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一种解决复杂性状基因剖析中多重比较问题的新方法。

A new approach to the problem of multiple comparisons in the genetic dissection of complex traits.

作者信息

Weller J I, Song J Z, Heyen D W, Lewin H A, Ron M

机构信息

Institute of Animal Sciences, Agricultural Research Organization, the Volcani Center, Bet Dagan 50250, Israel.

出版信息

Genetics. 1998 Dec;150(4):1699-706. doi: 10.1093/genetics/150.4.1699.

DOI:10.1093/genetics/150.4.1699
PMID:9832544
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1460417/
Abstract

Saturated genetic marker maps are being used to map individual genes affecting quantitative traits. Controlling the "experimentwise" type-I error severely lowers power to detect segregating loci. For preliminary genome scans, we propose controlling the "false discovery rate," that is, the expected proportion of true null hypotheses within the class of rejected null hypotheses. Examples are given based on a granddaughter design analysis of dairy cattle and simulated backcross populations. By controlling the false discovery rate, power to detect true effects is not dependent on the number of tests performed. If no detectable genes are segregating, controlling the false discovery rate is equivalent to controlling the experimentwise error rate. If quantitative loci are segregating in the population, statistical power is increased as compared to control of the experimentwise type-I error. The difference between the two criteria increases with the increase in the number of false null hypotheses. The false discovery rate can be controlled at the same level whether the complete genome or only part of it has been analyzed. Additional levels of contrasts, such as multiple traits or pedigrees, can be handled without the necessity of a proportional decrease in the critical test probability.

摘要

饱和遗传标记图谱正被用于定位影响数量性状的单个基因。严格控制“实验性”I型错误会严重降低检测分离位点的能力。对于初步的基因组扫描,我们建议控制“错误发现率”,即被拒绝的零假设类别中真零假设的预期比例。基于奶牛的孙女设计分析和模拟回交群体给出了示例。通过控制错误发现率,检测真实效应的能力不依赖于所进行的测试数量。如果没有可检测的基因在分离,控制错误发现率等同于控制实验性错误率。如果数量基因座在群体中分离,与控制实验性I型错误相比,统计能力会提高。这两个标准之间的差异随着假零假设数量的增加而增大。无论分析的是整个基因组还是其仅一部分,错误发现率都可以控制在同一水平。额外的对比水平,如多个性状或谱系,可以在无需按比例降低临界测试概率的情况下进行处理。

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