In this vignette, we describe usage of a suite of tools, SEESAW, Statistical Estimation of allelic Expression using Salmon and Swish, which allow for testing allelic imbalance across samples.
The methods are described in Wu et al. (2022) doi: 10.1101/2022.08.12.503785.
SEESAW makes use of Swish (Zhu et al. 2019) for paired inference, which is an extension of the SAMseq (Li and Tibshirani 2011) methods for permutation-based FDR control.
Minimal code for running SEESAW is shown below.
On the command line:
# generate diploid txome with g2gtools:
# http://churchill-lab.github.io/g2gtools/
> salmon index -p #threads -t diploid_fasta -i diploid_txome --keepDuplicates
> salmon quant -i diploid_txome -l A -p #threads \
--numBootstraps 30 -o output -1 read1 -2 read2
From within R/Bioconductor:
# first build tx2gene to gene- or TSS-level
# (for isoform level skip `tx2gene`)
library(ensembldb)
library(plyranges)
# gene level:
tx2gene <- transcripts(edb) %>%
select(tx_id, group_id=gene_id)
# TSS level:
tx2gene <- makeTx2Tss(edb, maxgap=50) %>%
select(tx_id, gene_id, group_id, tss)
# import counts:
y <- importAllelicCounts(
coldata, a1="alt", a2="ref",
format="wide", tx2gene=tx2gene
)
# testing with Swish:
y <- labelKeep(y)
y <- y[mcols(y)$keep,]
# see below for other tests and details
y <- swish(y, x="allele", pair="sample", fast=1)
mcols(y)$qvalue # <-- gives FDR-bounded sets
Type of tests
SEESAW allows for testing global allelic imbalance across all samples (pairwise testing within each individual), as well as differential, or dynamic allelic imbalance (pairwise allelic fold changes estimated within individual, followed by testing across two groups, or along an additional covariate). Each of these allelic imbalance (AI) analyses takes into account the potentially heterogeneous amount of inferential uncertainty per sample, per feature (transcript, transcript-group, or gene), and per allele.
Steps in SEESAW
Running SEESAW involves generation of a diploid transcriptome (e.g. using g2gtools, construction of a diploid Salmon index (specifying --keepDuplicates
), followed by Salmon quantification with a number of bootstrap inferential replicates (we recommend 30 bootstrap replicates). These three steps (diploid reference preparation, indexing, quantification with bootstraps) provide the input data for the following statistical analyses in R/Bioconductor. The steps shown in this vignette leverage Bioconductor infrastructure including SummarizedExperiment for storage of input data and results, tximport for data import, and GRanges and Gviz for plotting.
In short the SEESAW steps are as listed, and diagrammed below:
--keepDuplicates
makeTx2Tss()
aggregates data to TSS-level (optional)importAllelicCounts()
creates a SummarizedExperimentlabelKeep()
and swish()
(skip scaling)Below we demonstrate an analysis where transcripts are grouped by their transcription start site (TSS), although gene-level or transcript-level analysis is also possible. Additionally, any custom grouping could be used, by manually generating a t2g
table as shown below. Special plotting functions in fishpond facilitate visualization of allelic and isoform changes at different resolutions, alongside gene models. In three examples, we perform global AI testing, differential AI testing, and dynamic AI testing, in all cases on simulated data associated with human genes.
We begin assuming steps 1-3 have been completed. We can use the makeTx2Tss
function to generate a GRanges object t2g
that connects transcripts to transcript groups.
