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R/peelingOneIterate.R
In DiNAMIC.Duo: Finding Recurrent DNA Copy Number Alterations and Differences
#' A Function to Apply the Peeling Algorithm in a Single Copy Number Matrix
#'
#' This function iteratively applies the peelingOne function, thereby identifying multiple
#'
#' peaks across the genome in a single cohort. Gains and losses should be analyzed separately.
#'
#' @param X A matrix of normalized gene-level copy number data (rows = genes, columns = subjects).
#'
#' @param posDT A data frame containing genomic position information for the genes in X.
#'
#' @param gain A logical value indicating whether gains (TRUE) or losses (FALSE) will be peeled.
#'
#' Default = TRUE.
#'
#' @param nullDist An empirical null distribution produced by the cyclic shift algorithm.
#'
#' Default = NULL.
#'
#' @param threshold A tuning parameter that controls the size of the peeled region. Rows of X
#'
#' with mean copy number less than threshold will not be peeled. Default = NULL.
#'
#' @param numIters The number of times peelingOne will be iterated. Default = 5.
#'
#' @return A list containing two elements: X and interval. X is an updated version of the input
#' copy number matrix in which the peak at k has been removed, and interval is genomic region
#' containing k. By construction, interval cannot extend beyond the chromosome arm containing k.
#'
#' @details The \code{\link{peelingOne}} function applies the peeling algorithm described by
#' Walter et al. (Bioinformatics, 2011;27(5):678–685) at a given marker k. Because tumor genomes
#' may contain multiple regions of copy number gain or loss, it important to apply the peeling
#' process iteratively, thereby identifying multiple markers and surrounding genomic regions.
#'
#' @examples lusc=pD[["X"]]
#'
#' posDT=pD[["posDT"]]
#'
#' gain = TRUE
#'
#' nullDist = NULL
#'
#' threshold = NULL
#'
#' numIters = 3
#'
#' peeledLusc=peelingOneIterate(X=lusc,posDT=posDT,gain=TRUE,nullDist=NULL,threshold=NULL,numIters=3)
#'
#' @export
peelingOneIterate = function (X, posDT, gain = TRUE, nullDist = NULL, threshold = NULL, numIters = 5)
{
output = data.frame(chr = rep(NA, numIters), peelStart = rep(NA, numIters), peelStop = rep(NA, numIters),
peakLoc = rep(NA, numIters), peakVal = rep(NA, numIters), peakPVal = rep(NA, numIters))
gainLossInd = (-1)^(1 + gain)
X1 = X * gainLossInd
for (i in 1:numIters)
{
tempK = which.max(rowMeans(X1))
tempPeakVal = gainLossInd * signif(rowMeans(X1)[tempK], 4)
tempPeakPVal = ifelse(is.null(nullDist), NA, (1 + sum(nullDist > tempPeakVal))/length(nullDist) * (gainLossInd == 1) +
(1 + sum(nullDist < tempPeakVal))/length(nullDist) * (gainLossInd == -1))
tempPeakPval = min(tempPeakPVal, 1)
tempPeel = peelingOne(X = X1, posDT = posDT, k = tempK, threshold = threshold)
output[i,] = c(posDT[tempK, 1], tempPeel[[2]][1], tempPeel[[2]][2], posDT[tempK, 2],
tempPeakVal, tempPeakPVal)
X1 = tempPeel[[1]]
}
return(output)
}
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#' A Function to Apply the Peeling Algorithm in a Single Copy Number Matrix
#'
#' This function iteratively applies the peelingOne function, thereby identifying multiple
#'
#' peaks across the genome in a single cohort. Gains and losses should be analyzed separately.
#'
#' @param X A matrix of normalized gene-level copy number data (rows = genes, columns = subjects).
#'
#' @param posDT A data frame containing genomic position information for the genes in X.
#'
#' @param gain A logical value indicating whether gains (TRUE) or losses (FALSE) will be peeled.
#'
#' Default = TRUE.
#'
#' @param nullDist An empirical null distribution produced by the cyclic shift algorithm.
#'
#' Default = NULL.
#'
#' @param threshold A tuning parameter that controls the size of the peeled region. Rows of X
#'
#' with mean copy number less than threshold will not be peeled. Default = NULL.
#'
#' @param numIters The number of times peelingOne will be iterated. Default = 5.
#'
#' @return A list containing two elements: X and interval. X is an updated version of the input
#' copy number matrix in which the peak at k has been removed, and interval is genomic region
#' containing k. By construction, interval cannot extend beyond the chromosome arm containing k.
#'
#' @details The \code{\link{peelingOne}} function applies the peeling algorithm described by
#' Walter et al. (Bioinformatics, 2011;27(5):678–685) at a given marker k. Because tumor genomes
#' may contain multiple regions of copy number gain or loss, it important to apply the peeling
#' process iteratively, thereby identifying multiple markers and surrounding genomic regions.
#'
#' @examples lusc=pD[["X"]]
#'
#' posDT=pD[["posDT"]]
#'
#' gain = TRUE
#'
#' nullDist = NULL
#'
#' threshold = NULL
#'
#' numIters = 3
#'
#' peeledLusc=peelingOneIterate(X=lusc,posDT=posDT,gain=TRUE,nullDist=NULL,threshold=NULL,numIters=3)
#'
#' @export
peelingOneIterate = function (X, posDT, gain = TRUE, nullDist = NULL, threshold = NULL, numIters = 5)
{
output = data.frame(chr = rep(NA, numIters), peelStart = rep(NA, numIters), peelStop = rep(NA, numIters),
peakLoc = rep(NA, numIters), peakVal = rep(NA, numIters), peakPVal = rep(NA, numIters))
gainLossInd = (-1)^(1 + gain)
X1 = X * gainLossInd
for (i in 1:numIters)
{
tempK = which.max(rowMeans(X1))
tempPeakVal = gainLossInd * signif(rowMeans(X1)[tempK], 4)
tempPeakPVal = ifelse(is.null(nullDist), NA, (1 + sum(nullDist > tempPeakVal))/length(nullDist) * (gainLossInd == 1) +
(1 + sum(nullDist < tempPeakVal))/length(nullDist) * (gainLossInd == -1))
tempPeakPval = min(tempPeakPVal, 1)
tempPeel = peelingOne(X = X1, posDT = posDT, k = tempK, threshold = threshold)
output[i,] = c(posDT[tempK, 1], tempPeel[[2]][1], tempPeel[[2]][2], posDT[tempK, 2],
tempPeakVal, tempPeakPVal)
X1 = tempPeel[[1]]
}
return(output)
}
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