Nothing
R/metaGene.R
In groHMM: GRO-seq Analysis Pipeline
Defines functions
averagePlot
metaGene_nL
metaGeneMatrix_foreachChrom
metaGeneMatrix
samplingMetaGene
runMetaGene
metaGene_foreachChrom
metaGene
Documented in
averagePlot
metaGene
metaGeneMatrix
metaGene_nL
runMetaGene
###########################################################################
##
## Copyright 2013, 2014 Charles Danko and Minho Chae.
##
## This program is part of the groHMM R package
##
## groHMM is free software: you can redistribute it and/or modify it
## under the terms of the GNU General Public License as published by
## the Free Software Foundation, either version 3 of the License, or
## (at your option) any later version.
##
## This program is distributed in the hope that it will be useful, but
## WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
## or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
## for more details.
##
## You should have received a copy of the GNU General Public License along
## with this program. If not, see <http://www.gnu.org/licenses/>.
##
##########################################################################
#' Returns a histogram of the number of reads in each section of a moving
#' window centered on a certain feature.
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, set the option 'mc.cores'.
#'
#' @param features A GRanges object representing a set of genomic coordinates.
#' The meta-plot will be centered on the transcription start site (TSS)
#' @param reads A GRanges object representing a set of mapped reads.
#' Instead of 'reads', 'plusCVG' and 'minusCVG' can be used Default: NULL
#' @param plusCVG An IntegerRangesList object for reads with '+' strand.
#' @param minusCVG An IntegerRangesList object for reads with '-' strand.
#' @param size The size of the moving window.
#' @param up Distance upstream of each features to align and histogram.
#' Default: 10 kb.
#' @param down Distance downstream of each features to align and histogram.
#' If NULL, same as up. Default: NULL.
#' @param ... Extra argument passed to mclapply
#' @return Returns a integer-Rle representing the 'typical' signal
#' centered on a point of interest.
#' @author Charles G. Danko and Minho Chae
#' @examples
#' features <- GRanges("chr7", IRanges(1000, 1000), strand="+")
#' reads <- GRanges("chr7", IRanges(start=c(1000:1004, 1100),
#' width=rep(1, 6)), strand="+")
#' mg <- metaGene(features, reads, size=4, up=10)
metaGene <- function(features, reads=NULL, plusCVG=NULL, minusCVG=NULL,
size=100L, up=10000L, down=NULL, ...) {
seqlevels(features) <- seqlevelsInUse(features)
# Check 'reads'
if (is.null(reads)) {
if (is.null(plusCVG) || is.null(minusCVG))
stop("Either 'reads' or 'plusCVG' and 'minusCVG' must be used")
} else {
seqlevels(reads) <- seqlevelsInUse(reads)
plusCVG <- coverage(reads[strand(reads)=="+",])
minusCVG <- coverage(reads[strand(reads)=="-",])
}
if (is.null(down)) down <- up
featureList <- split(features, seqnames(features))
H <- mclapply(seqlevels(features), metaGene_foreachChrom,
featureList=featureList, plusCVG=plusCVG, minusCVG=minusCVG,
size=size, up=up, down=down, ...)
M <- sapply(seq_len(length(H)), function(x) as.integer(H[[x]]))
return(Rle(apply(M, 1, sum)))
}
metaGene_foreachChrom <- function(chrom, featureList, plusCVG, minusCVG,
size, up, down) {
f <- featureList[[chrom]]
pCVG <- plusCVG[[chrom]]
mCVG <- minusCVG[[chrom]]
offset <- floor(size/2L)
pro <- promoters(f, upstream=up+offset, downstream=(down+offset-1L))
M <- sapply(1:length(pro), function(x) {
if (as.character(strand(pro)[x]) == "+")
as.integer(runsum(pCVG[start(pro)[x]:end(pro)[x]],
k=size))
else
as.integer(rev(runsum(mCVG[start(pro)[x]:end(pro)[x]],
k=size)))
})
return(Rle(apply(M, 1, sum)))
}
#' Runs metagene analysis for sense and antisense direction.
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, set the option 'mc.cores'.
#'
#' @param features GRanges A GRanges object representing a set of genomic
#' coordinates, i.e., set of genes.
#' @param reads GRanges of reads.
#' @param anchorType Either 'TSS' or 'TTS'. Metagene will be centered on the
#' transcription start site(TSS) or transcription termination site(TTS).
#' Default: TSS.
#' @param size Numeric. The size of the moving window. Default: 100L
#' @param normCounts Numeric. Normalization vector such as average reads.
#' Default: 1L
#' @param up Numeric. Distance upstream of each feature to align and histogram.
