R/process_normalization.R
In HuaZou/MicrobiomeAnalysis: Data analysis toolkits in metagenomics
Defines functions
scale_Range
scale_Pareto
scale_Zscore
scale_MeanCenter
scale_variables
normalize_feature
get_norm_factors
set_nf
norm_cpm
trans_clr
gm_mean
norm_clr
norm_tmm
norm_rle
norm_css
norm_tss
norm_rarefy
Documented in
norm_clr
norm_cpm
norm_css
norm_rarefy
norm_rle
norm_tmm
norm_tss
scale_variables
#' @title Normalize the microbial abundance data
#'
#' @description
#' It is critical to normalize the feature table to eliminate any bias due to
#' differences in the sampling sequencing depth.This function implements six
#' widely-used normalization methods for microbial compositional data.
#'
#' @author Created by Yang Cao
#'
#' @param object a matrix, data.frame, [phyloseq::phyloseq-class] or
#' [phyloseq::otu_table-class] object.
#' @param method the methods used to normalize the microbial abundance data.
#' Options includes:
#' * "none": do not normalize.
#' * "rarefy": random subsampling counts to the smallest library size in the
#' data set.
#' * "TSS": total sum scaling, also referred to as "relative abundance", the
#' abundances were normalized by dividing the corresponding sample library
#' size.
#' * "TMM": trimmed mean of m-values. First, a sample is chosen as reference.
#' The scaling factor is then derived using a weighted trimmed mean over
#' the differences of the log-transformed gene-count fold-change between
#' the sample and the reference.
#' * "RLE", relative log expression, RLE uses a pseudo-reference calculated
#' using the geometric mean of the gene-specific abundances over all
#' samples. The scaling factors are then calculated as the median of the
#' gene counts ratios between the samples and the reference.
#' * "CSS": cumulative sum scaling, calculates scaling factors as the
#' cumulative sum of gene abundances up to a data-derived threshold.
#' * "CLR": centered log-ratio normalization.
#' * "CPM": pre-sample normalization of the sum of the values to 1e+06.
#' @param ... other arguments passed to the corresponding normalization
#' methods.
#'
#' @seealso [edgeR::calcNormFactors()],[DESeq2::estimateSizeFactorsForMatrix()],
#' [metagenomeSeq::cumNorm()]
#'
#' @importMethodsFrom BiocGenerics normalize
#' @importFrom phyloseq sample_data<-
#' @exportMethod normalize
#'
#' @aliases normalize,phyloseq-method
#' @rdname normalize-methods
#'
#' @return the same class with `object`.
#'
#' @examples
#' data(caporaso)
#' normalize(caporaso, "TSS")
#'
setMethod(
"normalize", "phyloseq",
function(object,
method = "TSS",
...) {
otu <- otu_table(object)
otu_normed <- normalize(otu, method = method, ...)
# extract norm_factor attributes and prepend to the sample_data
nf <- attr(otu_normed, "norm_factor")
if (!is.null(nf)) {
sample_data(object) <- cbind(
sample_data(object),
norm_factor = nf
)
}
# please note otu_table<- function will drop the norm_factor attribute
otu_table(object) <- otu_normed
object
}
)
#' @importMethodsFrom BiocGenerics normalize
#' @aliases normalize,otu_table-method normalize
#' @rdname normalize-methods
#'
setMethod(
"normalize", "otu_table",
function(object,
method = "TSS",
...) {
methods <- c("none", "rarefy", "TSS", "TMM", "RLE", "CSS", "CLR", "CPM")
if (method %in% methods) {
object_normed <- switch(method,
none = object,
rarefy = norm_rarefy(object, ...),
TSS = norm_tss(object),
TMM = norm_tmm(object, ...),
RLE = norm_rle(object, ...),
CSS = norm_css(object, ...),
CLR = norm_clr(object),
CPM = norm_cpm(object)
)
} else {
stop(
"`method` must be one of none, rarefy, TSS,",
" TMM, RLE, CSS, CLR, or CPM",
call. = FALSE
)
}
object_normed
}
)
#' @importMethodsFrom BiocGenerics normalize
#' @aliases normalize,data.frame-method normalize
#' @rdname normalize-methods
#'
setMethod(
"normalize", "data.frame",
function(object,
method = "TSS",
...) {
otu <- otu_table(object, taxa_are_rows = TRUE)
otu_norm <- normalize(otu, method, ...)
nf <- attr(otu_norm, "norm_factor")
res <- as.data.frame(otu_norm)
if (!is.null(nf)) {
attr(res, "norm_factor") <- nf
}
res
}
)
#' @importMethodsFrom BiocGenerics normalize
#' @aliases normalize,matrix-method normalize
#' @rdname normalize-methods
setMethod(
"normalize", "matrix",
function(object,
method = "TSS",
...) {
otu <- as.data.frame(object)
otu_norm <- normalize(otu, method, ...)
nf <- attr(otu_norm, "norm_factor")
res <- as.matrix(otu_norm)
if (!is.null(nf)) {
attr(res, "norm_factor") <- nf
}
res
}
)
## Four normalization methods do not save the norm factor: value, rarefy,
## clr and tss; where three methods save the norm factor: css, rle, tmm.
#' Normalize feature table by rafefying such that all samples have the same
#' number of total counts (library size).
#'
#' For rarefying, reads in the different samples are randomly removed until
#' the same predefined number has been reached, to assure all samples have the
#' same library size. Rarefying normalization method is the standard in
#' microbial ecology. Please note that the authors of phyloseq do not advocate
#' using this rarefying a normalization procedure, despite its recent
#' popularity
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object.
#' @param size,rng_seed,replace,trim_otus,verbose extra arguments passed to
#' [`phyloseq::rarefy_even_depth()`].
