R/Simulate_set.R
In kdkorthauer/scDD: Mixture modeling of single-cell RNA-seq data to identify genes with differential distributions
Defines functions
simulateSet
Documented in
simulateSet
#' simulateSet
#'
#' Simulation of a complete dataset, where the number of each type of
#' differential distributions and equivalent distributions is specified.
#'
#' @inheritParams singleCellSimu
#'
#' @inheritParams scDD
#'
#' @inheritParams findFC
#'
#' @param nDE Number of DE genes to simulate
#'
#' @param nDP Number of DP genes to simulate
#'
#' @param nDM Number of DM genes to simulate
#'
#' @param nDB Number of DB genes to simulate
#'
#' @param nEE Number of EE genes to simulate
#'
#' @param nEP Number of EP genes to simulate
#'
#' @param plots Logical indicating whether or not to generate fold change and
#' validation plots
#'
#' @param random.seed Numeric value for a call to \code{set.seed} for
#' reproducibility.
#'
#' @param plot.file Character containing the file string if the plots are to be
#' sent to a pdf instead of to the standard output.
#'
#' @param param a \code{MulticoreParam} or \code{SnowParam} object of
#' the \code{BiocParallel}
#' package that defines a parallel backend. The default option is
#' \code{BiocParallel::bpparam()} which will automatically creates a cluster
#' appropriate for
#' the operating system. Alternatively, the user can specify the number
#' of cores they wish to use by first creating the corresponding
#' \code{MulticoreParam} (for Linux-like OS) or \code{SnowParam} (for Windows)
#' object, and then passing it into the \code{scDD}
#' function. This could be done to specify a parallel backend on a Linux-like
#' OS with, say 12
#' cores by setting \code{param=BiocParallel::MulticoreParam(workers=12)}
#'
#' @inheritParams singleCellSimu
#'
#' @inheritParams findIndex
#'
#' @import SingleCellExperiment
#'
#' @importFrom BiocParallel register
#'
#' @import SingleCellExperiment
#'
#' @export
#'
#'
#' @references Korthauer KD, Chu LF, Newton MA, Li Y, Thomson J, Stewart R,
#' Kendziorski C. A statistical approach for identifying differential
#' distributions
#' in single-cell RNA-seq experiments. Genome Biology. 2016 Oct 25;17(1):222.
#' \url{https://genomebiology.biomedcentral.com/articles/10.1186/s13059-016-
#' 1077-y}
#'
#' @return An object of class \code{SingleCellExperiment} that contains
#' simulated single-cell expression and metadata. The \code{assays}
#' slot contains a named list of matrices, where the simulated counts are
#' housed in the one named \code{normcounts}. This matrix should have one
#' row for each gene (\code{nDE + nDP + nDM + nDB + nEE
#' + nEP} rows) and one sample for each column (\code{numSamples} columns).
#' The \code{colData} slot contains a data.frame with one row per
#' sample and a column that represents biological condition, which is
#' in the form of numeric values (either 1 or 2) that indicates which
#' condition each sample belongs to (in the same order as the columns of
#' \code{normcounts}). The \code{rowData} slot contains information about the
#' category of the gene (EE, EP, DE, DM, DP, or DB), as well as the simulated
#' foldchange value.