#' Default: 1 kb
#' @param down Numeric. Distance downstream of each feature to align and
#' histogram. If NULL, down is same as up. Default: NULL
#' @param sampling Logical. If TRUE, subsampling of Metagene is used.
#' Default: FALSE
#' @param nSampling Numeric. Number of subsampling. Default: 1000L
#' @param samplingRatio Numeric. Ratio of sampling for features. Default: 0.1
#' @param ... Extra argument passed to mclapply.
#' @return A list of integer-Rle for sense and antisene.
#' @author Minho Chae
#' @examples
#' features <- GRanges("chr7", IRanges(start=1000:1001, width=rep(1,2)),
#' strand=c("+", "-"))
#' reads <- GRanges("chr7", IRanges(start=c(1000:1003, 1100:1101),
#' width=rep(1, 6)), strand=rep(c("+","-"), 3))
#' ## Not run:
#' # mg <- runMetaGene(features, reads, size=4, up=10)
runMetaGene <- function(features, reads, anchorType="TSS", size=100L,
normCounts=1L, up=10000L, down=NULL, sampling=FALSE, nSampling=1000L,
samplingRatio=0.1, ...) {
# Check 'anchorType'
if (!anchorType %in% c("TSS", "TTS")) {
stop("'anchorType' must be either 'TSS' or 'TTS'")
}
if (anchorType == "TSS") {
f <- resize(features, width=1L, fix="start")
} else if (anchorType == "TTS") {
f <- resize(features, width=1L, fix="end")
}
if (is.null(down)) down <- up
fRev <- f
strand(fRev) <- rev(strand(f))
plusCVG <- coverage(reads[strand(reads)=="+",])
minusCVG <- coverage(reads[strand(reads)=="-",])
message("sense ... ", appendLF=FALSE)
if (sampling) {
sense <- samplingMetaGene(features=f, plusCVG=plusCVG,
minusCVG=minusCVG, size=size, up=up, down=down,
nSampling=nSampling, samplingRatio=samplingRatio, ...)
} else {
sense <- metaGene(features=f, plusCVG=plusCVG, minusCVG=minusCVG,
size=size, up=up, down=down, ...)
sense <- sense/length(features)
}
message("OK")
message("antisense ... ", appendLF=FALSE)
if (sampling) {
antisense <- samplingMetaGene(features=fRev, plusCVG=plusCVG,
minusCVG=minusCVG, size=size, up=up, down=down,
nSampling=nSampling, samplingRatio=samplingRatio, ...)
} else {
antisense <- metaGene(features=fRev, plusCVG=plusCVG, minusCVG=minusCVG,
size=size, up=up, down=down, ...)
antisense <- antisense/length(features)
}
message("OK")
sense <- sense*normCounts
antisense <- antisense*normCounts
return(list(sense=sense, antisense=antisense))
}
samplingMetaGene <- function(features, plusCVG, minusCVG, size=100L, up=10000L,
down=NULL, nSampling=1000L, samplingRatio=0.1, ...) {
samplingSize <- round(length(features)*samplingRatio)
metaList <- mclapply(1:length(features), function(x) {
metaGene(features=features[x,], plusCVG=plusCVG, minusCVG=minusCVG,
size=size, up=up, down=down)
}, ...)
allSamples <- mclapply(1:nSampling, function(x) {
inx <- sample(1:length(features), size=samplingSize, replace=TRUE)
onesample <- metaList[inx]
mat <- sapply(onesample, function(x) as.integer(x))
Rle(apply(mat, 1, sum))
}, ...)
M <- sapply(allSamples, function(x) as.integer(x))
return(Rle(apply(M, 1, median)) / samplingSize)
}
#' Returns a matrix, with rows representing read counts across a specified
#' gene, or other features of interest.
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, use the argument 'mc.cores'.
#'
#' @param features A GRanges object representing a set of genomic coordinates.
#' @param reads A GRanges object representing a set of mapped reads.
#' @param size The size of the moving window.
#' @param up Distance upstream of each f to align and histogram Default: 1 kb.
#' @param down Distance downstream of each f to align and histogram
#' Default: same as up.
#' @param debug If set to TRUE, provides additional print options.
#' Default: FALSE
#' @param ... Extra argument passed to mclapply
#' @return Returns a vector representing the 'typical' signal across
#' genes of different length.
