' @param readLen integer. Length of simulated reads
#' @param libSize integer. Size of simulated FASTQ file
#' @param fileName character. Name of output file.
#' @param TPM numeric. Proportion of reads per gene in gene annotation
#' @param NB_r numeric. Target r dispersion parameter. Bigger values of r tend
#' to generate a normal distribution. See ?stats::rnbinom()
#' @param NB_mu numeric. Target mean of the resulting distribution
#' @param nCores integer. Number of cores to run the function with. Multicore
#' capability not available in Windows OS.
#'
#' @return Writes FASTQ fileName
tx_generateSingleEndFASTQ <- function(genome, geneAnnot, readLen, libSize,
fileName, TPM = NULL, NB_r = 5, NB_mu = 500, nCores){
# filter transcripts by size
txOME_seqs <- tx_get_transcriptSeqs(genome = genome, geneAnnot = geneAnnot,
nCores = nCores)
txOME_seqs <- txOME_seqs[BiocGenerics::width(txOME_seqs) >= readLen]
if(length(txOME_seqs) != length(geneAnnot)){
stop("Some genes in gene annotation are shorter than total read length\n")
}
if(!is.null(TPM)){
if(length(TPM) != length(geneAnnot)){
stop("If TPM is provided, its length must be equal to geneAnnot's length")
}
}
# Random starts
metaTX <- list(seqs = txOME_seqs, width = BiocGenerics::width(txOME_seqs))
if(is.null(TPM)){
metaTX$TPM <- stats::rnbinom(n = length(txOME_seqs), size = NB_r, mu = NB_mu)
metaTX$TPM <- round(metaTX$TPM * (libSize / sum(metaTX$TPM)))
}else{
metaTX$TPM <- TPM
metaTX$TPM <- round(metaTX$TPM * (libSize / sum(metaTX$TPM)))
}
metaTX$range1 <- metaTX$width - readLen + 1
metaTX$starts_1 <- lapply(seq_along(metaTX$TPM), function(i){
sample(seq(1, metaTX$range1[i]), size = metaTX$TPM[i], replace = TRUE)
})
#Extract sequences
metaTX$reads1 <- lapply(seq_along(metaTX$seqs), function(i){
stringr::str_sub(metaTX$seqs[i], metaTX$starts_1[[i]],
metaTX$starts_1[[i]] + readLen - 1) %>%
Biostrings::DNAStringSet()
}) %>% do.call(what = "c")
names(metaTX$reads1) <- paste0("R1_", 1:length(metaTX$reads1))
qualStr <- paste(rep("H", readLen), collapse = "")
# Writing FASTQ
Biostrings::writeXStringSet(x = metaTX$reads1,
quali = Biostrings::BStringSet(
rep(qualStr, each = length(metaTX$reads1))),
filepath = fileName, format = "fastq",
compress = TRUE)
}
AngelCampos/tx_tools documentation built on April 8, 2024, 9:46 p.m.
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Defines functions tx_generateSingleEndFASTQ tx_generatePairedEndFASTQ tx_plot_metaGeneByBins
Documented in tx_generatePairedEndFASTQ tx_generateSingleEndFASTQ tx_plot_metaGeneByBins
#' Plot metagene by bins
#'
#' @param txDT data.table. A table as output by the \code{\link{tx_makeDT_coverage}}(),
#' \code{\link{tx_makeDT_nucFreq}}() or \code{\link{tx_makeDT_covNucFreq}}() functions.
#' @param colName character. Name of the column of numeric (or logical) class to be plot
#' @param nBins integer. Number of bins to divide each gene on
#' @param FUN character. Function to be used to summarize values across bins and genes.
#' @param minTxLength integer. Minimum transcript length to be included in analysis.
#' @param smooth logical. Set to FALSE for not smoothing line.
#' @param na.rm logical. Remove NA values from computations, by default is TRUE.
#'
#' @return ggplot
tx_plot_metaGeneByBins <- function(txDT, colName, nBins = 100, FUN = "mean",
minTxLength = 300, smooth = TRUE, na.rm = TRUE){
if(nBins >= minTxLength){
stop("Number of bins most be smaller than minimum",
"transcript length.")
}
if(!(colName %in% colnames(txDT))){
stop("colName is not a column in txDT.")
