R/hashedDrops.R

Defines functions .hashed_drops

#' Demultiplex cell hashing data
#'
#' Demultiplex cell barcodes into their samples of origin based on the most abundant hash tag oligo (HTO).
#' Also identify potential doublets based on the presence of multiple significant HTOs.
#'
#' @param x A numeric/integer matrix-like object containing UMI counts.
#' Rows correspond to HTOs and columns correspond to cell barcodes.
#' Each barcode is assumed to correspond to a cell, i.e., cell calling is assumed to have already been performed.
#'
#' Alternatively, a \linkS4class{SummarizedExperiment} object containing such a matrix.
#' @param ambient A numeric vector of length equal to \code{nrow(x)},
#' specifying the relative abundance of each HTO in the ambient solution - see Details.
#' @param min.prop Numeric scalar to be used to infer the ambient profile when \code{ambient=NULL}, see \code{\link{ambientProfileBimodal}}.
#' @param pseudo.count A numeric scalar specifying the minimum pseudo-count when computing log-fold changes.
#' @param doublet.nmads A numeric scalar specifying the number of median absolute deviations (MADs) to use to identify doublets.
#' @param doublet.min A numeric scalar specifying the minimum threshold on the log-fold change to use to identify doublets.
#' @param doublet.mixture Logical scalar indicating whether to use a 2-component mixture model to identify doublets.
#' @param confident.nmads A numeric scalar specifying the number of MADs to use to identify confidently assigned singlets.
#' @param confident.min A numeric scalar specifying the minimum threshold on the log-fold change to use to identify singlets.
#' @param combinations An integer matrix specifying valid \emph{combinations} of HTOs.
#' Each row corresponds to a single sample and specifies the indices of rows in \code{x} corresponding to the HTOs used to label that sample.
#' @param constant.ambient Logical scalar indicating whether a constant level of ambient contamination should be used to estimate \code{LogFC2} for all cells.
#' @param assay.type Integer or string specifying the assay containing the count matrix.
#' @param ... For the generic, further arguments to pass to individual methods.
#'
#' For the SummarizedExperiment method, further arguments to pass to the ANY method.
#'
#' @return
#' A \linkS4class{DataFrame} with one row per column of \code{x}, containing the following fields:
#' \itemize{
#' \item \code{Total}, integer specifying the total count across all HTOs for each barcode.
#' \item \code{Best}, integer specifying the HTO with the highest abundance for each barcode.
#' \item \code{Second}, integer specifying the HTO with the second-highest abundance.
#' \item \code{LogFC}, numeric containing the log-fold change between the abundances of the best and second-best HTO.
#' \item \code{LogFC2}, numeric containing the log-fold change in the second-best HTO over the ambient contamination.
#' \item \code{Doublet}, logical specifying whether a barcode is a doublet.
#' \item \code{Confident}, logical specifying whether a barcode is a confidently assigned singlet.
#' }
#' In addition, the metadata contains \code{ambient}, a numeric vector containing the (estimate of the) ambient profile;
#' \code{doublet.threshold}, the threshold applied to \code{LogFC2} to identify doublets;
#' and \code{confident.threshold}, the threshold applied to non-doublet \code{LogFC} values to identify confident singlets.
#'
#' If \code{combinations} is specified, \code{Best} instead specifies the sample (i.e., row index of \code{combinations}).
#' The interpretation of \code{LogFC} and \code{LogFC2} are slightly different, and \code{Second} is not reported - see \dQuote{Resolving combinatorial hashes}.
#'
#' @details
#' The idea behind cell hashing is that cells from the same sample are stained with reagent conjugated with a single HTO.
#' Cells are mixed across multiple samples and subjected to droplet-based single-cell sequencing.
#' Cell barcode libraries can then be demultiplexed into individual samples based on whether their unique HTO is detected.
