R/binning_aggregation.R
In databio/MIRA: Methylation-Based Inference of Regulatory Activity
Defines functions
binRegion
BSAggregate
BSBinAggregate
Documented in
binRegion
BSBinAggregate
#####################################################################
#Binning and aggregation functions
#BSAggregate is primary function for this and workhorse of MIRA
#####################################################################
#' Bins regions and aggregates methylation data across the regions by bin
#'
#' First bins regions and averages the proportion of methylation for
#' all methylation sites within each bin (ie the methylation of
#' all sites within region 1, bin 1 are averaged, then all sites
#' within region 1, bin 2 are averaged, etc.)
#' Then aggregates methylation across all regions by bin by averaging
#' the proportion of methylation in each corresponding
#' bin (ie all bin1's together, all bin2's together, etc.).
#'
#'
#' @param BSDT A single data table that has DNA methylation data
#' on individual sites including a "chr" column with chromosome,
#' a "start" column with the coordinate number for the cytosine,
#' a "methylProp" column with proportion of methylation (0 to 1),
#' optionally a "methylCount" column with number of
#' methylated reads for each site, and
#' optionally a "coverage" column with total number of reads for each site
#' (hasCoverage param).
#' @param rangeDT A data table with the sets of regions to be binned,
#' with columns named "start", "end". Strand may also be given and will
#' affect the output. See "Value" section.
#' @param binNum Number of bins across the region.
#' @param byRegionGroup Default TRUE will aggregate methylation over
#' corresponding bins for each region (all bin1's aggregated, all bin2's, etc).
#' byRegionGroup = FALSE is deprecated.
#' @param minBaseCovPerBin Filter out bins where the sum of coverage values is
#' less than X before returning.
#' @param splitFactor With default NULL, aggregation will be done
#' separately/individually for each sample.
#' @param hasCoverage Default TRUE. Whether there is a coverage column
#'
#' @return With splitFactor = NULL, it will return a data.table
#' with binNum rows,
#' containing aggregated methylation data over regions in region set "rangeDT".
#' Each region was split into bins; methylation was put in these bins;
#' Output contains sum of the all corresponding bins
#' for the regions of each region set ie for all regions in each region set:
#' first bins summed, second bins summed, etc.
#' Columns of the output should be "bin", "methylProp", and, if
#' coverage was included as input col, "coverage"
#'
#' Info about how strand of rangeDT affects output:
#' The MIRA profile will be symmetrical if no strand information is given for
#' the regions (produced by averaging the profile with the reverse of the
#' profile), because the orientation of the regions is arbitrary with respect
#' to biological features (like a promoter for instance) that could be
#' oriented directionally (e.g. 5' to 3'). If strand information is given,
#' regions on the minus strand will be flipped before being aggregated
#' with plus strand regions so the MIRA profile will be in
#' 5' to 3' orientation.
#' @examples
#' data("exampleBSDT") # exampleBSDT
#' data("exampleRegionSet") # exampleRegionSet
#' exampleBSDT <- addMethPropCol(exampleBSDT)
#' aggregateBins <- BSBinAggregate(BSDT = exampleBSDT,
#' rangeDT = exampleRegionSet,
#' binNum = 11, splitFactor = NULL)
#'
#' @export
BSBinAggregate <- function(BSDT, rangeDT, binNum, minBaseCovPerBin = 500,
byRegionGroup = TRUE, splitFactor = NULL,
hasCoverage = TRUE) {
# BSDT should not be a list but can be converted
if (is(BSDT, "list")) {
if (length(BSDT) == 1) {
BSDT <- BSDT[[1]]
} else {
stop(cleanws("Only one BSDT may be given to function.
BSDT should not be a list."))
}
}
if (!is(BSDT, "data.table")) {
stop("BSDT must be a data.table")
}
# if given GRanges object, change to DT
if (is(rangeDT, "GRanges")) {
rangeDT <- grToDt(GR = rangeDT, includeStrand = TRUE)
}
if (!is(rangeDT, "data.table")) {
stop("rangeDT must be a data.table")
}
seqnamesColName <- "seqnames" # default column name
if ("chr" %in% colnames(rangeDT)) {
# message("seqnames column name set to: chr")
seqnamesColName <- "chr"
} else {
# Got neither.
stop("rangeDT must have a seqnames or chr column")
}
if (! ("strand" %in% colnames(rangeDT))) {
rangeDT[, strand := "*"]
warning("Since strand not given, set to '*' ")
}
## if (!silent) {
# message("Binning...")
##}
binnedDT <- rangeDT[, binRegion(start, end,
binNum, get(seqnamesColName), strand)]
binnedGR <- sapply(split(binnedDT, binnedDT$binID), dtToGr)
# message("Aggregating...")
if (hasCoverage) {
# aggregate methylation (mean) and sum coverage values
aggrJCommand <- buildJ(c("methylProp", "coverage"),
c("mean", "sum"))
} else {
# if no coverage only aggregate methylation level
aggrJCommand <- buildJ("methylProp", "mean")
}
binnedBSDT <- BSAggregate(BSDT = BSDT,
regionsGRL = GRangesList(binnedGR),
jCommand = aggrJCommand,
byRegionGroup = byRegionGroup,
splitFactor = splitFactor,
hasCoverage = hasCoverage)
# binnedBSDT will be NULL if there was absolutely no overlap between
# region set and BSDT
# don't do some of the following steps if there is no overlap/binnedBSDT is NULL
if (is.null(binnedBSDT)) {
warning(cleanws("No overlap between sample (BSDT) and region set.
