R/readQueryFile.R
In betsig/branchpointer: Prediction of intronic splicing branchpoints
Defines functions
readQueryFile
getQueryLoc
getExonDists
exonsToIntrons
Documented in
exonsToIntrons
getExonDists
getQueryLoc
readQueryFile
#' Convert exon annotation GRanges to intron locations
#'
#' Converts exon annotation to intron locations overlapping the branchpoint region
#' for exculsion of non-branchpoint region SNPs
#' Returns a character vector of chromosome locations
#' @param exons GRanges containing exon co-ordinates.
#' Should be produced by gtfToExons()
#' @param maxDist Maximum distance from the 3' exon to create the branchpoint region.
#' @return GRanges containing intron window co-ordinates
#' @import GenomicRanges
#' @keywords internal
#' @author Beth Signal
exonsToIntrons <- function(exons, maxDist = 50){
introns <- exons
posInd <- which(as.logical(strand(exons) == "+"))
start(introns[posInd]) <- start(introns[posInd]) - (maxDist + 1)
end(introns[posInd]) <- start(introns[posInd]) + maxDist
negInd <- which(as.logical(strand(exons) == "-"))
end(introns[negInd]) <- end(introns[negInd]) + (maxDist + 1)
start(introns[negInd]) <- end(introns[negInd]) - maxDist
return(introns)
}
#' Get the closest 3' and 5' exons
#'
#' Finds the closest annotated exons from a genomic co-ordinate.
#' Returns the distance to the 3' exon, distance to the 5' exon,
#' ids of the 3' and 5' exon,
#' and if the exons are from the same parent gene
#' @param query GenomicRangesquery
#' @param exons GenomicRanges containing exon co-ordinates.
#' Should be produced by gtfToExons()
#' @param queryType type of query. "SNP" or "region"
#' @return GenomicRanges with distance to the closest 3' and 5' exons,
#' whether these exons are part of the same gene (i.e is the location intronic),
#' and the identifiers for the 3' and 5' exons.
#' @import GenomicRanges
#' @keywords internal
#' @author Beth Signal
getExonDists <- function(query, exons, queryType){
# if using regions, region start will be used for negative strand queries
# & region end for positive strand queries
negInd <- which(as.logical(strand(query) == '-'))
posInd <- which(as.logical(strand(query) == '+'))
queryPoint <- query
width(ranges(queryPoint))[negInd] <- 1
end <- end(ranges(queryPoint))[posInd]
start(ranges(queryPoint[posInd])) <- end
width(ranges(queryPoint[posInd])) <- 1
f <- GenomicRanges::follow(queryPoint,exons)
gene5 <- exons$gene_id[f]
exon5 <- exons$exon_id[f]
keep <- which(!is.na(f))
f <- f[keep]
to5prime <- rep(NA, length(queryPoint))
to5prime[keep] <- GenomicRanges::distance(queryPoint[keep],exons[f]) + 1
p <- GenomicRanges::precede(queryPoint, exons)
gene3 <- exons$gene_id[p]
exon3 <- exons$exon_id[p]
keep <- which(!is.na(p))
p <- p[keep]
to3prime <- rep(NA, length(queryPoint))
to3prime[keep] <- GenomicRanges::distance(queryPoint[keep],exons[p]) + 1
sameGene <- gene3 == gene5
query$to_3prime <- to3prime
query$to_5prime <- to5prime
query$same_gene <- sameGene
query$exon_3prime <- exon3
query$exon_5prime <- exon5
return(query)
}
#' Find the closest 3' and 5' exons to a branchpointer query
#'
#' Finds the closest annotated exons from genomic co-ordinates in a branchpointer query GRanges
#' @param query branchpointer query GenomicRanges
#' must have chromosome at position 2, genomic co-ordinate at position 3,
#' and strand at position 4.
#' @param queryType type of query file (\code{"SNP"} or \code{"region"})
#' @param exons data.frame containing exon co-ordinates.
#' Should be produced by gtfToExons()
#' @param maxDist maximum distance a SNP can be from an annotated 3' exon.