#' @export
#' @rdname normalize-methods
#' @aliases norm_rarefy
#' @importFrom phyloseq rarefy_even_depth sample_sums
#' @seealso [`phyloseq::rarefy_even_depth()`]
norm_rarefy <- function(object,
size = min(sample_sums(object)),
rng_seed = FALSE,
replace = TRUE,
trim_otus = TRUE,
verbose = TRUE) {
object_rarefied <- rarefy_even_depth(
object,
sample.size = size,
rngseed = rng_seed,
replace = replace,
trimOTUs = trim_otus,
verbose = verbose
)
# do not save the norm_factor
# the norm factors can be calculated in the subsequently differential
# analysis method, e.g. edgeR, DESeq
object_rarefied
}
#' Total-Sum Scaling (TSS) method
#'
#' TSS simply transforms the feature table into relative abundance by dividing
#' the number of total reads of each sample.
#'
#' @param object object a [phyloseq::phyloseq-class] or
#' [phyloseq::otu_table-class] object
#' @export
#' @rdname normalize-methods
#' @aliases norm_tss
#' @importFrom phyloseq otu_table<-
norm_tss <- function(object) {
otu <- otu_table(object)
size <- colSums(otu)
otu_normed <- sweep(otu, MARGIN = 2, STATS = size, FUN = "/")
otu_table(object) <- otu_table(
otu_normed,
taxa_are_rows = taxa_are_rows(object)
)
# do not save the norm_factor, the norm factors are calculated based on the
# subsequently differential analysis method, e.g. edgeR, DESeq
object
}
#' Cumulative-Sum Scaling (CSS) method
#'
#' CSS is based on the assumption that the count distributions in each sample
#' are equivalent for low abundant genes up to a certain threshold. Only the
#' segment of each sample’s count distribution that is relatively invariant
#' across samples is scaled by CSS
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object.
#' @param sl The value to scale.
#' @importFrom phyloseq sample_data<-
#' @importFrom metagenomeSeq newMRexperiment cumNorm cumNormStatFast MRcounts
#' @seealso [metagenomeSeq::calcNormFactors()]
#' @export
#' @rdname normalize-methods
#' @aliases norm_css
norm_css <- function(object, sl = 1000) {
if (inherits(object, "phyloseq")) {
object_mgs <- phyloseq2metagenomeSeq(object)
} else if (inherits(object, "otu_table")) {
object_mgs <- otu_table2metagenomeSeq(object)
}
# cumNormStatFast requires counts of all samples at least have two
# non zero features. Thus, if there are samples with only one non-zer
# features, cumNormStat is taken to compute the pth quantile.
count <- as(otu_table(object), "matrix")
fun_p <- select_quantile_func(count)
nf <- metagenomeSeq::calcNormFactors(object_mgs, p = fun_p(object_mgs))
nf <- unlist(nf) / sl
object_nf <- set_nf(object, nf)
object_nf
}
#' Relative log expression (RLE) normalization
#'
#' RLE assumes most features are not differential and uses the relative
#' abundances to calculate the normalization factor.
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object
#' @param locfunc a function to compute a location for a sample. By default,
#' the median is used.
#' @param type method for estimation: either "ratio"or "poscounts" (recommend).
#' @param geo_means default `NULL`, which means the geometric means of the
#' counts are used. A vector of geometric means from another count matrix can
#' be provided for a "frozen" size factor calculation.
#' @param control_genes default `NULL`, which means all taxa are used for size
#' factor estimation, numeric or logical index vector specifying the taxa
#' used for size factor estimation (e.g. core taxa).
#' @seealso [DESeq2::estimateSizeFactorsForMatrix()]
#' @export
#' @rdname normalize-methods
#' @aliases norm_rle
norm_rle <- function(object,
locfunc = stats::median,
type = c("poscounts", "ratio"),
geo_means = NULL,
control_genes = NULL) {
stopifnot(class(object) %in% c("phyloseq", "otu_table"))
type <- match.arg(type, c("poscounts", "ratio"))
# use substitute() to create missing argument
geo_means <- ifelse(is.null(geo_means), substitute(), geo_means)
control_genes <- ifelse(is.null(control_genes), substitute(), control_genes)
otu <- as(otu_table(object), "matrix")
nf <- estimateSizeFactorsForMatrix(
otu,
locfunc = locfunc,
geoMeans = geo_means,
controlGenes = control_genes,
type = type
)
object_nf <- set_nf(object, nf)
object_nf
}
# https://github.com/biobakery/Maaslin2/blob/master/R/utility_scripts.R
#
#' TMM (trimmed mean of m-values) normalization
#'
#' TMM calculates the normalization factor using a robust statistics based on
#' the assumption that most features are not differential and should, in
#' average, be equal between the samples. The TMM scaling factor is calculated
#' as the weighted mean of log-ratios between each pair of samples, after
#' excluding the highest count OTUs and OTUs with the largest log-fold change.
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object
#' @param ref_column column to use as reference
#' @param logratio_trim amount of trim to use on log-ratios
#' @param sum_trim amount of trim to use on the combined absolute levels
#' ("A" values)
#' @param do_weighting whether to compute the weights or not
#' @param Acutoff cutoff on "A" values to use before trimming
#' @seealso [edgeR::calcNormFactors()]
#' @export
#' @rdname normalize-methods
#' @aliases norm_tmm
norm_tmm <- function(object,
ref_column = NULL,
logratio_trim = 0.3,
sum_trim = 0.05,
do_weighting = TRUE,
Acutoff = -1e10) {
otu <- as(otu_table(object), "matrix")
nf <- edgeR::calcNormFactors(
otu,
method = "TMM",
refcolumn = ref_column,
logratioTrim = logratio_trim,
sumTrim = sum_trim,
doWeighting = do_weighting,
Acutoff = Acutoff
)
object_nf <- set_nf(object, nf)
object_nf
}
#' CLR (centered log-ratio) normalization
#'
#' In CLR, the log-ratios are computed relative to the geometric mean of all
#' features.