#' @author Charles G. Danko and Minho Chae
## Returns a matrix of counts. Rows represent different streches of DNA.
## Columns represent positions relative to a certain feature. Summed together,
## these should be a meta-gene.
##
## Arguments:
## f -> data.frame of: CHR, START, STRAND.
## p -> data.frame of: CHR, START, END, STRAND.
## size -> The size of the moving window.
## up -> Distance upstream of each f to align and histogram.
## down -> Distance downstream of each f to align and histogram (NULL).
##
## Assumptions: Same as MetaGene
metaGeneMatrix <- function(features, reads, size= 50, up=1000, down=up,
debug=FALSE, ...) {
C <- sort(unique(as.character(seqnames(features))))
## Run parallel version.
mcp <- mclapply(seq_along(C), metaGeneMatrix_foreachChrom, C=C,
features=features, reads=reads, size=size, up=up, down=down,
debug=debug, ...)
## Append data from all chromosomes.
H <- NULL
for(i in seq_along(C)) {
# Which KG? prb?
indxF <- which(as.character(seqnames(features)) == C[i])
indxPrb <- which(as.character(seqnames(reads)) == C[i])
if((NROW(indxF) >0) & (NROW(indxPrb) >0)) {
H <- rbind(H, mcp[[i]])
}
}
return(H)
}
metaGeneMatrix_foreachChrom <- function(i, C, features, reads, size, up, down,
debug) {
# Which KG? prb?
indxF <- which(as.character(seqnames(features)) == C[i])
indxPrb <- which(as.character(seqnames(reads)) == C[i])
if((NROW(indxF) >0) & (NROW(indxPrb) >0)) {
# Order -- Make sure, b/c this is one of our main assumptions.
# Otherwise violated for DBTSS.
ord <- order(start(features[indxF,]))
# Type coersions.
FeatureStart <- start(features[indxF,][ord])
FeatureStr <- as.character(strand(features[indxF,][ord]))
PROBEStart <- start(reads[indxPrb,])
PROBEEnd <- end(reads[indxPrb,])
PROBEStr <- as.character(strand(reads[indxPrb,]))
size <- as.integer(size)
up <- as.integer(up)
down <- as.integer(down)
# Set dimensions.
dim(FeatureStart) <- c(NROW(FeatureStart), NCOL(FeatureStart))
dim(FeatureStr) <- c(NROW(FeatureStr), NCOL(FeatureStr))
dim(PROBEStart) <- c(NROW(PROBEStart), NCOL(PROBEStart))
dim(PROBEEnd) <- c(NROW(PROBEEnd), NCOL(PROBEEnd))
dim(PROBEStr) <- c(NROW(PROBEStr), NCOL(PROBEStr))
if(debug) {
message(C[i],": Counting reads in specified region.")
}
Hprime <- .Call("MatrixOfReadsByFeature", FeatureStart, FeatureStr,
PROBEStart, PROBEEnd, PROBEStr,
size, up, down, PACKAGE = "groHMM")
return(Hprime)
}
return(integer(0))
}
#' Returns a histogram of the number of reads in each section of a moving
#' window of #' variable size across genes.
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, use the argument 'mc.cores'.
#'
#' @param features A GRanges object representing a set of genomic coordinates.
#' @param reads A GRanges object representing a set of mapped reads.
#' @param n_windows The number of windows to break genes into.
#' @param debug If set to TRUE, provides additional print options.
#' Default: FALSE
#' @param ... Extra argument passed to mclapply
#' @return Returns a vector representing the 'typical' signal across genes of
#' different length.
#' @author Charles G. Danko and Minho Chae
## Returns a histogram of the number of reads in each section of a
## moving window of variable size across genes.
##
## Arguments:
## f -> data.frame of: CHR, START, END, STRAND.
## p -> data.frame of: CHR, START, END, STRAND.
## n_windows -> The resolution of the MetaGene -- i.e. the number of moving
## windows to break it into..
##
## Assumptions:
## (1) Gene list should be ordered!
## (2) Gene list should be pretty short, as most of the processing and
## looping over genes is currently done in R.
#
metaGene_nL <- function(features, reads, n_windows=1000, debug=FALSE, ...) {
C <- sort(unique(as.character(seqnames(features))))
H <- rep(0,n_windows)
for(i in 1:NROW(C)) {
if(debug) {
message(C[i])
}
# Which KG? prb?
indxF <- which(as.character(seqnames(features)) == C[i])
indxPrb <- which(as.character(seqnames(reads)) == C[i])
if((NROW(indxF) >0) & (NROW(indxPrb) >0)) {
# Order -- Make sure, b/c this is one of our main assumptions.
# Otherwise violated for DBTSS.
ord <- order(start(features[indxF,]))