Returning NULL for this sample, region set combination."))
} else {
# If we aren't aggregating by bin, then don't restrict to min reads!
if (byRegionGroup) {
if (hasCoverage) {
# only keep rows (bins) with coverage >= minBaseCovPerBin
binnedBSDT <- binnedBSDT[coverage >= minBaseCovPerBin, ]
}
if (NROW(binnedBSDT) < binNum) {
# telling user what sample failed if sample name is in BSDT
if ("sampleName" %in% names(BSDT)) {
thisSample <- BSDT[1, sampleName]
} else {
thisSample <- "this sample"
}
warning(paste0("Less than minBaseCovPerBin. Unable to return bins for ",
thisSample, " for this region set."))
}
}
}
return(binnedBSDT)
}
# BSaggregate: Aggregate a BSDT across regions or region groups,
# for multiple samples at a time.
# This function is as BScombineByRegion, but can handle not only multiple
# samples in BSDT, but also simultaneously multiple region sets by passing
# a regionsGRL (GRangesList object).However currently code for symmetrical
# averaging will cause it to only work with one region set (which may be
# split up into multiple GRanges in a GRangesList).
# you can use jCommand to do other functions.
# Given a bisulfite data table as input, with an identifier column for
# different samples; plus a GRanges objects with regions to aggregate.
#
# @param BSDT The bisulfite data.table (output from one of the parsing
# functions for methylation calls) that you wish to aggregate. It can
# be a combined table, with individual samples identified by column passed
# to splitFactor. "chr", "start", "methylCount" columns should be in BSDT.
# "coverage", and "methylProp" columns are optional (hasCoverage
# must be set to FALSE if there is not coverage column)
# @param regionsGRL Regions across which you want to aggregate.
# @param excludeGR A GenomicRanges object with regions you want to
# exclude from the aggregation function. These regions will be eliminated
# from the input table and not counted.
# @param regionsGRL.length Vector with number of regions in each bin.
# From bin1 to binN. With default NULL value, it will be auto assigned.
# @param splitFactor Used to make "by string" to be plugged into a data.table
# "by=" statemnt. With default NULL value, by string will be "list(regionID)"
# @param keepCols Deprecated, NULL value should be used for MIRA aggregation.
# @param sumCols Deprecated, NULL value should be used for MIRA aggregation.
# @param jCommand You can pass a custom command in the j slot to data.table
# specifying which columns to aggregate, and which functions to use. You
# can use buildJ() to build a jCommand argument easily. jCommand may be
# used twice so changing column names in the jCommand could introduce errors
# @param byRegionGroup You can aggregate by regionID or by regionGroupID;
# this reflects the regionsGRL that you pass; by default, BSAggregate will
# aggregate each region individually -- scores will then be contiguous, and
# the output is 1 row per region.
# Turn on this flag to aggregate across all region groups, making the result
# uncontiguous, and resulting in 1 row per *region group*.
# (byRegionGroup=TRUE is used for normal MIRA behaviour that
# aggregates across regions by bins
# -- all bin1's together, all bin2's together etc.--, in which case
# "region group" in the description above refers to bin number,
# and you would have 1 row per bin)
# @param keep.na Not used in general MIRA context.
# @param hasCoverage Default TRUE. Assuming there is a coverage column
# unless told otherwise
#
# @return In context of MIRA, with byRegionGroup = TRUE and jCommand =
# list( methylProp = mean(methylProp), coverage = sum(coverage) )",
# this function will return a data.table with
# binNum rows (parameter for BSBinAggregate)
# containing aggregated methylation from BSDT over binned regions from a region
# set.
#
BSAggregate <- function(BSDT, regionsGRL, excludeGR = NULL,
regionsGRL.length = NULL, splitFactor = NULL,
keepCols = NULL, sumCols = NULL, jCommand = NULL,
byRegionGroup = FALSE, keep.na = FALSE, hasCoverage = TRUE) {
# Assert that regionsGRL is a GRL.
# If regionsGRL is given as a GRanges, we convert to GRL
if (is(regionsGRL, "GRanges")) {
regionsGRL <- GRangesList(regionsGRL);
} else if (!is(regionsGRL, "GRangesList")) {
stop("regionsGRL is not a GRanges or GRangesList object");
}
# make sure methylProp column is present
if (!("methylProp" %in% colnames(BSDT))) {
stop("BSDT must have a methylProp column.")