#'
#' @examples
#'
#' # Load toy example ExpressionSet to simulate from
#'
#' data(scDatEx)
#'
#'
#' # check that this object is a member of the ExpressionSet class
#' # and that it contains 142 samples and 500 genes
#'
#' class(scDatEx)
#' show(scDatEx)
#'
#'
#' # set arguments to pass to simulateSet function
#' # we will simuate 30 genes total; 5 genes of each type;
#' # and 100 samples in each of two conditions
#'
#' nDE <- 5
#' nDP <- 5
#' nDM <- 5
#' nDB <- 5
#' nEE <- 5
#' nEP <- 5
#' numSamples <- 100
#' seed <- 816
#'
#'
#' # create simulated set with specified numbers of DE, DP, DM, DM, EE, and
#' # EP genes,
#' # specified number of samples, DE genes are 2 standard deviations apart, and
#' # multimodal genes have modal distance of 4 standard deviations
#'
#' SD <- simulateSet(scDatEx, numSamples=numSamples, nDE=nDE, nDP=nDP, nDM=nDM,
#' nDB=nDB, nEE=nEE, nEP=nEP, sd.range=c(2,2), modeFC=4,
#' plots=FALSE,
#' random.seed=seed)
simulateSet <- function(SCdat, numSamples=100,
nDE=250, nDP=250, nDM=250, nDB=250,
nEE=5000, nEP=4000, sd.range=c(1,3), modeFC=c(2,3,4),
plots=TRUE, plot.file=NULL, random.seed=284,
varInflation=NULL, condition="condition",
param=bpparam()){
if(!is.null(plot.file)){
pdf(file=paste0(plot.file))
}
# reference category/condition - the first listed one
ref <- unique(colData(SCdat)[[condition]])[1]
message(paste0("Setting up parallel back-end using ",
param$workers, " cores" ))
BiocParallel::register(BPPARAM = param)
message("Identifying a set of genes to simulate from...")
index <- findIndex(SCdat, condition)
message("Simulating DE fold changes...")
FC <- findFC(SCdat, index, sd.range=sd.range, N=6, overExpressionProb = 0.5,
plot.FC=plots, condition)
constantZero <- NULL
generateZero <- "empirical"
message("Simulating individual genes...")
# pull off matrix of expression values for condition 1
Dataset1 <- normcounts(SCdat[,colData(SCdat)[[condition]]==ref])
set.seed(random.seed)
# initialize pe_mat and fcs
pe_mat <- NULL
fcs <- NULL
### DE
if (nDE > 0){
SD1 <- singleCellSimu(Dataset1, Method = "DE", index, FC, modeFC,
Validation = FALSE, numGenes=nDE, numDE=nDE,
numSamples=numSamples, generateZero=generateZero,
constantZero=constantZero, varInflation)
Simulated_Data <- SD1[[1]]
rnms <- rep("EE", nrow(Simulated_Data))
rnms[SD1[[2]]] <- "DE"
rownames(Simulated_Data) <- rnms
pe_mat <- Simulated_Data
fcs <- SD1[[3]]
}
### DP
if (nDP > 0){
SD2 <- singleCellSimu(Dataset1, Method = "DP", index, FC, modeFC,
DP = c(0.33,0.66), Validation = FALSE,
numGenes=nDP, numDE=nDP, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation=varInflation)
Simulated_Data_DP <- SD2[[1]]
rnms <- rep("EE", nrow(Simulated_Data_DP))
rnms[SD2[[2]]] <- "DP"
rownames(Simulated_Data_DP) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_DP)
fcs <- c(fcs, SD2[[3]])
}
### DM
if (nDM > 0){
SD3 <- singleCellSimu(Dataset1, Method = "DM", index, FC, modeFC,
Validation = FALSE,
numGenes=nDM, numDE=nDM, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation)
Simulated_Data_DM <- SD3[[1]]
rnms <- rep("EE", nrow(Simulated_Data_DM))
rnms[SD3[[2]]] <- "DM"
rownames(Simulated_Data_DM) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_DM)
fcs <- c(fcs, SD3[[3]])
}
### DB
if (nDB > 0){
SD4 <- singleCellSimu(Dataset1, Method = "DB", index, FC, modeFC,
DP = c(0.5,0.5), Validation = FALSE,
numGenes=nDB, numDE=nDB, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation)
Simulated_Data_DB <- SD4[[1]]
rnms <- rep("EE", nrow(Simulated_Data_DB))
rnms[SD4[[2]]] <- "DB"
rownames(Simulated_Data_DB) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_DB)
fcs <- c(fcs, SD4[[3]])
}
### EP
if (nEP > 0){
SD5 <- singleCellSimu(Dataset1, Method = "DP", index, FC, modeFC,
DP = c(0.50,0.50), Validation = FALSE,
numGenes=nEP, numDE=0, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation)
Simulated_Data_EP <- SD5[[1]]
rnms <- rep("EP", nrow(Simulated_Data_EP))
rnms[SD5[[2]]] <- "DP"
rownames(Simulated_Data_EP) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_EP)
fcs <- c(fcs, SD5[[3]])
}
### EE
if (nEE > 0){
SD6<- singleCellSimu(Dataset1, Method = "DE", index, FC, modeFC,
Validation = plots,
numGenes=nEE, numDE=0, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation=varInflation)
Simulated_Data_EE <- SD6[[1]]
rnms <- rep("EE", nrow(Simulated_Data_EE))
rnms[SD6[[2]]] <- "DE"
rownames(Simulated_Data_EE) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_EE)
fcs <- c(fcs, rep(NA, nEE))
}
names(fcs) <- rownames(pe_mat)
if (nDE + nDP + nDM + nDB + nEE + nEP == 0){
stop("Error: This function simulates gene expression data, but the number of
genes to simulate was set to zero. Please specify a nonzero number of
either DE, DP, DM, DB, EE, or EP genes.")