# Type coersions.
FeatureStart <- start(features[indxF,][ord])
FeatureEnd <- end(features[indxF,][ord])
FeatureStr <- as.character(strand(features[indxF,][ord]))
PROBEStart <- start(reads[indxPrb,])
PROBEEnd <- end(reads[indxPrb,])
PROBEStr <- as.character(strand(reads[indxPrb,]))
# Set dimensions.
dim(FeatureStart) <- c(NROW(FeatureStart), NCOL(FeatureStart))
dim(FeatureStr) <- c(NROW(FeatureStr), NCOL(FeatureStr))
dim(PROBEStart) <- c(NROW(PROBEStart), NCOL(PROBEStart))
dim(PROBEEnd) <- c(NROW(PROBEEnd), NCOL(PROBEEnd))
dim(PROBEStr) <- c(NROW(PROBEStr), NCOL(PROBEStr))
#for(iFeatures in 1:NROW(FeatureStart)) {
mcpg <- mclapply(c(1:NROW(FeatureStart)), function(iFeatures) {
ws <- (FeatureEnd[iFeatures]-FeatureStart[iFeatures])/n_windows
## This WILL be an interger.
if(debug) {
message(C[i],": Counting reads in specified region:",
FeatureStart[iFeatures],"-",FeatureEnd[iFeatures])
message(C[i],": Window size:",
FeatureStart[iFeatures],"-",FeatureEnd[iFeatures])
message(C[i],": End-Start:",
FeatureEnd[iFeatures]-FeatureStart[iFeatures])
}
DataByOne <- .Call("WindowAnalysis", PROBEStart, PROBEEnd,
PROBEStr, FeatureStr[iFeatures], as.integer(1),
as.integer(1), FeatureStart[iFeatures],
FeatureEnd[iFeatures],
PACKAGE = "groHMM")
if(debug) {
message("DataByOne size:",NROW(DataByOne))
}
## This seems almost immeidate on my pentium M machine.
Hprime <- unlist(lapply(1:NROW(H), function(i) {
indx <- ceiling(ws*(i-1)+1):ceiling(ws*i)
return(sum(DataByOne[indx]))
}))
## Reverse it for "-" strands.
if(FeatureStr[iFeatures] == "-")
Hprime <- rev(Hprime)
#H <- H + Hprime/ws ## Put in units of: number of reads/base
return(Hprime/ws)
}, ...)
## Add genes from mclapply together.
for(iFeatures in 1:NROW(FeatureStart)) {
H<- H+mcpg[[i]]
}
}
if(debug) {
message(C[i],": Done!")
}
}
return(H)
}
#' Returns the average profile of tiling array probe intensity values or
#' wiggle-like count data centered on a set of genomic positions
#' (specified by 'Peaks').
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, use the argument 'mc.cores'.
#'
#' @param ProbeData Data.frame representing chromosome, window center,
#' and a value.
#' @param Peaks Data.frame representing chromosome, and window center.
#' @param size Numeric. The size of the moving window. Default: 50 bp.
#' @param bins The bins of the meta gene -- i.e. the number of moving windows
#' to break it into. Default +/- 1kb from center.
#' @return A vector representing the 'typical' signal centered on the peaks of
#' interest.
#' @author Charles G. Danko and Minho Chae
## Returns the average profile of tiling array probe intensity values or
## wiggle-like count data centered on a set of genomic positions.
##
## Arguments:
## Peaks -> data.frame of: CHR, CENTER, STRAND.
## (note that STRAND is currenly not supported, and does nothing).
## ProbeData -> data.frame of: CHR, CENTER, VALUE
## bins -> The bins of the meta gene -- i.e. the number of
## moving windows to break it into.
##
## TODO:
## (1) Implement support for a Peaks$starnd
## (2) ...
averagePlot <- function(ProbeData, Peaks, size=50, bins= seq(-1000,1000,size)){
## For each chromsome.
ProbeData$minDist <- rep(999)
for(chr in unique(Peaks[[1]])) {
## Get the set of data that fits.
indxPeaks <- which(Peaks[[1]] == chr)
## The '$' ensures that chrom is end of line. Otherwise, grep for chr1
## returns chr10-chr19 as well.
## Should work fine, even when chromsome is simply "chrN".
indxAffxProbes <- grep(paste(chr,"$", sep=""), ProbeData[[1]], perl=TRUE)
## Calculate the minimum distance between the probe and the vector
## over all features ...
ProbeData$minDist[indxAffxProbes] <-
unlist(lapply(indxAffxProbes, function(x) {
## TODO: For strand to switch it, just multiply by strand here.
return((ProbeData[x,2] -
Peaks[indxPeaks,2])[which.min(abs(ProbeData[x,2] -
Peaks[indxPeaks,2]))])}))
}
## Make bins. Take averages and all that...
means <- unlist(lapply(c(1:NROW(bins)),
function(i){mean(ProbeData[(ProbeData$minDist >=
(bins[i]-size) & ProbeData$minDist < bins[i]),3])}))
return(data.frame(windowCenter= bins+(size/2), means))
}
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Defines functions averagePlot metaGene_nL metaGeneMatrix_foreachChrom metaGeneMatrix samplingMetaGene runMetaGene metaGene_foreachChrom metaGene
