R/plot_mds_pca.R
In szymczak-lab/QCnormSE: Quality Control of Normalized Gene Expression Data
Defines functions
get_outliers_mds_pca_2d
prepare_var_for_plot
plot_mds_pca_2d
plot_mds_pca
calculate_mds_pca
Documented in
calculate_mds_pca
plot_mds_pca
plot_mds_pca_2d
#' MDS or PCA
#'
#' Performs dimensionality reduction using multi-dimensional scaling (MDS) or
#' principal component analysis (PCA) on the sample level.
#'
#' @param se
#' \code{\link[SummarizedExperiment]{RangedSummarizedExperiment-class}}
#' object
#' @param assay Character or integer. Name or number of assay containing
#' expression data to be used for dimensionality reduction.
#' @param method Method to use: "pca" (default), "mds".
#' @param dist Distance method to be used for MDS: see method argument in
#' \code{\link[stats]{dist}} function.
#' @param center Logical. Should the data be centered by mean? (default: TRUE).
#' @param scale Logical. Should the data be scaled by standard deviation?
#' (default: FALSE).
#'
#' @return list with components scores (data.frame with components of PCA or
#' MDS analysis) and var.explained (vector with explained variance; only for
#' PCA).
#'
#' @importFrom stats cmdscale dist na.omit prcomp
#' @export
#'
#' @examples
#' data("se.gene")
#'
#' ## PCA
#' res.pca = calculate_mds_pca(se = se.gene,
#' method = "pca")
#'
#' ## MDS
#' res.mds = calculate_mds_pca(se = se.gene,
#' method = "mds")
calculate_mds_pca <- function(se,
assay = 1,
method = "pca",
dist = "euclidean",
center = TRUE,
scale = FALSE) {
if (is.character(assay) && !(assay %in% names(assays(se)))) {
stop(paste("assay", assay, "not found!"))
}
expr = assays(se)[[assay]]
## remove genes with missing values
if (any(is.na(expr))) {
se.reduced = remove_genes(se = se,
assay = assay,
method = "missing",
freq = 0)
expr = assays(se.reduced)[[assay]]
print(paste("removed", nrow(se) - nrow(se.reduced),
"genes with missing values!"))
}
if (center) {
mean = apply(expr, 1, mean)
expr = expr - mean
}
if (scale) {
sd = apply(expr, 1, sd)
expr = expr / sd
}
if (method == "pca") {
res = prcomp(na.omit(t(expr)),
center = FALSE,
scale = FALSE)
scores = res$x[, seq_len(3)]
var.explained = (res$sdev^2)[seq_len(3)] / sum(res$sdev^2)
} else if (method == "mds") {
# if (dist == "gower") {
# d = daisy(t(expr), metric = "gower", stand = FALSE)
# } else {
# d = Dist(t(expr), method = dist)
# }
d = dist(t(expr))
fit = cmdscale(d, eig = TRUE, k = 3)
scores = fit$points
colnames(scores) = paste0("C", 1:ncol(scores))
var.explained = NULL
} else {
stop(paste("method", method, "not known!"))
}
scores = data.frame(scores)
# colnames(scores) = paste("component",
# seq_len(ncol(scores)),
# sep = ".")
return(list(scores = scores,
var.explained = var.explained))
}
#' MDS or PCA plot
#'
#' Plots components estimated with the function \code{\link{calculate_mds_pca}}.
#' Color and shape of each sample can be set based on different variables.
#'
#' @param res List. Output of \code{\link{calculate_mds_pca}}.
#' @param se
#' \code{\link[SummarizedExperiment]{RangedSummarizedExperiment-class}}
#' object
#' @param var.color Character or integer vector. Variable used to determine
#' color. If NULL black color will be used for all samples.
#' @param palette Color palette to be used (default palette from
#' \code{\link[ggpubr]{get_palette}}).
#' @param var.shape Character or integer vector. Variable used to determine
#' shape. If NULL filled circles will be used for all samples.
#' @param shape.values Vector with symbols. Needs to provide a symbol for each
#' unique value of var.shape.
