R/dataFilter.R
In linquynus/RCAv2-beta: Reference Component Analysis
Defines functions
dataFilter
Documented in
dataFilter
#' Filter the dataset and remove genes and cells that could be of poor quality using user-defined thresholds
#'
#' @param rca.obj RCA object.
#' @param nGene.thresholds numeric vector with lower and upper nGene thresholds
#' @param nUMI.thresholds numeric vector with lower and upper nUMI thresholds
#' @param percent.mito.thresholds numeric vector with lower and upper pMito thresholds
#' @param min.cell.exp minimum number of cells a gene must be expressed in
#' @param plot boolean - if True, plot data filter metrics
#' @param folderpath path to save data filter metric plots to
#' @param filename file name of saved plots
#' @return RCA object.
#' @export
#'
dataFilter <- function(rca.obj, nGene.thresholds = c(100, NULL), nUMI.thresholds = c(1000, NULL), percent.mito.thresholds = c(0.0, 0.2), min.cell.exp = 10, plot = T, folderpath = ".", filename = "RCA_Filter.pdf") {
if(!(require(gridExtra) && require(ggplot2))){
print("Ensure that grid.arrange and ggplot2 are installed")
}
# Extract data from RCA object
data <- rca.obj$raw.data
### Gene filter ###
if(!is.null(min.cell.exp)) {
# Select genes with expression in a minimum number of cells
geneExpVec <- Matrix::rowSums(data>0)
filt.genes <- rownames(data)[which(geneExpVec > min.cell.exp)]
} else {
filt.genes <- rownames(data)
}
### Cell filter - nGene ###
# Assign filtered data
filt.cells <- colnames(data)
if(!is.null(nGene.thresholds)) {
# Compute nGene vector
nGeneVec <- Matrix::colSums(data>0)
if(is.numeric(nGene.thresholds) & (length(nGene.thresholds) == 2)) {
nGene.filt.cells <- filt.cells[which((nGeneVec >= nGene.thresholds[1]) & (nGeneVec <= nGene.thresholds[2]))]
} else if(is.numeric(nGene.thresholds) & (length(nGene.thresholds) == 1)) {
nGene.filt.cells <- filt.cells[which(nGeneVec >= nGene.thresholds)]
} else {
warning("nGene.thresholds was not of the appropriate format. Please enter a numeric vector with lower and upper thresholds.")
nGene.filt.cells <- filt.cells
}
} else {
warning("No nGene.thresholds provided.")
nGene.filt.cells <- filt.cells
}
### Cell filter - nUMI ###
if(!is.null(nUMI.thresholds)) {
# Compute nUMI vector
nUMIVec <- Matrix::colSums(data)
if(is.numeric(nUMI.thresholds) & (length(nUMI.thresholds) == 2)) {
nUMI.filt.cells <- filt.cells[which((nUMIVec >= nUMI.thresholds[1]) & (nUMIVec <= nUMI.thresholds[2]))]
} else if(is.numeric(nGene.thresholds) & (length(nUMI.thresholds) == 1)) {
nUMI.filt.cells <- filt.cells[which(nUMIVec >= nUMI.thresholds)]
} else {
warning("nUMI.thresholds was not of the appropriate format. Please enter a numeric vector with lower and upper thresholds.")
nUMI.filt.cells <- filt.cells
}
} else {
warning("No nUMI.thresholds provided.")
nUMI.filt.cells <- filt.cells
}
### Cell filter - Mitochondrial Rate ###
if(!is.null(percent.mito.thresholds)) {
# Select mito genes
mito.genes = grep(pattern = "^MT-", x = rownames(data), value = T)
# Compute percent.mito vector
pMitoVec <- Matrix::colSums(data[mito.genes, ])/Matrix::colSums(data)
if(is.numeric(percent.mito.thresholds) & (length(percent.mito.thresholds) == 2)) {
pMito.filt.cells <- filt.cells[which((pMitoVec >= percent.mito.thresholds[1]) & (pMitoVec <= percent.mito.thresholds[2]))]
} else if(is.numeric(percent.mito.thresholds) & (length(percent.mito.thresholds) == 1)) {
pMito.filt.cells <- filt.cells[, which(pMitoVec >= percent.mito.thresholds)]
} else {
warning("percent.mito.thresholds was not of the appropriate format. Please enter a numeric vector with lower and upper thresholds.")
pMito.filt.cells <- filt.cells
}
} else {
warning("No percent.mito.thresholds provided.")