Documented in averagePlot metaGene metaGeneMatrix metaGene_nL runMetaGene
###########################################################################
##
## Copyright 2013, 2014 Charles Danko and Minho Chae.
##
## This program is part of the groHMM R package
##
## groHMM is free software: you can redistribute it and/or modify it
## under the terms of the GNU General Public License as published by
## the Free Software Foundation, either version 3 of the License, or
## (at your option) any later version.
##
## This program is distributed in the hope that it will be useful, but
## WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
## or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
## for more details.
##
## You should have received a copy of the GNU General Public License along
## with this program. If not, see <http://www.gnu.org/licenses/>.
##
##########################################################################
#' Returns a histogram of the number of reads in each section of a moving
#' window centered on a certain feature.
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, set the option 'mc.cores'.
#'
#' @param features A GRanges object representing a set of genomic coordinates.
#' The meta-plot will be centered on the transcription start site (TSS)
#' @param reads A GRanges object representing a set of mapped reads.
#' Instead of 'reads', 'plusCVG' and 'minusCVG' can be used Default: NULL
#' @param plusCVG An IntegerRangesList object for reads with '+' strand.
#' @param minusCVG An IntegerRangesList object for reads with '-' strand.
#' @param size The size of the moving window.
#' @param up Distance upstream of each features to align and histogram.
#' Default: 10 kb.
#' @param down Distance downstream of each features to align and histogram.
#' If NULL, same as up. Default: NULL.
#' @param ... Extra argument passed to mclapply
#' @return Returns a integer-Rle representing the 'typical' signal
#' centered on a point of interest.
#' @author Charles G. Danko and Minho Chae
#' @examples
#' features <- GRanges("chr7", IRanges(1000, 1000), strand="+")
#' reads <- GRanges("chr7", IRanges(start=c(1000:1004, 1100),
#' width=rep(1, 6)), strand="+")
#' mg <- metaGene(features, reads, size=4, up=10)
metaGene <- function(features, reads=NULL, plusCVG=NULL, minusCVG=NULL,
size=100L, up=10000L, down=NULL, ...) {
seqlevels(features) <- seqlevelsInUse(features)
# Check 'reads'
if (is.null(reads)) {
if (is.null(plusCVG) || is.null(minusCVG))
stop("Either 'reads' or 'plusCVG' and 'minusCVG' must be used")
} else {
seqlevels(reads) <- seqlevelsInUse(reads)
plusCVG <- coverage(reads[strand(reads)=="+",])
minusCVG <- coverage(reads[strand(reads)=="-",])
}
if (is.null(down)) down <- up
featureList <- split(features, seqnames(features))
H <- mclapply(seqlevels(features), metaGene_foreachChrom,
featureList=featureList, plusCVG=plusCVG, minusCVG=minusCVG,
size=size, up=up, down=down, ...)
M <- sapply(seq_len(length(H)), function(x) as.integer(H[[x]]))
return(Rle(apply(M, 1, sum)))
}
metaGene_foreachChrom <- function(chrom, featureList, plusCVG, minusCVG,
size, up, down) {
f <- featureList[[chrom]]
pCVG <- plusCVG[[chrom]]
mCVG <- minusCVG[[chrom]]
offset <- floor(size/2L)
pro <- promoters(f, upstream=up+offset, downstream=(down+offset-1L))
M <- sapply(1:length(pro), function(x) {
if (as.character(strand(pro)[x]) == "+")
as.integer(runsum(pCVG[start(pro)[x]:end(pro)[x]],
k=size))
else
as.integer(rev(runsum(mCVG[start(pro)[x]:end(pro)[x]],
k=size)))
})
return(Rle(apply(M, 1, sum)))
}
#' Runs metagene analysis for sense and antisense direction.
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, set the option 'mc.cores'.
#'
#' @param features GRanges A GRanges object representing a set of genomic
#' coordinates, i.e., set of genes.
#' @param reads GRanges of reads.
#' @param anchorType Either 'TSS' or 'TTS'. Metagene will be centered on the
#' transcription start site(TSS) or transcription termination site(TTS).
#' Default: TSS.
#' @param size Numeric. The size of the moving window. Default: 100L
#' @param normCounts Numeric. Normalization vector such as average reads.
#' Default: 1L
#' @param up Numeric. Distance upstream of each feature to align and histogram.
#' Default: 1 kb
#' @param down Numeric. Distance downstream of each feature to align and
#' histogram. If NULL, down is same as up. Default: NULL
#' @param sampling Logical. If TRUE, subsampling of Metagene is used.