#' @param filter remove SNP queries prior to finding finding nearest exons.
#' @return GenomicRanges with the query and its location relative to the 3' and 5' exons
#' @keywords internal
#' @import GenomicRanges
#' @author Beth Signal
getQueryLoc <- function(query, queryType, maxDist=50, filter=TRUE, exons){
if(missing(queryType) | !(queryType %in% c("SNP", "region"))){
stop("please specify queryType as \"region\" or \"SNP\"")
}
if(missing(exons)){
stop("please specify exon annotation object")
}
if(queryType=="SNP"){
if(filter){
message("filtering for SNPs in branchpoint windows")
introns <- exonsToIntrons(exons, maxDist)
o <- GenomicRanges::findOverlaps(query, introns)
keep <- unique(o@from)
query <- query[keep]
}
}
nearestExons <- getExonDists(query, exons, queryType)
#remove any points not in same gene
rm <- which(nearestExons$same_gene == FALSE |
is.na(nearestExons$exon_3prime) |
is.na(nearestExons$exon_5prime))
if(length(rm) > 0){
nearestExons <- nearestExons[-rm]
}
if(queryType=="region"){
#if introns regions are closer to the 3'SS than the branchpoint region
# move the region to cover the window of the nearest exon
near3 <- which(nearestExons$to_3prime < 18)
if(length(near3) > 0){
addDistance <- 18 - nearestExons$to_3prime[near3]
negStrand <- which(as.logical(strand(nearestExons)[near3] == "-"))
posStrand <- which(as.logical(strand(nearestExons)[near3] == "+"))
if(length(negStrand) > 0){
start(ranges(nearestExons))[near3][negStrand] <-
start(ranges(nearestExons))[near3][negStrand] + addDistance[negStrand]
}
if(length(posStrand) > 0){
end(ranges(nearestExons))[near3][posStrand] <-
end(ranges(nearestExons))[near3][posStrand] - addDistance[posStrand]
}
}
#if introns regions are further from the 3'SS than the branchpoint region
notNear3 <- which(nearestExons$to_3prime > 44)
if(length(notNear3) > 0){
nearestExons <- nearestExons[-notNear3]
}
nearestExons <- getExonDists(nearestExons,exons,queryType)
#adjust query location to only cover the 27nt window
#negStrand -- move end
negStrand <- which(as.logical(strand(nearestExons) == "-"))
if(length(negStrand) > 0){
end(ranges(nearestExons[negStrand])) <-
start(ranges(nearestExons[negStrand])) -
nearestExons$to_3prime[negStrand] + 44
}
#posStrand -- move start
posStrand <- which(as.logical(strand(nearestExons) == "+"))
if(length(posStrand) > 0){
start(ranges(nearestExons[posStrand])) <-
end(ranges(nearestExons[posStrand])) +
nearestExons$to_3prime[posStrand] - 44
}
}else if(queryType=="SNP"){
#if a 5' or 3' exon can't be found remove from analysis
rm <- which(nearestExons$to_3prime==-1 | nearestExons$to_5prime==-1)
if(length(rm) > 0){
nearestExons <- nearestExons[-rm,]
}
rm <- which(nearestExons$to_3prime > maxDist)
if(length(rm) > 0){
nearestExons <- nearestExons[-rm,]
}
#check both exons come from the same parent gene
#(i.e query is in intronic region)
rm <- which(!(nearestExons$same_gene))
if(length(rm) > 0){
nearestExons <- nearestExons[-rm,]
}
}
return(nearestExons)
}
#' Read a query file
#'
#' Reads and formats a manually generated query file, and finds realtive locations of the closest annotated exons
#' Converts unstranded SNPs to two entries for each strand.
#' Checks for duplicate names and replaces if found.
#' @param queryFile tab delimited file containing query information.
#' For intronic regions should be in the format: region id, chromosome name, region start, region end, strand.
#' For SNP variants should be in the format: SNP id, chromosome name, SNP position, strand, reference allele (A/T/C/G), alternative allele (A/T/C/G)
#' @param queryType type of query file (\code{"SNP"} or \code{"region"})
#' @param exons GRanges containing exon co-ordinates.