suppressPackageStartupMessages(library(ensembldb))
library(EnsDb.Hsapiens.v86)
library(fishpond)
edb <- EnsDb.Hsapiens.v86
t2g <- makeTx2Tss(edb) # GRanges object
mcols(t2g)[,c("tx_id","group_id")]
## DataFrame with 216741 rows and 2 columns
## tx_id group_id
## <character> <character>
## ENST00000456328 ENST00000456328 ENSG00000223972-11869
## ENST00000450305 ENST00000450305 ENSG00000223972-12010
## ENST00000488147 ENST00000488147 ENSG00000227232-29570
## ENST00000619216 ENST00000619216 ENSG00000278267-17436
## ENST00000473358 ENST00000473358 ENSG00000243485-29554
## ... ... ...
## ENST00000420810 ENST00000420810 ENSG00000224240-2654..
## ENST00000456738 ENST00000456738 ENSG00000227629-2659..
## ENST00000435945 ENST00000435945 ENSG00000237917-2663..
## ENST00000435741 ENST00000435741 ENSG00000231514-2662..
## ENST00000431853 ENST00000431853 ENSG00000235857-5685..
Alternatively for gene-level analysis, one could either prepare a t2g
data.frame with tx_id
and gene_id
columns, or a t2g
GRanges object with a column group_id
that is equal to gene_id
.
Here we will use simulated data, but we can import allelic counts with the importAllelicCounts()
function. It is best to read over the manual page for this function. For TSS-level analysis, the t2g
GRanges generated above should be passed to the tx2gene
argument. This will summarize transcript-level counts to the TSS level, and will attach rowRanges
that provide the genomic locations of the grouped transcripts. Note that importAllelicCounts
does not yet have the ability to automatically generate ranges based on sequence hashing (as occurs in tximeta
).
Because we use --keepDuplicates
in the step when we build the Salmon index, there will be a number of features in which there is no information about the allelic expression in the reads. We can find these features in bootstrap data by examining when the inferential replicates are nearly identical for the two alleles, as this is how the EM will split the reads. Removing these features avoids downstream problems during differential testing. Code for this filtering follows:
We begin by generating a simulated data object that resembles what one would obtain with importAllelicCounts()
. The import function arranges the a2
(non-effect) allelic counts first, followed by the a1
(effect) allelic counts. Allelic ratios are calculated as a1/a2
, which follows the notational standard in PLINK and other tools.
## DataFrame with 20 rows and 2 columns
## allele sample
## <factor> <factor>
## s1-a2 a2 sample1
## s2-a2 a2 sample2
## s3-a2 a2 sample3
## s4-a2 a2 sample4
## s5-a2 a2 sample5
## ... ... ...
## s6-a1 a1 sample6
## s7-a1 a1 sample7
## s8-a1 a1 sample8
## s9-a1 a1 sample9
## s10-a1 a1 sample10
## [1] "a2" "a1"
A hidden code chunk is used to add ranges from the EnsDb to the simulated dataset. For a real dataset, the ranges would be added either by importAllelicCounts
(if using tx2gene
) or could be added manually for transcript- or gene-level analysis, using the rowRanges<-
setter function. The ranges are only needed for the plotAllelicGene
plotting function below.
<hidden code chunk>
We can already plot a heatmap of allelic ratios, before performing statistical testing. We can see in the first gene, ADSS, there appear to be two groups of transcripts with opposing allelic fold change. SEESAW makes use of pheatmap for plotting a heatmap of allelic ratios.
y <- computeInfRV(y) # for posterior mean, variance
gene <- rowRanges(y)$gene_id[1]
idx <- mcols(y)$gene_id == gene
plotAllelicHeatmap(y, idx=idx)
The following two functions perform a Swish analysis, comparing the allelic counts within sample, while accounting for uncertainty in the assignment of the reads. The underlying test statistic is a Wilcoxon signed-rank statistic, which compares the two allele counts from each sample, so a paired analysis.
Scaling: Note that we do not use scaleInfReps
in the allelic pipeline. Because we compare the two alleles within samples, there is no need to perform scaling of the counts to adjust for sequencing depth. We simply import counts, filter low counts with lableKeep
and then run the statistical testing with swish
.
Fast mode: for basic allelic analysis, we use a paired test, comparing one allele to the other. The default in swish
for a simple paired test is to use a Wilcoxon signed rank test statistic with bootstrap aggregation and permutation significance. The ranks must be recomputed per permutation, which is a slow operation that is not necessary with other designs in swish
. A faster test statistic is the one-sample z-score, which gives similar results. Here we demonstrate using the fast version of the paired test. Note that fast=1
is only relevant for simple paired tests, not for other designs, which are already fast.