#' Default: FALSE
#' @param nSampling Numeric. Number of subsampling. Default: 1000L
#' @param samplingRatio Numeric. Ratio of sampling for features. Default: 0.1
#' @param ... Extra argument passed to mclapply.
#' @return A list of integer-Rle for sense and antisene.
#' @author Minho Chae
#' @examples
#' features <- GRanges("chr7", IRanges(start=1000:1001, width=rep(1,2)),
#' strand=c("+", "-"))
#' reads <- GRanges("chr7", IRanges(start=c(1000:1003, 1100:1101),
#' width=rep(1, 6)), strand=rep(c("+","-"), 3))
#' ## Not run:
#' # mg <- runMetaGene(features, reads, size=4, up=10)
runMetaGene <- function(features, reads, anchorType="TSS", size=100L,
normCounts=1L, up=10000L, down=NULL, sampling=FALSE, nSampling=1000L,
samplingRatio=0.1, ...) {
# Check 'anchorType'
if (!anchorType %in% c("TSS", "TTS")) {
stop("'anchorType' must be either 'TSS' or 'TTS'")
}
if (anchorType == "TSS") {
f <- resize(features, width=1L, fix="start")
} else if (anchorType == "TTS") {
f <- resize(features, width=1L, fix="end")
}
if (is.null(down)) down <- up
fRev <- f
strand(fRev) <- rev(strand(f))
plusCVG <- coverage(reads[strand(reads)=="+",])
minusCVG <- coverage(reads[strand(reads)=="-",])
message("sense ... ", appendLF=FALSE)
if (sampling) {
sense <- samplingMetaGene(features=f, plusCVG=plusCVG,
minusCVG=minusCVG, size=size, up=up, down=down,
nSampling=nSampling, samplingRatio=samplingRatio, ...)
} else {
sense <- metaGene(features=f, plusCVG=plusCVG, minusCVG=minusCVG,
size=size, up=up, down=down, ...)
sense <- sense/length(features)
}
message("OK")
message("antisense ... ", appendLF=FALSE)
if (sampling) {
antisense <- samplingMetaGene(features=fRev, plusCVG=plusCVG,
minusCVG=minusCVG, size=size, up=up, down=down,
nSampling=nSampling, samplingRatio=samplingRatio, ...)
} else {
antisense <- metaGene(features=fRev, plusCVG=plusCVG, minusCVG=minusCVG,
size=size, up=up, down=down, ...)
antisense <- antisense/length(features)
}
message("OK")
sense <- sense*normCounts
antisense <- antisense*normCounts
return(list(sense=sense, antisense=antisense))
}
samplingMetaGene <- function(features, plusCVG, minusCVG, size=100L, up=10000L,
down=NULL, nSampling=1000L, samplingRatio=0.1, ...) {
samplingSize <- round(length(features)*samplingRatio)
metaList <- mclapply(1:length(features), function(x) {
metaGene(features=features[x,], plusCVG=plusCVG, minusCVG=minusCVG,
size=size, up=up, down=down)
}, ...)
allSamples <- mclapply(1:nSampling, function(x) {
inx <- sample(1:length(features), size=samplingSize, replace=TRUE)
onesample <- metaList[inx]
mat <- sapply(onesample, function(x) as.integer(x))
Rle(apply(mat, 1, sum))
}, ...)
M <- sapply(allSamples, function(x) as.integer(x))
return(Rle(apply(M, 1, median)) / samplingSize)
}
#' Returns a matrix, with rows representing read counts across a specified
#' gene, or other features of interest.
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, use the argument 'mc.cores'.
#'
#' @param features A GRanges object representing a set of genomic coordinates.
#' @param reads A GRanges object representing a set of mapped reads.
#' @param size The size of the moving window.
#' @param up Distance upstream of each f to align and histogram Default: 1 kb.
#' @param down Distance downstream of each f to align and histogram
#' Default: same as up.
#' @param debug If set to TRUE, provides additional print options.
#' Default: FALSE
#' @param ... Extra argument passed to mclapply
#' @return Returns a vector representing the 'typical' signal across
#' genes of different length.
#' @author Charles G. Danko and Minho Chae
## Returns a matrix of counts. Rows represent different streches of DNA.
## Columns represent positions relative to a certain feature. Summed together,
## these should be a meta-gene.
##
## Arguments:
## f -> data.frame of: CHR, START, STRAND.
## p -> data.frame of: CHR, START, END, STRAND.
## size -> The size of the moving window.
## up -> Distance upstream of each f to align and histogram.
## down -> Distance downstream of each f to align and histogram (NULL).
##
## Assumptions: Same as MetaGene
metaGeneMatrix <- function(features, reads, size= 50, up=1000, down=up,
debug=FALSE, ...) {
C <- sort(unique(as.character(seqnames(features))))
## Run parallel version.
mcp <- mclapply(seq_along(C), metaGeneMatrix_foreachChrom, C=C,
features=features, reads=reads, size=size, up=up, down=down,
debug=debug, ...)
