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R/processCapRout.R
In nearBynding: Discern RNA structure proximal to protein binding
Defines functions
processCapRout
Documented in
processCapRout
#' @title processCapRout
#'
#' @description Creates context-separated bedGraph files of CapR output for
#' genome and transcriptome alignments.
#'
#' @param CapR_outfile Name of CapR output file. Required
#' @param output_prefix Prefix string to be appended to all output files.
#' Required.
#' @param chrom_size Name of chromosome size file. File must be in two-column
#' format without a header where first column is chromosome name and second
#' column is chromosome length, as from getChainChrSize. Required.
#' @param genome_gtf The name of the GTF/GFF file that contains all exome
#' annotations. Required
#' @param RNA_fragment RNA component of interest. Options depend on the gtf
#' file but often include "gene", "transcript", "exon", "CDS", "five_prime_utr",
#' and/or "three_prime_utr". Default "exon" for the whole exome.
#' @param chain The name of the chain file to be used. Format should be like
#' chain files derived from GRangesMappingToChainFile. Required
#'
#' @return writes bedGraph files of structure signal for each of the six
#' CapR contexts 1) mapped to the genome and 2) lifted-over to the transcriptome
#'
#' @examples
#' ## make chain file
#' load(system.file("extdata/transcript_list.Rda", package="nearBynding"))
#' gtf<-system.file("extdata/Homo_sapiens.GRCh38.chr4&5.gtf",
#' package="nearBynding")
#' GenomeMappingToChainFile(genome_gtf = gtf,
#' out_chain_name = "test.chain",
#' RNA_fragment = "three_prime_utr",
#' transcript_list = transcript_list,
#' alignment = "hg38")
#' ## get chromosome size file
#' getChainChrSize(chain = "test.chain",
#' out_chr = "chr4and5_3UTR.size")
#'
#' processCapRout(CapR_outfile = system.file("extdata/chr4and5_3UTR.out",
#' package="nearBynding"),
#' chain = "test.chain",
#' output_prefix = "chr4and5_3UTR",
#' chrom_size = "chr4and5_3UTR.size",
#' genome_gtf = gtf,
#' RNA_fragment = "three_prime_utr")
#'
#' @importFrom magrittr '%>%'
#' @importFrom utils read.delim
#' @importFrom S4Vectors elementMetadata
#' @importFrom GenomicRanges makeGRangesFromDataFrame
#' @importFrom BiocGenerics strand type
#'
#' @export
processCapRout <- function(CapR_outfile,
output_prefix,
chrom_size,
genome_gtf,
RNA_fragment,
chain) {
folded_transcripts_appended <- readLines(CapR_outfile)
transcript_names <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 1) == ">"
)]
transcript_names <- lapply(transcript_names, function(x) {
substr(x, 2, nchar(x))
}) %>% unlist()
bulge <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 5) == "Bulge"
)]
exterior <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 8) == "Exterior"
)]
hairpin <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 7) == "Hairpin"
)]
internal <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 8) == "Internal"
)]
multibranch <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 11) == "Multibranch"
)]
stem <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 4) == "Stem"
)]
cut_transcripts <- function(x) {
transcript <- strsplit(x, " ") %>% unlist()
transcript <- transcript[2:length(transcript)]
return(transcript)
}
bulge_cut <- lapply(bulge, cut_transcripts) %>% unlist()
exterior_cut <- lapply(exterior, cut_transcripts) %>% unlist()
hairpin_cut <- lapply(hairpin, cut_transcripts) %>% unlist()
internal_cut <- lapply(internal, cut_transcripts) %>% unlist()
multibranch_cut <- lapply(multibranch, cut_transcripts) %>% unlist()
stem_cut <- lapply(stem, cut_transcripts) %>% unlist()
# double check that transcriptome length total (chr size file)
# equals number of folded transcript positions
chr_size <- read.delim(chrom_size, header = FALSE)
if (sum(chr_size$V2) - length(bulge_cut) != 0) {
stop("The length of the CapR output does not equal the length of
chromosome size. Make sure that the input chromosome size
corresponds to the folded CapR transcripts.")