We can return to the heatmap, and now add q-values, etc. For details on adding metadata to a pheatmap plot object, see ?pheatmap
.
dat <- data.frame(minusLogQ=-log10(mcols(y)$qvalue[idx]),
row.names=rownames(y)[idx])
plotAllelicHeatmap(y, idx=idx, annotation_row=dat)
In order to visualize the inferential uncertainty, we can make use of plotInfReps()
:
par(mfrow=c(2,1), mar=c(1,4.1,2,2))
plotInfReps(y, idx=1, x="allele", cov="sample", xaxis=FALSE, xlab="")
plotInfReps(y, idx=2, x="allele", cov="sample", xaxis=FALSE, xlab="")
Plotting results in genomic context
For analysis at the isoform or TSS-level, it may be useful to display results within a gene, relating the allelic differences to various gene features. SEESAW provides plotAllelicGene()
in order to build visualization of Swish test statistics, allelic proportions, and isoform proportions, in a genomic context, making use of Gviz. Note that this function is not relevant for gene-level AI analysis. The first three arguments to plotAllelicGene()
are the SummarizedExperiment object, the name of a gene (should match gene_id
column), and a TxDb or EnsDb to use for plotting the gene model at the top. The statistics and proportions are then plotted at the first position of the feature (start
for +
features and end
for -
features).
You can also specify the gene using symbol
:
In the allelic proportion and isoform proportion tracks, a line is drawn through the mean proportion for a2 and a1 allele, and for the isoform proportion, across samples, at the start site for each transcript group. The line is meant only to help visualize the mean value as it may change across transcript groups, but the line has no meaning in the ranges in between features. That is, unlike continuous genomic features (methylation or accessibility), there is no meaning to the allelic proportion or isoform proportion outside of measured start sites of transcription.
We can further customize the plot, for example, changing the labels displayed on the gene model, and changing the labels for the alleles. An ideogram can be added with ideogram=TRUE
, although this requires connecting to an external FTP site.
See importAllelicGene()
manual page for more details.
plotAllelicGene(y, gene, edb,
transcriptAnnotation="transcript",
labels=list(a2="maternal",a1="paternal"))
We can also customize the display of the alleles in the plotInfReps()
plots, by adding a new factor, while carefully noting the existing and new allele labels, to make sure the annotation is correct:
## [1] "a2" "a1"
Above, we tested for global AI, where the allelic fold change is consistent across all samples. We can also test for differential or dynamic AI, by adding specification of a cov
(covariate) which can be either a two-group factor, or a continuous variable. Here we demonstrate differential AI, when cov
is a two-group factor, in this case called "condition"
.
## DataFrame with 24 rows and 3 columns
## allele sample condition
## <factor> <factor> <factor>
## s1-a2 a2 sample1 A
## s2-a2 a2 sample2 A
## s3-a2 a2 sample3 A
## s4-a2 a2 sample4 A
## s5-a2 a2 sample5 A
## ... ... ... ...
## s8-a1 a1 sample8 B
## s9-a1 a1 sample9 B
## s10-a1 a1 sample10 B
## s11-a1 a1 sample11 B
## s12-a1 a1 sample12 B
##
## a2 a1
## A 6 6
## B 6 6
In the following, we test for changes in allelic imbalance across condition
. This is implemented as an “interaction” test, where we test if the fold change associated with allele
, for paired samples, differs across condition
.
In this simulated data, the top two features exhibit differential AI with low uncertainty, so these emerge as highly significant, as expected.