#'
#' We identify the sample of origin for each cell barcode as that corresponding to the most abundant HTO.
#' (See below for more details on exactly how \dQuote{most abundant} is defined.)
#' The log-fold change between the largest and second-largest abundances is reported for each barcode (\code{LogFC}), 
#' with large log-fold changes representing confident assignment to a single sample.
#' We also report the log-fold change of the second-most abundant HTO over the estimated level of ambient contamination (\code{LogFC2}),
#' with large log-fold changes indicating that a doublet is present.
#'
#' To facilitate quality control, we explicitly identify problematic barcodes as outliers on the relevant metrics.
#' \itemize{
#' \item By default, we identify putative doublets as those with \code{LogFC2} values that are
#' (i) \code{doublet.nmads} MADs above the median and (ii) greater than \code{doublet.min}.
#' The hard threshold is more-or-less arbitrary and aims to avoid overly aggressive detection 
#' of large outliers in a naturally right-skewed distribution 
#' (given that the log-fold changes are positive by definition, and most of the distribution is located near zero).
#' \item Alternatively, if \code{doublet.mixture=TRUE}, we fit a two-component mixture model to the \code{LogFC2} distribution.
#' Doublets are identified as all members of the component with the larger mean.
#' This avoids the need for the arbitrary parameters mentioned above but only works when there are many doublets,
#' otherwise both components will be fitted to the non-doublet values.
#' (Initialization of the model assumes at least 5\% doublets.)
#' }
#' Of the non-doublet libraries, we consider them to be confidently assigned to a single sample if their \code{LogFC} values are (i) \emph{not} less than \code{confident.nmads} MADs below the median and (ii) greater than \code{confident.min}.
#' The hard threshold is again arbitrary, but this time it aims to avoid insufficiently aggressive outlier detection - 
#' typically from an inflation of the MAD when the \code{LogFC} values are large, positive and highly variable.
#'
#' @section Use only on non-empty droplets:
#' This function assumes that cell calling has already been performed, e.g., with \code{\link{emptyDrops}}.
#' Specifically, \code{x} should only contain columns corresponding to non-empty droplets.
#' If empty droplets are included, their log-fold changes will simply reflect stochastic sampling in the ambient solution
#' and violate the assumptions involved in outlier detection.
#'
#' If \code{x} contains columns for both empty and non-empty droplets,
#' it is straightforward to simply run \code{\link{emptyDrops}} on the HTO count matrix to identify the latter.
#' Note that some fiddling with the \code{lower=} argument may be required,
#' depending on the sequencing depth of the HTO libraries.
#'
#' @section Adjusting abundances for ambient contamination:
#' HTO abundances require some care to compute due to the presence of ambient contamination in each library.
#' Ideally, the experiment would be performed in such a manner that the concentration of each HTO is the same.
#' However, if one HTO is present at higher concentration in the ambient solution,
#' this might incorrectly cause us to assign all barcodes to the corresponding sample.
#' 
#' To adjust for ambient contamination, we assume that the ambient contamination in each library follows the same profile as \code{ambient}.
#' We further assume that a minority of HTOs in a library are actually driven by the presence of cell(s), the rest coming from the ambient solution.
#' We estimate the level of ambient contamination in each barcode by scaling \code{ambient}, using a \pkg{DESeq}-like normalization algorithm to compute the scaling factor.
#' (The requisite assumption of a non-DE majority follows from the two assumptions above.)
#' We then subtract the scaled ambient proportions from the HTO count profile to remove the effect of contamination.
