Matching Items (2)
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Description

Whole genome sequencing (WGS) is a promising strategy to unravel variants or genes responsible for human diseases and traits. However, there is a lack of robust platforms for a comprehensive downstream analysis. In the present study, we first proposed three novel algorithms, sequence gap-filled gene feature annotation, bit-block encoded genotypes

Whole genome sequencing (WGS) is a promising strategy to unravel variants or genes responsible for human diseases and traits. However, there is a lack of robust platforms for a comprehensive downstream analysis. In the present study, we first proposed three novel algorithms, sequence gap-filled gene feature annotation, bit-block encoded genotypes and sectional fast access to text lines to address three fundamental problems. The three algorithms then formed the infrastructure of a robust parallel computing framework, KGGSeq, for integrating downstream analysis functions for whole genome sequencing data. KGGSeq has been equipped with a comprehensive set of analysis functions for quality control, filtration, annotation, pathogenic prediction and statistical tests. In the tests with whole genome sequencing data from 1000 Genomes Project, KGGSeq annotated several thousand more reliable non-synonymous variants than other widely used tools (e.g. ANNOVAR and SNPEff). It took only around half an hour on a small server with 10 CPUs to access genotypes of ∼60 million variants of 2504 subjects, while a popular alternative tool required around one day. KGGSeq's bit-block genotype format used 1.5% or less space to flexibly represent phased or unphased genotypes with multiple alleles and achieved a speed of over 1000 times faster to calculate genotypic correlation.

ContributorsLi, Miaoxin (Author) / Li, Jiang (Author) / Li, Mulin Jun (Author) / Pan, Zhicheng (Author) / Hsu, Jacob Shujui (Author) / Liu, Dajiang J. (Author) / Zhan, Xiaowei (Author) / Wang, Junwen (Author) / Song, Youqiang (Author) / Sham, Pak Chung (Author) / College of Health Solutions (Contributor)
Created2017-01-23
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Description

It remains challenging to predict regulatory variants in particular tissues or cell types due to highly context-specific gene regulation. By connecting large-scale epigenomic profiles to expression quantitative trait loci (eQTLs) in a wide range of human tissues/cell types, we identify critical chromatin features that predict variant regulatory potential. We present

It remains challenging to predict regulatory variants in particular tissues or cell types due to highly context-specific gene regulation. By connecting large-scale epigenomic profiles to expression quantitative trait loci (eQTLs) in a wide range of human tissues/cell types, we identify critical chromatin features that predict variant regulatory potential. We present cepip, a joint likelihood framework, for estimating a variant’s regulatory probability in a context-dependent manner. Our method exhibits significant GWAS signal enrichment and is superior to existing cell type-specific methods. Furthermore, using phenotypically relevant epigenomes to weight the GWAS single-nucleotide polymorphisms, we improve the statistical power of the gene-based association test.

ContributorsLi, Mulin Jun (Author) / Li, Miaoxin (Author) / Liu, Zipeng (Author) / Yan, Bin (Author) / Pan, Zhicheng (Author) / Huang, Dandan (Author) / Liang, Qian (Author) / Ying, Dingge (Author) / Xu, Feng (Author) / Yao, Hongcheng (Author) / Wang, Panwen (Author) / Kocher, Jean-Pierre A. (Author) / Xia, Zhengyuan (Author) / Sham, Pak Chung (Author) / Liu, Jun S. (Author) / Wang, Junwen (Author) / College of Health Solutions (Contributor)
Created2017-03-16