}
if (!is.null(plot.file)){
dev.off()
}
# continuity correction
unifmat <- matrix(runif(nrow(pe_mat)*ncol(pe_mat)), nrow=nrow(pe_mat),
ncol=ncol(pe_mat))
pe_mat2 <- pe_mat + unifmat
pe_mat2[pe_mat==0] <- 0
SD <- list(Simulated_Data=pe_mat2, FC=fcs)
condition <- c(rep(1, numSamples), rep(2, numSamples))
fcs <- data.frame(Category=names(fcs),
FC=as.numeric(fcs))
rownames(SD[[1]]) <- paste0(rownames(SD[[1]]), 1:nrow(SD[[1]]), sep="")
rownames(fcs) <- rownames(SD[[1]])
colnames(SD[[1]]) <- names(condition) <- paste0("Sample",
1:ncol(SD[[1]]), sep="")
sce <- SingleCellExperiment(assays=list(normcounts=SD[[1]]),
colData=data.frame(condition),
rowData=fcs)
message(paste0("Done! Simulated ", nDE, " DE, ", nDP, " DP, ", nDM, " DM, ",
nDB, " DB, ", nEE, " EE, and ", nEP, " EP genes "))
return(sce)
}
kdkorthauer/scDD documentation built on March 27, 2022, 5:11 a.m.
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Defines functions simulateSet
Documented in simulateSet
#' simulateSet
#'
#' Simulation of a complete dataset, where the number of each type of
#' differential distributions and equivalent distributions is specified.
#'
#' @inheritParams singleCellSimu
#'
#' @inheritParams scDD
#'
#' @inheritParams findFC
#'
#' @param nDE Number of DE genes to simulate
#'
#' @param nDP Number of DP genes to simulate
#'
#' @param nDM Number of DM genes to simulate
#'
#' @param nDB Number of DB genes to simulate
#'
#' @param nEE Number of EE genes to simulate
#'
#' @param nEP Number of EP genes to simulate
#'
#' @param plots Logical indicating whether or not to generate fold change and
#' validation plots
#'
#' @param random.seed Numeric value for a call to \code{set.seed} for
#' reproducibility.
#'
#' @param plot.file Character containing the file string if the plots are to be
#' sent to a pdf instead of to the standard output.
#'
#' @param param a \code{MulticoreParam} or \code{SnowParam} object of
#' the \code{BiocParallel}
#' package that defines a parallel backend. The default option is
#' \code{BiocParallel::bpparam()} which will automatically creates a cluster
#' appropriate for
#' the operating system. Alternatively, the user can specify the number
#' of cores they wish to use by first creating the corresponding
#' \code{MulticoreParam} (for Linux-like OS) or \code{SnowParam} (for Windows)
#' object, and then passing it into the \code{scDD}
#' function. This could be done to specify a parallel backend on a Linux-like
#' OS with, say 12
#' cores by setting \code{param=BiocParallel::MulticoreParam(workers=12)}
#'
#' @inheritParams singleCellSimu
#'
#' @inheritParams findIndex
#'
#' @import SingleCellExperiment
#'
#' @importFrom BiocParallel register
#'
#' @import SingleCellExperiment
#'
#' @export
#'
#'
#' @references Korthauer KD, Chu LF, Newton MA, Li Y, Thomson J, Stewart R,
#' Kendziorski C. A statistical approach for identifying differential
#' distributions
#' in single-cell RNA-seq experiments. Genome Biology. 2016 Oct 25;17(1):222.