#' Abundances that would otherwise be negative are set to zero.
#'
#' The scaling factor for each barcode is defined by computing ratios between the HTO counts and \code{ambient}, and taking the median across all HTOs.
#' However, this strict definition is only used when there are at least 5 HTOs being considered.
#' For experiments with 3-4 HTOs, we assume that higher-order multiplets are negligible and define the scaling factor as the third-largest ratio.
#' For experiments with only 2 HTOs, the second-most abundant HTO is always used to estimate the ambient contamination.
#' 
#' Ideally, \code{ambient} would be obtained from libraries that do not correspond to cell-containing droplets.
#' For example, we could get this information from the \code{\link{metadata}} of the \code{\link{emptyDrops}} output,
#' had we run \code{\link{emptyDrops}} on the HTO count matrix (see below).
#' Unfortunately, in some cases (e.g., public data), counts are provided for only the cell-containing barcodes.
#' If \code{ambient=NULL}, the profile is inferred from \code{x} using \code{\link{ambientProfileBimodal}}.
#'
#' @section Computing the log-fold changes:
#' HTO abundances may be set to zero after subtracting the ambient noise.
#' Thus, we need to add a pseudo-count to ensure that we can actually compute the log-fold changes described in \dQuote{Value}.
#'
#' For each barcode, we define the pseudo-count as the average ambient HTO count, i.e., the average of the scaled \code{ambient} for that barcode. 
#' This is motivated by the assumption that the number of contaminating transcript molecules is roughly the same in each droplet,
#' such that any differences in ambient coverage between libraries reflect barcode-specific biases (capture efficiency, sequencing depth) that would also affect cell-derived HTO counts. 
#' By using the average ambient count as the pseudo-count, we ensure that the shrinkage of the log-fold changes is not driven by the sequencing depth,
#' e.g., a constant pseudo-count would inflict greater shrinkage on libraries that have not been sequenced as deeply.
#' This avoids excessive variability in the log-fold change distribution that would otherwise reduce the precision of outlier detection.
#' Another nice aspect of this approach is that it collapses to a no-op if the experiment is well-executed with identical concentrations of all HTOs in the ambient solution.
#' (That said, we still enforce a minimum pseudo-count of \code{pseudo.count} if the average ambient count is lower than that,
#' simply to avoid highly variable log-fold changes when dealing with very low counts.)
#'
#' Once the pseudo-count is added to the ambient-subtracted abundances, we compute the log-fold changes as described in \dQuote{Value}.
#' \code{LogFC} is defined as the log-fold change in the most abundant HTO over the second-most abundant HTO.
#' \code{LogFC2} is defined as the log-fold change in the second-most abundant HTO over the ambient contamination.
#' By default, the denominator for \code{LogFC2} is set to the per-barcode average ambient count, equivalent to the pseudo-count used above.
#' This cancels out any variation in sequencing depth for more precise outlier calls.
#'
#' @section Handling 2 or fewer samples:
#' If \code{x} has no more than two rows, \code{LogFC2}, \code{Doublet} and \code{doublet.threshold} are set to \code{NA}.
#' Strictly speaking, doublet detection is not possible as the second HTO is always used to estimate the ambient scaling and thus \code{LogFC2} is always zero.
#' \code{Confident} calls are still available in the output of this function so assignment to the individual samples can still be performed.
#' In this scenario, the non-confident assignments are probably also doublets, though this cannot be said with much certainty.
#'
#' To work around this limitation, we can set \code{constant.ambient=TRUE},
#' which defines the denominator of each barcode's \code{LogFC2} as the median of the per-barcode average ambient counts across all barcodes.