}
if (! is.null(excludeGR)) {
BSDT <- BSFilter(BSDT, minReads = 0, excludeGR)
}
bsgr <- BSdtToGRanges(list(BSDT));
colModes <- sapply(BSDT, mode);
if (is.null(sumCols)) {
sumCols <- setdiff(colnames(BSDT), c("chr", "start", "end",
"strand", splitFactor, keepCols))
# Restrict to numeric columns.
sumCols <- intersect(sumCols,
names(colModes[which(colModes == "numeric")]))
}
# It's required to do a findoverlaps on each region individually,
# Not on a GRL, because of the way overlaps with GRLs work. So,
# we must convert the GRL to a GR, but we must keep track of which
# regions came from which group.
regionsGR <- unlist(regionsGRL)
if (is.null(regionsGRL.length)) {
if (length(regionsGRL) > 100) {
message(cleanws("BSAggregate: Calculating sizes. You can speed this
up by supplying a regionsGRL.length vector..."),
appendLF = FALSE)
}
regionsGRL.length <- sapply(regionsGRL, length)
# message("Done counting regionsGRL lengths.");
}
# Build a table to keep track of which regions belong to which group
region2group <- data.table(
regionID = seq_along(regionsGR),
chr = as.vector(seqnames(regionsGR)),
start = as.vector(start(regionsGR)),
end = as.vector(end(regionsGR)),
withinGroupID = as.vector(unlist(sapply(regionsGRL.length, seq))),
regionGroupID = rep(seq_along(regionsGRL), regionsGRL.length))
setkey(region2group, regionID)
# message("Finding overlaps...");
fo <- findOverlaps(bsgr[[1]], regionsGR)
setkey(BSDT, chr, start)
# Gut check:
# stopifnot(all(elementMetadata(bsgr[[1]])$coverage == BSDT$coverage))
# message("Setting regionIDs...");
BSDT <- BSDT[queryHits(fo), ] # restrict the table to CpGs in any region.
if (NROW(BSDT) < 1) {
# warning("No BSDT sites in the given region list.
# Please expand your regionsGRL")
return(NULL)
}
BSDT[, regionID := subjectHits(fo)] # record which region they overlapped.
# if (!keep.na) {
# BSDT <- BSDT[queryHits(fo), ]
#}
if (is.null(jCommand)) {
cols <- c(sumCols, keepCols)
funcs <- c(rep("sum", length(sumCols)), rep("unique", length(keepCols)))
jCommand <- buildJ(cols, funcs)
}
# message("jCommand: ", jCommand)
# Build the by string
if (is.null(splitFactor)) {
byString <- paste0("list(regionID)");
} else {
byString <- paste0("list(", paste("regionID", paste0(splitFactor, ""),
collapse = ",", sep = ","), ")")
}
# Now actually do the aggregate:
# message("Combining...");
# for MIRA: average methylProp and sum coverage within each instance of
# each bin (ie average methylProp's in bin1 of first region, average
# methylProp's in bin1 of second region etc. for all bins and all regions
# separately)
bsCombined <- BSDT[, eval(parse(text = jCommand)),
by = eval(parse(text = byString))]
setkey(bsCombined, regionID)
# Now aggregate across groups.
# I do this in 2 steps to avoid assigning regions to groups,
# which takes awhile. I think this preserves memory and is faster.
# Define aggregation column. aggregate by region or by region group?
if (byRegionGroup) {
# must set allow = TRUE here in case there are multiple IDs (splitCol)
# adds regionGroupID column from region2group to bsCombined
bsCombined[region2group, regionGroupID := regionGroupID, allow = TRUE]
if (! is.null(splitFactor)) {
byStringGroup <- paste0("list(",
paste("regionGroupID",
paste0(splitFactor, collapse = ","),
sep = ","),
")")
} else {
byStringGroup <- "list(regionGroupID)"
}
# actual aggregation operation
# for normal MIRA use: averaging methylProp's and summing
# coverage for all bins with the same number (ie all
# bin1's together, all bin2's together, etc.)
# NOTE: 2nd use of the jCommand so if the first jCommand use changed
# column names that are required by the jCommand
# then this 2nd jCommand use will cause an error
bsCombined <- bsCombined[, eval(parse(text = jCommand)),
by = eval(parse(text = byStringGroup))]
# if any strand information was not given, averaging the profiles
# about the center to account for unknown strand orientation,
# also averaging coverage about center
# ie if any "*" are present then average
if ("*" %in% unique(as.character(strand(regionsGR)))) {
bsCombined[, methylProp := (methylProp + rev(methylProp)) / 2]
if (hasCoverage) {
bsCombined[, coverage := (coverage + rev(coverage)) / 2]
}
}
# changing "regionGroupID" name to "bin" which is less confusing
# for normal MIRA use cases
setnames(bsCombined, old = "regionGroupID", new = "bin")
return(bsCombined[]);
} else {
warning(cleanws("Using byRegionGroup = FALSE may
result in missing functionalities such as symmetrical averaging"))
e <- region2group[bsCombined, ]
setkey(e, regionID);
return(e);
}
# WARNING: There are now 2^2 ways to aggregate, sum vs mean
# at each level: across regions, then across region sets. THis
# doesn't give you a choice at this point.
}
#' Divide region into similarly sized bins.