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object
#' @export
#' @rdname normalize-methods
#' @aliases norm_clr
norm_clr <- function(object) {
otu <- as(otu_table(object), "matrix")
otu_norm <- apply(otu, 2, trans_clr)
otu_table(object) <- otu_table(
otu_norm,
taxa_are_rows = taxa_are_rows(object)
)
# do not save the norm_factor, the norm factors are calculated based on the
# subsequently differential analysis method, e.g. edgeR, DESeq
object
}
# from joey711/shiny-phyloseq/blob/master/panels/paneldoc/Transform.md
gm_mean <- function(x, na.rm = TRUE) {
# The geometric mean, with some error-protection bits.
exp(sum(log(x[x > 0 & !is.na(x)]), na.rm = na.rm) / length(x))
}
trans_clr <- function(x, base = exp(1)) {
x <- log((x / gm_mean(x)), base)
x[!is.finite(x) | is.na(x)] <- 0.0
return(x)
}
#' Normalize the sum of values of each sample to million (counts per million)
#'
#' `norm_cpm`: This normalization method is from the original LEfSe algorithm,
#' recommended when very low values are present (as shown in the LEfSe galaxy).
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' @export
#' @rdname normalize-methods
#' @aliases norm_cpm
#' @importFrom phyloseq transform_sample_counts
norm_cpm <- function(object) {
otu <- as(otu_table(object), "matrix") %>%
as.data.frame()
# whether the object is summarized
hie <- check_tax_summarize(object)
if (hie) {
features <- row.names(otu)
features_split <- strsplit(features, "|", fixed = TRUE)
single_indx <- which(lengths(features_split) < 2)
## keep the counts of a sample identical with `normalization`
## if we norm the counts in two steps:
## 1. calculate scale size: norm_coef = normalization/lib_size;
## 2. multiple the scale size value * norm_coef
## the counts of a sample colSums(otu) may not equal to the argument
## normalization.
## e.g. normalization = 1e6, colSums(otu) = 999999
## Finally, the kruskal test may be inaccurate,
## e.g. https://github.com/yiluheihei/microbiomeMarker/issues/13
ps_normed <- transform_sample_counts(
object,
function(x) x * 1e+06 / sum(x[single_indx])
)
} else {
ps_normed <- transform_sample_counts(
object,
function(x) x * 1e+06 / sum(x)
)
}
otu_normed <- data.frame(otu_table(ps_normed))
otu_normed <- purrr::map_df(
otu_normed,
function(x) {
if (mean(x) && stats::sd(x) / mean(x) < 1e-10) {
return(round(x * 1e6) / 1e6)
} else {
return(x)
}
}
)
otu_normed <- as.data.frame(otu_normed)
row.names(otu_normed) <- row.names(otu)
colnames(otu_normed) <- colnames(otu)
otu_table(object) <- otu_table(otu_normed, taxa_are_rows = TRUE)
# do not save the norm_factor, the norm factors are calculated based on the
# subsequently differential analysis method, e.g. edgeR, DESeq
object
}
# set the norm factors of the object, if object is in phyloseq-class, add a
# var `norm_factor` in the sample_data to save the norm factors of each sample;
# if object in otu_table-class, add a attributes `norm_factor` to the object
# to save the norm factors.
#' @importFrom phyloseq sample_data<-
#' @noRd
set_nf <- function(object, nf) {
# ensure norm factors from sample_data and attributes of otu_table are
# identical
names(nf) <- NULL
if (inherits(object, "phyloseq")) {
sample_data(object) <- cbind(sample_data(object), norm_factor = nf)
# to keep accordance with otu_table,
# we also add the attributes `norm_factor` to otu_table
ot <- otu_table(object)
attr(ot, "norm_factor") <- nf
otu_table(object) <- ot
} else if (inherits(object, "otu_table")) {
attr(object, "norm_factor") <- nf
} else {
stop("object must be a `phloseq` or `otu_table` object")
}
object
}
#' Extract the normalization factors
#'
#' This function will be used to extract the normalization factors. After
#' dividing the observed feature table by normalization factors (eliminate
#' sequencing biases), we will obtain the normalized feature table.
#'
#' @param object a [`phyloseq::phyloseq-class`], [phyloseq::otu_table-class]
#' object.
#' @return a numeric vector with the length equal to the number of samples, or
#' `NULL` if the `object` has not been normalized.
#' @noRd
get_norm_factors <- function(object) {
if (inherits(object, "phyloseq")) {
nf <- sample_data(object)$norm_factor
} else {
nf <- attr(object, "norm_factor")
}
nf
}
# Deprecated functions ----------------------------------------------------
# This function is deprecated
#' normalize the summarized feature
#' @param feature otu table or data.frame
#' @param normalization set the normalization value
#' @noRd
normalize_feature <- function(feature, normalization) {
if (inherits(feature, "otu_table")) {
if (!taxa_are_rows(feature)) {
feature <- t(feature)
}
feature <- feature@.Data %>% data.frame()
}
if (is.null(normalization)) {
return(feature)
}
feature_split <- strsplit(row.names(feature), "\\|")
hie <- ifelse(any(lengths(feature_split) > 1), TRUE, FALSE)
if (hie) {
single_indx <- which(lengths(feature_split) < 2)
abd <- purrr::map_dbl(feature, ~ sum(.x[single_indx]))
} else {
abd <- purrr::map_dbl(feature, sum)
}
normed_coef <- normalization / abd
normed_feature <- purrr::map2_df(
feature, normed_coef,
function(x, y) {
res <- x * y
if (mean(res) && stats::sd(res) / mean(res) < 1e-10) {
res <- round(res * 1e6) / 1e6
}
res
}
)
# for row names setting, phyloseq requires otu_table and tax_table has the
# same taxa
normed_feature <- as.data.frame(normed_feature)
row.names(normed_feature) <- row.names(feature)
otu_table(normed_feature, taxa_are_rows = TRUE)
}
#' @title Data scaling adjusts each variable/feature
#'
#' @description
#' Data Normalization not only normalizes data by samples, but also
#' scales data by variable/feature. Data scaling adjusts each variable/feature
#' by a scaling factor computed based on the dispersion of the variable. The
#' former is to change data distribution per sample and the latter is to put
#' variable/feature into same distribution.
