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This vignette provides a description of how to use the r Biocpkg("GENESIS")
package to analyze sequence data. We demonstrate the use of mixed models for genetic association testing, as PC-AiR PCs can be used as fixed effect covariates to adjust for population stratification, and a kinship matrix (or genetic relationship matrix) estimated from PC-Relate can be used to account for phenotype correlation due to genetic similarity among samples. To illustrate the methods, we use a small subset of data from 1000 Genomes Phase 3.
The first step is to convert a VCF file into the GDS file format used by r Biocpkg("GENESIS")
. We use the r Biocpkg("SeqArray")
package, which defines the extended GDS format used to capture all data in a VCF file. If the VCF files are split by chromosome, they can be combined into a single GDS file.
library(SeqArray) vcffile <- system.file("extdata", "1KG", paste0("1KG_phase3_subset_chr", 1:22, ".vcf.gz"), package="GENESIS") gdsfile <- tempfile() seqVCF2GDS(vcffile, gdsfile, verbose=FALSE) gds <- seqOpen(gdsfile) gds
Next, we combine the GDS file with information about the samples, which we store in an AnnotatedDataFrame
(defined in the r Biocpkg("Biobase")
package). An AnnotatedDataFrame
combines a data.frame
with metadata describing each column. A SeqVarData
object (defined in the r Biocpkg("SeqVarTools")
package), contains both an open GDS file and an AnnotatedDataFrame
describing the samples. The sample.id
column in the AnnotatedDataFrame
must match the sample.id
node in the GDS file.
library(GENESIS) library(Biobase) library(SeqVarTools) data(sample_annotation_1KG) annot <- sample_annotation_1KG head(annot) # simulate some phenotype data set.seed(4) annot$outcome <- rnorm(nrow(annot)) metadata <- data.frame(labelDescription=c("sample id", "1000 genomes population", "sex", "simulated phenotype"), row.names=names(annot)) annot <- AnnotatedDataFrame(annot, metadata) all.equal(annot$sample.id, seqGetData(gds, "sample.id")) seqData <- SeqVarData(gds, sampleData=annot)
PC-AiR and PC-Relate are described in detail in a separate vignette. Here, we demonstrate their use to provide adjustment for population structure and relatedness in a mixed model.
Step 1 is to get initial estimates of kinship using KING, which is robust to population structure but not admixture. The KING algorithm is available in SNPRelate. We select a subset of variants for this calculation with LD pruning.
# set seed for LD pruning set.seed(100)
library(SNPRelate) # LD pruning to get variant set snpset <- snpgdsLDpruning(gds, method="corr", slide.max.bp=10e6, ld.threshold=sqrt(0.1), verbose=FALSE) pruned <- unlist(snpset, use.names=FALSE) king <- snpgdsIBDKING(gds, snp.id=pruned, verbose=FALSE) kingMat <- king$kinship dimnames(kingMat) <- list(king$sample.id, king$sample.id)
The next step is PC-AiR, in which we select a set of unrelated samples that is maximally informative about all ancestries in the sample, use this unrelated set for Principal Component Analysis (PCA), then project the relatives onto the PCs. We use a kinship threshold of degree 3 (unrelated is less than first cousins). In this example, we use the KING estimates for both kinship (kinobj
) and ancestry divergence (divobj
). KING kinship estimates are negative for samples with different ancestry.
pcs <- pcair(seqData, kinobj=kingMat, kin.thresh=2^(-9/2), divobj=kingMat, div.thresh=-2^(-9/2), snp.include=pruned)
We need to determine which PCs are ancestry informative. To do this we need population information for the 1000 Genomes samples. We make a parallel coordinates plot, color-coding by 1000 Genomes population.
library(dplyr) library(RColorBrewer) library(ggplot2) library(GGally) pc.df <- as.data.frame(pcs$vectors) names(pc.df) <- paste0("PC", 1:ncol(pcs$vectors)) pc.df$sample.id <- row.names(pcs$vectors) pc.df <- left_join(pc.df, pData(annot), by="sample.id") pop.cols <- setNames(brewer.pal(12, "Paired"), c("ACB", "ASW", "CEU", "GBR", "CHB", "JPT", "CLM", "MXL", "LWK", "YRI", "GIH", "PUR")) ggplot(pc.df, aes(PC1, PC2, color=Population)) + geom_point() + scale_color_manual(values=pop.cols)
ggparcoord(pc.df, columns=1:10, groupColumn="Population", scale="uniminmax") + scale_color_manual(values=pop.cols) + xlab("PC") + ylab("")
The first 2 PCs separate populations, so we use them to compute kinship estimates adjusting for ancestry. The pcrelate
method requires creating a SeqVarBlockIterator
object, which should iterate over the pruned SNPs only.
seqSetFilter(seqData, variant.id=pruned) iterator <- SeqVarBlockIterator(seqData, variantBlock=20000, verbose=FALSE) pcrel <- pcrelate(iterator, pcs=pcs$vectors[,1:2], training.set=pcs$unrels) seqResetFilter(seqData, verbose=FALSE)
kinship <- pcrel$kinBtwn ggplot(kinship, aes(k0, kin)) + geom_hline(yintercept=2^(-seq(3,9,2)/2), linetype="dashed", color="grey") + geom_point(alpha=0.5) + ylab("kinship estimate") + theme_bw()
To improve our estimates for PCs and kinship, we could run another iteration of PC-AiR and PC-Relate, this time using the PC-Relate kinship estimates as the kinobj
argument to pcair
. The KING matrix is still used for ancestry divergence. We could then use those new PCs to calculate revised kinship estimates.