#' \url{https://genomebiology.biomedcentral.com/articles/10.1186/s13059-016-
#' 1077-y}
#'
#' @return An object of class \code{SingleCellExperiment} that contains
#' simulated single-cell expression and metadata. The \code{assays}
#' slot contains a named list of matrices, where the simulated counts are
#' housed in the one named \code{normcounts}. This matrix should have one
#' row for each gene (\code{nDE + nDP + nDM + nDB + nEE
#' + nEP} rows) and one sample for each column (\code{numSamples} columns).
#' The \code{colData} slot contains a data.frame with one row per
#' sample and a column that represents biological condition, which is
#' in the form of numeric values (either 1 or 2) that indicates which
#' condition each sample belongs to (in the same order as the columns of
#' \code{normcounts}). The \code{rowData} slot contains information about the
#' category of the gene (EE, EP, DE, DM, DP, or DB), as well as the simulated
#' foldchange value.
#'
#' @examples
#'
#' # Load toy example ExpressionSet to simulate from
#'
#' data(scDatEx)
#'
#'
#' # check that this object is a member of the ExpressionSet class
#' # and that it contains 142 samples and 500 genes
#'
#' class(scDatEx)
#' show(scDatEx)
#'
#'
#' # set arguments to pass to simulateSet function
#' # we will simuate 30 genes total; 5 genes of each type;
#' # and 100 samples in each of two conditions
#'
#' nDE <- 5
#' nDP <- 5
#' nDM <- 5
#' nDB <- 5
#' nEE <- 5
#' nEP <- 5
#' numSamples <- 100
#' seed <- 816
#'
#'
#' # create simulated set with specified numbers of DE, DP, DM, DM, EE, and
#' # EP genes,
#' # specified number of samples, DE genes are 2 standard deviations apart, and
#' # multimodal genes have modal distance of 4 standard deviations
#'
#' SD <- simulateSet(scDatEx, numSamples=numSamples, nDE=nDE, nDP=nDP, nDM=nDM,
#' nDB=nDB, nEE=nEE, nEP=nEP, sd.range=c(2,2), modeFC=4,
#' plots=FALSE,
#' random.seed=seed)
simulateSet <- function(SCdat, numSamples=100,
nDE=250, nDP=250, nDM=250, nDB=250,
nEE=5000, nEP=4000, sd.range=c(1,3), modeFC=c(2,3,4),
plots=TRUE, plot.file=NULL, random.seed=284,
varInflation=NULL, condition="condition",
param=bpparam()){
if(!is.null(plot.file)){
pdf(file=paste0(plot.file))
}
# reference category/condition - the first listed one
ref <- unique(colData(SCdat)[[condition]])[1]
message(paste0("Setting up parallel back-end using ",
param$workers, " cores" ))
BiocParallel::register(BPPARAM = param)
message("Identifying a set of genes to simulate from...")
index <- findIndex(SCdat, condition)
message("Simulating DE fold changes...")
FC <- findFC(SCdat, index, sd.range=sd.range, N=6, overExpressionProb = 0.5,
plot.FC=plots, condition)
constantZero <- NULL
generateZero <- "empirical"
message("Simulating individual genes...")