#'
#' @author Created by Hua Zou (12/02/2022 Shenzhen China)
#'
#' @param object (Required). a [`phyloseq::phyloseq-class`] or
#' [`SummarizedExperiment::SummarizedExperiment-class`] object.
#' @param level (Optional). character. Summarization
#' level (from \code{rank_names(pseq)}, default: NULL).
#' @param method (Optional). character. scaling methods. Options are:
#' * "none", return the original data
#' * "mean_center": values minus mean statistic.
#' * "zscore": mean-centered and divided by the
#' standard deviation of each variable.
#' * "pareto": mean-centered and divided by the square root of
#' the standard deviation of each variable.
#' * "range": mean-centered and divided by the range of each variable.
#' (default: "none").
#'
#' @usage scale_variables(
#' object,
#' level = c(NULL, "Kingdom", "Phylum", "Class",
#' "Order", "Family", "Genus",
#' "Species", "Strain", "unique"),
#' method = c("none", "mean_center", "zscore",
#' "pareto", "range")
#' )
#'
#' @export
#'
#' @return A [`phyloseq::phyloseq-class`] or
#' [`SummarizedExperiment::SummarizedExperiment-class`] object with cleaned data.
#'
#' @importFrom dplyr %>%
#'
#' @examples
#'
#' \dontrun{
#' # phyloseq object
#' data("enterotypes_arumugam")
#' scale_variables(
#' object = enterotypes_arumugam,
#' level = "Phylum",
#' method = "mean_center")
#'
#' # SummarizedExperiment object
#' data("Zeybel_2022_protein")
#' scale_variables(
#' Zeybel_2022_protein,
#' method = "zscore")
#' }
#'
scale_variables <- function(
object,
level = NULL,
method = c("none", "mean_center", "zscore",
"pareto", "range")) {
# object = enterotypes_arumugam
# level = "Genus"
# method = "zscore"
# object = Zeybel_2022_protein
# level = NULL
# method = "zscore"
method <- match.arg(
method, c("none", "mean_center", "zscore",
"pareto", "range")
)
if (any(inherits(object, "environment"), inherits(object, "phyloseq"))) {
# taxa level
if (!is.null(level)) {
object <- aggregate_taxa(x = object, level = level)
} else {
object <- object
}
# profile: Row->features; Column->samples
otu <- as(otu_table(object), "matrix")
} else if (inherits(object, "SummarizedExperiment")) {
# profile: Row->features; Column->samples (features-by-samples matrix)
otu <- SummarizedExperiment::assay(object) %>%
as.data.frame()
} else {
otu <- as.matrix(object)
}
if (method == "none") {
abd <- otu
} else if (method == "mean_center") {
abd <- apply(otu, 1, scale_MeanCenter) %>%
t()
} else if (method == "zscore") {
abd <- apply(otu, 1, scale_Zscore) %>%
t()
} else if (method == "pareto") {
abd <- apply(otu, 1, scale_Pareto) %>%
t()
} else if (method == "range") {
abd <- apply(otu, 1, scale_Range) %>%
t()
}
if (any(inherits(object, "environment"), inherits(object, "phyloseq"))) {
phyloseq::otu_table(object) <- phyloseq::otu_table(abd, taxa_are_rows = taxa_are_rows(object))
} else if (inherits(object, "SummarizedExperiment")) {
if (nrow(abd) != nrow(otu)) {
rdata <- SummarizedExperiment::rowData(object)
cdata <- SummarizedExperiment::colData(object)
if (length(object@metadata) == 0) {
mdata <- NULL
} else {
mdata <- object@metadata
}
res <- import_SE(object = abd,
rowdata = rdata,
coldata = cdata,
metadata = mdata)
# res <- base::subset(res, colnames(prf_tab) %in% colnames(depurdata))
} else {
SummarizedExperiment::assay(object) <- abd
}
} else {
object <- abd
}
return(object)
}
#' values minus mean statistic
#' @keywords internal
#' @noRd
scale_MeanCenter <- function(x) {
return(x - mean(x, na.rm = TRUE)) # mean(x, na.rm = TRUE)
}
#' mean-centered and divided by the standard deviation of each variable
#' @keywords internal
#' @noRd
scale_Zscore <- function(x) {
return((x - mean(x, na.rm = TRUE)) / sd(x, na.rm = TRUE))
}
#' mean-centered and divided by the square root of the standard deviation
#' of each variable.
#' @keywords internal
#' @noRd
scale_Pareto <- function(x) {
return((x - mean(x, na.rm = TRUE)) / sqrt(sd(x, na.rm = TRUE)))
}
#' mean-centered and divided by the range of each variable.