## DataFrame with 2 rows and 2 columns
## stat qvalue
## <numeric> <numeric>
## gene-1 17.3 0.005
## gene-2 -17.5 0.005
The non-AI features have roughly uniform p-values:
We can plot the allelic counts with uncertainty, grouped by the condition (black and grey lines at bottom).
plotInfReps(y, idx=1, x="allele", cov="condition",
xaxis=FALSE, legend=TRUE, legendPos="bottomright")
We can also visualize the data across multiple features, in terms of allelic ratios:
Now we demonstrate dynamic AI testing when cov
(covariate) is a continuous variable. In this case, the user should specify a correlation test, either cor="pearson"
or "spearman"
, which is the underlying test statistic used by Swish (it will then be averaged over bootstraps and a permutation null is generated to assess FDR). We have found that Pearson correlations work well in our testing, but the Spearman correlation offers additional robustness against outlying values in cov
.
## DataFrame with 20 rows and 3 columns
## allele sample time
## <factor> <factor> <numeric>
## s1-a2 a2 sample1 0.00
## s2-a2 a2 sample2 0.11
## s3-a2 a2 sample3 0.22
## s4-a2 a2 sample4 0.33
## s5-a2 a2 sample5 0.44
## ... ... ... ...
## s6-a1 a1 sample6 0.56
## s7-a1 a1 sample7 0.67
## s8-a1 a1 sample8 0.78
## s9-a1 a1 sample9 0.89
## s10-a1 a1 sample10 1.00
A hidden code chunk adds ranges to our simulation data.
<hidden code chunk>
In the following, we test for changes in allelic imbalance within sample that correlate with a covariate time
.
Note the first two features have small q-values and opposite test statistic; here the test statistic is the average Pearson correlation of the allelic log fold change with the time
variable, averaging over bootstrap replicates.
## DataFrame with 2 rows and 2 columns
## stat qvalue
## <numeric> <numeric>
## ADSS-244452134 0.870969 0.005
## ADSS-244419273 -0.861573 0.005
For plotting inferential replicates over a continuous variable, we must first compute summary statistics of inferential mean and variance:
Now we can examine the allelic counts across the time
variable:
par(mfrow=c(2,1), mar=c(2.5,4,2,2))
plotInfReps(y, idx=1, x="time", cov="allele", shiftX=.01, xaxis=FALSE, xlab="", main="")
par(mar=c(4.5,4,0,2))
plotInfReps(y, idx=2, x="time", cov="allele", shiftX=.01, main="")
With a little more code, we can add a lowess
line for each series:
plotInfReps(y, idx=1, x="time", cov="allele", shiftX=.01)
dat <- data.frame(
time = y$time[1:10],
a2 = assay(y, "mean")[1,y$allele=="a2"],
a1 = assay(y, "mean")[1,y$allele=="a1"])
lines(lowess(dat[,c(1,2)]), col="dodgerblue")
lines(lowess(dat[,c(1,3)]), col="goldenrod4")
Visualizing the allelic proportion in a heatmap helps to see relationships with the time
variable, while also showing data from multiple features at once:
idx <- c(1:4)
row_dat <- data.frame(minusLogQ=-log10(mcols(y)$qvalue[idx]),
row.names=rownames(y)[idx])
col_dat <- data.frame(time=y$time[1:10],
row.names=paste0("s",1:10))
plotAllelicHeatmap(y, idx=idx,
annotation_row=row_dat,
annotation_col=col_dat)
Plotting results in genomic context
Previously, in the global AI section, we demonstrated how to plot TSS-level results in a genomic context using plotAllelicGene()
. Here we demonstrate how to repeat such a plot for differential or dynamic AI analysis. There is an extra step for dynamic analysis (binning the continuous covariate into groups) but otherwise the code would be similar.
We begin by binning the time
covariate into a few groups, so that we can diagram the allelic and isoform proportions in the genomic context, but facetting across time.