#' Should be produced by gtfToExons()
#' @param maxDist maximum distance a SNP can be from an annotated 3' exon.
#' @param filter remove SNP queries prior to finding finding nearest exons.
#' @return Formatted query GRanges
#' @export
#' @import GenomicRanges
#' @importFrom data.table fread
#' @importClassesFrom data.table data.table
#' @importFrom S4Vectors Rle
#' @importFrom IRanges IRanges
#' @examples
#' smallExons <- system.file("extdata","gencode.v26.annotation.small.gtf", package = "branchpointer")
#' exons <- gtfToExons(smallExons)
#'
#' querySNPFile <- system.file("extdata","SNP_example.txt", package = "branchpointer")
#' querySNP <- readQueryFile(querySNPFile, queryType = "SNP", exons)
#'
#' queryIntronFile <- system.file("extdata","intron_example.txt", package = "branchpointer")
#' queryIntron <- readQueryFile(queryIntronFile,queryType = "region", exons)
#' @author Beth Signal
readQueryFile <- function(queryFile, queryType, exons, maxDist=50, filter=TRUE){
if(missing(queryType)){
queryTest <- data.table::fread(
queryFile,header = TRUE,
nrows=1)
if(ncol(queryTest) == 5){
queryType <- "region"
message("first line of file has 5 columns")
message("using query_type = \"region\"")
}else if(ncol(queryTest) == 6){
queryType <- "SNP"
message("first line of file has 6 columns")
message("using query_type = \"SNP\"")
}else{
stop("please specify query_type and provide correctly formatted file")
}
}
if (!(queryType %in% c("SNP", "region"))) {
message("please specify query_type as \"region\" or \"SNP\"")
}else{
if (queryType == "SNP") {
query <- data.table::fread(
queryFile,header = TRUE,
colClasses = c(
"character", "character", "numeric",
"character", "character", "character"
), data.table=FALSE)
colnames(query)[1:6] <-
c("id", "chromosome","chrom_start","strand","ref_allele", "alt_allele")
#check single nts
query$ref_allele <- toupper(query$ref_allele)
query$alt_allele <- toupper(query$alt_allele)
#check for unstranded queries & replace with positive & negative
unstranded <- which(query$strand != "+" | query$strand != "-")
if (length(unstranded) > 0) {
query.pos <- query[unstranded,]
query.pos$id <- paste0(query.pos$id, "_pos")
query.pos$strand <- "+"
query.neg <- query[unstranded,]
query.neg$id <- paste0(query.neg$id, "_neg")
query.neg$strand <- "-"
query <- rbind(query[-unstranded,], query.pos,query.neg)
}
queryGRanges <- GRanges(seqnames=S4Vectors::Rle(query$chromosome),
ranges=IRanges::IRanges(start=query$chrom_start, width=1),
strand=query$strand,
id=query$id,
ref_allele=query$ref_allele,
alt_allele=query$alt_allele)
}else if (queryType == "region") {
query <- data.table::fread(
queryFile, header = TRUE,colClasses = c(
"character","character","numeric","numeric","character"
), data.table=FALSE)
colnames(query) <-
c("id","chromosome","chrom_start","chrom_end","strand")
queryGRanges <- GenomicRanges::GRanges(
seqnames = S4Vectors::Rle(query$chromosome),
ranges = IRanges::IRanges(start = query$chrom_start,
end = query$chrom_end),
strand = query$strand,
id = query$id)
}
#check for duplicated query ids
if (any(duplicated(queryGRanges$id))) {
message(paste0(length(which(
duplicated(queryGRanges$id)
))," query ids are not unique"))
message("Check output for new names or rename")
queryGRanges$id = make.names(queryGRanges$id, unique = TRUE)
}
#find 3'/5'exons
if(length(queryGRanges) > 0){
queryGRanges.loc <- getQueryLoc(queryGRanges, queryType, maxDist = maxDist, filter = filter,
exons = exons)
return(queryGRanges.loc)
}
}
}
betsig/branchpointer documentation built on Sept. 27, 2021, 10:31 p.m.