#' @keywords internal
#' @noRd
scale_Range <- function(x) {
if (max(x, na.rm = TRUE) == min(x, na.rm = TRUE)) {
return(x)
} else {
return((x - mean(x, na.rm = TRUE)) / (max(x, na.rm = TRUE) - min(x, na.rm = TRUE)))
}
}
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Defines functions scale_Range scale_Pareto scale_Zscore scale_MeanCenter scale_variables normalize_feature get_norm_factors set_nf norm_cpm trans_clr gm_mean norm_clr norm_tmm norm_rle norm_css norm_tss norm_rarefy
Documented in norm_clr norm_cpm norm_css norm_rarefy norm_rle norm_tmm norm_tss scale_variables
#' @title Normalize the microbial abundance data
#'
#' @description
#' It is critical to normalize the feature table to eliminate any bias due to
#' differences in the sampling sequencing depth.This function implements six
#' widely-used normalization methods for microbial compositional data.
#'
#' @author Created by Yang Cao
#'
#' @param object a matrix, data.frame, [phyloseq::phyloseq-class] or
#' [phyloseq::otu_table-class] object.
#' @param method the methods used to normalize the microbial abundance data.
#' Options includes:
#' * "none": do not normalize.
#' * "rarefy": random subsampling counts to the smallest library size in the
#' data set.
#' * "TSS": total sum scaling, also referred to as "relative abundance", the
#' abundances were normalized by dividing the corresponding sample library
#' size.
#' * "TMM": trimmed mean of m-values. First, a sample is chosen as reference.
#' The scaling factor is then derived using a weighted trimmed mean over
#' the differences of the log-transformed gene-count fold-change between
#' the sample and the reference.
#' * "RLE", relative log expression, RLE uses a pseudo-reference calculated
#' using the geometric mean of the gene-specific abundances over all
#' samples. The scaling factors are then calculated as the median of the
#' gene counts ratios between the samples and the reference.
#' * "CSS": cumulative sum scaling, calculates scaling factors as the
#' cumulative sum of gene abundances up to a data-derived threshold.
#' * "CLR": centered log-ratio normalization.
#' * "CPM": pre-sample normalization of the sum of the values to 1e+06.
#' @param ... other arguments passed to the corresponding normalization
#' methods.
#'
#' @seealso [edgeR::calcNormFactors()],[DESeq2::estimateSizeFactorsForMatrix()],
#' [metagenomeSeq::cumNorm()]
#'
#' @importMethodsFrom BiocGenerics normalize
#' @importFrom phyloseq sample_data<-
#' @exportMethod normalize
#'
#' @aliases normalize,phyloseq-method
#' @rdname normalize-methods
#'
#' @return the same class with `object`.
#'
#' @examples
#' data(caporaso)
#' normalize(caporaso, "TSS")
#'
setMethod(
"normalize", "phyloseq",
function(object,
method = "TSS",
...) {
otu <- otu_table(object)
otu_normed <- normalize(otu, method = method, ...)
# extract norm_factor attributes and prepend to the sample_data
nf <- attr(otu_normed, "norm_factor")
if (!is.null(nf)) {
sample_data(object) <- cbind(
sample_data(object),
norm_factor = nf
)
}
# please note otu_table<- function will drop the norm_factor attribute
otu_table(object) <- otu_normed
object
}
)
#' @importMethodsFrom BiocGenerics normalize
#' @aliases normalize,otu_table-method normalize
#' @rdname normalize-methods
#'
setMethod(
"normalize", "otu_table",
function(object,
method = "TSS",
...) {
methods <- c("none", "rarefy", "TSS", "TMM", "RLE", "CSS", "CLR", "CPM")
if (method %in% methods) {
object_normed <- switch(method,
none = object,
rarefy = norm_rarefy(object, ...),
TSS = norm_tss(object),
TMM = norm_tmm(object, ...),
RLE = norm_rle(object, ...),
CSS = norm_css(object, ...),
CLR = norm_clr(object),
CPM = norm_cpm(object)
)
} else {
stop(
"`method` must be one of none, rarefy, TSS,",
" TMM, RLE, CSS, CLR, or CPM",
call. = FALSE
)
}
object_normed
}
)
#' @importMethodsFrom BiocGenerics normalize
#' @aliases normalize,data.frame-method normalize
#' @rdname normalize-methods
#'
setMethod(
"normalize", "data.frame",
function(object,
method = "TSS",
...) {
otu <- otu_table(object, taxa_are_rows = TRUE)
otu_norm <- normalize(otu, method, ...)
nf <- attr(otu_norm, "norm_factor")
res <- as.data.frame(otu_norm)
if (!is.null(nf)) {
attr(res, "norm_factor") <- nf
}
res
}
)
#' @importMethodsFrom BiocGenerics normalize
#' @aliases normalize,matrix-method normalize
#' @rdname normalize-methods
setMethod(
"normalize", "matrix",
function(object,
method = "TSS",
...) {
otu <- as.data.frame(object)
otu_norm <- normalize(otu, method, ...)
nf <- attr(otu_norm, "norm_factor")
res <- as.matrix(otu_norm)
if (!is.null(nf)) {
attr(res, "norm_factor") <- nf
}
res
}
)
## Four normalization methods do not save the norm factor: value, rarefy,
## clr and tss; where three methods save the norm factor: css, rle, tmm.
#' Normalize feature table by rafefying such that all samples have the same
#' number of total counts (library size).
#'
#' For rarefying, reads in the different samples are randomly removed until
#' the same predefined number has been reached, to assure all samples have the
#' same library size. Rarefying normalization method is the standard in
#' microbial ecology. Please note that the authors of phyloseq do not advocate
#' using this rarefying a normalization procedure, despite its recent
#' popularity
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object.
#' @param size,rng_seed,replace,trim_otus,verbose extra arguments passed to
#' [`phyloseq::rarefy_even_depth()`].