The first step for association testing is to fit the model under the null hypothesis that each SNP has no effect. This null model contains all of the covariates, including ancestry representative PCs, as well as any random effects, such as a polygenic effect due to genetic relatedness, but it does not include any SNP genotype terms as fixed effects.
The type of model fit depends on the arguments to fitNullModel
. Including a cov.mat
argument will result in a mixed model, while omitting this argument will run a standard linear model. A logistic model is specified with family="binomial"
. In the case of a logistic model and a covariance matrix, fitNullModel
will use the GMMAT algorithm. Including a group.var
argument will allow heteroscedastic variance (for linear models or linear mixed models only).
# add PCs to sample annotation in SeqVarData object annot <- AnnotatedDataFrame(pc.df) sampleData(seqData) <- annot # covariance matrix from pcrelate output grm <- pcrelateToMatrix(pcrel, scaleKin=2) # fit the null model nullmod <- fitNullModel(seqData, outcome="outcome", covars=c("sex", "Population", paste0("PC", 1:2)), cov.mat=grm, verbose=FALSE)
To run a test using the null model, we first create an iterator object specifying how we want variants to be selected. (See the documentation for the SeqVarIterator
class in r Biocpkg("SeqVarTools")
for more details.) For single-variant tests (GWAS), it is common to use a block iterator that reads variants in blocks (default is 10,000 variants per block).
For example purposes, we restrict our analysis to chromosome 1. The seqSetFilter
function can be used to restrict the set of variants tested in other ways (e.g., variants that pass a quality filter).
# select chromosome 1 seqSetFilterChrom(seqData, include=1) iterator <- SeqVarBlockIterator(seqData, verbose=FALSE) assoc <- assocTestSingle(iterator, nullmod, verbose=FALSE) head(assoc)
The default test is a Score test, but the Wald test is also available for continuous outcomes.
If there are multiallelic variants, each alternate allele is tested separately. The allele.index
column in the output differentiates between different alternate alleles for the same variant.
We make a QQ plot to examine the results.
qqPlot <- function(pval) { pval <- pval[!is.na(pval)] n <- length(pval) x <- 1:n dat <- data.frame(obs=sort(pval), exp=x/n, upper=qbeta(0.025, x, rev(x)), lower=qbeta(0.975, x, rev(x))) ggplot(dat, aes(-log10(exp), -log10(obs))) + geom_line(aes(-log10(exp), -log10(upper)), color="gray") + geom_line(aes(-log10(exp), -log10(lower)), color="gray") + geom_point() + geom_abline(intercept=0, slope=1, color="red") + xlab(expression(paste(-log[10], "(expected P)"))) + ylab(expression(paste(-log[10], "(observed P)"))) + theme_bw() } qqPlot(assoc$Score.pval)
We can aggregate rare variants for association testing to decrease multiple testing burden and increase statistical power. We can create functionally agnostic units using a SeqVarWindowIterator
. This iterator type generates a sliding window over the genome, with user-specified width and step size. We can also create units with specific start and end points or containing specific variants, using a SeqVarRangeIterator
or a SeqVarListIterator
.
In this example, we illustrate defining ranges based on known genes. We run a burden test, setting a maximum alternate allele frequency to exclude common variants.
library(GenomicRanges) library(TxDb.Hsapiens.UCSC.hg19.knownGene) # return the variants on chromosome 1 as a GRanges object seqSetFilterChrom(seqData, include=1) gr <- granges(gds) # find variants that overlap with each gene txdb <- TxDb.Hsapiens.UCSC.hg19.knownGene gr <- renameSeqlevels(gr, paste0("chr", seqlevels(gr))) ts <- transcriptsByOverlaps(txdb, gr, columns="GENEID") # simplistic example - define genes as overlapping transcripts genes <- reduce(ts) genes <- renameSeqlevels(genes, sub("chr", "", seqlevels(genes))) # create an iterator where each successive unit is a different gene iterator <- SeqVarRangeIterator(seqData, variantRanges=genes, verbose=FALSE) # do a burden test on the rare variants in each gene assoc <- assocTestAggregate(iterator, nullmod, AF.max=0.05, test="Burden", verbose=FALSE)
The output of an aggregate test is a list with two elements: 1) a data.frame with the test results for each aggregate unit, and 2) a list of data.frames containing the variants in each aggregate unit.
head(assoc$results) head(assoc$variantInfo)
seqClose(gds) unlink(gdsfile)
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