#' This is useful in scenarios where \code{nrow(x)} is too small and we cannot assume that the abundances of most HTOs are driven by ambient contamination.
#' By assuming most barcodes are not doublets, we can obtain a dataset-wide baseline for the ambient contamination to compute \code{LogFC2}.
#' The cost of this approach is that the log-fold changes will be more variable as sequencing depth is not cancelled out. 
#' 
#' If \code{x} has no more than one row, \code{Confident}, \code{LogFC} and \code{confident.threshold} are set to \code{NA}.
#' Obviously, if there is only one HTO, the identity of the assigned sample is a foregone conclusion.
#'
#' @section Resolving combinatorial hashes:
#' In some applications, samples are labelled with a combination of HTOs to enable achieve greater multiplexing throughput.
#' This is accommodated by passing \code{combinations} to specify the valid HTO combinations that were used for sample labelling.
#' Each row of \code{combinations} corresponds to a sample and should contain non-duplicated row indices of \code{x} corresponding to the HTOs used in that sample.
#'
#' The calculation for the single-HTO case is then generalized for HTO combinations.
#' The most important differences are that:
#' \itemize{
#' \item The reported \code{LogFC} is now the log-fold change between the \eqn{n}th most abundant HTO and the \eqn{n+1}th HTO,
#' where \eqn{n} is the number of HTOs in a valid combination. 
#' This captures the drop-off in abundance beyond the expected number of HTOs.
#' \item The reported \code{LogFC2} is now the log-fold change of the \eqn{n+1}th HTO over the ambient contamination.
#' This captures the high abundance of the more-than-expected number of HTOs when doublets are present.
#' \item \code{Best} no longer refers to the row index of \code{x}, but instead to the row index of \code{combinations}.
#' This may contain \code{NA} values if a particular combination of HTOs is observed but not present in the expected set.
#' \item \code{Second} is no longer reported as we cannot conveniently determine the identity of the second sample.
#' }
#'
#' We also generalize the edge-case behavior when there are not enough HTOs to support doublet detection. 
#' Consider that an inter-sample doublet may result in up to \eqn{2n} abundant HTOs.
#' Estimation of the scaling factor will attempt to avoid using the top \eqn{2n} ratios.
#' If \code{nrow(x)} is equal to or less than \eqn{2n}, doublet statistics will not be reported at all, 
#' i.e., \code{Doublet} and \code{LogFC2} are set to \code{NA}.
#' This can be overcome by setting \code{constant.ambient=TRUE} as described above.
#'
#' @author Aaron Lun
#' @examples
#' # Mocking up an example dataset with 10 HTOs and 10% doublets.
#' ncells <- 1000
#' nhto <- 10
#' y <- matrix(rpois(ncells*nhto, 50), nrow=nhto)
#' true.sample <- sample(nhto, ncells, replace=TRUE)
#' y[cbind(true.sample, seq_len(ncells))] <- 1000
#'
#' ndoub <- ncells/10
#' next.sample <- (true.sample[1:ndoub]  + 1) %% nrow(y)
#' next.sample[next.sample==0] <- nrow(y)
#' y[cbind(next.sample, seq_len(ndoub))] <- 500
#'
#' # Computing hashing statistics.
#' stats <- hashedDrops(y)
#'
#' # Doublets show up in the top-left, singlets in the bottom right.
#' plot(stats$LogFC, stats$LogFC2)
#'
#' # Most cells should be singlets with low second log-fold changes.
#' hist(stats$LogFC2, breaks=50)
#'
#' # Identify confident singlets or doublets at the given threshold.
#' summary(stats$Confident)
#' summary(stats$Doublet)
#' 
#' # Checking against the known truth, in this case
#' # 'Best' contains the putative sample of origin.
#' table(stats$Best, true.sample) 
#'
#' @references
#' Stoeckius M, Zheng S, Houck-Loomis B et al. (2018)
#' Cell Hashing with barcoded antibodies enables multiplexing and doublet detection for single cell genomics.
#' \emph{Genome Biol.} 19, 1:224
#'
#' @seealso
#' \code{\link{emptyDrops}}, to identify which barcodes are likely to contain cells.
#' 
#' @name hashedDrops
NULL