#' @param title Character. Title of the plot. If NULL title will be set based
#' on method.
#' @param factor Numeric. Parameter of the function
#' \code{\link[aplpack]{compute.bagplot}}. (default: 5)
#' @param ellipse Logical. Should ellipses around points be drawn? (default:
#' FALSE).
#' @param ellipse.type Character. Type of ellipse as given in
#' \code{\link[ggpubr]{ggscatter}} (default: "convex").
#'
#' @return List with the following components:
#' \itemize{
#' \item info: data.frame with information about outlier samples for each
#' pairwise combination of component sor NULL
#' \item plot: Plot with three scatterplot as returned by
#' \code{\link[ggpubr]{ggarrange}}
#' }
#'
#' @import ggpubr ggplot2
#' @importFrom aplpack compute.bagplot
#' @export
#'
#' @examples
#' data("se.gene")
#'
#' ## PCA
#' res.pca = calculate_mds_pca(se = se.gene,
#' method = "pca")
#'
#' ## color code by group
#' plot_mds_pca(res = res.pca,
#' se = se.gene,
#' var.color = "group")
plot_mds_pca <- function(res,
se,
var.color = NULL,
palette = NULL,
var.shape = NULL,
shape.values = NULL,
title = NULL,
factor = 5,
ellipse = FALSE,
ellipse.type = "convex") {
## set title to method (set based on colnames of scores)
# method = ifelse(grepl("^PC", colnames(scores)[1]),
method = ifelse(!is.null(res$var.explained), "PCA", "MDS")
if (is.null(title)) title = method
## 2 dimensional results
dims = list(c(1, 2), c(1, 3), c(2, 3))
res = lapply(dims,
FUN = plot_mds_pca_2d,
res = res,
se = se,
var.color = var.color,
palette = palette,
var.shape = var.shape,
shape.values = shape.values,
title = "",
ellipse = ellipse,
ellipse.type = ellipse.type)
## plots
plots.l = lapply(res,
FUN = function(x) {
return(x$plot)
})
legend = ifelse(is.null(var.color) & is.null(var.shape),
"none", "bottom")
g = ggarrange(plotlist = plots.l,
ncol = 3,
nrow = 1,
legend = legend,
common.legend = TRUE)
g = annotate_figure(g,
top = text_grob(title,
face = "bold",
size = 14))
# print(g)
info.out = do.call(rbind,
lapply(res,
FUN = function(x) {
return(x$info)
}))
return(list(info = info.out,
plot = g))
}
#' MDS or PCA plot (2D)
#'
#' Plots two specified components estimated with the function
#' \code{\link{calculate_mds_pca}}. Color and shape of each sample can be set
#' based on different variables.
#'
#' @param res List. Output of \code{\link{calculate_mds_pca}}.
#' \code{\link{calculate_mds_pca}}.
#' @param dim Numeric vector (2). Numbers of components to be plotted.
#' @param se
#' \code{\link[SummarizedExperiment]{RangedSummarizedExperiment-class}}
#' object
#' @param var.color Character. Name of variable used to determine
#' color. If NULL black color will be used for all samples.
#' @param palette Color palette to be used (default palette used in
#' \code{\link[ggpubr]{ggscatter}}).
#' @param var.shape Character. Name of variable used to determine
#' shape. If NULL filled circles will be used for all samples.
#' @param shape.values Vector with symbols. Needs to provide a symbol for each
#' unique value of var.shape.
#' @param title Character. Main title of plot.
#' @param factor Numeric. Parameter of the function
#' \code{\link[aplpack]{compute.bagplot}}. (default: 5)
#' @param ellipse Logical. Should ellipses around points be drawn? (default:
#' FALSE).
#' @param ellipse.type Character. Type of ellipse as given in
#' \code{\link[ggpubr]{ggscatter}} (default: "convex").
