Competitive screening experiments, in which bulk cell cultures infected with a heterogeneous viral library are experimentally manipulated to identify guide RNAs or shRNAs that influence cell viability, are conceptually straightforward but often challenging to implement. Here, we present gCrisprTools, an R/Bioconductor analysis suite facilitating quality assessment, target prioritization, and interpretation of arbitrarily complex competitive screening experiments. gCrisprTools provides functionalities for detailed and principled ana lysis of diverse aspects of these experiments both as a standalone pipeline or as an extension to alternative analytical approaches.
Install gCrisprTools in the usual way:
if (!requireNamespace("BiocManager", quietly=TRUE)) install.packages("BiocManager") BiocManager::install("gCrisprTools")
This vignette is only one of the resources provided in gCrisprTools
to help you understand, analyse, and explore pooled screening data. As appropriate, please see the /vignettes
subdirectory for additional documentation describing example code, and the /inst
directory for more information about algorithm implementation and package layout.
gCrisprTools
uses the existing Biobase
framework for data storage and manipulation and consequently depends heavily on the Biobase
and limma
packages.
library(Biobase) library(limma) library(gCrisprTools)
To use the various methods available in this package, you will first need to conform your screen data into an ExpressionSet
object containing cassette abundance counts in the assayData slot, retrievable with exprs()
. This package assumes that end users are familiar enough with the R/Bioconductor framework and their own sequencing pipelines to extract raw cassette counts from FASTQ files and to compose them into an ExpressionSet
. For newer users read counting may be facilitated with cutadapt or other software designed for these purposes; details about composition of ExpressionSet
objects can be found in the Biobase vignette.
Raw cassette counts should be contained within an ExpressionSet
object, with the counts retrievable withexprs()
. The column names (colnames()
) should correspond to unique sample identifiers, and the row names (row.names()
) should correspond to identifiers uniquely specifying each cassette of interest.
data("es", package = "gCrisprTools") es head(exprs(es))
gCrisprTools requires an annotation object mapping the individual cassettes to genes or other genomic features for most applications. The annotation object should be provided as a named data.frame
, with columns describing the 'geneID
' and 'geneSymbol
' of the target elements to which each cassette is annotated. These columns should contain character vectors with elements that uniquely describe the targets in the screen; by convention, the geneID
field contains an official identifier that unambiguously describes each target element in a manner suitable for external software (e.g., an Entrez ID). The geneSymbol
column indicates a more human-readable descriptor, such as a gene symbol.
The annotation object may optionally contain other columns with additional information about the corresponding cassettes.
data("ann", package = "gCrisprTools") head(ann)
Many gCrisprTools
functions require or are enhanced by a sample key detailing the experimental groups of the functions included in the study. This key should be provided as a named factor, with names
perfectly matching the colnames
of the ExpressionSet. The first level of the sample key should correspond to the 'control' condition, indexing samples whose cassette distributions are expected to be the minimally distorted by experimental treatments.
sk <- relevel(as.factor(pData(es)$TREATMENT_NAME), "ControlReference") names(sk) <- row.names(pData(es)) sk
Users may provide a matrix of alignment statistics to enhance some applications, including QC reporting. These should be provided as a numeric matrix in which rows correspond to targets
(reads containing a target cassette), nomatch
(reads containing a cassette sequence but not a known target sequence), rejections
(reads not containg a cassette sequence), and double_match
(reads derived from multiple cassettes). The column names should exactly match the colnames()
of the ExpressionSet object. Simple charting functionality is also provided to inspect the alignment rates of each sample.
data("aln", package = "gCrisprTools") head(aln) ct.alignmentChart(aln, sk)
gCrisprTools
provides tools for common data preprocessing steps, including eliminating underinfected or contaminant cassettes and sample-level normalization.
Low abundance cassettes can be removed by specifying a minimum number of counts or a level relative to the trimmed distribution maximum.
es.floor <- ct.filterReads(es, read.floor = 30, sampleKey = sk) es <- ct.filterReads(es, trim = 1000, log2.ratio = 4, sampleKey = sk) ##Convenience function for conforming the annotation object to exclude the trimmed gRNAs ann <- ct.prepareAnnotation(ann, es, controls = "NoTarget")
A suite of normalization tools are provided with the ct.normalizeGuides()
wrapper function; see the relevant manual pages for further details about these methods.
