Abstract
BackgroundLess than two percent of the human genome is protein coding, yet that small fraction harbours the majority of known disease causing mutations. Despite rapidly falling whole genome sequencing (WGS) costs, much research and increasingly the clinical use of sequence data is likely to remain focused on the protein coding exome. We set out to quantify and understand how WGS compares with the targeted capture and sequencing of the exome (exome-seq), for the specific purpose of identifying single nucleotide polymorphisms (SNPs) in exome targeted regions.ResultsWe have compared polymorphism detection sensitivity and systematic biases using a set of tissue samples that have been subject to both deep exome and whole genome sequencing. The scoring of detection sensitivity was based on sequence down sampling and reference to a set of gold-standard SNP calls for each sample. Despite evidence of incremental improvements in exome capture technology over time, whole genome sequencing has greater uniformity of sequence read coverage and reduced biases in the detection of non-reference alleles than exome-seq. Exome-seq achieves 95% SNP detection sensitivity at a mean on-target depth of 40 reads, whereas WGS only requires a mean of 14 reads. Known disease causing mutations are not biased towards easy or hard to sequence areas of the genome for either exome-seq or WGS.ConclusionsFrom an economic perspective, WGS is at parity with exome-seq for variant detection in the targeted coding regions. WGS offers benefits in uniformity of read coverage and more balanced allele ratio calls, both of which can in most cases be offset by deeper exome-seq, with the caveat that some exome-seq targets will never achieve sufficient mapped read depth for variant detection due to technical difficulties or probe failures. As WGS is intrinsically richer data that can provide insight into polymorphisms outside coding regions and reveal genomic rearrangements, it is likely to progressively replace exome-seq for many applications.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2105-15-247) contains supplementary material, which is available to authorized users.
Highlights
Less than two percent of the human genome is protein coding, yet that small fraction harbours the majority of known disease causing mutations
A further six human whole genome samples (1KG-whole genome sequencing (WGS)) were obtained from the 1000 Genomes Project [14], all aligned to the reference genome
We focused on heterozygous single nucleotide polymorphisms (SNPs) as the more challenging problem: only 2-3X per-site depth was required to accurately detect at least 95% of homozygous SNPs in all four data sets
Summary
Less than two percent of the human genome is protein coding, yet that small fraction harbours the majority of known disease causing mutations. The cost of sequencing DNA has decreased steeply since the introduction of next-generation short read technologies [1] It is at the point where cohorts of whole human genomes are sequenced for study. Experimental approaches to determine the function of candidate disease variants at protein coding or transcript splice sites are well developed and accepted by the research community For these reasons, exome centric analysis will remain common in research and is increasingly used in clinical genetic settings [3]. The targeted capture followed by sequencing of specific regions, such as the 30 Mb human exome (exome-seq), has proven to be a cost-effective and productive strategy for the identification of single nucleotide polymorphisms (SNPs) and small insertions and deletions in this rich vein of the genome. In this work we set out to compare exome-seq with whole genome sequencing (WGS) in terms of their sensitivity to correctly detect known variants over the whole exome
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