基于代理表型的非加性关联分析鉴定新的牛综合征。

Non-additive association analysis using proxy phenotypes identifies novel cattle syndromes.

机构信息

Massey University, Palmerston North, New Zealand.

Livestock Improvement Corporation, Hamilton, New Zealand.

出版信息

Nat Genet. 2021 Jul;53(7):949-954. doi: 10.1038/s41588-021-00872-5. Epub 2021 May 27.

DOI:10.1038/s41588-021-00872-5

PMID:34045765

Abstract

Mammalian species carry ~100 loss-of-function variants per individual, where ~1-5 of these impact essential genes and cause embryonic lethality or severe disease when homozygous. The functions of the remainder are more difficult to resolve, although the assumption is that these variants impact fitness in less manifest ways. Here we report one of the largest sequence-resolution screens of cattle to date, targeting discovery and validation of non-additive effects in 130,725 animals. We highlight six novel recessive loci with impacts generally exceeding the largest-effect variants identified from additive genome-wide association studies, presenting analogs of human diseases and hitherto-unrecognized disorders. These loci present compelling missense (PLCD4, MTRF1 and DPF2), premature stop (MUS81) and splice-disrupting (GALNT2 and FGD4) mutations, together explaining substantial proportions of inbreeding depression. These results demonstrate that the frequency distribution of deleterious alleles segregating in selected species can afford sufficient power to directly map novel disorders, presenting selection opportunities to minimize the incidence of genetic disease.

摘要

哺乳动物个体携带约 100 个功能丧失变异，其中约 1-5 个影响必需基因，当纯合时会导致胚胎致死或严重疾病。其余的功能更难确定，尽管假设这些变异会以不太明显的方式影响适应性。在这里，我们报告了迄今为止针对牛的最大规模的序列分辨率筛选之一，旨在发现和验证 130725 只动物中的非加性效应。我们重点介绍了六个新的隐性基因座，其影响通常超过从加性全基因组关联研究中确定的最大效应变异，呈现出与人疾病和迄今尚未认识到的疾病的类似物。这些基因座呈现出引人注目的错义（PLCD4、MTRF1 和 DPF2）、过早终止（MUS81）和剪接破坏（GALNT2 和 FGD4）突变，共同解释了大量近交衰退的原因。这些结果表明，在选择的物种中分离的有害等位基因的频率分布可以提供足够的力量来直接绘制新的疾病图谱，为最小化遗传疾病的发病率提供了选择机会。

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基于代理表型的非加性关联分析鉴定新的牛综合征。

Non-additive association analysis using proxy phenotypes identifies novel cattle syndromes.

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