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玉米巢式关联作图的遗传设计与统计功效

Genetic design and statistical power of nested association mapping in maize.

作者信息

Yu Jianming, Holland James B, McMullen Michael D, Buckler Edward S

机构信息

Institute for Genomic Diversity, Cornell University, Ithaca, New York 14853-2703, USA.

出版信息

Genetics. 2008 Jan;178(1):539-51. doi: 10.1534/genetics.107.074245.

DOI:10.1534/genetics.107.074245
PMID:18202393
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2206100/
Abstract

We investigated the genetic and statistical properties of the nested association mapping (NAM) design currently being implemented in maize (26 diverse founders and 5000 distinct immortal genotypes) to dissect the genetic basis of complex quantitative traits. The NAM design simultaneously exploits the advantages of both linkage analysis and association mapping. We demonstrated the power of NAM for high-power cost-effective genome scans through computer simulations based on empirical marker data and simulated traits with different complexities. With common-parent-specific (CPS) markers genotyped for the founders and the progenies, the inheritance of chromosome segments nested within two adjacent CPS markers was inferred through linkage. Genotyping the founders with additional high-density markers enabled the projection of genetic information, capturing linkage disequilibrium information, from founders to progenies. With 5000 genotypes, 30-79% of the simulated quantitative trait loci (QTL) were precisely identified. By integrating genetic design, natural diversity, and genomics technologies, this new complex trait dissection strategy should greatly facilitate endeavors to link molecular variation with phenotypic variation for various complex traits.

摘要

我们研究了目前在玉米中实施的巢式关联作图(NAM)设计(26个不同的奠基亲本和5000个不同的永久基因型)的遗传和统计特性,以剖析复杂数量性状的遗传基础。NAM设计同时利用了连锁分析和关联作图的优势。我们通过基于经验标记数据和具有不同复杂性的模拟性状的计算机模拟,证明了NAM在高效低成本基因组扫描方面的能力。通过对奠基亲本和后代进行共同亲本特异性(CPS)标记基因分型,利用连锁分析推断两个相邻CPS标记内嵌套的染色体片段的遗传情况。用额外的高密度标记对奠基亲本进行基因分型,能够将遗传信息(捕获连锁不平衡信息)从奠基亲本投射到后代。对于5000个基因型,30%-79%的模拟数量性状位点(QTL)被精确鉴定。通过整合遗传设计、自然多样性和基因组技术,这种新的复杂性状剖析策略应能极大地促进将分子变异与各种复杂性状的表型变异联系起来的研究工作。

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