cgpCaVEManWrapper: Simple Execution of CaVEMan in Order to Detect Somatic Single Nucleotide Variants in NGS Data
David Jones, Keiran M. Raine, Helen Davies, Patrick S. Tarpey, Adam P. Butler, Jon W. Teague, Serena Nik-Zainal, Peter J. Campbell
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Abstract
CaVEMan is an expectation maximization–based somatic substitution-detection algorithm that is written in C. The algorithm analyzes sequence data from a test sample, such as a tumor relative to a reference normal sample from the same patient and the reference genome. It performs a comparative analysis of the tumor and normal sample to derive a probabilistic estimate for putative somatic substitutions. When combined with a set of validated post-hoc filters, CaVEMan generates a set of somatic substitution calls with high recall and positive predictive value. Here we provide instructions for using a wrapper script called cgpCaVEManWrapper, which runs the CaVEMan algorithm and additional downstream post-hoc filters. We describe both a simple one-shot run of cgpCaVEManWrapper and a more in-depth implementation suited to large-scale compute farms. © 2016 by John Wiley & Sons, Inc.
cgpCaVEManWrapper:简单执行CaVEMan以检测NGS数据中的体细胞单核苷酸变异
CaVEMan是一种基于期望最大化的体细胞替代检测算法,用c语言编写。该算法分析来自测试样本的序列数据,例如来自同一患者和参考基因组的相对于参考正常样本的肿瘤。它执行肿瘤和正常样本的比较分析,以得出假定的体细胞替代的概率估计。当与一组经过验证的事后过滤器相结合时,CaVEMan生成了一组具有高召回率和正预测值的体细胞替换呼叫。在这里,我们提供了使用名为cgpCaVEManWrapper的包装器脚本的说明,该脚本运行CaVEMan算法和其他下游事后过滤器。我们描述了cgpCaVEManWrapper的一个简单的一次性运行,以及适合大规模计算场的更深入的实现。©2016 by John Wiley &儿子,Inc。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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