#'
#' Given a start, end, and number of bins, to divide,
#' this function will split the regions into bins.
#' Bins will be only approximately the same size, due to rounding.
#' (they should not be more than 1 different).
#'
#' Use case: take a set of regions, like CG islands, and bin them; now you can
#' aggregate signal scores across the bins, giving you an aggregate signal
#' in bins across many regions of the same type.
#'
#' In theory, this just runs on 3 values, but you can run it inside a
#' data.table j expression to divide a bunch of regions in the same way.
#' @param start Coordinate for beginning of range/range.
#' @param end Coordinate for end of range/region.
#' @param bins How many bins to divide this range/region.
#' @param idDF A string/vector of strings that has chromosome (e.g. "chr1")
#' for given start and end values
#' @param strand "strand" column of the data.table (or single
#' strand value if binRegion is only used on one region). Default is "*".
#'
#' @return
#' A data.table, expanded to nrow = number of bins, with these id columns:
#' id: region ID
#' binID: repeating ID (this is the value to aggregate across)
#' ubinID: unique bin IDs
#' @export
#' @examples
#' library(data.table)
#' start <- c(100, 1000, 3000)
#' end <- c(500, 1400, 3400)
#' chr <- c("chr1", "chr1", "chr2")
#' strand <- c("*", "*", "*")
#' # strand not included in object
#' # since MIRA assumes "*" already unless given something else
#' regionsToBinDT <- data.table(chr, start, end)
#' numberOfBins <- 15
#' # data.table "j command" using column names and numberOfBins variable
#' binnedRegionDT <- regionsToBinDT[, binRegion(start, end, numberOfBins, chr)]
binRegion <- function(start, end, bins, idDF = NULL, strand = "*") {
# if (!is.null(idDF) & (!is(idDF, "data.frame"))) {
# stop("idDF should be a data.frame")
#}
# conditionally altered later
finalColNames <- c("chr", "start", "end", "id", "binID", "ubinID")
if (!("*" %in% strand)) {
if ("+" %in% strand) {
plusIndex <- which(strand == "+")
# once for plus strand coordinates
plusStart <- start[plusIndex]
plusEnd <- end[plusIndex]
binSize <- (plusEnd - plusStart) / (bins)
breaks <- round(rep(plusStart, each = (bins + 1))
+ (0:(bins)) * rep(binSize, each = (bins + 1)))
endpoints <- (bins + 1) * (1:(length(plusStart)))
startpoints <- 1 + (bins + 1) * (0:(length(plusStart) - 1))
plusDT <- data.table(start = breaks[-endpoints],
end = breaks[-startpoints],
id = rep(plusIndex, each = bins),
binID = 1:bins,
strand = "+",
key = "id")
dt <- plusDT # placeholder but may be returned
}
if ("-" %in% strand) {
minusIndex <- which(strand == "-")
minusStart <- start[minusIndex]
minusEnd <- end[minusIndex]
binSize <- (minusEnd - minusStart) / (bins)
breaks <- round(rep(minusStart, each = (bins + 1))
+ (0:(bins)) * rep(binSize, each = (bins + 1)))
endpoints <- (bins + 1) * (1:(length(minusStart)))
startpoints <- 1 + (bins + 1) * (0:(length(minusStart) - 1))
minusDT <- data.table(start = breaks[-endpoints],
end = breaks[-startpoints],
id = rep(minusIndex, each = bins),
binID = bins:1,
strand = "-",
key = "id")
dt <- minusDT # placeholder but may be returned
}
# if there are both + and - strands
# combining and sorting plus and minus data.tables
if (("+" %in% strand) && ("-" %in% strand)) {
dt <- rbindlist(list(plusDT, minusDT))
setorder(x = dt, id, binID) # setorder(dt, id) might also work?
}
# included only if + /- are present
finalColNames <- c(finalColNames, "strand")
dt[, ubinID := 1:nrow(dt)]
}else { # some strand information is "*", don't flip bin directions
binSize <- (end - start) / (bins)
breaks <- round(rep(start, each = (bins + 1))
+ (0:(bins)) * rep(binSize, each = (bins + 1)))
endpoints <- (bins + 1) * (1:(length(start)))
startpoints <- 1 + (bins + 1) * (0:(length(start) - 1))
# do all regions in the same order
dt <- data.table(start = breaks[-endpoints],
end = breaks[-startpoints],
id = rep((seq_along(start)), each = bins),
binID = 1:bins,
ubinID = seq_along(breaks[-startpoints]),
key = "id")
}
if (!is.null(idDF)) {
chr <- rep(idDF, each = bins)
dt <- dt[, chr := chr]
setcolorder(dt, finalColNames) # putting chr first, does not copy
}
return(dt[])
}
databio/MIRA documentation built on April 16, 2020, 9:53 p.m.