}
geneLens <- tx_get_geneLengths(txDT)
txDT <- txDT[txDT$gene %in% names(geneLens)[geneLens > minTxLength]]
GENES <- as.character(unique(txDT$gene))
if(length(GENES) < 1){
stop("No genes after filtering parameters")
}
meanCovBinned <- parallel::mclapply(seq(GENES), function(i){
iGene <- GENES[i]
tmpDT <- txDT[txDT$gene == iGene,]
tmpDT$group <- tmpDT$txcoor %>% ggplot2::cut_number(n = nBins)
out <- tapply(tmpDT[[colName]], tmpDT$group, FUN, na.rm = na.rm)
out[is.nan(out)] <- NA
out
}) %>% do.call(what = "rbind") %>% apply(MARGIN = 2, FUN = FUN, na.rm = na.rm) %>%
magrittr::set_names(NULL)
DF <- data.frame(bins = seq(meanCovBinned) %>% as.numeric(),
score = meanCovBinned)
plotTitle <- paste("METAGENE BY BINS -", FUN, colName) %>% toupper()
plotSub <- paste0("n(genes) =", length(GENES), ", minTxLen =", minTxLength,
", smooth.sp =", smooth)
Y_axis <- paste(FUN, colName)
if(smooth){
DF$smooth <- stats::smooth.spline(DF$score)$y
ggplot2::ggplot(DF, ggplot2::aes(x = .data$bins, y = .data$smooth)) +
ggplot2::geom_line() + ggplot2::theme_classic() +
ggplot2::ggtitle(plotTitle, plotSub) + ggplot2::ylab(Y_axis)
}else{
ggplot2::ggplot(DF, ggplot2::aes(x = .data$bins, y = .data$score)) +
ggplot2::geom_line() + ggplot2::theme_classic() +
ggplot2::ggtitle(plotTitle, plotSub) + ggplot2::ylab(Y_axis)
}
}
# Ideas for functions ##########################################################
# # Apply a function in a binned manner to a data.table column
# tx_DT_bin_function <- function(DT, col, bins = 100, fun = mean){
# tapply(X = DT[[col]], INDEX = cut_interval(1:nrow(DT), bins), FUN = fun) %>% set_names(c())
# }
# # Apply a function in a binned manner to a vector
# tx_bin_function <- function(x, bins = 100, fun = mean){
# tapply(X = x, INDEX = cut_interval(1:length(x), bins), FUN = fun) %>% set_names(c())
# }
#' Generate paired-end FASTQ file
#'
#' Simulates a paired-end FASTQ files from a genome and a gene annotation.
#' The distribution of reads is randomly selected following a negative binomial
#' distribution.
#'
#' @param genome list. The full reference genome sequences, as loaded by
#' \code{\link{tx_load_genome}}() or prepackaged by BSgenome, see ?BSgenome::available.genomes
#' @param geneAnnot GRanges. Gene annotation as loaded by \code{\link{tx_load_bed}}().
#' @param readLen_1 integer. Length of simulated reads1
#' @param readLen_2 integer. Length of simulated reads2
#' @param insertSize integer. Length of simulated insert (gap between reads)
#' @param libSize integer. Size of simulated FASTQ file
#' @param TPM numeric. Proportion of reads per gene in gene annotation.
#' Overrides negative binomial distribution generation.
#' @param NB_r numeric. Target r dispersion parameter. Bigger values of r tend
#' to generate a normal distribution. See ?stats::rnbinom()
#' @param NB_mu numeric. Target mean of the resulting distribution
#' @param nCores integer. Number of cores to run the function with. Multicore
#' capability not available in Windows OS.
#' @param fileName_r1 character. Name of output file reads1.
#' @param fileName_r2 character. Name of output file reads2.
#'
#' @return Writes FASTQ files fileName_r1 and fileName_r2
#'
tx_generatePairedEndFASTQ <- function(genome, geneAnnot, readLen_1, readLen_2,
insertSize, libSize, fileName_r1,
fileName_r2, TPM = NULL, NB_r = 5, NB_mu = 500, nCores){
# filter transcripts by size
totReadLen <- (readLen_1 + readLen_2 + insertSize)
txOME_seqs <- tx_get_transcriptSeqs(genome = genome, geneAnnot = geneAnnot,
nCores = nCores)
txOME_seqs <- txOME_seqs[BiocGenerics::width(txOME_seqs) >= totReadLen]
if(length(txOME_seqs) != length(geneAnnot)){
stop("Some genes in gene annotation are shorter than total read length\n")
}
if(!is.null(TPM)){
if(length(TPM) != length(geneAnnot)){
stop("If TPM is provided, its length must be equal to geneAnnot's length")
}
}
# Random starts
metaTX <- list(seqs = txOME_seqs, width = BiocGenerics::width(txOME_seqs))
if(is.null(TPM)){
metaTX$TPM <- stats::rnbinom(n = length(txOME_seqs), size = NB_r, mu = NB_mu)
metaTX$TPM <- round(metaTX$TPM * (libSize / sum(metaTX$TPM)))
}else{
metaTX$TPM <- TPM