#'
#' @import ggpubr ggplot2
#' @export
#'
#' @return List with the following components:
#' \itemize{
#' \item info: data.frame with information about outlier samples or NULL
#' \item plot: Scatterplot as returned by \code{\link[ggpubr]{ggscatter}}
#' }
#'
#' @examples
#' data("se.gene")
#'
#' ## PCA
#' res.pca = calculate_mds_pca(se = se.gene,
#' method = "pca")
#'
#' ## color code by group
#' plot_mds_pca_2d(res = res.pca,
#' dim = c(1, 2),
#' se = se.gene,
#' var.color = "group")
plot_mds_pca_2d <- function(res,
dim = c(1, 2),
se,
var.color = NULL,
palette = NULL,
var.shape = NULL,
shape.values = NULL,
title = NULL,
factor = 5,
ellipse = FALSE,
ellipse.type = "convex") {
scores = res$scores
xlab = paste("Component", dim[1])
ylab = paste("Component", dim[2])
if (!is.null(res$var.explained)) {
var = round(res$var.explained * 100, digits = 2)
xlab = paste0(xlab, " (", var[dim[1]], "%)")
ylab = paste0(ylab, " (", var[dim[2]], "%)")
if (is.null(title)) {
title = "PCA"
}
} else {
if (is.null(title)) {
title = "MDS"
}
}
## set color and shape
info = data.frame(prepare_var_for_plot(se = se,
var = var.color),
prepare_var_for_plot(se = se,
var = var.shape))
colnames(info) = c(ifelse(is.null(var.color), "color", var.color),
ifelse(is.null(var.shape), "shape", var.shape))
scores = cbind(info, scores)
g = ggscatter(scores,
x = colnames(scores)[dim[1] + 2],
y = colnames(scores)[dim[2] + 2],
color = colnames(scores)[1],
shape = colnames(scores)[2],
size = 3,
xlab = xlab,
ylab = ylab,
title = title,
ellipse = ellipse,
ellipse.type = ellipse.type)
if (!is.null(shape.values)) {
g = g + scale_shape_manual(values = shape.values)
}
if (is.null(var.color)) {
g = g + guides(color = FALSE)
}
if (is.null(var.shape)) {
g = g + guides(shape = "none")
}
## set colors
if (!is.null(palette)) {
if (is.factor(scores[, 1])) {
g = change_palette(g, palette)
} else {
g = g + gradient_color(palette)
}
} else {
if (length(unique(scores[, 1])) == 1) {
g = change_palette(g, "black")
}
}
## identify outliers
info.out = get_outliers_mds_pca_2d(scores = res$scores,
dim = dim,
factor = factor)
return(list(info = info.out,
plot = g))
}
# internal function used by plot_mds_pca
#
# if var = NULL returns vector of 1s
#
#' @keywords internal
prepare_var_for_plot <- function(se,
var = NULL) {
if (is.null(var)) {
values = rep(1, ncol(se))
} else {
if (!(var %in% colnames(colData(se)))) {
stop(paste("var", var, "not found in colnames of colData!"))
}
values = colData(se)[, var]
}
if (length(unique(values)) <= 10) {
values = as.factor(values)
}
if (is.factor(values)) {
droplevels(values)
}
return(values)
}
# internal function used by plot_mds_pca
#
# determines outliers in two dimensional plot
#
#' @importFrom aplpack compute.bagplot
#' @keywords internal
get_outliers_mds_pca_2d <- function(scores,
dim = c(1, 2),
factor = 5) {
method = ifelse(grepl("^PC", colnames(scores)[1]),
"PCA", "MDS")
criterion = paste(method, "dim", paste(dim, collapse = "."), sep = ".")
info.bagplot = compute.bagplot(x = scores[, dim[1]],
y = scores[, dim[2]],
factor = factor)
out = info.bagplot$pxy.outlier
if (!is.null(out)) {
ind.out = apply(out, 1, function(x) {
which(scores[, dim[1]] == x[1] & scores[, dim[2]] == x[2])
})
if (is.list(ind.out)) {
ind.out = unique(unlist(ind.out))
}
info.out = data.frame(id = rownames(scores)[ind.out],
criterion = rep(criterion, length(ind.out)),
stringsAsFactors = FALSE)
} else {
info.out = NULL
}
return(info.out)
}
szymczak-lab/QCnormSE documentation built on March 25, 2023, 1:05 p.m.