#' @importFrom Matrix t colSums
#' @importFrom S4Vectors DataFrame
#' @importFrom stats median mad
#' @importFrom beachmat colBlockApply
.hashed_drops <- function(x, ambient=NULL, min.prop=0.05, pseudo.count=5, constant.ambient=FALSE, 
    doublet.nmads=3, doublet.min=2, doublet.mixture=FALSE, confident.nmads=3, confident.min=2, combinations=NULL)
{ 
    totals <- colSums(x)
    cell.names <- colnames(x)

    if (is.null(ambient)) {
        ambient <- ambientProfileBimodal(x, min.prop)
    }
    original.ambient <- ambient

    discard <- as.logical(ambient == 0) # protect against array 'ambient', see MarioniLab/DropletUtils#82.
    x <- x[!discard,,drop=FALSE]
    ambient <- ambient[!discard]
    
    if (is.null(combinations)) {
        n.expected <- 1L
    } else {
        n.expected <- ncol(combinations)
    }

    if (constant.ambient) {
        output <- colBlockApply(x, FUN=hashed_constant, prop=ambient, pseudo_count=pseudo.count, n_expected=n.expected)

        lfc <- log2(unlist(lapply(output, "[[", i="FC"), use.names=FALSE))
        const.amb <- median(unlist(lapply(output, "[[", i="Ambient"), use.names=FALSE))
        lfc2 <- log2(unlist(lapply(output, "[[", i="Numerator"), use.names=FALSE)/const.amb)

        best.sample <- do.call(cbind, lapply(output, "[[", i="Best"))
        second.sample <- unlist(lapply(output, "[[", i="Second"), use.names=FALSE)
    } else {
        output <- colBlockApply(x, FUN=hashed_deltas, prop=ambient, pseudo_count=pseudo.count, n_expected=n.expected)
        lfc <- log2(unlist(lapply(output, "[[", i="FC"), use.names=FALSE))
        lfc2 <- log2(unlist(lapply(output, "[[", i="FC2"), use.names=FALSE))
        best.sample <- do.call(cbind, lapply(output, "[[", i="Best"))
        second.sample <- unlist(lapply(output, "[[", i="Second"), use.names=FALSE)
    }

    no.lfc2 <- all(is.na(lfc2))
    if (!no.lfc2) {
        if (!doublet.mixture) {
            # Using outlier detection to prune out doublets.
            med2 <- median(lfc2)
            mad2 <- mad(lfc2, center=med2)
            upper.threshold <- med2 + doublet.nmads * mad2
            upper.threshold <- max(upper.threshold, doublet.min)
            is.doublet <- lfc2 > upper.threshold 
        } else {
            is.doublet <- !.get_lower_dist(lfc2, p=0.05)
            upper.threshold <- max(lfc2[!is.doublet])
        }
    } else {
        # To keep the next step happy; we will flip it back to all-NA's soon enough.
        is.doublet <- logical(ncol(x))
        upper.threshold <- NA_real_
    }

    # Using outlier detection to identify confident singlets.
    no.lfc1 <- all(is.na(lfc))
    if (!no.lfc1) {
        lfc.singlet <- lfc[!is.doublet]
        med.singlet <- median(lfc.singlet)
        mad.singlet <- mad(lfc.singlet, center=med.singlet)

        lower.threshold <- med.singlet - confident.nmads * mad.singlet
        lower.threshold <- max(lower.threshold, confident.min)
        confident.singlet <- lfc > lower.threshold & !is.doublet
    } else {
        confident.singlet <- rep(NA, ncol(x))
        lower.threshold <- NA_real_
    }

    if (no.lfc2) {
        if (!no.lfc1 && !constant.ambient) {
            warning("could not obtain explicit doublet calls, consider using 'constant.ambient=TRUE'")
        }
        is.doublet <- rep(NA, ncol(x))
    }

    # Translating from indices to combinations, if requested.
    keep <- which(!discard)
    best.sample[] <- keep[best.sample + 1L]

    output <- DataFrame(row.names=cell.names, Total=totals)

    if (is.null(combinations)) {
        output$Best <- drop(best.sample)
        output$Second <- keep[second.sample + 1L]
    } else {
        best.sample <- t(best.sample)
        combinations <- t(apply(combinations, 1, sort))
        colnames(combinations) <- colnames(best.sample) <- seq_len(n.expected)
        output$Best <- match(DataFrame(best.sample), DataFrame(combinations))
    }

    output <- cbind(output, DataFrame(LogFC=lfc, LogFC2=lfc2, Doublet=is.doublet, Confident=confident.singlet))

    metadata(output) <- list(
        ambient=original.ambient,
        confident.threshold=lower.threshold,
        doublet.threshold=upper.threshold
    )

    output
}

#' @export
#' @rdname hashedDrops
setGeneric("hashedDrops", function(x, ...) standardGeneric("hashedDrops"))

#' @export
#' @rdname hashedDrops
setMethod("hashedDrops", "ANY", .hashed_drops)

#' @export
#' @rdname hashedDrops
#' @importFrom SummarizedExperiment assay
setMethod("hashedDrops", "SummarizedExperiment", function(x, ..., assay.type="counts") {
    .hashed_drops(assay(x, assay.type), ...)
})
MarioniLab/DropletUtils documentation built on Oct. 12, 2024, 5:40 p.m.