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Defines functions binRegion BSAggregate BSBinAggregate
Documented in binRegion BSBinAggregate
#####################################################################
#Binning and aggregation functions
#BSAggregate is primary function for this and workhorse of MIRA
#####################################################################
#' Bins regions and aggregates methylation data across the regions by bin
#'
#' First bins regions and averages the proportion of methylation for
#' all methylation sites within each bin (ie the methylation of
#' all sites within region 1, bin 1 are averaged, then all sites
#' within region 1, bin 2 are averaged, etc.)
#' Then aggregates methylation across all regions by bin by averaging
#' the proportion of methylation in each corresponding
#' bin (ie all bin1's together, all bin2's together, etc.).
#'
#'
#' @param BSDT A single data table that has DNA methylation data
#' on individual sites including a "chr" column with chromosome,
#' a "start" column with the coordinate number for the cytosine,
#' a "methylProp" column with proportion of methylation (0 to 1),
#' optionally a "methylCount" column with number of
#' methylated reads for each site, and
#' optionally a "coverage" column with total number of reads for each site
#' (hasCoverage param).
#' @param rangeDT A data table with the sets of regions to be binned,
#' with columns named "start", "end". Strand may also be given and will
#' affect the output. See "Value" section.
#' @param binNum Number of bins across the region.
#' @param byRegionGroup Default TRUE will aggregate methylation over
#' corresponding bins for each region (all bin1's aggregated, all bin2's, etc).
#' byRegionGroup = FALSE is deprecated.
#' @param minBaseCovPerBin Filter out bins where the sum of coverage values is
#' less than X before returning.
#' @param splitFactor With default NULL, aggregation will be done
#' separately/individually for each sample.
#' @param hasCoverage Default TRUE. Whether there is a coverage column
#'
#' @return With splitFactor = NULL, it will return a data.table
#' with binNum rows,
#' containing aggregated methylation data over regions in region set "rangeDT".
#' Each region was split into bins; methylation was put in these bins;
#' Output contains sum of the all corresponding bins
#' for the regions of each region set ie for all regions in each region set:
#' first bins summed, second bins summed, etc.
#' Columns of the output should be "bin", "methylProp", and, if
#' coverage was included as input col, "coverage"
#'
#' Info about how strand of rangeDT affects output:
#' The MIRA profile will be symmetrical if no strand information is given for
#' the regions (produced by averaging the profile with the reverse of the
#' profile), because the orientation of the regions is arbitrary with respect
#' to biological features (like a promoter for instance) that could be
#' oriented directionally (e.g. 5' to 3'). If strand information is given,
#' regions on the minus strand will be flipped before being aggregated
#' with plus strand regions so the MIRA profile will be in
#' 5' to 3' orientation.
#' @examples
#' data("exampleBSDT") # exampleBSDT
#' data("exampleRegionSet") # exampleRegionSet
#' exampleBSDT <- addMethPropCol(exampleBSDT)
#' aggregateBins <- BSBinAggregate(BSDT = exampleBSDT,
#' rangeDT = exampleRegionSet,
#' binNum = 11, splitFactor = NULL)
#'
#' @export
BSBinAggregate <- function(BSDT, rangeDT, binNum, minBaseCovPerBin = 500,
byRegionGroup = TRUE, splitFactor = NULL,
hasCoverage = TRUE) {
# BSDT should not be a list but can be converted
if (is(BSDT, "list")) {
if (length(BSDT) == 1) {
BSDT <- BSDT[[1]]
} else {
stop(cleanws("Only one BSDT may be given to function.
BSDT should not be a list."))
}
}
if (!is(BSDT, "data.table")) {
stop("BSDT must be a data.table")
}
# if given GRanges object, change to DT
if (is(rangeDT, "GRanges")) {
rangeDT <- grToDt(GR = rangeDT, includeStrand = TRUE)
}
if (!is(rangeDT, "data.table")) {
stop("rangeDT must be a data.table")
}
seqnamesColName <- "seqnames" # default column name
if ("chr" %in% colnames(rangeDT)) {
# message("seqnames column name set to: chr")
seqnamesColName <- "chr"
} else {
# Got neither.
stop("rangeDT must have a seqnames or chr column")
}
if (! ("strand" %in% colnames(rangeDT))) {
rangeDT[, strand := "*"]
warning("Since strand not given, set to '*' ")
}
## if (!silent) {
# message("Binning...")
##}
binnedDT <- rangeDT[, binRegion(start, end,
binNum, get(seqnamesColName), strand)]
binnedGR <- sapply(split(binnedDT, binnedDT$binID), dtToGr)
# message("Aggregating...")
if (hasCoverage) {
# aggregate methylation (mean) and sum coverage values
aggrJCommand <- buildJ(c("methylProp", "coverage"),
c("mean", "sum"))
} else {
# if no coverage only aggregate methylation level
aggrJCommand <- buildJ("methylProp", "mean")
}
binnedBSDT <- BSAggregate(BSDT = BSDT,
regionsGRL = GRangesList(binnedGR),
jCommand = aggrJCommand,
byRegionGroup = byRegionGroup,
splitFactor = splitFactor,
hasCoverage = hasCoverage)
# binnedBSDT will be NULL if there was absolutely no overlap between
# region set and BSDT
# don't do some of the following steps if there is no overlap/binnedBSDT is NULL
if (is.null(binnedBSDT)) {
warning(cleanws("No overlap between sample (BSDT) and region set.
