Next-generation whole-exome sequencing contribution to identification of rare autosomal recessive diseases

Rančelis, Tautvydas; Kučinskas, Vaidutis

doi:10.6001/actamedica.v20i1.2626

Cited by 2 publications

(1 citation statement)

References 54 publications

(84 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Only a very small fraction of reports in literature discussed the LifeScope’s pipeline with respect to its alternatives [ 5 , 12 ]. Our study attempts to fill this gap by performing a comparative analysis of popular color-space competent open source tools and the proprietary LifeScope program within a framework of LITGEN project (Genetic diversity of the population of Lithuania and changes of its genetic structure related with evolution and common diseases) [ 14 ]. The major contributions of our study consists of: Comparative analysis of the effects of mapping programs on the outcome of variant calling We analyzed color-space competent mapping programs LifeScope, MAQ, SHRiMP and BFAST using near default settings.…”

Section: Introductionmentioning

confidence: 99%

Challenges in exome analysis by LifeScope and its alternative computational pipelines

et al. 2015

Self Cite

View full text Add to dashboard Cite

BackgroundEvery next generation sequencing (NGS) platform relies on proprietary and open source computational tools to analyze sequencing data. NGS tools for Illumina platforms are well documented which is not the case with AB SOLiD systems. We applied several computational and variant calling pipelines to analyse targeted exome sequencing data obtained using AB SOLiD 5500 system. Our investigated tools comprised proprietary LifeScope’s pipeline in combination with open source color-space competent mapping programs and a variant caller. We present instrumental details of the pipelines that were used and quantitative comparative analysis of variant lists generated by LifeScope’s pipeline versus open source tools.ResultsSufficient coverage of targeted regions was achieved by all investigated pipelines. High variability was observed in identities of variants across the mapping programs. We observed less than 50 % concordance of variant lists produced by approaches based on different mapping algorithms. We summarized different approaches with regards to coverage (DP) and quality (QUAL) properties of the variants provided by GATK and found that LifeScope’s computational pipeline is superior. Fusion of information on mapping profiles (pileup) at genomic positions of variants in several different alignments proved to be a useful strategy to assess questionable singleton variants.ConclusionsWe quantitatively supported a conclusion that Lifescope’s pipeline is superior for processing sequencing data obtained by AB SOLiD 5500 system. Nevertheless the use of alternative pipelines is encouraged because aggregation of information from other mapping and variant calling approaches helps to resolve questionable calls and increases the confidence of the call. It was noted that a coverage threshold for variant to be considered for further analysis has to be chosen in data-driven way to prevent a loss of important information.

show abstract