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Defines functions get_outliers_mds_pca_2d prepare_var_for_plot plot_mds_pca_2d plot_mds_pca calculate_mds_pca
Documented in calculate_mds_pca plot_mds_pca plot_mds_pca_2d
#' MDS or PCA
#'
#' Performs dimensionality reduction using multi-dimensional scaling (MDS) or
#' principal component analysis (PCA) on the sample level.
#'
#' @param se
#' \code{\link[SummarizedExperiment]{RangedSummarizedExperiment-class}}
#' object
#' @param assay Character or integer. Name or number of assay containing
#' expression data to be used for dimensionality reduction.
#' @param method Method to use: "pca" (default), "mds".
#' @param dist Distance method to be used for MDS: see method argument in
#' \code{\link[stats]{dist}} function.
#' @param center Logical. Should the data be centered by mean? (default: TRUE).
#' @param scale Logical. Should the data be scaled by standard deviation?
#' (default: FALSE).
#'
#' @return list with components scores (data.frame with components of PCA or
#' MDS analysis) and var.explained (vector with explained variance; only for
#' PCA).
#'
#' @importFrom stats cmdscale dist na.omit prcomp
#' @export
#'
#' @examples
#' data("se.gene")
#'
#' ## PCA
#' res.pca = calculate_mds_pca(se = se.gene,
#' method = "pca")
#'
#' ## MDS
#' res.mds = calculate_mds_pca(se = se.gene,
#' method = "mds")
calculate_mds_pca <- function(se,
assay = 1,
method = "pca",
dist = "euclidean",
center = TRUE,
scale = FALSE) {
if (is.character(assay) && !(assay %in% names(assays(se)))) {
stop(paste("assay", assay, "not found!"))
}
expr = assays(se)[[assay]]
## remove genes with missing values
if (any(is.na(expr))) {
se.reduced = remove_genes(se = se,
assay = assay,
method = "missing",
freq = 0)
expr = assays(se.reduced)[[assay]]
print(paste("removed", nrow(se) - nrow(se.reduced),
"genes with missing values!"))
}
if (center) {
mean = apply(expr, 1, mean)
expr = expr - mean
}
if (scale) {
sd = apply(expr, 1, sd)
expr = expr / sd
}
if (method == "pca") {
res = prcomp(na.omit(t(expr)),
center = FALSE,
scale = FALSE)
scores = res$x[, seq_len(3)]
var.explained = (res$sdev^2)[seq_len(3)] / sum(res$sdev^2)
} else if (method == "mds") {
# if (dist == "gower") {
# d = daisy(t(expr), metric = "gower", stand = FALSE)
# } else {
# d = Dist(t(expr), method = dist)
# }
d = dist(t(expr))
fit = cmdscale(d, eig = TRUE, k = 3)
scores = fit$points
colnames(scores) = paste0("C", 1:ncol(scores))
var.explained = NULL
} else {
stop(paste("method", method, "not known!"))
}
scores = data.frame(scores)
# colnames(scores) = paste("component",
# seq_len(ncol(scores)),
# sep = ".")
return(list(scores = scores,
var.explained = var.explained))
}
#' MDS or PCA plot
#'
#' Plots components estimated with the function \code{\link{calculate_mds_pca}}.
#' Color and shape of each sample can be set based on different variables.
#'
#' @param res List. Output of \code{\link{calculate_mds_pca}}.
#' @param se
#' \code{\link[SummarizedExperiment]{RangedSummarizedExperiment-class}}
#' object
#' @param var.color Character or integer vector. Variable used to determine
#' color. If NULL black color will be used for all samples.
#' @param palette Color palette to be used (default palette from
#' \code{\link[ggpubr]{get_palette}}).
#' @param var.shape Character or integer vector. Variable used to determine
#' shape. If NULL filled circles will be used for all samples.
#' @param shape.values Vector with symbols. Needs to provide a symbol for each
#' unique value of var.shape.