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Defines functions readQueryFile getQueryLoc getExonDists exonsToIntrons
Documented in exonsToIntrons getExonDists getQueryLoc readQueryFile
#' Convert exon annotation GRanges to intron locations
#'
#' Converts exon annotation to intron locations overlapping the branchpoint region
#' for exculsion of non-branchpoint region SNPs
#' Returns a character vector of chromosome locations
#' @param exons GRanges containing exon co-ordinates.
#' Should be produced by gtfToExons()
#' @param maxDist Maximum distance from the 3' exon to create the branchpoint region.
#' @return GRanges containing intron window co-ordinates
#' @import GenomicRanges
#' @keywords internal
#' @author Beth Signal
exonsToIntrons <- function(exons, maxDist = 50){
introns <- exons
posInd <- which(as.logical(strand(exons) == "+"))
start(introns[posInd]) <- start(introns[posInd]) - (maxDist + 1)
end(introns[posInd]) <- start(introns[posInd]) + maxDist
negInd <- which(as.logical(strand(exons) == "-"))
end(introns[negInd]) <- end(introns[negInd]) + (maxDist + 1)
start(introns[negInd]) <- end(introns[negInd]) - maxDist
return(introns)
}
#' Get the closest 3' and 5' exons
#'
#' Finds the closest annotated exons from a genomic co-ordinate.
#' Returns the distance to the 3' exon, distance to the 5' exon,
#' ids of the 3' and 5' exon,
#' and if the exons are from the same parent gene
#' @param query GenomicRangesquery
#' @param exons GenomicRanges containing exon co-ordinates.
#' Should be produced by gtfToExons()
#' @param queryType type of query. "SNP" or "region"
#' @return GenomicRanges with distance to the closest 3' and 5' exons,
#' whether these exons are part of the same gene (i.e is the location intronic),
#' and the identifiers for the 3' and 5' exons.
#' @import GenomicRanges
#' @keywords internal
#' @author Beth Signal
getExonDists <- function(query, exons, queryType){
# if using regions, region start will be used for negative strand queries
# & region end for positive strand queries
negInd <- which(as.logical(strand(query) == '-'))
posInd <- which(as.logical(strand(query) == '+'))
queryPoint <- query
width(ranges(queryPoint))[negInd] <- 1
end <- end(ranges(queryPoint))[posInd]
start(ranges(queryPoint[posInd])) <- end
width(ranges(queryPoint[posInd])) <- 1
f <- GenomicRanges::follow(queryPoint,exons)
gene5 <- exons$gene_id[f]
exon5 <- exons$exon_id[f]
keep <- which(!is.na(f))
f <- f[keep]
to5prime <- rep(NA, length(queryPoint))
to5prime[keep] <- GenomicRanges::distance(queryPoint[keep],exons[f]) + 1
p <- GenomicRanges::precede(queryPoint, exons)
gene3 <- exons$gene_id[p]
exon3 <- exons$exon_id[p]
keep <- which(!is.na(p))
p <- p[keep]
to3prime <- rep(NA, length(queryPoint))
to3prime[keep] <- GenomicRanges::distance(queryPoint[keep],exons[p]) + 1
sameGene <- gene3 == gene5
query$to_3prime <- to3prime
query$to_5prime <- to5prime
query$same_gene <- sameGene
query$exon_3prime <- exon3
query$exon_5prime <- exon5
return(query)
}
#' Find the closest 3' and 5' exons to a branchpointer query
#'
#' Finds the closest annotated exons from genomic co-ordinates in a branchpointer query GRanges
#' @param query branchpointer query GenomicRanges
#' must have chromosome at position 2, genomic co-ordinate at position 3,
#' and strand at position 4.
#' @param queryType type of query file (\code{"SNP"} or \code{"region"})
#' @param exons data.frame containing exon co-ordinates.
#' Should be produced by gtfToExons()
#' @param maxDist maximum distance a SNP can be from an annotated 3' exon.