We create the binned covariate using cut
, and rename the labels for nicer labels in our plot. For differential AI, this step would be skipped (as there already exists a two-group covariate for grouping samples).
y$time_bins <- cut(y$time,breaks=c(0,.25,.75,1),
include.lowest=TRUE, labels=FALSE)
y$time_bins <- paste0("time-",y$time_bins)
table(y$time_bins[ y$allele == "a2" ])
##
## time-1 time-2 time-3
## 3 4 3
We can then make our facetted allelic proportion plot:
gene <- rowRanges(y)$gene_id[1]
plotAllelicGene(y, gene, edb, cov="time_bins",
qvalue=FALSE, log2FC=FALSE)
If we also want to visualize how isoform proportions may be changing, we can add covFacetIsoform=TRUE
, which additionally facets the isoform proportion plot by the covariate:
The SEESAW suite currently supports testing AI globally (across all samples), testing for differential AI (across two groups), or testing for dynamic AI (whether the allelic ratio changes over a continuous covariate such as time).
However, additional designs can also be used within the nonparametric testing framework of Swish (and originally SAMseq). The general idea of the testing framework is to compute a test statistic, average that over inferential replicates, and then permute the samples in order to generate a null distribution of the bootstrap-averaged test statistic. The qvalue method and package is then used to return the final inference. Here we explore testing outside of swish
function, by following these steps. We will test for differential correlation of allelic ratios across two groups.
First, we simulate a dataset with two groups, and insert differential correlation for one feature:
set.seed(1)
y1 <- makeSimSwishData(dynamicAI=TRUE)
y2 <- makeSimSwishData(dynamicAI=TRUE)
y2$sample <- factor(rep(paste0("sample",11:20),2))
y <- cbind(y1, y2)
y$group <- factor(rep(c("A","B"),each=20))
table(y$time, y$group) # 2 allelic counts per cell
##
## A B
## 0 2 2
## 0.11 2 2
## 0.22 2 2
## 0.33 2 2
## 0.44 2 2
## 0.56 2 2
## 0.67 2 2
## 0.78 2 2
## 0.89 2 2
## 1 2 2
We change the direction of AI trend for the first feature:
reps <- grep("infRep", assayNames(y), value=TRUE)
for (k in reps) {
assay(y,k)[1,21:40] <- assay(y,k)[1,c(31:40,21:30)]
}
To visualize the differential correlation of AI with time for the first and second feature (left side, group A; right side, group B, features by row):
y <- computeInfRV(y)
par(mfrow=c(2,2),mar=c(3,3,3,1))
for (i in 1:2) {
plotInfReps(y[,y$group=="A"], idx=i, x="time", cov="allele", shiftX=.01)
plotInfReps(y[,y$group=="B"], idx=i, x="time", cov="allele", shiftX=.01)
}
We define a number of variables that will be used to compute test statistics:
pc <- 5 # a pseudocount
idx1 <- which(y$allele == "a1")
idx2 <- which(y$allele == "a2")
# the sample must be aligned
all.equal(y$sample[idx1], y$sample[idx2])
## [1] TRUE
cov <- y$time[idx1]
group <- y$group[idx1]
# interaction of group and covariate (time)
design <- model.matrix(~group + cov + group:cov)
For efficiency, we precompute the allelic LFC array (features x samples x infReps):
reps <- grep("infRep", assayNames(y), value=TRUE)
nreps <- length(reps)
infReps <- assays(y)[reps]
infRepsArray <- abind::abind(as.list(infReps), along=3)
lfcArray <- log2(infRepsArray[,idx1,] + pc) -
log2(infRepsArray[,idx2,] + pc)
For the statistic, we extract the coefficient for the interaction of group and the time covariate, using limma::lmFit
applied to a matrix of log2 fold changes. We then compute basic t-statistics from this table of linear model coefficients. It is useful to define a function to repeat this operation (over inferential replicates and permutations).