pMito.filt.cells <- filt.cells
}
# Select only the cells that satisfy all 3 cell filtering criteria
filt.cells <- intersect(intersect(nGene.filt.cells, nUMI.filt.cells), pMito.filt.cells)
# If plot is True
if(plot) {
# Create dataframe for 3D plot
cellFiltDf <- data.frame(nGene = nGeneVec, nUMI = nUMIVec, pMito = pMitoVec)
cellFiltDf$isFilt <- ifelse(test = rownames(cellFiltDf) %in% filt.cells, yes = "Retained", no = "Discarded")
# Colors for scatter plot
colors <- c("grey", "black")
# Create 2D plots for all pairwise combinations of nGene, nUMI and pMito
# nGene x pMito
# Create threshold lines
nGene.thres.lines <- lapply(nGene.thresholds, function(thres){
geom_vline(aes(xintercept = thres), color = "red", linetype="dashed", size=1)
})
pMito.thres.lines <- lapply(percent.mito.thresholds, function(thres){
geom_hline(aes(yintercept = thres), color = "red", linetype="dashed", size=1)
})
# Create plot
nGene_pMito_plot <- ggplot(data = cellFiltDf, aes(x = nGene, y = pMito, colour = isFilt)) + geom_point(size = 1) + geom_jitter() + scale_color_manual(values = colors) + nGene.thres.lines + pMito.thres.lines + theme_bw() + ggtitle("a) nGene vs pMito")+theme(legend.position="none")
# nUMI x pMito
# Create threshold lines
nUMI.thres.lines <- lapply(nUMI.thresholds, function(thres){
geom_vline(aes(xintercept = thres), color = "red", linetype="dashed", size=1)
})
# Create plot
nUMI_pMito_plot <- ggplot(data = cellFiltDf, aes(x = nUMI, y = pMito, colour = isFilt)) + geom_point(size = 1) + geom_jitter() + scale_color_manual(values = colors) + nUMI.thres.lines + pMito.thres.lines + theme_bw() + ggtitle("b) nUMI vs pMito")+theme(legend.position="none")
# nGene x nUMI
# Change nUMI threshold lines to horizontal lines
nUMI.thres.lines <- lapply(nUMI.thresholds, function(thres){
geom_hline(aes(yintercept = thres), color = "red", linetype="dashed", size=1)
})
# Create plot
nGene_nUMI_plot <- ggplot(data = cellFiltDf, aes(x = nGene, y = nUMI, colour = isFilt)) + geom_point(size = 1) + geom_jitter() + scale_color_manual(values = colors) + nGene.thres.lines + nUMI.thres.lines + theme_bw() + ggtitle("c) nGene vs nUMI")+theme(legend.position="right")+theme(legend.key.height=unit(1.5,"cm"))+labs(colour="")
pdf(file = paste0(folderpath,"/",filename), width = 15, height = 5)
# Arrange scatter plots
grid.arrange(nGene_pMito_plot, nUMI_pMito_plot, nGene_nUMI_plot, nrow = 1,widths=c(1,1,1.3))
# Save plot
dev.off()
}
# Combine results from cell and gene filtering
rca.obj$raw.data <- as(data[filt.genes, filt.cells], "dgCMatrix")
# Return
return(rca.obj)
}
linquynus/RCAv2-beta documentation built on Aug. 9, 2020, 12:34 a.m.
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Defines functions dataFilter
Documented in dataFilter
#' Filter the dataset and remove genes and cells that could be of poor quality using user-defined thresholds
#'
#' @param rca.obj RCA object.
#' @param nGene.thresholds numeric vector with lower and upper nGene thresholds
#' @param nUMI.thresholds numeric vector with lower and upper nUMI thresholds
#' @param percent.mito.thresholds numeric vector with lower and upper pMito thresholds
#' @param min.cell.exp minimum number of cells a gene must be expressed in
#' @param plot boolean - if True, plot data filter metrics
#' @param folderpath path to save data filter metric plots to
#' @param filename file name of saved plots
#' @return RCA object.
#' @export
#'
dataFilter <- function(rca.obj, nGene.thresholds = c(100, NULL), nUMI.thresholds = c(1000, NULL), percent.mito.thresholds = c(0.0, 0.2), min.cell.exp = 10, plot = T, folderpath = ".", filename = "RCA_Filter.pdf") {
if(!(require(gridExtra) && require(ggplot2))){
print("Ensure that grid.arrange and ggplot2 are installed")
}
# Extract data from RCA object
data <- rca.obj$raw.data
### Gene filter ###
if(!is.null(min.cell.exp)) {
# Select genes with expression in a minimum number of cells
geneExpVec <- Matrix::rowSums(data>0)
filt.genes <- rownames(data)[which(geneExpVec > min.cell.exp)]
} else {
filt.genes <- rownames(data)
}
### Cell filter - nGene ###
# Assign filtered data
filt.cells <- colnames(data)
if(!is.null(nGene.thresholds)) {
# Compute nGene vector
nGeneVec <- Matrix::colSums(data>0)
if(is.numeric(nGene.thresholds) & (length(nGene.thresholds) == 2)) {
nGene.filt.cells <- filt.cells[which((nGeneVec >= nGene.thresholds[1]) & (nGeneVec <= nGene.thresholds[2]))]
} else if(is.numeric(nGene.thresholds) & (length(nGene.thresholds) == 1)) {
nGene.filt.cells <- filt.cells[which(nGeneVec >= nGene.thresholds)]
} else {
warning("nGene.thresholds was not of the appropriate format. Please enter a numeric vector with lower and upper thresholds.")
nGene.filt.cells <- filt.cells
}
} else {
warning("No nGene.thresholds provided.")