#' @param title Character. Title of the plot. If NULL title will be set based
#' on method.
#' @param factor Numeric. Parameter of the function
#' \code{\link[aplpack]{compute.bagplot}}. (default: 5)
#' @param ellipse Logical. Should ellipses around points be drawn? (default:
#' FALSE).
#' @param ellipse.type Character. Type of ellipse as given in
#' \code{\link[ggpubr]{ggscatter}} (default: "convex").
#'
#' @return List with the following components:
#' \itemize{
#' \item info: data.frame with information about outlier samples for each
#' pairwise combination of component sor NULL
#' \item plot: Plot with three scatterplot as returned by
#' \code{\link[ggpubr]{ggarrange}}
#' }
#'
#' @import ggpubr ggplot2
#' @importFrom aplpack compute.bagplot
#' @export
#'
#' @examples
#' data("se.gene")
#'
#' ## PCA
#' res.pca = calculate_mds_pca(se = se.gene,
#' method = "pca")
#'
#' ## color code by group
#' plot_mds_pca(res = res.pca,
#' se = se.gene,
#' var.color = "group")
plot_mds_pca <- function(res,
se,
var.color = NULL,
palette = NULL,
var.shape = NULL,
shape.values = NULL,
title = NULL,
factor = 5,
ellipse = FALSE,
ellipse.type = "convex") {
## set title to method (set based on colnames of scores)
# method = ifelse(grepl("^PC", colnames(scores)[1]),
method = ifelse(!is.null(res$var.explained), "PCA", "MDS")
if (is.null(title)) title = method
## 2 dimensional results
dims = list(c(1, 2), c(1, 3), c(2, 3))
res = lapply(dims,
FUN = plot_mds_pca_2d,
res = res,
se = se,
var.color = var.color,
palette = palette,
var.shape = var.shape,
shape.values = shape.values,
title = "",
ellipse = ellipse,
ellipse.type = ellipse.type)
## plots
plots.l = lapply(res,
FUN = function(x) {
return(x$plot)
})
legend = ifelse(is.null(var.color) & is.null(var.shape),
"none", "bottom")
g = ggarrange(plotlist = plots.l,
ncol = 3,
nrow = 1,
legend = legend,
common.legend = TRUE)
g = annotate_figure(g,
top = text_grob(title,
face = "bold",
size = 14))
# print(g)
info.out = do.call(rbind,
lapply(res,
FUN = function(x) {
return(x$info)
}))
return(list(info = info.out,
plot = g))
}
#' MDS or PCA plot (2D)
#'
#' Plots two specified components estimated with the function
#' \code{\link{calculate_mds_pca}}. Color and shape of each sample can be set
#' based on different variables.
#'
#' @param res List. Output of \code{\link{calculate_mds_pca}}.
#' \code{\link{calculate_mds_pca}}.
#' @param dim Numeric vector (2). Numbers of components to be plotted.
#' @param se
#' \code{\link[SummarizedExperiment]{RangedSummarizedExperiment-class}}
#' object
#' @param var.color Character. Name of variable used to determine
#' color. If NULL black color will be used for all samples.
#' @param palette Color palette to be used (default palette used in
#' \code{\link[ggpubr]{ggscatter}}).
#' @param var.shape Character. Name of variable used to determine
#' shape. If NULL filled circles will be used for all samples.
#' @param shape.values Vector with symbols. Needs to provide a symbol for each
#' unique value of var.shape.
#' @param title Character. Main title of plot.
#' @param factor Numeric. Parameter of the function
#' \code{\link[aplpack]{compute.bagplot}}. (default: 5)
#' @param ellipse Logical. Should ellipses around points be drawn? (default:
#' FALSE).
#' @param ellipse.type Character. Type of ellipse as given in
#' \code{\link[ggpubr]{ggscatter}} (default: "convex").
