Department of Genetics, Development & Molecular Biology, School of Biology, Aristotle University of Thessaloniki, 54124, Thessaloniki, Greece.
Division of Genetics and Genomics, School of Veterinary Studies, The Roslin Institute and Royal (Dick), University of Edinburgh, Easter Bush, Midlothian, EH25 9RG, UK.
Genet Sel Evol. 2021 Dec 2;53(1):90. doi: 10.1186/s12711-021-00682-7.
The management of farm animal genetic resources and the adaptation of animals to climate change will probably have major effects on the long-term sustainability of the livestock sector. Genomic data harbour useful relevant information that needs to be harnessed for effectively managing genetic resources. In this paper, we report the genome characterization of the highly productive Mediterranean Chios dairy sheep and focus on genetic diversity measures related with local adaptation and selection and the genetic architecture of animal resilience to weather fluctuations as a novel adaptative trait linked to climate change.
We detected runs of homozygosity (ROH) and heterozygosity (ROHet) that revealed multiple highly homozygous and heterozygous hotspots across the Chios sheep genome. A particularly highly homozygous region was identified on chromosome 13 as a candidate of directional genetic selection associated with milk traits, which includes annotated genes that were previously shown to be linked to local adaptation to harsh environmental conditions. Favourable heterozygosity related with a potentially protective role against livestock diseases and enhanced overall fitness was revealed in heterozygous-rich regions on sheep chromosomes 3, 10, 13 and 19. Furthermore, genomic analyses were conducted on sheep resilience phenotypes that display changes in milk production in response to weather variation. Sheep resilience to heat stress was a significantly heritable trait (h = 0.26) and genetically antagonistic to milk production. Genome-wide association and regional heritability mapping analyses revealed novel genomic markers and regions on chromosome 5 that were significantly associated with sheep resilience to climate change. Subsequently, an annotation analysis detected a set of genes on chromosome 5 that were associated with olfactory receptor complexes that could participate in heat stress mitigation through changes in respiration rate and respiratory evaporation. Other genes were grouped in previously reported biological processes relevant to livestock heat dissipation, including stress and immune response.
Our results may contribute to the optimal management of sheep genetic resources and inform modern selective breeding programmes that aim at mitigating future environmental challenges towards sustainable farming, while better balancing animal adaptation and productivity. Our results are directly relevant to the studied breed and the respective environmental conditions; however, the methodology may be extended to other livestock species of interest.
农场动物遗传资源管理和动物对气候变化的适应可能会对畜牧业的长期可持续性产生重大影响。基因组数据包含有用的相关信息,需要加以利用,以有效管理遗传资源。本文报告了生产性能极高的地中海基克拉泽斯乳用绵羊的基因组特征,并重点介绍了与地方适应性和选择相关的遗传多样性措施,以及动物对天气波动的弹性的遗传结构,这是与气候变化有关的一种新的适应性特征。
我们检测到了纯合子(ROH)和杂合子(ROHet)的连续区,这些连续区揭示了基克拉泽斯绵羊基因组中的多个高度纯合和杂合热点。在第 13 号染色体上确定了一个特别高度纯合的区域,作为与乳性状相关的定向遗传选择的候选区域,该区域包含先前显示与恶劣环境条件下的地方适应性相关的注释基因。在绵羊染色体 3、10、13 和 19 上的杂合子丰富区域中发现了与牲畜疾病的潜在保护作用相关的有利杂合子,并增强了整体适应性。此外,还对表现出对天气变化的产奶量变化的绵羊弹性表型进行了基因组分析。对热应激的绵羊弹性是一个显著可遗传的性状(h=0.26),与产奶量呈遗传拮抗关系。全基因组关联和区域遗传力作图分析揭示了与绵羊对气候变化的弹性相关的染色体 5 上的新基因组标记和区域。随后,注释分析在染色体 5 上检测到一组与嗅觉受体复合物相关的基因,这些基因可能通过改变呼吸率和呼吸蒸发来参与缓解热应激。其他基因被分组到与牲畜散热有关的先前报道的生物学过程中,包括应激和免疫反应。
我们的研究结果可能有助于优化绵羊遗传资源的管理,并为旨在减轻未来环境挑战以实现可持续农业的现代选择性育种计划提供信息,同时更好地平衡动物适应性和生产力。我们的研究结果与所研究的品种及其相应的环境条件直接相关;然而,该方法可以扩展到其他感兴趣的牲畜物种。