nGene.filt.cells <- filt.cells
}
### Cell filter - nUMI ###
if(!is.null(nUMI.thresholds)) {
# Compute nUMI vector
nUMIVec <- Matrix::colSums(data)
if(is.numeric(nUMI.thresholds) & (length(nUMI.thresholds) == 2)) {
nUMI.filt.cells <- filt.cells[which((nUMIVec >= nUMI.thresholds[1]) & (nUMIVec <= nUMI.thresholds[2]))]
} else if(is.numeric(nGene.thresholds) & (length(nUMI.thresholds) == 1)) {
nUMI.filt.cells <- filt.cells[which(nUMIVec >= nUMI.thresholds)]
} else {
warning("nUMI.thresholds was not of the appropriate format. Please enter a numeric vector with lower and upper thresholds.")
nUMI.filt.cells <- filt.cells
}
} else {
warning("No nUMI.thresholds provided.")
nUMI.filt.cells <- filt.cells
}
### Cell filter - Mitochondrial Rate ###
if(!is.null(percent.mito.thresholds)) {
# Select mito genes
mito.genes = grep(pattern = "^MT-", x = rownames(data), value = T)
# Compute percent.mito vector
pMitoVec <- Matrix::colSums(data[mito.genes, ])/Matrix::colSums(data)
if(is.numeric(percent.mito.thresholds) & (length(percent.mito.thresholds) == 2)) {
pMito.filt.cells <- filt.cells[which((pMitoVec >= percent.mito.thresholds[1]) & (pMitoVec <= percent.mito.thresholds[2]))]
} else if(is.numeric(percent.mito.thresholds) & (length(percent.mito.thresholds) == 1)) {
pMito.filt.cells <- filt.cells[, which(pMitoVec >= percent.mito.thresholds)]
} else {
warning("percent.mito.thresholds was not of the appropriate format. Please enter a numeric vector with lower and upper thresholds.")
pMito.filt.cells <- filt.cells
}
} else {
warning("No percent.mito.thresholds provided.")
pMito.filt.cells <- filt.cells
}
# Select only the cells that satisfy all 3 cell filtering criteria
filt.cells <- intersect(intersect(nGene.filt.cells, nUMI.filt.cells), pMito.filt.cells)
# If plot is True
if(plot) {
# Create dataframe for 3D plot
cellFiltDf <- data.frame(nGene = nGeneVec, nUMI = nUMIVec, pMito = pMitoVec)
cellFiltDf$isFilt <- ifelse(test = rownames(cellFiltDf) %in% filt.cells, yes = "Retained", no = "Discarded")
# Colors for scatter plot
colors <- c("grey", "black")
# Create 2D plots for all pairwise combinations of nGene, nUMI and pMito
# nGene x pMito
# Create threshold lines
nGene.thres.lines <- lapply(nGene.thresholds, function(thres){
geom_vline(aes(xintercept = thres), color = "red", linetype="dashed", size=1)
})
pMito.thres.lines <- lapply(percent.mito.thresholds, function(thres){
geom_hline(aes(yintercept = thres), color = "red", linetype="dashed", size=1)
})
# Create plot
nGene_pMito_plot <- ggplot(data = cellFiltDf, aes(x = nGene, y = pMito, colour = isFilt)) + geom_point(size = 1) + geom_jitter() + scale_color_manual(values = colors) + nGene.thres.lines + pMito.thres.lines + theme_bw() + ggtitle("a) nGene vs pMito")+theme(legend.position="none")
# nUMI x pMito
# Create threshold lines
nUMI.thres.lines <- lapply(nUMI.thresholds, function(thres){
geom_vline(aes(xintercept = thres), color = "red", linetype="dashed", size=1)
})
# Create plot
nUMI_pMito_plot <- ggplot(data = cellFiltDf, aes(x = nUMI, y = pMito, colour = isFilt)) + geom_point(size = 1) + geom_jitter() + scale_color_manual(values = colors) + nUMI.thres.lines + pMito.thres.lines + theme_bw() + ggtitle("b) nUMI vs pMito")+theme(legend.position="none")
# nGene x nUMI
# Change nUMI threshold lines to horizontal lines
nUMI.thres.lines <- lapply(nUMI.thresholds, function(thres){
geom_hline(aes(yintercept = thres), color = "red", linetype="dashed", size=1)
})
# Create plot
nGene_nUMI_plot <- ggplot(data = cellFiltDf, aes(x = nGene, y = nUMI, colour = isFilt)) + geom_point(size = 1) + geom_jitter() + scale_color_manual(values = colors) + nGene.thres.lines + nUMI.thres.lines + theme_bw() + ggtitle("c) nGene vs nUMI")+theme(legend.position="right")+theme(legend.key.height=unit(1.5,"cm"))+labs(colour="")
pdf(file = paste0(folderpath,"/",filename), width = 15, height = 5)
# Arrange scatter plots
grid.arrange(nGene_pMito_plot, nUMI_pMito_plot, nGene_nUMI_plot, nrow = 1,widths=c(1,1,1.3))
# Save plot
dev.off()
}
# Combine results from cell and gene filtering
rca.obj$raw.data <- as(data[filt.genes, filt.cells], "dgCMatrix")
# Return
return(rca.obj)
}
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