通过使用降秩同源矩阵提高方差分量数量性状位点分析的效率。

Increasing the efficiency of variance component quantitative trait loci analysis by using reduced-rank identity-by-descent matrices.

作者信息

Rönnegård Lars, Mischenko Kateryna, Holmgren Sverker, Carlborg Orjan

机构信息

Linnaeus Centre for Bioinformatics, Uppsala University, Uppsala, Sweden.

出版信息

Genetics. 2007 Jul;176(3):1935-8. doi: 10.1534/genetics.107.071977. Epub 2007 May 4.

DOI:10.1534/genetics.107.071977

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1931556/

Abstract

Recent technological development in genetics has made large-scale marker genotyping fast and practicable, facilitating studies for detection of QTL in large general pedigrees. We developed a method that speeds up restricted maximum-likelihood (REML) algorithms for QTL analysis by simplifying the inversion of the variance-covariance matrix of the trait vector. The method was tested in an experimental chicken pedigree including 767 phenotyped individuals and 14 genotyped markers on chicken chromosome 1. The computation time in a chromosome scan covering 475 cM was reduced by 43% when the analysis was based on linkage only and by 72% when linkage disequilibrium information was included. The relative advantage of using our method increases with pedigree size, marker density, and linkage disequilibrium, indicating even greater improvements in the future.

摘要

遗传学领域最近的技术发展使得大规模标记基因分型变得快速且可行，这推动了在大型普通系谱中检测数量性状基因座（QTL）的研究。我们开发了一种方法，通过简化性状向量方差协方差矩阵的求逆运算，加速用于QTL分析的限制最大似然（REML）算法。该方法在一个实验性鸡系谱中进行了测试，该系谱包括767个有表型的个体以及鸡1号染色体上的14个基因分型标记。当仅基于连锁进行分析时，在覆盖475厘摩（cM）的染色体扫描中，计算时间减少了43%；当纳入连锁不平衡信息时，计算时间减少了72%。使用我们方法的相对优势会随着系谱大小、标记密度和连锁不平衡而增加，这表明未来会有更大的改进。

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