computeStat <- function(k, design, name) {
fit <- limma::lmFit(lfcArray[,,k], design)
tstats <- fit$coef/fit$stdev.unscaled/fit$sigma
tstats[,name]
}
We then use the SAMseq/Swish strategy to average over the inferential replicates, for the observed data:
Finally, we repeat, while permuting the group labels for the samples 100 times:
n <- nrow(design)
nperms <- 100
nulls <- matrix(nrow=nrow(y), ncol=nperms)
set.seed(1)
for (p in seq_len(nperms)) {
# permute group labels
pgroup <- group[sample(n)]
pdesign <- model.matrix(~pgroup + cov + pgroup:cov)
nulls[,p] <- rowMeans(sapply(1:nreps, \(k) computeStat(k, pdesign, "pgroupB:cov")))
}
The rest of the process is providing the observed statistic and the null statistics to the qvalue
function:
pvalue <- qvalue::empPvals(abs(stat), abs(nulls))
q_res <- qvalue::qvalue(pvalue)
locfdr <- q_res$lfdr
qvalue <- q_res$qvalues
res <- data.frame(stat, pvalue, locfdr, qvalue)
We can see the first feature is retained with a low q-value while the others show a relatively flat histogram of p-values.
## stat pvalue locfdr qvalue
## gene-1 -6.89602993 0.00001 0.0388765 0.0100000
## gene-2 -0.08979129 0.70415 1.0000000 0.9913997
## gene-3 -0.16623033 0.48227 1.0000000 0.9772813
## gene-4 0.04186206 0.85828 1.0000000 0.9980000
## gene-5 -0.13609701 0.56461 1.0000000 0.9772813
## gene-6 0.15545421 0.51181 1.0000000 0.9772813
This general process for extracting arbitrary statistics on the allelic log fold change and making use of permutation for generating q-values can be applied to various designs.
For further questions about the SEESAW steps, please post to one of these locations:
fishpond
or swish
## R version 4.4.0 beta (2024-04-15 r86425)
## Platform: x86_64-pc-linux-gnu
## Running under: Ubuntu 22.04.4 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.19-bioc/R/lib/libRblas.so
## LAPACK: /usr/lib/x86_64-linux-gnu/lapack/liblapack.so.3.10.0
##
## locale:
## [1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
## [3] LC_TIME=en_US.UTF-8 LC_COLLATE=en_US.UTF-8
## [5] LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8
## [7] LC_PAPER=en_US.UTF-8 LC_NAME=C
## [9] LC_ADDRESS=C LC_TELEPHONE=C
## [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
##
## time zone: America/New_York
## tzcode source: system (glibc)
##
## attached base packages:
## [1] stats4 stats graphics grDevices utils datasets methods
## [8] base
##
## other attached packages:
## [1] SummarizedExperiment_1.34.0 MatrixGenerics_1.16.0
## [3] matrixStats_1.3.0 fishpond_2.10.0
## [5] EnsDb.Hsapiens.v86_2.99.0 ensembldb_2.28.0
## [7] AnnotationFilter_1.28.0 GenomicFeatures_1.56.0
## [9] AnnotationDbi_1.66.0 Biobase_2.64.0
## [11] GenomicRanges_1.56.0 GenomeInfoDb_1.40.0
## [13] IRanges_2.38.0 S4Vectors_0.42.0
## [15] BiocGenerics_0.50.0
##
## loaded via a namespace (and not attached):
## [1] RColorBrewer_1.1-3 rstudioapi_0.16.0
## [3] jsonlite_1.8.8 magrittr_2.0.3