es <- ct.normalizeGuides(es, 'scale', annotation = ann, sampleKey = sk, plot.it = TRUE) timepoints <- gsub('^(Control|Death)', '', pData(es)$TREATMENT_NAME) names(timepoints) <- colnames(es) es.norm <- ct.normalizeGuides(es, 'FQ', annotation = ann, sampleKey = timepoints, plot.it = TRUE) es.norm <- ct.normalizeGuides(es, 'slope', annotation = ann, sampleKey = sk, plot.it = TRUE) es.norm <- ct.normalizeGuides(es, 'controlScale', annotation = ann, sampleKey = sk, plot.it = TRUE, geneSymb = 'NoTarget') es.norm <- ct.normalizeGuides(es, 'controlSpline', annotation = ann, sampleKey = sk, plot.it = TRUE, geneSymb = 'NoTarget')
For convenience, experiment-level dynamics and the effects of various preprocessing steps may be automatically summarized in the form of a report. The following code isn't run as part of this vignette, but if run from the terminal path2QC
will indicate the path to an html Quality Control report.
#Not run: path2QC <- ct.makeQCReport(es, trim = 1000, log2.ratio = 0.05, sampleKey = sk, annotation = ann, aln = aln, identifier = 'Crispr_QC_report', lib.size = NULL )
The gCrisprTools
package provides a series of functions for assessing distributional and technical properties of sequencing libraries. Please see additional details about all of these methods on their respective manual pages.
The raw cassette count distributions can be visualized to determine whether samples were inadequately sequenced or if PCR amplification artifacts might be present.
ct.rawCountDensities(es, sk)
Aspects of cassette distributions are often better visualized with a 'waterfall' plot than a standard density estimate, which can clarify the ranking relationships in specific parts of the distribution.
ct.gRNARankByReplicate(es, sk) #Visualization of gRNA abundance distribution
These plots also enable explicit visualization of cassettes of interest in the context of the experimental distribution.
ct.gRNARankByReplicate(es, sk, annotation = ann, geneSymb = "Target1633")
gCrisprTools
provides tools for visualizing the behavior of control gRNAs across experimental conditions.
ct.viewControls(es, ann, sk, normalize = FALSE, geneSymb = 'NoTarget')
Depending on the screen in question, it can be useful to quantify the extent to which experimental libraries have been distorted by experimental treatments. gCrisprTools
provides tools to estimate an empirical cumulative distribution function describing the cassettes or (targets) within a screen.
ct.guideCDF(es, sk, plotType = "gRNA")
The core analytical machinery of gCrisprTools is built on the linear modelling framework implemented in the limma
package. Specifically, users employ limma/voom
to generate an experimental contrast of interest at the gRNA level. The model coefficent and P-value estimates may be subsequently processed with the infrastructure provided by gCrisprTools
.
design <- model.matrix(~ 0 + REPLICATE_POOL + TREATMENT_NAME, pData(es)) colnames(design) <- gsub('TREATMENT_NAME', '', colnames(design)) contrasts <-makeContrasts(DeathExpansion - ControlExpansion, levels = design) vm <- voom(exprs(es), design) fit <- lmFit(vm, design) fit <- contrasts.fit(fit, contrasts) fit <- eBayes(fit)
After generating a fit object (class MArrayLM
) for a contrast of interest, we may summarize the signals from the various cassettes annotated to each target via RRA$\alpha$ aggregation. The core algorithm is described in detail in the original publication on Robust Rank Aggregation[^1] and has been implemented according to the $\alpha$ thresholding modification proposed by Li et al.[^2] Briefly, gRNA signals contained in the specified fit object are ranked and normalized, and these ranks are grouped by the associated target and assigned a score ($\rho$) on the basis of the skewness of the gRNA signal ranks. The statistical significance of each target-level score is then assessed by permutation of the gRNA target assignments. Q-values are computed directly from the resulting P-value distributions using the FDR approach described by Benjamini and Hochberg.[^3]
A more extensive treatment of RRA$\alpha$ and comparisons to MAGeCK may be found in inst/Mageck_&_gCrisprTools.html
.
resultsDF <- ct.generateResults( fit, annotation = ann, RRAalphaCutoff = 0.1, permutations = 1000, scoring = "combined" )
The resulting dataframe contains columns passing some of the information from the fit and annotation objects, as well as a number of statistics describing the evidence for a target's depletion or enrichment within the context of the screen. These include the Target-level P and Q values quantifying the evidence for enrichment or depletion, the median log2 fold change of all of the gRNAs associated with each target, and the rankings of the target-level $/rho$ statistics (gene-level scores may be useful for ranking targets with equivalent P-values).
After identifying candidate targets, various aspects of the contrast may be visualized with gCrisprTools
.