#' @export
#' @rdname normalize-methods
#' @aliases norm_rarefy
#' @importFrom phyloseq rarefy_even_depth sample_sums
#' @seealso [`phyloseq::rarefy_even_depth()`]
norm_rarefy <- function(object,
size = min(sample_sums(object)),
rng_seed = FALSE,
replace = TRUE,
trim_otus = TRUE,
verbose = TRUE) {
object_rarefied <- rarefy_even_depth(
object,
sample.size = size,
rngseed = rng_seed,
replace = replace,
trimOTUs = trim_otus,
verbose = verbose
)
# do not save the norm_factor
# the norm factors can be calculated in the subsequently differential
# analysis method, e.g. edgeR, DESeq
object_rarefied
}
#' Total-Sum Scaling (TSS) method
#'
#' TSS simply transforms the feature table into relative abundance by dividing
#' the number of total reads of each sample.
#'
#' @param object object a [phyloseq::phyloseq-class] or
#' [phyloseq::otu_table-class] object
#' @export
#' @rdname normalize-methods
#' @aliases norm_tss
#' @importFrom phyloseq otu_table<-
norm_tss <- function(object) {
otu <- otu_table(object)
size <- colSums(otu)
otu_normed <- sweep(otu, MARGIN = 2, STATS = size, FUN = "/")
otu_table(object) <- otu_table(
otu_normed,
taxa_are_rows = taxa_are_rows(object)
)
# do not save the norm_factor, the norm factors are calculated based on the
# subsequently differential analysis method, e.g. edgeR, DESeq
object
}
#' Cumulative-Sum Scaling (CSS) method
#'
#' CSS is based on the assumption that the count distributions in each sample
#' are equivalent for low abundant genes up to a certain threshold. Only the
#' segment of each sample’s count distribution that is relatively invariant
#' across samples is scaled by CSS
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object.
#' @param sl The value to scale.
#' @importFrom phyloseq sample_data<-
#' @importFrom metagenomeSeq newMRexperiment cumNorm cumNormStatFast MRcounts
#' @seealso [metagenomeSeq::calcNormFactors()]
#' @export
#' @rdname normalize-methods
#' @aliases norm_css
norm_css <- function(object, sl = 1000) {
if (inherits(object, "phyloseq")) {
object_mgs <- phyloseq2metagenomeSeq(object)
} else if (inherits(object, "otu_table")) {
object_mgs <- otu_table2metagenomeSeq(object)
}
# cumNormStatFast requires counts of all samples at least have two
# non zero features. Thus, if there are samples with only one non-zer
# features, cumNormStat is taken to compute the pth quantile.
count <- as(otu_table(object), "matrix")
fun_p <- select_quantile_func(count)
nf <- metagenomeSeq::calcNormFactors(object_mgs, p = fun_p(object_mgs))
nf <- unlist(nf) / sl
object_nf <- set_nf(object, nf)
object_nf
}
#' Relative log expression (RLE) normalization
#'
#' RLE assumes most features are not differential and uses the relative
#' abundances to calculate the normalization factor.
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object
#' @param locfunc a function to compute a location for a sample. By default,
#' the median is used.
#' @param type method for estimation: either "ratio"or "poscounts" (recommend).
#' @param geo_means default `NULL`, which means the geometric means of the
#' counts are used. A vector of geometric means from another count matrix can
#' be provided for a "frozen" size factor calculation.
#' @param control_genes default `NULL`, which means all taxa are used for size
#' factor estimation, numeric or logical index vector specifying the taxa
#' used for size factor estimation (e.g. core taxa).
#' @seealso [DESeq2::estimateSizeFactorsForMatrix()]
#' @export
#' @rdname normalize-methods
#' @aliases norm_rle
norm_rle <- function(object,
locfunc = stats::median,
type = c("poscounts", "ratio"),
geo_means = NULL,
control_genes = NULL) {
stopifnot(class(object) %in% c("phyloseq", "otu_table"))
type <- match.arg(type, c("poscounts", "ratio"))
# use substitute() to create missing argument
geo_means <- ifelse(is.null(geo_means), substitute(), geo_means)
control_genes <- ifelse(is.null(control_genes), substitute(), control_genes)
otu <- as(otu_table(object), "matrix")
nf <- estimateSizeFactorsForMatrix(
otu,
locfunc = locfunc,
geoMeans = geo_means,
controlGenes = control_genes,
type = type
)
object_nf <- set_nf(object, nf)
object_nf
}
# https://github.com/biobakery/Maaslin2/blob/master/R/utility_scripts.R
#
#' TMM (trimmed mean of m-values) normalization
#'
#' TMM calculates the normalization factor using a robust statistics based on
#' the assumption that most features are not differential and should, in
#' average, be equal between the samples. The TMM scaling factor is calculated
#' as the weighted mean of log-ratios between each pair of samples, after
#' excluding the highest count OTUs and OTUs with the largest log-fold change.
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object
#' @param ref_column column to use as reference
#' @param logratio_trim amount of trim to use on log-ratios
#' @param sum_trim amount of trim to use on the combined absolute levels
#' ("A" values)
#' @param do_weighting whether to compute the weights or not
#' @param Acutoff cutoff on "A" values to use before trimming
#' @seealso [edgeR::calcNormFactors()]
#' @export
#' @rdname normalize-methods
#' @aliases norm_tmm
norm_tmm <- function(object,
ref_column = NULL,
logratio_trim = 0.3,
sum_trim = 0.05,
do_weighting = TRUE,
Acutoff = -1e10) {
otu <- as(otu_table(object), "matrix")
nf <- edgeR::calcNormFactors(
otu,
method = "TMM",
refcolumn = ref_column,
logratioTrim = logratio_trim,
sumTrim = sum_trim,
doWeighting = do_weighting,
Acutoff = Acutoff
)
object_nf <- set_nf(object, nf)
object_nf
}
#' CLR (centered log-ratio) normalization
#'
#' In CLR, the log-ratios are computed relative to the geometric mean of all
#' features.