Returning NULL for this sample, region set combination."))
} else {
# If we aren't aggregating by bin, then don't restrict to min reads!
if (byRegionGroup) {
if (hasCoverage) {
# only keep rows (bins) with coverage >= minBaseCovPerBin
binnedBSDT <- binnedBSDT[coverage >= minBaseCovPerBin, ]
}
if (NROW(binnedBSDT) < binNum) {
# telling user what sample failed if sample name is in BSDT
if ("sampleName" %in% names(BSDT)) {
thisSample <- BSDT[1, sampleName]
} else {
thisSample <- "this sample"
}
warning(paste0("Less than minBaseCovPerBin. Unable to return bins for ",
thisSample, " for this region set."))
}
}
}
return(binnedBSDT)
}
# BSaggregate: Aggregate a BSDT across regions or region groups,
# for multiple samples at a time.
# This function is as BScombineByRegion, but can handle not only multiple
# samples in BSDT, but also simultaneously multiple region sets by passing
# a regionsGRL (GRangesList object).However currently code for symmetrical
# averaging will cause it to only work with one region set (which may be
# split up into multiple GRanges in a GRangesList).
# you can use jCommand to do other functions.
# Given a bisulfite data table as input, with an identifier column for
# different samples; plus a GRanges objects with regions to aggregate.
#
# @param BSDT The bisulfite data.table (output from one of the parsing
# functions for methylation calls) that you wish to aggregate. It can
# be a combined table, with individual samples identified by column passed
# to splitFactor. "chr", "start", "methylCount" columns should be in BSDT.
# "coverage", and "methylProp" columns are optional (hasCoverage
# must be set to FALSE if there is not coverage column)
# @param regionsGRL Regions across which you want to aggregate.
# @param excludeGR A GenomicRanges object with regions you want to
# exclude from the aggregation function. These regions will be eliminated
# from the input table and not counted.
# @param regionsGRL.length Vector with number of regions in each bin.
# From bin1 to binN. With default NULL value, it will be auto assigned.
# @param splitFactor Used to make "by string" to be plugged into a data.table
# "by=" statemnt. With default NULL value, by string will be "list(regionID)"
# @param keepCols Deprecated, NULL value should be used for MIRA aggregation.
# @param sumCols Deprecated, NULL value should be used for MIRA aggregation.
# @param jCommand You can pass a custom command in the j slot to data.table
# specifying which columns to aggregate, and which functions to use. You
# can use buildJ() to build a jCommand argument easily. jCommand may be
# used twice so changing column names in the jCommand could introduce errors
# @param byRegionGroup You can aggregate by regionID or by regionGroupID;
# this reflects the regionsGRL that you pass; by default, BSAggregate will
# aggregate each region individually -- scores will then be contiguous, and
# the output is 1 row per region.
# Turn on this flag to aggregate across all region groups, making the result
# uncontiguous, and resulting in 1 row per *region group*.
# (byRegionGroup=TRUE is used for normal MIRA behaviour that
# aggregates across regions by bins
# -- all bin1's together, all bin2's together etc.--, in which case
# "region group" in the description above refers to bin number,
# and you would have 1 row per bin)
# @param keep.na Not used in general MIRA context.
# @param hasCoverage Default TRUE. Assuming there is a coverage column
# unless told otherwise
#
# @return In context of MIRA, with byRegionGroup = TRUE and jCommand =
# list( methylProp = mean(methylProp), coverage = sum(coverage) )",
# this function will return a data.table with
# binNum rows (parameter for BSBinAggregate)
# containing aggregated methylation from BSDT over binned regions from a region
# set.
#
BSAggregate <- function(BSDT, regionsGRL, excludeGR = NULL,
regionsGRL.length = NULL, splitFactor = NULL,
keepCols = NULL, sumCols = NULL, jCommand = NULL,
byRegionGroup = FALSE, keep.na = FALSE, hasCoverage = TRUE) {
# Assert that regionsGRL is a GRL.
# If regionsGRL is given as a GRanges, we convert to GRL
if (is(regionsGRL, "GRanges")) {
regionsGRL <- GRangesList(regionsGRL);
} else if (!is(regionsGRL, "GRangesList")) {
stop("regionsGRL is not a GRanges or GRangesList object");
}
# make sure methylProp column is present
if (!("methylProp" %in% colnames(BSDT))) {
stop("BSDT must have a methylProp column.")