#'
#' @import ggpubr ggplot2
#' @export
#'
#' @return List with the following components:
#' \itemize{
#' \item info: data.frame with information about outlier samples or NULL
#' \item plot: Scatterplot as returned by \code{\link[ggpubr]{ggscatter}}
#' }
#'
#' @examples
#' data("se.gene")
#'
#' ## PCA
#' res.pca = calculate_mds_pca(se = se.gene,
#' method = "pca")
#'
#' ## color code by group
#' plot_mds_pca_2d(res = res.pca,
#' dim = c(1, 2),
#' se = se.gene,
#' var.color = "group")
plot_mds_pca_2d <- function(res,
dim = c(1, 2),
se,
var.color = NULL,
palette = NULL,
var.shape = NULL,
shape.values = NULL,
title = NULL,
factor = 5,
ellipse = FALSE,
ellipse.type = "convex") {
scores = res$scores
xlab = paste("Component", dim[1])
ylab = paste("Component", dim[2])
if (!is.null(res$var.explained)) {
var = round(res$var.explained * 100, digits = 2)
xlab = paste0(xlab, " (", var[dim[1]], "%)")
ylab = paste0(ylab, " (", var[dim[2]], "%)")
if (is.null(title)) {
title = "PCA"
}
} else {
if (is.null(title)) {
title = "MDS"
}
}
## set color and shape
info = data.frame(prepare_var_for_plot(se = se,
var = var.color),
prepare_var_for_plot(se = se,
var = var.shape))
colnames(info) = c(ifelse(is.null(var.color), "color", var.color),
ifelse(is.null(var.shape), "shape", var.shape))
scores = cbind(info, scores)
g = ggscatter(scores,
x = colnames(scores)[dim[1] + 2],
y = colnames(scores)[dim[2] + 2],
color = colnames(scores)[1],
shape = colnames(scores)[2],
size = 3,
xlab = xlab,
ylab = ylab,
title = title,
ellipse = ellipse,
ellipse.type = ellipse.type)
if (!is.null(shape.values)) {
g = g + scale_shape_manual(values = shape.values)
}
if (is.null(var.color)) {
g = g + guides(color = FALSE)
}
if (is.null(var.shape)) {
g = g + guides(shape = "none")
}
## set colors
if (!is.null(palette)) {
if (is.factor(scores[, 1])) {
g = change_palette(g, palette)
} else {
g = g + gradient_color(palette)
}
} else {
if (length(unique(scores[, 1])) == 1) {
g = change_palette(g, "black")
}
}
## identify outliers
info.out = get_outliers_mds_pca_2d(scores = res$scores,
dim = dim,
factor = factor)
return(list(info = info.out,
plot = g))
}
# internal function used by plot_mds_pca
#
# if var = NULL returns vector of 1s
#
#' @keywords internal
prepare_var_for_plot <- function(se,
var = NULL) {
if (is.null(var)) {
values = rep(1, ncol(se))
} else {
if (!(var %in% colnames(colData(se)))) {
stop(paste("var", var, "not found in colnames of colData!"))
}
values = colData(se)[, var]
}
if (length(unique(values)) <= 10) {
values = as.factor(values)
}
if (is.factor(values)) {
droplevels(values)
}
return(values)
}
# internal function used by plot_mds_pca
#
# determines outliers in two dimensional plot
#
#' @importFrom aplpack compute.bagplot
#' @keywords internal
get_outliers_mds_pca_2d <- function(scores,
dim = c(1, 2),
factor = 5) {
method = ifelse(grepl("^PC", colnames(scores)[1]),
"PCA", "MDS")
criterion = paste(method, "dim", paste(dim, collapse = "."), sep = ".")
info.bagplot = compute.bagplot(x = scores[, dim[1]],
y = scores[, dim[2]],
factor = factor)
out = info.bagplot$pxy.outlier
if (!is.null(out)) {
ind.out = apply(out, 1, function(x) {
which(scores[, dim[1]] == x[1] & scores[, dim[2]] == x[2])
})
if (is.list(ind.out)) {
ind.out = unique(unlist(ind.out))
}
info.out = data.frame(id = rownames(scores)[ind.out],
criterion = rep(criterion, length(ind.out)),
stringsAsFactors = FALSE)
} else {
info.out = NULL
}
return(info.out)
}
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