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' object
#' @export
#' @rdname normalize-methods
#' @aliases norm_clr
norm_clr <- function(object) {
otu <- as(otu_table(object), "matrix")
otu_norm <- apply(otu, 2, trans_clr)
otu_table(object) <- otu_table(
otu_norm,
taxa_are_rows = taxa_are_rows(object)
)
# do not save the norm_factor, the norm factors are calculated based on the
# subsequently differential analysis method, e.g. edgeR, DESeq
object
}
# from joey711/shiny-phyloseq/blob/master/panels/paneldoc/Transform.md
gm_mean <- function(x, na.rm = TRUE) {
# The geometric mean, with some error-protection bits.
exp(sum(log(x[x > 0 & !is.na(x)]), na.rm = na.rm) / length(x))
}
trans_clr <- function(x, base = exp(1)) {
x <- log((x / gm_mean(x)), base)
x[!is.finite(x) | is.na(x)] <- 0.0
return(x)
}
#' Normalize the sum of values of each sample to million (counts per million)
#'
#' `norm_cpm`: This normalization method is from the original LEfSe algorithm,
#' recommended when very low values are present (as shown in the LEfSe galaxy).
#'
#' @param object a [phyloseq::phyloseq-class] or [phyloseq::otu_table-class]
#' @export
#' @rdname normalize-methods
#' @aliases norm_cpm
#' @importFrom phyloseq transform_sample_counts
norm_cpm <- function(object) {
otu <- as(otu_table(object), "matrix") %>%
as.data.frame()
# whether the object is summarized
hie <- check_tax_summarize(object)
if (hie) {
features <- row.names(otu)
features_split <- strsplit(features, "|", fixed = TRUE)
single_indx <- which(lengths(features_split) < 2)
## keep the counts of a sample identical with `normalization`
## if we norm the counts in two steps:
## 1. calculate scale size: norm_coef = normalization/lib_size;
## 2. multiple the scale size value * norm_coef
## the counts of a sample colSums(otu) may not equal to the argument
## normalization.
## e.g. normalization = 1e6, colSums(otu) = 999999
## Finally, the kruskal test may be inaccurate,
## e.g. https://github.com/yiluheihei/microbiomeMarker/issues/13
ps_normed <- transform_sample_counts(
object,
function(x) x * 1e+06 / sum(x[single_indx])
)
} else {
ps_normed <- transform_sample_counts(
object,
function(x) x * 1e+06 / sum(x)
)
}
otu_normed <- data.frame(otu_table(ps_normed))
otu_normed <- purrr::map_df(
otu_normed,
function(x) {
if (mean(x) && stats::sd(x) / mean(x) < 1e-10) {
return(round(x * 1e6) / 1e6)
} else {
return(x)
}
}
)
otu_normed <- as.data.frame(otu_normed)
row.names(otu_normed) <- row.names(otu)
colnames(otu_normed) <- colnames(otu)
otu_table(object) <- otu_table(otu_normed, taxa_are_rows = TRUE)
# do not save the norm_factor, the norm factors are calculated based on the
# subsequently differential analysis method, e.g. edgeR, DESeq
object
}
# set the norm factors of the object, if object is in phyloseq-class, add a
# var `norm_factor` in the sample_data to save the norm factors of each sample;
# if object in otu_table-class, add a attributes `norm_factor` to the object
# to save the norm factors.
#' @importFrom phyloseq sample_data<-
#' @noRd
set_nf <- function(object, nf) {
# ensure norm factors from sample_data and attributes of otu_table are
# identical
names(nf) <- NULL
if (inherits(object, "phyloseq")) {
sample_data(object) <- cbind(sample_data(object), norm_factor = nf)
# to keep accordance with otu_table,
# we also add the attributes `norm_factor` to otu_table
ot <- otu_table(object)
attr(ot, "norm_factor") <- nf
otu_table(object) <- ot
} else if (inherits(object, "otu_table")) {
attr(object, "norm_factor") <- nf
} else {
stop("object must be a `phloseq` or `otu_table` object")
}
object
}
#' Extract the normalization factors
#'
#' This function will be used to extract the normalization factors. After
#' dividing the observed feature table by normalization factors (eliminate
#' sequencing biases), we will obtain the normalized feature table.
#'
#' @param object a [`phyloseq::phyloseq-class`], [phyloseq::otu_table-class]
#' object.
#' @return a numeric vector with the length equal to the number of samples, or
#' `NULL` if the `object` has not been normalized.
#' @noRd
get_norm_factors <- function(object) {
if (inherits(object, "phyloseq")) {
nf <- sample_data(object)$norm_factor
} else {
nf <- attr(object, "norm_factor")
}
nf
}
# Deprecated functions ----------------------------------------------------
# This function is deprecated
#' normalize the summarized feature
#' @param feature otu table or data.frame
#' @param normalization set the normalization value
#' @noRd
normalize_feature <- function(feature, normalization) {
if (inherits(feature, "otu_table")) {
if (!taxa_are_rows(feature)) {
feature <- t(feature)
}
feature <- feature@.Data %>% data.frame()
}
if (is.null(normalization)) {
return(feature)
}
feature_split <- strsplit(row.names(feature), "\\|")
hie <- ifelse(any(lengths(feature_split) > 1), TRUE, FALSE)
if (hie) {
single_indx <- which(lengths(feature_split) < 2)
abd <- purrr::map_dbl(feature, ~ sum(.x[single_indx]))
} else {
abd <- purrr::map_dbl(feature, sum)
}
normed_coef <- normalization / abd
normed_feature <- purrr::map2_df(
feature, normed_coef,
function(x, y) {
res <- x * y
if (mean(res) && stats::sd(res) / mean(res) < 1e-10) {
res <- round(res * 1e6) / 1e6
}
res
}
)
# for row names setting, phyloseq requires otu_table and tax_table has the
# same taxa
normed_feature <- as.data.frame(normed_feature)
row.names(normed_feature) <- row.names(feature)
otu_table(normed_feature, taxa_are_rows = TRUE)
}
#' @title Data scaling adjusts each variable/feature
#'
#' @description
#' Data Normalization not only normalizes data by samples, but also
#' scales data by variable/feature. Data scaling adjusts each variable/feature
#' by a scaling factor computed based on the dispersion of the variable. The
#' former is to change data distribution per sample and the latter is to put
#' variable/feature into same distribution.