}
gtf <- import(genome_gtf)
gtf <- with(gtf, plyranges::filter(gtf, type == RNA_fragment))
# write bedgraph file for each transcript
# create bedGraph for each structure separately
bg_shell <- as.data.frame(matrix(NA, ncol = 4, nrow = sum(chr_size$V2)))
colnames(bg_shell) <- c("chr", "start", "end", "score")
n <- 1
for (t in transcript_names) {
gtf_t <- gtf[(elementMetadata(gtf)[, "transcript_id"] == t)]
bg_shell[n:(n + sum(gtf_t@ranges@width) - 1), "chr"] <-
gtf_t@seqnames@values %>% as.character()
if (gtf_t@strand@values[1] == "+") {
for (unit in seq_len(length(gtf_t))) {
gtf_t_unit <- gtf_t[unit]
bg_shell[n:(n + gtf_t_unit@ranges@width - 1), "start"] <-
gtf_t_unit@ranges@start:(gtf_t_unit@ranges@start +
gtf_t_unit@ranges@width - 1)
n <- n + gtf_t_unit@ranges@width
}
} else {
for (unit in length(gtf_t):1) {
gtf_t_unit <- gtf_t[unit]
bg_shell[n:(n + gtf_t_unit@ranges@width - 1), "start"] <-
rev(gtf_t_unit@ranges@start:(gtf_t_unit@ranges@start +
gtf_t_unit@ranges@width - 1))
n <- n + gtf_t_unit@ranges@width
}
}
}
bg_shell$end <- bg_shell$start
if (nchar(bg_shell[1, "chr"]) < 3) {
bg_shell$chr <- paste0("chr", bg_shell$chr)
}
# bulge
df_bulge <- bg_shell
df_bulge$score <- bulge_cut %>% as.numeric()
GRanges_bulge <- makeGRangesFromDataFrame(df_bulge,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_bulge, paste0(output_prefix,"_bulge.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix,"_bulge.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix, "_bulge_liftOver.bedGraph"))
# exterior
df_exterior <- bg_shell
df_exterior$score <- exterior_cut %>% as.numeric()
GRanges_exterior <- makeGRangesFromDataFrame(df_exterior,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_exterior,paste0(output_prefix,"_exterior.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix,"_exterior.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0( output_prefix,"_exterior_liftOver.bedGraph"))
# hairpin
df_hairpin <- bg_shell
df_hairpin$score <- hairpin_cut %>% as.numeric()
GRanges_hairpin <- makeGRangesFromDataFrame(df_hairpin,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_hairpin, paste0(output_prefix,"_hairpin.bedGraph"))
liftOverToExomicBG(input = paste0( output_prefix,"_hairpin.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix,"_hairpin_liftOver.bedGraph"))
# internal
df_internal <- bg_shell
df_internal$score <- internal_cut %>% as.numeric()
GRanges_internal <- makeGRangesFromDataFrame(df_internal,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_internal,paste0(output_prefix,"_internal.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix,"_internal.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix,"_internal_liftOver.bedGraph"))
# multibranch
df_multibranch <- bg_shell
df_multibranch$score <- multibranch_cut %>% as.numeric()
GRanges_multibranch <- makeGRangesFromDataFrame(df_multibranch,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_multibranch, paste0(output_prefix,
"_multibranch.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix, "_multibranch.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix,"_multibranch_liftOver.bedGraph"))
# stem
df_stem <- bg_shell
df_stem$score <- stem_cut %>% as.numeric()
GRanges_stem <- makeGRangesFromDataFrame(df_stem,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_stem, paste0(output_prefix,"_stem.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix,"_stem.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix,"_stem_liftOver.bedGraph"))
}
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nearBynding documentation built on Nov. 8, 2020, 8:15 p.m.