# pull off matrix of expression values for condition 1
Dataset1 <- normcounts(SCdat[,colData(SCdat)[[condition]]==ref])
set.seed(random.seed)
# initialize pe_mat and fcs
pe_mat <- NULL
fcs <- NULL
### DE
if (nDE > 0){
SD1 <- singleCellSimu(Dataset1, Method = "DE", index, FC, modeFC,
Validation = FALSE, numGenes=nDE, numDE=nDE,
numSamples=numSamples, generateZero=generateZero,
constantZero=constantZero, varInflation)
Simulated_Data <- SD1[[1]]
rnms <- rep("EE", nrow(Simulated_Data))
rnms[SD1[[2]]] <- "DE"
rownames(Simulated_Data) <- rnms
pe_mat <- Simulated_Data
fcs <- SD1[[3]]
}
### DP
if (nDP > 0){
SD2 <- singleCellSimu(Dataset1, Method = "DP", index, FC, modeFC,
DP = c(0.33,0.66), Validation = FALSE,
numGenes=nDP, numDE=nDP, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation=varInflation)
Simulated_Data_DP <- SD2[[1]]
rnms <- rep("EE", nrow(Simulated_Data_DP))
rnms[SD2[[2]]] <- "DP"
rownames(Simulated_Data_DP) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_DP)
fcs <- c(fcs, SD2[[3]])
}
### DM
if (nDM > 0){
SD3 <- singleCellSimu(Dataset1, Method = "DM", index, FC, modeFC,
Validation = FALSE,
numGenes=nDM, numDE=nDM, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation)
Simulated_Data_DM <- SD3[[1]]
rnms <- rep("EE", nrow(Simulated_Data_DM))
rnms[SD3[[2]]] <- "DM"
rownames(Simulated_Data_DM) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_DM)
fcs <- c(fcs, SD3[[3]])
}
### DB
if (nDB > 0){
SD4 <- singleCellSimu(Dataset1, Method = "DB", index, FC, modeFC,
DP = c(0.5,0.5), Validation = FALSE,
numGenes=nDB, numDE=nDB, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation)
Simulated_Data_DB <- SD4[[1]]
rnms <- rep("EE", nrow(Simulated_Data_DB))
rnms[SD4[[2]]] <- "DB"
rownames(Simulated_Data_DB) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_DB)
fcs <- c(fcs, SD4[[3]])
}
### EP
if (nEP > 0){
SD5 <- singleCellSimu(Dataset1, Method = "DP", index, FC, modeFC,
DP = c(0.50,0.50), Validation = FALSE,
numGenes=nEP, numDE=0, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation)
Simulated_Data_EP <- SD5[[1]]
rnms <- rep("EP", nrow(Simulated_Data_EP))
rnms[SD5[[2]]] <- "DP"
rownames(Simulated_Data_EP) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_EP)
fcs <- c(fcs, SD5[[3]])
}
### EE
if (nEE > 0){
SD6<- singleCellSimu(Dataset1, Method = "DE", index, FC, modeFC,
Validation = plots,
numGenes=nEE, numDE=0, numSamples=numSamples,
generateZero=generateZero, constantZero=constantZero,
varInflation=varInflation)
Simulated_Data_EE <- SD6[[1]]
rnms <- rep("EE", nrow(Simulated_Data_EE))
rnms[SD6[[2]]] <- "DE"
rownames(Simulated_Data_EE) <- rnms
pe_mat <- rbind(pe_mat, Simulated_Data_EE)
fcs <- c(fcs, rep(NA, nEE))
}
names(fcs) <- rownames(pe_mat)
if (nDE + nDP + nDM + nDB + nEE + nEP == 0){
stop("Error: This function simulates gene expression data, but the number of
genes to simulate was set to zero. Please specify a nonzero number of
either DE, DP, DM, DB, EE, or EP genes.")
}
if (!is.null(plot.file)){
dev.off()
}
# continuity correction
unifmat <- matrix(runif(nrow(pe_mat)*ncol(pe_mat)), nrow=nrow(pe_mat),
ncol=ncol(pe_mat))
pe_mat2 <- pe_mat + unifmat
pe_mat2[pe_mat==0] <- 0
SD <- list(Simulated_Data=pe_mat2, FC=fcs)
condition <- c(rep(1, numSamples), rep(2, numSamples))
fcs <- data.frame(Category=names(fcs),
FC=as.numeric(fcs))
rownames(SD[[1]]) <- paste0(rownames(SD[[1]]), 1:nrow(SD[[1]]), sep="")
rownames(fcs) <- rownames(SD[[1]])
colnames(SD[[1]]) <- names(condition) <- paste0("Sample",
1:ncol(SD[[1]]), sep="")
sce <- SingleCellExperiment(assays=list(normcounts=SD[[1]]),
colData=data.frame(condition),
rowData=fcs)
message(paste0("Done! Simulated ", nDE, " DE, ", nDP, " DP, ", nDM, " DM, ",
nDB, " DB, ", nEE, " EE, and ", nEP, " EP genes "))
return(sce)
}
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