#' @param filter remove SNP queries prior to finding finding nearest exons.
#' @return GenomicRanges with the query and its location relative to the 3' and 5' exons
#' @keywords internal
#' @import GenomicRanges
#' @author Beth Signal
getQueryLoc <- function(query, queryType, maxDist=50, filter=TRUE, exons){
if(missing(queryType) | !(queryType %in% c("SNP", "region"))){
stop("please specify queryType as \"region\" or \"SNP\"")
}
if(missing(exons)){
stop("please specify exon annotation object")
}
if(queryType=="SNP"){
if(filter){
message("filtering for SNPs in branchpoint windows")
introns <- exonsToIntrons(exons, maxDist)
o <- GenomicRanges::findOverlaps(query, introns)
keep <- unique(o@from)
query <- query[keep]
}
}
nearestExons <- getExonDists(query, exons, queryType)
#remove any points not in same gene
rm <- which(nearestExons$same_gene == FALSE |
is.na(nearestExons$exon_3prime) |
is.na(nearestExons$exon_5prime))
if(length(rm) > 0){
nearestExons <- nearestExons[-rm]
}
if(queryType=="region"){
#if introns regions are closer to the 3'SS than the branchpoint region
# move the region to cover the window of the nearest exon
near3 <- which(nearestExons$to_3prime < 18)
if(length(near3) > 0){
addDistance <- 18 - nearestExons$to_3prime[near3]
negStrand <- which(as.logical(strand(nearestExons)[near3] == "-"))
posStrand <- which(as.logical(strand(nearestExons)[near3] == "+"))
if(length(negStrand) > 0){
start(ranges(nearestExons))[near3][negStrand] <-
start(ranges(nearestExons))[near3][negStrand] + addDistance[negStrand]
}
if(length(posStrand) > 0){
end(ranges(nearestExons))[near3][posStrand] <-
end(ranges(nearestExons))[near3][posStrand] - addDistance[posStrand]
}
}
#if introns regions are further from the 3'SS than the branchpoint region
notNear3 <- which(nearestExons$to_3prime > 44)
if(length(notNear3) > 0){
nearestExons <- nearestExons[-notNear3]
}
nearestExons <- getExonDists(nearestExons,exons,queryType)
#adjust query location to only cover the 27nt window
#negStrand -- move end
negStrand <- which(as.logical(strand(nearestExons) == "-"))
if(length(negStrand) > 0){
end(ranges(nearestExons[negStrand])) <-
start(ranges(nearestExons[negStrand])) -
nearestExons$to_3prime[negStrand] + 44
}
#posStrand -- move start
posStrand <- which(as.logical(strand(nearestExons) == "+"))
if(length(posStrand) > 0){
start(ranges(nearestExons[posStrand])) <-
end(ranges(nearestExons[posStrand])) +
nearestExons$to_3prime[posStrand] - 44
}
}else if(queryType=="SNP"){
#if a 5' or 3' exon can't be found remove from analysis
rm <- which(nearestExons$to_3prime==-1 | nearestExons$to_5prime==-1)
if(length(rm) > 0){
nearestExons <- nearestExons[-rm,]
}
rm <- which(nearestExons$to_3prime > maxDist)
if(length(rm) > 0){
nearestExons <- nearestExons[-rm,]
}
#check both exons come from the same parent gene
#(i.e query is in intronic region)
rm <- which(!(nearestExons$same_gene))
if(length(rm) > 0){
nearestExons <- nearestExons[-rm,]
}
}
return(nearestExons)
}
#' Read a query file
#'
#' Reads and formats a manually generated query file, and finds realtive locations of the closest annotated exons
#' Converts unstranded SNPs to two entries for each strand.
#' Checks for duplicate names and replaces if found.
#' @param queryFile tab delimited file containing query information.
#' For intronic regions should be in the format: region id, chromosome name, region start, region end, strand.
#' For SNP variants should be in the format: SNP id, chromosome name, SNP position, strand, reference allele (A/T/C/G), alternative allele (A/T/C/G)
#' @param queryType type of query file (\code{"SNP"} or \code{"region"})
#' @param exons GRanges containing exon co-ordinates.
