Digital RNA allelotyping reveals tissue-specific and allele-specific gene expression in human

Abstract

Padlock probes, synthesized in large scale on programmable microarrays, capture expressed single-nucleotide polymorphisms for high-throughput sequencing in this method for RNA allelotyping. The approach combines the sensitivity of digital expression measurements with the efficiency of targeted resequencing to quantify allele specific gene expression in various tissues across several individuals. We developed a digital RNA allelotyping method for quantitatively interrogating allele-specific gene expression. This method involves ultra-deep sequencing of padlock-captured single-nucleotide polymorphisms (SNPs) from the transcriptome. We characterized four cell lines established from two human subjects in the Personal Genome Project. Approximately 11–22% of the heterozygous mRNA-associated SNPs showed allele-specific expression in each cell line and 4.3–8.5% were tissue-specific, suggesting the presence of tissue-specific cis regulation. When we applied allelotyping to two pairs of sibling human embryonic stem cell lines, the sibling lines were more similar in allele-specific expression than were the genetically unrelated lines. We found that the variation of allelic ratios in gene expression among different cell lines was primarily explained by genetic variations, much more so than by specific tissue types or growth conditions. Comparison of expressed SNPs on the sense and antisense transcripts suggested that allelic ratios are primarily determined by cis-regulatory mechanisms on the sense transcripts.