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## Convert gene symbols to gene ids Use the org.Hs.eg.db package to convert gene symbols to gene ids. ```{r} ## get entrez ids from gene symbols genesym <- c("TRPV1", "TRPV2", "TRPV3") geneid <- select( org.Hs.eg.db, keys=genesym, keytype="SYMBOL", columns="ENTREZID" ) geneid ```[ Back to top ]
## Create gene ranges We use the hg19 known gene track from UCSC to identify the TRPV gene ranges. These ranges will eventually be used to extract variants from a regions in the VCF file. Load the annotation package. ```{r} txdb <- TxDb.Hsapiens.UCSC.hg19.knownGene txdb ``` Our VCF file was aligned to a genome from NCBI and the known gene track was from UCSC. These institutions have different naming conventions for the chromosomes. In order to use these two pieces of data in a matching or overlap operation the chromosome names (also called sesqlevels) need to match. We will modify the txdb to match the VCF file. ```{r} txdb <- keepSeqlevels(txdb, "chr17") ``` Create a list of transcripts by gene: ```{r} txbygene <- transcriptsBy(txdb, "gene") ``` Create the gene ranges for the TRPV genes ```{r} gnrng <- unlist(range(txbygene[geneid$ENTREZID]), use.names=FALSE) names(gnrng) <- geneid$SYMBOL ```[ Back to top ]
## Extract variant subsets A ScanVcfParam object is used to retrieve data subsets. This object can specify genomic coordinates (ranges) or individual VCF elements. Extractions of ranges (vs fields) requires a tabix index. See ?indexTabix for details. ```{r} seqinfo(gnrng) seqlevels(gnrng) <- sub("chr", "", seqlevels(gnrng)) genome(gnrng) <- "B37" seqinfo(gnrng) ## seqlevelsStyle(gnrng) <- "NCBI" param <- ScanVcfParam(which = gnrng, info = "DP", geno = c("GT", "cPd")) param ## Extract the TRPV ranges from the VCF file vcf <- readVcf(file, param = param) ## Inspect the VCF object with the 'fixed', 'info' and 'geno' accessors vcf head(fixed(vcf)) geno(vcf) ``` ```{r} seqinfo(vcf) genome(vcf) <- "hg19" seqlevels(vcf) <- sub("([[:digit:]]+)", "chr\\1", seqlevels(vcf)) seqinfo(vcf) ## seqlevelsStyle(vcf) <- "UCSC" vcf <- keepSeqlevels(vcf, "chr17") ```[ Back to top ]
## Variant location in the gene model The locateVariants function identifies where a variant falls with respect to gene structure, e.g., exon, utr, splice site, etc. We use the gene model from the TxDb.Hsapiens.UCSC.hg19.knownGene package loaded eariler. ```{r, eval=FALSE} ## Use the 'region' argument to define the region ## of interest. See ?locateVariants for details. cds <- locateVariants(vcf, txdb, CodingVariants()) five <- locateVariants(vcf, txdb, FiveUTRVariants()) splice <- locateVariants(vcf, txdb, SpliceSiteVariants()) intron <- locateVariants(vcf, txdb, IntronVariants()) ``` ```{r} all <- locateVariants(vcf, txdb, AllVariants()) ``` Each row in cds represents a variant-transcript match so multiple rows per variant are possible. If we are interested in gene-centric questions the data can be summarized by gene regardless of transcript. ```{r} ## Did any variants match more than one gene? geneByQuery <- sapply(split(all$GENEID, all$QUERYID), unique) table(lengths(geneByQuery) > 1) ## Summarize the number of variants by gene: queryByGene <- sapply(split(all$QUERYID, all$GENEID), unique) table(lengths(queryByGene) > 1) sapply(queryByGene, length) ## Summarize variant location by gene: sapply(names(queryByGene), function(nm) { d <- all[all$GENEID %in% nm, c("QUERYID", "LOCATION")] table(d$LOCATION[duplicated(d) == FALSE]) }) ```[ Back to top ]
## Amino acid coding changes in non-synonymous variants Amino acid coding for non-synonymous variants can be computed with the function predictCoding. The BSgenome.Hsapiens.UCSC.hg19 package is used as the source of the reference alleles. Variant alleles are provided by the user. ```{r} aa <- predictCoding(vcf, txdb, Hsapiens) ``` predictCoding returns results for coding variants only. As with locateVariants, the output has one row per variant-transcript match so multiple rows per variant are possible. ```{r} ## Did any variants match more than one gene? aageneByQuery <- split(aa$GENEID, aa$QUERYID) table(lengths(sapply(aageneByQuery, unique)) > 1) ## Summarize the number of variants by gene: aaaqueryByGene <- split(aa$QUERYID, aa$GENEID, drop=TRUE) sapply(aaaqueryByGene, length) ## Summarize variant consequence by gene: sapply(names(aaaqueryByGene), function(nm) { d <- aa[aa$GENEID %in% nm, c("QUERYID","CONSEQUENCE")] table(d$CONSEQUENCE[duplicated(d) == FALSE]) }) ``` The variants 'not translated' are explained by the warnings thrown when predictCoding was called. Variants that have a missing varAllele or have an 'N' in the varAllele are not translated. If the varAllele substitution had resulted in a frameshift the consequence would be 'frameshift'. See ?predictCoding for details.[ Back to top ]
# Exploring Package Content Packages have extensive help pages, and include vignettes highlighting common use cases. The help pages and vignettes are available from within R. After loading a package, use syntax like help(package="VariantAnnotation") ?predictCoding to obtain an overview of help on the `VariantAnnotation` package, and the `predictCoding` function. View the package vignette with ```{r eval=FALSE} browseVignettes(package="VariantAnnotation") ``` To view vignettes providing a more comprehensive introduction to package functionality use ```{r eval=FALSE} help.start() ```[ Back to top ]
# sessionInfo() ```{r} sessionInfo() ```[ Back to top ]