Massive detection of cryptic recessive genetic defects in dairy cattle mining millions of life histories

IF 10.1 1区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Florian Besnard, Ana Guintard, Cécile Grohs, Laurence Guzylack-Piriou, Margarita Cano, Clémentine Escouflaire, Chris Hozé, Hélène Leclerc, Thierry Buronfosse, Lucie Dutheil, Jeanlin Jourdain, Anne Barbat, Sébastien Fritz, Marie-Christine Deloche, Aude Remot, Blandine Gaussères, Adèle Clément, Marion Bouchier, Elise Contat, Anne Relun, Vincent Plassard, Julie Rivière, Christine Péchoux, Marthe Vilotte, Camille Eche, Claire Kuchly, Mathieu Charles, Arnaud Boulling, Guillaume Viard, Stéphanie Minéry, Sarah Barbey, Clément Birbes, Coralie Danchin-Burge, Frédéric Launay, Sophie Mattalia, Aurélie Allais-Bonnet, Bérangère Ravary, Yves Millemann, Raphaël Guatteo, Christophe Klopp, Christine Gaspin, Carole Iampietro, Cécile Donnadieu, Denis Milan, Marie-Anne Arcangioli, Mekki Boussaha, Gilles Foucras, Didier Boichard, Aurélien Capitan
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Abstract

Dairy cattle breeds are populations of limited effective size, subject to recurrent outbreaks of recessive defects that are commonly studied using positional cloning. However, this strategy, based on the observation of animals with characteristic features, may overlook a number of conditions, such as immune or metabolic genetic disorders, which may be confused with pathologies of environmental etiology. We present a data mining framework specifically designed to detect recessive defects in livestock that have been previously missed due to a lack of specific signs, incomplete penetrance, or incomplete linkage disequilibrium. This approach leverages the massive data generated by genomic selection. Its basic principle is to compare the observed and expected numbers of homozygotes for sliding haplotypes in animals with different life histories. Within three cattle breeds, we report 33 new loci responsible for increased risk of juvenile mortality and present a series of validations based on large-scale genotyping, clinical examination, and functional studies for candidate variants affecting the NOA1, RFC5, and ITGB7 genes. In particular, we describe disorders associated with NOA1 and RFC5 mutations for the first time in vertebrates. The discovery of these many new defects will help to characterize the genetic basis of inbreeding depression, while their management will improve animal welfare and reduce losses to the industry.
大规模检测奶牛隐性隐性遗传缺陷,挖掘数以百万计的生命历程
奶牛品种是有效规模有限的种群,经常爆发隐性缺陷,通常采用定位克隆技术对其进行研究。然而,这种基于观察动物特征的策略可能会忽略一些病症,如免疫或代谢遗传疾病,这些病症可能会与环境病因的病症相混淆。我们提出了一种数据挖掘框架,专门用于检测家畜的隐性缺陷,这些缺陷以前由于缺乏特异性体征、不完全渗透性或不完全连锁不平衡而被遗漏。这种方法利用了基因组选择产生的大量数据。其基本原理是比较具有不同生活史的动物中滑动单倍型的观察到的同源染色体数量和预期的同源染色体数量。在三个牛种中,我们报告了 33 个导致幼牛死亡风险增加的新位点,并根据大规模基因分型、临床检查和功能研究,对影响 NOA1、RFC5 和 ITGB7 基因的候选变异进行了一系列验证。特别是,我们首次在脊椎动物中描述了与 NOA1 和 RFC5 基因突变相关的疾病。这些新缺陷的发现将有助于确定近亲繁殖抑制的遗传基础,而它们的管理将改善动物福利并减少产业损失。
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来源期刊
Genome Biology
Genome Biology Biochemistry, Genetics and Molecular Biology-Genetics
CiteScore
21.00
自引率
3.30%
发文量
241
审稿时长
2 months
期刊介绍: Genome Biology stands as a premier platform for exceptional research across all domains of biology and biomedicine, explored through a genomic and post-genomic lens. With an impressive impact factor of 12.3 (2022),* the journal secures its position as the 3rd-ranked research journal in the Genetics and Heredity category and the 2nd-ranked research journal in the Biotechnology and Applied Microbiology category by Thomson Reuters. Notably, Genome Biology holds the distinction of being the highest-ranked open-access journal in this category. Our dedicated team of highly trained in-house Editors collaborates closely with our esteemed Editorial Board of international experts, ensuring the journal remains on the forefront of scientific advances and community standards. Regular engagement with researchers at conferences and institute visits underscores our commitment to staying abreast of the latest developments in the field.
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