SNP detection for massively parallel whole-genome resequencing

  1. Ruiqiang Li1,2,3,
  2. Yingrui Li1,3,
  3. Xiaodong Fang1,
  4. Huanming Yang1,
  5. Jian Wang1,
  6. Karsten Kristiansen1,2 and
  7. Jun Wang1,2,4
  1. 1 Beijing Genomics Institute at Shenzhen, Shenzhen 518000, China;
  2. 2 Department of Biochemistry and Molecular Biology, University of Southern Denmark, Odense M DK-5230, Denmark
    1. 3 These authors contributed equally to this work.

    Abstract

    Next-generation massively parallel sequencing technologies provide ultrahigh throughput at two orders of magnitude lower unit cost than capillary Sanger sequencing technology. One of the key applications of next-generation sequencing is studying genetic variation between individuals using whole-genome or target region resequencing. Here, we have developed a consensus-calling and SNP-detection method for sequencing-by-synthesis Illumina Genome Analyzer technology. We designed this method by carefully considering the data quality, alignment, and experimental errors common to this technology. All of this information was integrated into a single quality score for each base under Bayesian theory to measure the accuracy of consensus calling. We tested this methodology using a large-scale human resequencing data set of 36× coverage and assembled a high-quality nonrepetitive consensus sequence for 92.25% of the diploid autosomes and 88.07% of the haploid X chromosome. Comparison of the consensus sequence with Illumina human 1M BeadChip genotyped alleles from the same DNA sample showed that 98.6% of the 37,933 genotyped alleles on the X chromosome and 98% of 999,981 genotyped alleles on autosomes were covered at 99.97% and 99.84% consistency, respectively. At a low sequencing depth, we used prior probability of dbSNP alleles and were able to improve coverage of the dbSNP sites significantly as compared to that obtained using a nonimputation model. Our analyses demonstrate that our method has a very low false call rate at any sequencing depth and excellent genome coverage at a high sequencing depth.

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