## [5] farver_2.1.1 rmarkdown_2.26
## [7] BiocIO_1.14.0 zlibbioc_1.50.0
## [9] vctrs_0.6.5 memoise_2.0.1
## [11] Rsamtools_2.20.0 RCurl_1.98-1.14
## [13] base64enc_0.1-3 htmltools_0.5.8.1
## [15] S4Arrays_1.4.0 progress_1.2.3
## [17] curl_5.2.1 SparseArray_1.4.0
## [19] Formula_1.2-5 sass_0.4.9
## [21] bslib_0.7.0 htmlwidgets_1.6.4
## [23] plyr_1.8.9 Gviz_1.48.0
## [25] httr2_1.0.1 cachem_1.0.8
## [27] GenomicAlignments_1.40.0 lifecycle_1.0.4
## [29] pkgconfig_2.0.3 Matrix_1.7-0
## [31] R6_2.5.1 fastmap_1.1.1
## [33] GenomeInfoDbData_1.2.12 digest_0.6.35
## [35] colorspace_2.1-0 Hmisc_5.1-2
## [37] RSQLite_2.3.6 filelock_1.0.3
## [39] fansi_1.0.6 httr_1.4.7
## [41] abind_1.4-5 compiler_4.4.0
## [43] bit64_4.0.5 htmlTable_2.4.2
## [45] backports_1.4.1 BiocParallel_1.38.0
## [47] DBI_1.2.2 highr_0.10
## [49] biomaRt_2.60.0 rappdirs_0.3.3
## [51] DelayedArray_0.30.0 rjson_0.2.21
## [53] gtools_3.9.5 tools_4.4.0
## [55] foreign_0.8-86 nnet_7.3-19
## [57] glue_1.7.0 restfulr_0.0.15
## [59] grid_4.4.0 checkmate_2.3.1
## [61] cluster_2.1.6 reshape2_1.4.4
## [63] generics_0.1.3 gtable_0.3.5
## [65] BSgenome_1.72.0 data.table_1.15.4
## [67] hms_1.1.3 xml2_1.3.6
## [69] utf8_1.2.4 XVector_0.44.0
## [71] pillar_1.9.0 stringr_1.5.1
## [73] limma_3.60.0 splines_4.4.0
## [75] dplyr_1.1.4 BiocFileCache_2.12.0
## [77] lattice_0.22-6 deldir_2.0-4
## [79] rtracklayer_1.64.0 bit_4.0.5
## [81] biovizBase_1.52.0 tidyselect_1.2.1
## [83] SingleCellExperiment_1.26.0 Biostrings_2.72.0
## [85] knitr_1.46 gridExtra_2.3
## [87] ProtGenerics_1.36.0 xfun_0.43
## [89] statmod_1.5.0 pheatmap_1.0.12
## [91] stringi_1.8.3 UCSC.utils_1.0.0
## [93] lazyeval_0.2.2 yaml_2.3.8
## [95] evaluate_0.23 codetools_0.2-20
## [97] interp_1.1-6 tibble_3.2.1
## [99] qvalue_2.36.0 cli_3.6.2
## [101] rpart_4.1.23 munsell_0.5.1
## [103] jquerylib_0.1.4 dichromat_2.0-0.1
## [105] Rcpp_1.0.12 svMisc_1.2.3
## [107] dbplyr_2.5.0 png_0.1-8
## [109] XML_3.99-0.16.1 parallel_4.4.0
## [111] ggplot2_3.5.1 blob_1.2.4
## [113] prettyunits_1.2.0 jpeg_0.1-10
## [115] latticeExtra_0.6-30 bitops_1.0-7
## [117] VariantAnnotation_1.50.0 scales_1.3.0
## [119] crayon_1.5.2 rlang_1.1.3
## [121] KEGGREST_1.44.0
Li, J, and R Tibshirani. 2011. “Finding consistent patterns: A nonparametric approach for identifying differential expression in RNA-Seq data.” Statistical Methods in Medical Research 22 (5): 519–36. https://doi.org/10.1177/0962280211428386.
Wu, Euphy, Noor P. Singh, Kwangbom Choi, Mohsen Zakeri, Matthew Vincent, Gary A. Churchill, Cheryl L. Ackert-Bicknell, Rob Patro, and Michael I. Love. 2022. “Detecting Isoform-Level Allelic Imbalance Accounting for Inferential Uncertainty.” bioRxiv. https://doi.org/10.1101/2022.08.12.503785.
Zhu, A, A Srivastava, JG Ibrahim, R Patro, and MI Love. 2019. “Nonparametric expression analysis using inferential replicate counts.” Nucleic Acids Research 47 (18): e105. https://doi.org/10.1093/nar/gkz622.