The ct.topTargets
function enables simple visualization of the model effect estimates (log2 fold changes) and associated uncertainties of all cassettes associated with the top-ranking targets.
ct.topTargets(fit, resultsDF, ann, targets = 10, enrich = TRUE)
In some screens it can be useful to visualize the degree of library distortion associated with the strongest signals. Such an approach can supply additional confidence in a particular candidate of interest by showing that clear differences are evident outside of the linear modeling framework (which may be inaccurate in heavily distorted libraries).
ct.stackGuides( es, sk, plotType = "Target", annotation = ann, subset = names(sk)[grep('Expansion', sk)] )
gCrisprTools
provides methods to visualize the behavior of individual cassettes annotated to target of interest, and positions these within the observed distribution of effect sizes across all cassettes within the experiment.
ct.viewGuides("Target1633", fit, ann)
Sometimes it can be useful to visualize known sets of targets together in the context of the full screen contrast:
ct.signalSummary(resultsDF, targets = list('TargetSetA' = c(sample(unique(resultsDF$geneSymbol), 3)), 'TargetSetB' = c(sample(unique(resultsDF$geneSymbol), 2))))
As with the Quality Control components of an individual screen, gCrisprTools
provides functionality to automatically generate contrast-level reports.
#Not run: path2Contrast <- ct.makeContrastReport(eset = es, fit = fit, sampleKey = sk, results = resultsDF, annotation = ann, comparison.id = NULL, identifier = 'Crispr_Contrast_Report')
If you wish, you can also make a single report encompassing both quality control and the contrast of interest.
#Not run: path2report <- ct.makeReport(fit = fit, eset = es, sampleKey = sk, annotation = ann, results = resultsDF, aln = aln, outdir = ".")
In addition to identifying targets of interest within a screen, it may be worthwhile to ask more comprehensive questions about the targets identified. gCrisprTools
provides a series of basic functions for determining the enrichment of known or unknown target groups within the context of a screen.
If a screen was performed with a library targeting genes, gCrisprTools
can provide basic ontological enrichment testing by leveraging the various functions available in the sparrow
package.
#Not run: genesetdb <- sparrow::getMSigGeneSetDb(collection = 'h', species = 'human', id.type = 'entrez') # If you have a library that targets elements unevenly (e.g., variable numbers of # elements/promoters per genes), you can conform it via GREAT genesetdb.GREAT <- ct.GREATdb(ann, gsdb = genesetdb) ct.seas(resultsDF, gdb = genesetdb) #ct.seas(resultsDF, gdb = genesetdb.GREAT)
The sparrow
package is quite rich, and the the possible applications and extensions of geneset testing in crispr screens are detailed in the Crispr_example_workflow
and Contrast_Comparisons
vignettes, and in the vignettes of the sparrow
package.
In some cases, it may be useful to ask whether a set of known targets is disproportionately enriched or depleted within a screen. gCrisprTools
provides functions for answering these sorts of questions with ct.ROC()
, which generates Reciever-Operator Characteristics for a specified gene set within a screen, and ct.PRC()
, which draws precision-recall curves. When called, both functions return the raw data necessary to reproduce or combine these results, along with appropriate statistics for assessing the significance of the overall signal within the specified target set (via a hypergeometric test).
data("essential.genes", package = "gCrisprTools") #Artificial list created for demonstration data("resultsDF", package = "gCrisprTools") ROC <- ct.ROC(resultsDF, essential.genes, 'enrich') str(ROC)
PRC <- ct.PRC(resultsDF, essential.genes, 'enrich') str(PRC)
Alternatively, the significance of the enrichment within the target set may be assessed directly with ct.targetSetEnrichment
.
##' tar <- sample(unique(resultsDF$geneSymbol), 20) ##' res <- ct.targetSetEnrichment(resultsDF, tar) targetsTest <- ct.targetSetEnrichment(resultsDF, essential.genes, enrich = FALSE) str(targetsTest)
[^1]: Kolde R, Laur S, Adler P, Vilo J. Robust rank aggregation for gene list integration and meta-analysis. Bioinformatics. 2012;28(4):573-80. PMID:22247279
[^2]: Li W, Xu H, Xiao T, Cong L, Love MI, Zhang F, Irizarry RA, Liu JS, Brown M, Liu XS. MAGeCK enables robust identification of essential genes from genome-scale CRISPR/Cas9 knockout screens. Genome Biol. 2014;15(12):554. PMID:25476604
[^3]:Benjamini Y, Hochberg Y. Controlling the false discovery rate: a practical and powerful approach to multiple testing. Journal of the Royal Statistical Society, Series B. 1995;57(1):289–300. MR 1325392.
sessionInfo()
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