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Defines functions processCapRout
Documented in processCapRout
#' @title processCapRout
#'
#' @description Creates context-separated bedGraph files of CapR output for
#' genome and transcriptome alignments.
#'
#' @param CapR_outfile Name of CapR output file. Required
#' @param output_prefix Prefix string to be appended to all output files.
#' Required.
#' @param chrom_size Name of chromosome size file. File must be in two-column
#' format without a header where first column is chromosome name and second
#' column is chromosome length, as from getChainChrSize. Required.
#' @param genome_gtf The name of the GTF/GFF file that contains all exome
#' annotations. Required
#' @param RNA_fragment RNA component of interest. Options depend on the gtf
#' file but often include "gene", "transcript", "exon", "CDS", "five_prime_utr",
#' and/or "three_prime_utr". Default "exon" for the whole exome.
#' @param chain The name of the chain file to be used. Format should be like
#' chain files derived from GRangesMappingToChainFile. Required
#'
#' @return writes bedGraph files of structure signal for each of the six
#' CapR contexts 1) mapped to the genome and 2) lifted-over to the transcriptome
#'
#' @examples
#' ## make chain file
#' load(system.file("extdata/transcript_list.Rda", package="nearBynding"))
#' gtf<-system.file("extdata/Homo_sapiens.GRCh38.chr4&5.gtf",
#' package="nearBynding")
#' GenomeMappingToChainFile(genome_gtf = gtf,
#' out_chain_name = "test.chain",
#' RNA_fragment = "three_prime_utr",
#' transcript_list = transcript_list,
#' alignment = "hg38")
#' ## get chromosome size file
#' getChainChrSize(chain = "test.chain",
#' out_chr = "chr4and5_3UTR.size")
#'
#' processCapRout(CapR_outfile = system.file("extdata/chr4and5_3UTR.out",
#' package="nearBynding"),
#' chain = "test.chain",
#' output_prefix = "chr4and5_3UTR",
#' chrom_size = "chr4and5_3UTR.size",
#' genome_gtf = gtf,
#' RNA_fragment = "three_prime_utr")
#'
#' @importFrom magrittr '%>%'
#' @importFrom utils read.delim
#' @importFrom S4Vectors elementMetadata
#' @importFrom GenomicRanges makeGRangesFromDataFrame
#' @importFrom BiocGenerics strand type
#'
#' @export
processCapRout <- function(CapR_outfile,
output_prefix,
chrom_size,
genome_gtf,
RNA_fragment,
chain) {
folded_transcripts_appended <- readLines(CapR_outfile)
transcript_names <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 1) == ">"
)]
transcript_names <- lapply(transcript_names, function(x) {
substr(x, 2, nchar(x))
}) %>% unlist()
bulge <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 5) == "Bulge"
)]
exterior <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 8) == "Exterior"
)]
hairpin <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 7) == "Hairpin"
)]
internal <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 8) == "Internal"
)]
multibranch <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 11) == "Multibranch"
)]
stem <- folded_transcripts_appended[which(
substr(folded_transcripts_appended, 1, 4) == "Stem"
)]
cut_transcripts <- function(x) {
transcript <- strsplit(x, " ") %>% unlist()
transcript <- transcript[2:length(transcript)]
return(transcript)
}
bulge_cut <- lapply(bulge, cut_transcripts) %>% unlist()
exterior_cut <- lapply(exterior, cut_transcripts) %>% unlist()
hairpin_cut <- lapply(hairpin, cut_transcripts) %>% unlist()
internal_cut <- lapply(internal, cut_transcripts) %>% unlist()
multibranch_cut <- lapply(multibranch, cut_transcripts) %>% unlist()
stem_cut <- lapply(stem, cut_transcripts) %>% unlist()
# double check that transcriptome length total (chr size file)
# equals number of folded transcript positions
chr_size <- read.delim(chrom_size, header = FALSE)
if (sum(chr_size$V2) - length(bulge_cut) != 0) {
stop("The length of the CapR output does not equal the length of
chromosome size. Make sure that the input chromosome size
corresponds to the folded CapR transcripts.")