metaTX$TPM <- round(metaTX$TPM * (libSize / sum(metaTX$TPM)))
}
metaTX$range1 <- metaTX$width - (totReadLen) + 1
metaTX$starts_1 <- lapply(seq_along(metaTX$TPM), function(i){
sample(seq(1, metaTX$range1[i]), size = metaTX$TPM[i], replace = TRUE)
})
#Extract sequences
metaTX$reads1 <- lapply(seq_along(metaTX$seqs), function(i){
stringr::str_sub(metaTX$seqs[i], metaTX$starts_1[[i]],
metaTX$starts_1[[i]] + readLen_1 - 1) %>%
Biostrings::DNAStringSet()
}) %>% do.call(what = "c")
metaTX$reads2 <- lapply(seq_along(metaTX$seqs), function(i){
stringr::str_sub(metaTX$seqs[i], metaTX$starts_1[[i]] + readLen_1 + insertSize,
metaTX$starts_1[[i]] + totReadLen - 1) %>%
Biostrings::DNAStringSet() %>% Biostrings::reverseComplement()
}) %>% do.call(what = "c")
names(metaTX$reads1) <- paste0("R1_", 1:length(metaTX$reads1))
names(metaTX$reads2) <- paste0("R2_", 1:length(metaTX$reads2))
qualStr_1 <- paste(rep("H", readLen_1), collapse = "")
qualStr_2 <- paste(rep("H", readLen_2), collapse = "")
# Writing FASTQS
Biostrings::writeXStringSet(x = metaTX$reads1,
quali = Biostrings::BStringSet(
rep(qualStr_1, each = length(metaTX$reads1))),
filepath = fileName_r1,
format = "fastq",
compress = TRUE)
Biostrings::writeXStringSet(x = metaTX$reads2,
quali = Biostrings::BStringSet(
rep(qualStr_2, each = length(metaTX$reads2))),
filepath = fileName_r2,
format = "fastq",
compress = TRUE)
}
#' Generate single-end FASTQ file
#'
#' Simulates a single-end FASTQ file from a genome and a gene annotation.
#' The distribution of reads is randomly selected following a negative binomial
#' distribution.
#'
#' @param genome list. The full reference genome sequences, as loaded by
#' \code{\link{tx_load_genome}}() or prepackaged by BSgenome, see ?BSgenome::available.genomes
#' @param geneAnnot GRanges. Gene annotation as loaded by \code{\link{tx_load_bed}}().
#' @param readLen integer. Length of simulated reads
#' @param libSize integer. Size of simulated FASTQ file
#' @param fileName character. Name of output file.
#' @param TPM numeric. Proportion of reads per gene in gene annotation
#' @param NB_r numeric. Target r dispersion parameter. Bigger values of r tend
#' to generate a normal distribution. See ?stats::rnbinom()
#' @param NB_mu numeric. Target mean of the resulting distribution
#' @param nCores integer. Number of cores to run the function with. Multicore
#' capability not available in Windows OS.
#'
#' @return Writes FASTQ fileName
tx_generateSingleEndFASTQ <- function(genome, geneAnnot, readLen, libSize,
fileName, TPM = NULL, NB_r = 5, NB_mu = 500, nCores){
# filter transcripts by size
txOME_seqs <- tx_get_transcriptSeqs(genome = genome, geneAnnot = geneAnnot,
nCores = nCores)
txOME_seqs <- txOME_seqs[BiocGenerics::width(txOME_seqs) >= readLen]
if(length(txOME_seqs) != length(geneAnnot)){
stop("Some genes in gene annotation are shorter than total read length\n")
}
if(!is.null(TPM)){
if(length(TPM) != length(geneAnnot)){
stop("If TPM is provided, its length must be equal to geneAnnot's length")
}
}
# Random starts
metaTX <- list(seqs = txOME_seqs, width = BiocGenerics::width(txOME_seqs))
if(is.null(TPM)){
metaTX$TPM <- stats::rnbinom(n = length(txOME_seqs), size = NB_r, mu = NB_mu)
metaTX$TPM <- round(metaTX$TPM * (libSize / sum(metaTX$TPM)))
}else{
metaTX$TPM <- TPM
metaTX$TPM <- round(metaTX$TPM * (libSize / sum(metaTX$TPM)))
}
metaTX$range1 <- metaTX$width - readLen + 1
metaTX$starts_1 <- lapply(seq_along(metaTX$TPM), function(i){
sample(seq(1, metaTX$range1[i]), size = metaTX$TPM[i], replace = TRUE)
})
#Extract sequences
metaTX$reads1 <- lapply(seq_along(metaTX$seqs), function(i){
stringr::str_sub(metaTX$seqs[i], metaTX$starts_1[[i]],
metaTX$starts_1[[i]] + readLen - 1) %>%
Biostrings::DNAStringSet()
}) %>% do.call(what = "c")
names(metaTX$reads1) <- paste0("R1_", 1:length(metaTX$reads1))
qualStr <- paste(rep("H", readLen), collapse = "")
# Writing FASTQ
Biostrings::writeXStringSet(x = metaTX$reads1,
quali = Biostrings::BStringSet(
rep(qualStr, each = length(metaTX$reads1))),
filepath = fileName, format = "fastq",
compress = TRUE)
}
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