## Append data from all chromosomes.
H <- NULL
for(i in seq_along(C)) {
# Which KG? prb?
indxF <- which(as.character(seqnames(features)) == C[i])
indxPrb <- which(as.character(seqnames(reads)) == C[i])
if((NROW(indxF) >0) & (NROW(indxPrb) >0)) {
H <- rbind(H, mcp[[i]])
}
}
return(H)
}
metaGeneMatrix_foreachChrom <- function(i, C, features, reads, size, up, down,
debug) {
# Which KG? prb?
indxF <- which(as.character(seqnames(features)) == C[i])
indxPrb <- which(as.character(seqnames(reads)) == C[i])
if((NROW(indxF) >0) & (NROW(indxPrb) >0)) {
# Order -- Make sure, b/c this is one of our main assumptions.
# Otherwise violated for DBTSS.
ord <- order(start(features[indxF,]))
# Type coersions.
FeatureStart <- start(features[indxF,][ord])
FeatureStr <- as.character(strand(features[indxF,][ord]))
PROBEStart <- start(reads[indxPrb,])
PROBEEnd <- end(reads[indxPrb,])
PROBEStr <- as.character(strand(reads[indxPrb,]))
size <- as.integer(size)
up <- as.integer(up)
down <- as.integer(down)
# Set dimensions.
dim(FeatureStart) <- c(NROW(FeatureStart), NCOL(FeatureStart))
dim(FeatureStr) <- c(NROW(FeatureStr), NCOL(FeatureStr))
dim(PROBEStart) <- c(NROW(PROBEStart), NCOL(PROBEStart))
dim(PROBEEnd) <- c(NROW(PROBEEnd), NCOL(PROBEEnd))
dim(PROBEStr) <- c(NROW(PROBEStr), NCOL(PROBEStr))
if(debug) {
message(C[i],": Counting reads in specified region.")
}
Hprime <- .Call("MatrixOfReadsByFeature", FeatureStart, FeatureStr,
PROBEStart, PROBEEnd, PROBEStr,
size, up, down, PACKAGE = "groHMM")
return(Hprime)
}
return(integer(0))
}
#' Returns a histogram of the number of reads in each section of a moving
#' window of #' variable size across genes.
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, use the argument 'mc.cores'.
#'
#' @param features A GRanges object representing a set of genomic coordinates.
#' @param reads A GRanges object representing a set of mapped reads.
#' @param n_windows The number of windows to break genes into.
#' @param debug If set to TRUE, provides additional print options.
#' Default: FALSE
#' @param ... Extra argument passed to mclapply
#' @return Returns a vector representing the 'typical' signal across genes of
#' different length.
#' @author Charles G. Danko and Minho Chae
## Returns a histogram of the number of reads in each section of a
## moving window of variable size across genes.
##
## Arguments:
## f -> data.frame of: CHR, START, END, STRAND.
## p -> data.frame of: CHR, START, END, STRAND.
## n_windows -> The resolution of the MetaGene -- i.e. the number of moving
## windows to break it into..
##
## Assumptions:
## (1) Gene list should be ordered!
## (2) Gene list should be pretty short, as most of the processing and
## looping over genes is currently done in R.
#
metaGene_nL <- function(features, reads, n_windows=1000, debug=FALSE, ...) {
C <- sort(unique(as.character(seqnames(features))))
H <- rep(0,n_windows)
for(i in 1:NROW(C)) {
if(debug) {
message(C[i])
}
# Which KG? prb?
indxF <- which(as.character(seqnames(features)) == C[i])
indxPrb <- which(as.character(seqnames(reads)) == C[i])
if((NROW(indxF) >0) & (NROW(indxPrb) >0)) {
# Order -- Make sure, b/c this is one of our main assumptions.
# Otherwise violated for DBTSS.
ord <- order(start(features[indxF,]))