#' Should be produced by gtfToExons()
#' @param maxDist maximum distance a SNP can be from an annotated 3' exon.
#' @param filter remove SNP queries prior to finding finding nearest exons.
#' @return Formatted query GRanges
#' @export
#' @import GenomicRanges
#' @importFrom data.table fread
#' @importClassesFrom data.table data.table
#' @importFrom S4Vectors Rle
#' @importFrom IRanges IRanges
#' @examples
#' smallExons <- system.file("extdata","gencode.v26.annotation.small.gtf", package = "branchpointer")
#' exons <- gtfToExons(smallExons)
#'
#' querySNPFile <- system.file("extdata","SNP_example.txt", package = "branchpointer")
#' querySNP <- readQueryFile(querySNPFile, queryType = "SNP", exons)
#'
#' queryIntronFile <- system.file("extdata","intron_example.txt", package = "branchpointer")
#' queryIntron <- readQueryFile(queryIntronFile,queryType = "region", exons)
#' @author Beth Signal
readQueryFile <- function(queryFile, queryType, exons, maxDist=50, filter=TRUE){
if(missing(queryType)){
queryTest <- data.table::fread(
queryFile,header = TRUE,
nrows=1)
if(ncol(queryTest) == 5){
queryType <- "region"
message("first line of file has 5 columns")
message("using query_type = \"region\"")
}else if(ncol(queryTest) == 6){
queryType <- "SNP"
message("first line of file has 6 columns")
message("using query_type = \"SNP\"")
}else{
stop("please specify query_type and provide correctly formatted file")
}
}
if (!(queryType %in% c("SNP", "region"))) {
message("please specify query_type as \"region\" or \"SNP\"")
}else{
if (queryType == "SNP") {
query <- data.table::fread(
queryFile,header = TRUE,
colClasses = c(
"character", "character", "numeric",
"character", "character", "character"
), data.table=FALSE)
colnames(query)[1:6] <-
c("id", "chromosome","chrom_start","strand","ref_allele", "alt_allele")
#check single nts
query$ref_allele <- toupper(query$ref_allele)
query$alt_allele <- toupper(query$alt_allele)
#check for unstranded queries & replace with positive & negative
unstranded <- which(query$strand != "+" | query$strand != "-")
if (length(unstranded) > 0) {
query.pos <- query[unstranded,]
query.pos$id <- paste0(query.pos$id, "_pos")
query.pos$strand <- "+"
query.neg <- query[unstranded,]
query.neg$id <- paste0(query.neg$id, "_neg")
query.neg$strand <- "-"
query <- rbind(query[-unstranded,], query.pos,query.neg)
}
queryGRanges <- GRanges(seqnames=S4Vectors::Rle(query$chromosome),
ranges=IRanges::IRanges(start=query$chrom_start, width=1),
strand=query$strand,
id=query$id,
ref_allele=query$ref_allele,
alt_allele=query$alt_allele)
}else if (queryType == "region") {
query <- data.table::fread(
queryFile, header = TRUE,colClasses = c(
"character","character","numeric","numeric","character"
), data.table=FALSE)
colnames(query) <-
c("id","chromosome","chrom_start","chrom_end","strand")
queryGRanges <- GenomicRanges::GRanges(
seqnames = S4Vectors::Rle(query$chromosome),
ranges = IRanges::IRanges(start = query$chrom_start,
end = query$chrom_end),
strand = query$strand,
id = query$id)
}
#check for duplicated query ids
if (any(duplicated(queryGRanges$id))) {
message(paste0(length(which(
duplicated(queryGRanges$id)
))," query ids are not unique"))
message("Check output for new names or rename")
queryGRanges$id = make.names(queryGRanges$id, unique = TRUE)
}
#find 3'/5'exons
if(length(queryGRanges) > 0){
queryGRanges.loc <- getQueryLoc(queryGRanges, queryType, maxDist = maxDist, filter = filter,
exons = exons)
return(queryGRanges.loc)
}
}
}
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