}
if (! is.null(excludeGR)) {
BSDT <- BSFilter(BSDT, minReads = 0, excludeGR)
}
bsgr <- BSdtToGRanges(list(BSDT));
colModes <- sapply(BSDT, mode);
if (is.null(sumCols)) {
sumCols <- setdiff(colnames(BSDT), c("chr", "start", "end",
"strand", splitFactor, keepCols))
# Restrict to numeric columns.
sumCols <- intersect(sumCols,
names(colModes[which(colModes == "numeric")]))
}
# It's required to do a findoverlaps on each region individually,
# Not on a GRL, because of the way overlaps with GRLs work. So,
# we must convert the GRL to a GR, but we must keep track of which
# regions came from which group.
regionsGR <- unlist(regionsGRL)
if (is.null(regionsGRL.length)) {
if (length(regionsGRL) > 100) {
message(cleanws("BSAggregate: Calculating sizes. You can speed this
up by supplying a regionsGRL.length vector..."),
appendLF = FALSE)
}
regionsGRL.length <- sapply(regionsGRL, length)
# message("Done counting regionsGRL lengths.");
}
# Build a table to keep track of which regions belong to which group
region2group <- data.table(
regionID = seq_along(regionsGR),
chr = as.vector(seqnames(regionsGR)),
start = as.vector(start(regionsGR)),
end = as.vector(end(regionsGR)),
withinGroupID = as.vector(unlist(sapply(regionsGRL.length, seq))),
regionGroupID = rep(seq_along(regionsGRL), regionsGRL.length))
setkey(region2group, regionID)
# message("Finding overlaps...");
fo <- findOverlaps(bsgr[[1]], regionsGR)
setkey(BSDT, chr, start)
# Gut check:
# stopifnot(all(elementMetadata(bsgr[[1]])$coverage == BSDT$coverage))
# message("Setting regionIDs...");
BSDT <- BSDT[queryHits(fo), ] # restrict the table to CpGs in any region.
if (NROW(BSDT) < 1) {
# warning("No BSDT sites in the given region list.
# Please expand your regionsGRL")
return(NULL)
}
BSDT[, regionID := subjectHits(fo)] # record which region they overlapped.
# if (!keep.na) {
# BSDT <- BSDT[queryHits(fo), ]
#}
if (is.null(jCommand)) {
cols <- c(sumCols, keepCols)
funcs <- c(rep("sum", length(sumCols)), rep("unique", length(keepCols)))
jCommand <- buildJ(cols, funcs)
}
# message("jCommand: ", jCommand)
# Build the by string
if (is.null(splitFactor)) {
byString <- paste0("list(regionID)");
} else {
byString <- paste0("list(", paste("regionID", paste0(splitFactor, ""),
collapse = ",", sep = ","), ")")
}
# Now actually do the aggregate:
# message("Combining...");
# for MIRA: average methylProp and sum coverage within each instance of
# each bin (ie average methylProp's in bin1 of first region, average
# methylProp's in bin1 of second region etc. for all bins and all regions
# separately)
bsCombined <- BSDT[, eval(parse(text = jCommand)),
by = eval(parse(text = byString))]
setkey(bsCombined, regionID)
# Now aggregate across groups.
# I do this in 2 steps to avoid assigning regions to groups,
# which takes awhile. I think this preserves memory and is faster.
# Define aggregation column. aggregate by region or by region group?
if (byRegionGroup) {
# must set allow = TRUE here in case there are multiple IDs (splitCol)
# adds regionGroupID column from region2group to bsCombined
bsCombined[region2group, regionGroupID := regionGroupID, allow = TRUE]
if (! is.null(splitFactor)) {
byStringGroup <- paste0("list(",
paste("regionGroupID",
paste0(splitFactor, collapse = ","),
sep = ","),
")")
} else {
byStringGroup <- "list(regionGroupID)"
}
# actual aggregation operation
# for normal MIRA use: averaging methylProp's and summing
# coverage for all bins with the same number (ie all
# bin1's together, all bin2's together, etc.)
# NOTE: 2nd use of the jCommand so if the first jCommand use changed
# column names that are required by the jCommand
# then this 2nd jCommand use will cause an error
bsCombined <- bsCombined[, eval(parse(text = jCommand)),
by = eval(parse(text = byStringGroup))]
# if any strand information was not given, averaging the profiles
# about the center to account for unknown strand orientation,
# also averaging coverage about center
# ie if any "*" are present then average
if ("*" %in% unique(as.character(strand(regionsGR)))) {
bsCombined[, methylProp := (methylProp + rev(methylProp)) / 2]
if (hasCoverage) {
bsCombined[, coverage := (coverage + rev(coverage)) / 2]
}
}
# changing "regionGroupID" name to "bin" which is less confusing
# for normal MIRA use cases
setnames(bsCombined, old = "regionGroupID", new = "bin")
return(bsCombined[]);
} else {
warning(cleanws("Using byRegionGroup = FALSE may
result in missing functionalities such as symmetrical averaging"))
e <- region2group[bsCombined, ]
setkey(e, regionID);
return(e);
}
# WARNING: There are now 2^2 ways to aggregate, sum vs mean
# at each level: across regions, then across region sets. THis
# doesn't give you a choice at this point.
}
#' Divide region into similarly sized bins.