# Type coersions.
FeatureStart <- start(features[indxF,][ord])
FeatureEnd <- end(features[indxF,][ord])
FeatureStr <- as.character(strand(features[indxF,][ord]))
PROBEStart <- start(reads[indxPrb,])
PROBEEnd <- end(reads[indxPrb,])
PROBEStr <- as.character(strand(reads[indxPrb,]))
# Set dimensions.
dim(FeatureStart) <- c(NROW(FeatureStart), NCOL(FeatureStart))
dim(FeatureStr) <- c(NROW(FeatureStr), NCOL(FeatureStr))
dim(PROBEStart) <- c(NROW(PROBEStart), NCOL(PROBEStart))
dim(PROBEEnd) <- c(NROW(PROBEEnd), NCOL(PROBEEnd))
dim(PROBEStr) <- c(NROW(PROBEStr), NCOL(PROBEStr))
#for(iFeatures in 1:NROW(FeatureStart)) {
mcpg <- mclapply(c(1:NROW(FeatureStart)), function(iFeatures) {
ws <- (FeatureEnd[iFeatures]-FeatureStart[iFeatures])/n_windows
## This WILL be an interger.
if(debug) {
message(C[i],": Counting reads in specified region:",
FeatureStart[iFeatures],"-",FeatureEnd[iFeatures])
message(C[i],": Window size:",
FeatureStart[iFeatures],"-",FeatureEnd[iFeatures])
message(C[i],": End-Start:",
FeatureEnd[iFeatures]-FeatureStart[iFeatures])
}
DataByOne <- .Call("WindowAnalysis", PROBEStart, PROBEEnd,
PROBEStr, FeatureStr[iFeatures], as.integer(1),
as.integer(1), FeatureStart[iFeatures],
FeatureEnd[iFeatures],
PACKAGE = "groHMM")
if(debug) {
message("DataByOne size:",NROW(DataByOne))
}
## This seems almost immeidate on my pentium M machine.
Hprime <- unlist(lapply(1:NROW(H), function(i) {
indx <- ceiling(ws*(i-1)+1):ceiling(ws*i)
return(sum(DataByOne[indx]))
}))
## Reverse it for "-" strands.
if(FeatureStr[iFeatures] == "-")
Hprime <- rev(Hprime)
#H <- H + Hprime/ws ## Put in units of: number of reads/base
return(Hprime/ws)
}, ...)
## Add genes from mclapply together.
for(iFeatures in 1:NROW(FeatureStart)) {
H<- H+mcpg[[i]]
}
}
if(debug) {
message(C[i],": Done!")
}
}
return(H)
}
#' Returns the average profile of tiling array probe intensity values or
#' wiggle-like count data centered on a set of genomic positions
#' (specified by 'Peaks').
#'
#' Supports parallel processing using mclapply in the 'parallel' package.
#' To change the number of processors, use the argument 'mc.cores'.
#'
#' @param ProbeData Data.frame representing chromosome, window center,
#' and a value.
#' @param Peaks Data.frame representing chromosome, and window center.
#' @param size Numeric. The size of the moving window. Default: 50 bp.
#' @param bins The bins of the meta gene -- i.e. the number of moving windows
#' to break it into. Default +/- 1kb from center.
#' @return A vector representing the 'typical' signal centered on the peaks of
#' interest.
#' @author Charles G. Danko and Minho Chae
## Returns the average profile of tiling array probe intensity values or
## wiggle-like count data centered on a set of genomic positions.
##
## Arguments:
## Peaks -> data.frame of: CHR, CENTER, STRAND.
## (note that STRAND is currenly not supported, and does nothing).
## ProbeData -> data.frame of: CHR, CENTER, VALUE
## bins -> The bins of the meta gene -- i.e. the number of
## moving windows to break it into.
##
## TODO:
## (1) Implement support for a Peaks$starnd
## (2) ...
averagePlot <- function(ProbeData, Peaks, size=50, bins= seq(-1000,1000,size)){
## For each chromsome.
ProbeData$minDist <- rep(999)
for(chr in unique(Peaks[[1]])) {
## Get the set of data that fits.
indxPeaks <- which(Peaks[[1]] == chr)
## The '$' ensures that chrom is end of line. Otherwise, grep for chr1
## returns chr10-chr19 as well.
## Should work fine, even when chromsome is simply "chrN".
indxAffxProbes <- grep(paste(chr,"$", sep=""), ProbeData[[1]], perl=TRUE)
## Calculate the minimum distance between the probe and the vector
## over all features ...
ProbeData$minDist[indxAffxProbes] <-
unlist(lapply(indxAffxProbes, function(x) {
## TODO: For strand to switch it, just multiply by strand here.
return((ProbeData[x,2] -
Peaks[indxPeaks,2])[which.min(abs(ProbeData[x,2] -
Peaks[indxPeaks,2]))])}))
}
## Make bins. Take averages and all that...
means <- unlist(lapply(c(1:NROW(bins)),
function(i){mean(ProbeData[(ProbeData$minDist >=
(bins[i]-size) & ProbeData$minDist < bins[i]),3])}))
return(data.frame(windowCenter= bins+(size/2), means))
}
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