#'
#' @author Created by Hua Zou (12/02/2022 Shenzhen China)
#'
#' @param object (Required). a [`phyloseq::phyloseq-class`] or
#' [`SummarizedExperiment::SummarizedExperiment-class`] object.
#' @param level (Optional). character. Summarization
#' level (from \code{rank_names(pseq)}, default: NULL).
#' @param method (Optional). character. scaling methods. Options are:
#' * "none", return the original data
#' * "mean_center": values minus mean statistic.
#' * "zscore": mean-centered and divided by the
#' standard deviation of each variable.
#' * "pareto": mean-centered and divided by the square root of
#' the standard deviation of each variable.
#' * "range": mean-centered and divided by the range of each variable.
#' (default: "none").
#'
#' @usage scale_variables(
#' object,
#' level = c(NULL, "Kingdom", "Phylum", "Class",
#' "Order", "Family", "Genus",
#' "Species", "Strain", "unique"),
#' method = c("none", "mean_center", "zscore",
#' "pareto", "range")
#' )
#'
#' @export
#'
#' @return A [`phyloseq::phyloseq-class`] or
#' [`SummarizedExperiment::SummarizedExperiment-class`] object with cleaned data.
#'
#' @importFrom dplyr %>%
#'
#' @examples
#'
#' \dontrun{
#' # phyloseq object
#' data("enterotypes_arumugam")
#' scale_variables(
#' object = enterotypes_arumugam,
#' level = "Phylum",
#' method = "mean_center")
#'
#' # SummarizedExperiment object
#' data("Zeybel_2022_protein")
#' scale_variables(
#' Zeybel_2022_protein,
#' method = "zscore")
#' }
#'
scale_variables <- function(
object,
level = NULL,
method = c("none", "mean_center", "zscore",
"pareto", "range")) {
# object = enterotypes_arumugam
# level = "Genus"
# method = "zscore"
# object = Zeybel_2022_protein
# level = NULL
# method = "zscore"
method <- match.arg(
method, c("none", "mean_center", "zscore",
"pareto", "range")
)
if (any(inherits(object, "environment"), inherits(object, "phyloseq"))) {
# taxa level
if (!is.null(level)) {
object <- aggregate_taxa(x = object, level = level)
} else {
object <- object
}
# profile: Row->features; Column->samples
otu <- as(otu_table(object), "matrix")
} else if (inherits(object, "SummarizedExperiment")) {
# profile: Row->features; Column->samples (features-by-samples matrix)
otu <- SummarizedExperiment::assay(object) %>%
as.data.frame()
} else {
otu <- as.matrix(object)
}
if (method == "none") {
abd <- otu
} else if (method == "mean_center") {
abd <- apply(otu, 1, scale_MeanCenter) %>%
t()
} else if (method == "zscore") {
abd <- apply(otu, 1, scale_Zscore) %>%
t()
} else if (method == "pareto") {
abd <- apply(otu, 1, scale_Pareto) %>%
t()
} else if (method == "range") {
abd <- apply(otu, 1, scale_Range) %>%
t()
}
if (any(inherits(object, "environment"), inherits(object, "phyloseq"))) {
phyloseq::otu_table(object) <- phyloseq::otu_table(abd, taxa_are_rows = taxa_are_rows(object))
} else if (inherits(object, "SummarizedExperiment")) {
if (nrow(abd) != nrow(otu)) {
rdata <- SummarizedExperiment::rowData(object)
cdata <- SummarizedExperiment::colData(object)
if (length(object@metadata) == 0) {
mdata <- NULL
} else {
mdata <- object@metadata
}
res <- import_SE(object = abd,
rowdata = rdata,
coldata = cdata,
metadata = mdata)
# res <- base::subset(res, colnames(prf_tab) %in% colnames(depurdata))
} else {
SummarizedExperiment::assay(object) <- abd
}
} else {
object <- abd
}
return(object)
}
#' values minus mean statistic
#' @keywords internal
#' @noRd
scale_MeanCenter <- function(x) {
return(x - mean(x, na.rm = TRUE)) # mean(x, na.rm = TRUE)
}
#' mean-centered and divided by the standard deviation of each variable
#' @keywords internal
#' @noRd
scale_Zscore <- function(x) {
return((x - mean(x, na.rm = TRUE)) / sd(x, na.rm = TRUE))
}
#' mean-centered and divided by the square root of the standard deviation
#' of each variable.
#' @keywords internal
#' @noRd
scale_Pareto <- function(x) {
return((x - mean(x, na.rm = TRUE)) / sqrt(sd(x, na.rm = TRUE)))
}
#' mean-centered and divided by the range of each variable.
#' @keywords internal
#' @noRd
scale_Range <- function(x) {
if (max(x, na.rm = TRUE) == min(x, na.rm = TRUE)) {
return(x)
} else {
return((x - mean(x, na.rm = TRUE)) / (max(x, na.rm = TRUE) - min(x, na.rm = TRUE)))
}
}
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