#'
#' Given a start, end, and number of bins, to divide,
#' this function will split the regions into bins.
#' Bins will be only approximately the same size, due to rounding.
#' (they should not be more than 1 different).
#'
#' Use case: take a set of regions, like CG islands, and bin them; now you can
#' aggregate signal scores across the bins, giving you an aggregate signal
#' in bins across many regions of the same type.
#'
#' In theory, this just runs on 3 values, but you can run it inside a
#' data.table j expression to divide a bunch of regions in the same way.
#' @param start Coordinate for beginning of range/range.
#' @param end Coordinate for end of range/region.
#' @param bins How many bins to divide this range/region.
#' @param idDF A string/vector of strings that has chromosome (e.g. "chr1")
#' for given start and end values
#' @param strand "strand" column of the data.table (or single
#' strand value if binRegion is only used on one region). Default is "*".
#'
#' @return
#' A data.table, expanded to nrow = number of bins, with these id columns:
#' id: region ID
#' binID: repeating ID (this is the value to aggregate across)
#' ubinID: unique bin IDs
#' @export
#' @examples
#' library(data.table)
#' start <- c(100, 1000, 3000)
#' end <- c(500, 1400, 3400)
#' chr <- c("chr1", "chr1", "chr2")
#' strand <- c("*", "*", "*")
#' # strand not included in object
#' # since MIRA assumes "*" already unless given something else
#' regionsToBinDT <- data.table(chr, start, end)
#' numberOfBins <- 15
#' # data.table "j command" using column names and numberOfBins variable
#' binnedRegionDT <- regionsToBinDT[, binRegion(start, end, numberOfBins, chr)]
binRegion <- function(start, end, bins, idDF = NULL, strand = "*") {
# if (!is.null(idDF) & (!is(idDF, "data.frame"))) {
# stop("idDF should be a data.frame")
#}
# conditionally altered later
finalColNames <- c("chr", "start", "end", "id", "binID", "ubinID")
if (!("*" %in% strand)) {
if ("+" %in% strand) {
plusIndex <- which(strand == "+")
# once for plus strand coordinates
plusStart <- start[plusIndex]
plusEnd <- end[plusIndex]
binSize <- (plusEnd - plusStart) / (bins)
breaks <- round(rep(plusStart, each = (bins + 1))
+ (0:(bins)) * rep(binSize, each = (bins + 1)))
endpoints <- (bins + 1) * (1:(length(plusStart)))
startpoints <- 1 + (bins + 1) * (0:(length(plusStart) - 1))
plusDT <- data.table(start = breaks[-endpoints],
end = breaks[-startpoints],
id = rep(plusIndex, each = bins),
binID = 1:bins,
strand = "+",
key = "id")
dt <- plusDT # placeholder but may be returned
}
if ("-" %in% strand) {
minusIndex <- which(strand == "-")
minusStart <- start[minusIndex]
minusEnd <- end[minusIndex]
binSize <- (minusEnd - minusStart) / (bins)
breaks <- round(rep(minusStart, each = (bins + 1))
+ (0:(bins)) * rep(binSize, each = (bins + 1)))
endpoints <- (bins + 1) * (1:(length(minusStart)))
startpoints <- 1 + (bins + 1) * (0:(length(minusStart) - 1))
minusDT <- data.table(start = breaks[-endpoints],
end = breaks[-startpoints],
id = rep(minusIndex, each = bins),
binID = bins:1,
strand = "-",
key = "id")
dt <- minusDT # placeholder but may be returned
}
# if there are both + and - strands
# combining and sorting plus and minus data.tables
if (("+" %in% strand) && ("-" %in% strand)) {
dt <- rbindlist(list(plusDT, minusDT))
setorder(x = dt, id, binID) # setorder(dt, id) might also work?
}
# included only if + /- are present
finalColNames <- c(finalColNames, "strand")
dt[, ubinID := 1:nrow(dt)]
}else { # some strand information is "*", don't flip bin directions
binSize <- (end - start) / (bins)
breaks <- round(rep(start, each = (bins + 1))
+ (0:(bins)) * rep(binSize, each = (bins + 1)))
endpoints <- (bins + 1) * (1:(length(start)))
startpoints <- 1 + (bins + 1) * (0:(length(start) - 1))
# do all regions in the same order
dt <- data.table(start = breaks[-endpoints],
end = breaks[-startpoints],
id = rep((seq_along(start)), each = bins),
binID = 1:bins,
ubinID = seq_along(breaks[-startpoints]),
key = "id")
}
if (!is.null(idDF)) {
chr <- rep(idDF, each = bins)
dt <- dt[, chr := chr]
setcolorder(dt, finalColNames) # putting chr first, does not copy
}
return(dt[])
}
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