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基于猪自然多微生物疾病挑战模型的疾病抗性性状的全基因组关联研究确定了主要组织相容性复合体区域的重要性。

Genome-wide association study of disease resilience traits from a natural polymicrobial disease challenge model in pigs identifies the importance of the major histocompatibility complex region.

机构信息

Department of Animal Science, Iowa State University, Ames, IA 50011, USA.

Department of Animal Science, University of California, Davis, Davis, CA 95616, USA.

出版信息

G3 (Bethesda). 2022 Mar 4;12(3). doi: 10.1093/g3journal/jkab441.

DOI:10.1093/g3journal/jkab441
PMID:35100362
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9210302/
Abstract

Infectious diseases cause tremendous financial losses in the pork industry, emphasizing the importance of disease resilience, which is the ability of an animal to maintain performance under disease. Previously, a natural polymicrobial disease challenge model was established, in which pigs were challenged in the late nursery phase by multiple pathogens to maximize expression of genetic differences in disease resilience. Genetic analysis found that performance traits in this model, including growth rate, feed and water intake, and carcass traits, as well as clinical disease phenotypes, were heritable and could be selected for to increase disease resilience of pigs. The objectives of the current study were to identify genomic regions that are associated with disease resilience in this model, using genome-wide association studies and fine-mapping methods, and to use gene set enrichment analyses to determine whether genomic regions associated with disease resilience are enriched for previously published quantitative trait loci, functional pathways, and differentially expressed genes subject to physiological states. Multiple quantitative trait loci were detected for all recorded performance and clinical disease traits. The major histocompatibility complex region was found to explain substantial genetic variance for multiple traits, including for growth rate in the late nursery (12.8%) and finisher (2.7%), for several clinical disease traits (up to 2.7%), and for several feeding and drinking traits (up to 4%). Further fine mapping identified 4 quantitative trait loci in the major histocompatibility complex region for growth rate in the late nursery that spanned the subregions for class I, II, and III, with 1 single-nucleotide polymorphism in the major histocompatibility complex class I subregion capturing the largest effects, explaining 0.8-27.1% of genetic variance for growth rate and for multiple clinical disease traits. This single-nucleotide polymorphism was located in the enhancer of TRIM39 gene, which is involved in innate immune response. The major histocompatibility complex region was pleiotropic for growth rate in the late nursery and finisher, and for treatment and mortality rates. Growth rate in the late nursery showed strong negative genetic correlations in the major histocompatibility complex region with treatment or mortality rates (-0.62 to -0.85) and a strong positive genetic correlation with growth rate in the finisher (0.79). Gene set enrichment analyses found genomic regions associated with resilience phenotypes to be enriched for previously identified disease susceptibility and immune capacity quantitative trait loci, for genes that were differentially expressed following bacterial or virus infection and immune response, and for gene ontology terms related to immune and inflammatory response. In conclusion, the major histocompatibility complex and other quantitative trait loci that harbor immune-related genes were identified to be associated with disease resilience traits in a large-scale natural polymicrobial disease challenge. The major histocompatibility complex region was pleiotropic for growth rate under challenge and for clinical disease traits. Four quantitative trait loci were identified across the class I, II, and III subregions of the major histocompatibility complex for nursery growth rate under challenge, with 1 single-nucleotide polymorphism in the major histocompatibility complex class I subregion capturing the largest effects. The major histocompatibility complex and other quantitative trait loci identified play an important role in host response to infectious diseases and can be incorporated in selection to improve disease resilience, in particular the identified single-nucleotide polymorphism in the major histocompatibility complex class I subregion.

摘要

传染病给养猪业造成了巨大的经济损失,强调了疾病抵抗力的重要性,即动物在患病时保持性能的能力。此前,建立了一种天然多病原体疾病挑战模型,在该模型中,猪在幼猪后期受到多种病原体的挑战,以最大限度地表达疾病抵抗力的遗传差异。遗传分析发现,该模型中的性能特征,包括生长速度、饲料和水的摄入以及胴体特征,以及临床疾病表型,是可遗传的,可以选择增加猪的疾病抵抗力。本研究的目的是使用全基因组关联研究和精细映射方法鉴定与该模型中疾病抵抗力相关的基因组区域,并使用基因集富集分析来确定与疾病抵抗力相关的基因组区域是否富集了先前发表的数量性状位点、功能途径和受生理状态影响的差异表达基因。多个数量性状位点被检测到与所有记录的性能和临床疾病特征相关。主要组织相容性复合体区域被发现解释了多个性状的大量遗传变异,包括幼猪后期的生长速度(12.8%)和育肥后期的生长速度(2.7%),以及多个临床疾病特征(高达 2.7%)和多个采食和饮水特征(高达 4%)。进一步的精细映射确定了主要组织相容性复合体区域中与幼猪后期生长速度相关的 4 个数量性状位点,这些位点跨越了 I 类、II 类和 III 类亚区,主要组织相容性复合体 I 类亚区的 1 个单核苷酸多态性捕获了最大的效应,解释了生长速度和多个临床疾病特征的 0.8-27.1%的遗传变异。该单核苷酸多态性位于 TRIM39 基因的增强子中,该基因参与先天免疫反应。主要组织相容性复合体区域与生长速度在幼猪后期和育肥后期、治疗率和死亡率呈多效性。幼猪后期的生长速度在主要组织相容性复合体区域与治疗率或死亡率呈强烈的负遗传相关性(-0.62 至-0.85),与育肥后期的生长速度呈强烈的正遗传相关性(0.79)。基因集富集分析发现,与弹性表型相关的基因组区域富含先前确定的疾病易感性和免疫能力数量性状位点、细菌或病毒感染和免疫反应后差异表达的基因以及与免疫和炎症反应相关的基因本体术语。总之,鉴定出主要组织相容性复合体和其他含有免疫相关基因的数量性状位点与大规模天然多病原体疾病挑战中的疾病抵抗力特征相关。主要组织相容性复合体区域与挑战下的生长速度和临床疾病特征呈多效性。在主要组织相容性复合体的 I 类、II 类和 III 亚区鉴定出 4 个与育肥后期生长速度相关的数量性状位点,主要组织相容性复合体 I 类亚区的 1 个单核苷酸多态性捕获了最大的效应。鉴定出的主要组织相容性复合体和其他数量性状位点在宿主对传染病的反应中起着重要作用,可以被纳入选择,以提高疾病抵抗力,特别是主要组织相容性复合体 I 类亚区中的鉴定出的单核苷酸多态性。

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