}
gtf <- import(genome_gtf)
gtf <- with(gtf, plyranges::filter(gtf, type == RNA_fragment))
# write bedgraph file for each transcript
# create bedGraph for each structure separately
bg_shell <- as.data.frame(matrix(NA, ncol = 4, nrow = sum(chr_size$V2)))
colnames(bg_shell) <- c("chr", "start", "end", "score")
n <- 1
for (t in transcript_names) {
gtf_t <- gtf[(elementMetadata(gtf)[, "transcript_id"] == t)]
bg_shell[n:(n + sum(gtf_t@ranges@width) - 1), "chr"] <-
gtf_t@seqnames@values %>% as.character()
if (gtf_t@strand@values[1] == "+") {
for (unit in seq_len(length(gtf_t))) {
gtf_t_unit <- gtf_t[unit]
bg_shell[n:(n + gtf_t_unit@ranges@width - 1), "start"] <-
gtf_t_unit@ranges@start:(gtf_t_unit@ranges@start +
gtf_t_unit@ranges@width - 1)
n <- n + gtf_t_unit@ranges@width
}
} else {
for (unit in length(gtf_t):1) {
gtf_t_unit <- gtf_t[unit]
bg_shell[n:(n + gtf_t_unit@ranges@width - 1), "start"] <-
rev(gtf_t_unit@ranges@start:(gtf_t_unit@ranges@start +
gtf_t_unit@ranges@width - 1))
n <- n + gtf_t_unit@ranges@width
}
}
}
bg_shell$end <- bg_shell$start
if (nchar(bg_shell[1, "chr"]) < 3) {
bg_shell$chr <- paste0("chr", bg_shell$chr)
}
# bulge
df_bulge <- bg_shell
df_bulge$score <- bulge_cut %>% as.numeric()
GRanges_bulge <- makeGRangesFromDataFrame(df_bulge,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_bulge, paste0(output_prefix,"_bulge.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix,"_bulge.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix, "_bulge_liftOver.bedGraph"))
# exterior
df_exterior <- bg_shell
df_exterior$score <- exterior_cut %>% as.numeric()
GRanges_exterior <- makeGRangesFromDataFrame(df_exterior,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_exterior,paste0(output_prefix,"_exterior.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix,"_exterior.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0( output_prefix,"_exterior_liftOver.bedGraph"))
# hairpin
df_hairpin <- bg_shell
df_hairpin$score <- hairpin_cut %>% as.numeric()
GRanges_hairpin <- makeGRangesFromDataFrame(df_hairpin,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_hairpin, paste0(output_prefix,"_hairpin.bedGraph"))
liftOverToExomicBG(input = paste0( output_prefix,"_hairpin.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix,"_hairpin_liftOver.bedGraph"))
# internal
df_internal <- bg_shell
df_internal$score <- internal_cut %>% as.numeric()
GRanges_internal <- makeGRangesFromDataFrame(df_internal,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_internal,paste0(output_prefix,"_internal.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix,"_internal.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix,"_internal_liftOver.bedGraph"))
# multibranch
df_multibranch <- bg_shell
df_multibranch$score <- multibranch_cut %>% as.numeric()
GRanges_multibranch <- makeGRangesFromDataFrame(df_multibranch,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_multibranch, paste0(output_prefix,
"_multibranch.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix, "_multibranch.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix,"_multibranch_liftOver.bedGraph"))
# stem
df_stem <- bg_shell
df_stem$score <- stem_cut %>% as.numeric()
GRanges_stem <- makeGRangesFromDataFrame(df_stem,
keep.extra.columns = TRUE)
export.bedGraph(GRanges_stem, paste0(output_prefix,"_stem.bedGraph"))
liftOverToExomicBG(input = paste0(output_prefix,"_stem.bedGraph"),
chrom_size = chrom_size,
chain = chain,
output_bg = paste0(output_prefix,"_stem_liftOver.bedGraph"))
}
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