Genome-wide association study for feed efficiency indicator traits in Nellore cattle considering genotype-by-environment interactions.

IF 2.8 3区生物学 Q2 GENETICS & HEREDITY

Frontiers in Genetics Pub Date : 2025-06-02 eCollection Date: 2025-01-01 DOI:10.3389/fgene.2025.1539056

João B Silva Neto, Luiz F Brito, Lucio Flavio M Mota, Claudio U Magnabosco, Fernando Baldi

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引用次数: 0

Abstract

Introduction: Feed efficiency is a key factor in animal production sustainability, directly affecting production costs, environmental efficiency, and farmer profitability. The inclusion of feeding efficiency traits in cattle breeding programs has occurred later than other species due to longer life cycles and the high costs associated with measuring feed intake. However, genomic selection has facilitated the inclusion of difficult-to-measure traits in selection schemes. Thus, understanding the genetic basis of feed efficiency, particularly under varying environmental conditions, is essential.

Methods: This study aimed to identify genomic regions associated with dry matter intake (DMI) and residual feed intake (RFI) in Nellore cattle by performing a genome-wide association study (GWAS) based on single-step genomic reaction norm models that account for genotype-by-environment interactions (G×E). Phenotypic data from 23,170 young bulls and heifers were collected across 301 feed efficiency trials. Genomic windows explaining more than 1% of the total direct additive genetic variance were identified for both the intercept and slope components of the reaction norm for each trait.

Results: For RFI, ten and eleven genomic windows explained more than 1% of the genetic variance for the intercept and slope, respectively. For DMI, 12 windows were identified for the intercept and 17 for the slope. Within these regions, Multiple protein-coding genes were annotated (RFI: 66 for intercept and 47 for slope; DMI: 107 for intercept and 109 for slope), which are involved in key biological processes such as insulin, leptin, glucose, protein, and lipid metabolism; energy balance; heat stress response; feeding behavior; digestion; and nutrient absorption.

Discussion: The results highlight the functional diversity of genes involved in feed efficiency and their dynamic response to environmental variation. While certain genes remained central across environments, others were specifically important under more challenging conditions, emphasizing the role of G×E in regulating these traits. Furthermore, the magnitude and direction of SNP effects varied across environmental gradients, reinforcing the relevance of G×E. Consequently, genomic estimated breeding values for DMI and RFI also differed between environmental extremes. These findings underscore the adaptability of genetic networks to environmental changes and are essential for refining strategies to improve feed efficiency in Nellore cattle.

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考虑基因型-环境相互作用的内洛牛饲料效率指标性状全基因组关联研究

饲料效率是动物生产可持续性的关键因素，直接影响生产成本、环境效率和农民盈利能力。由于较长的生命周期和与测量采食量相关的高成本，在牛育种计划中纳入饲养效率性状的时间比其他品种晚。然而，基因组选择促进了在选择方案中包含难以测量的性状。因此，了解饲料效率的遗传基础，特别是在不同的环境条件下，是至关重要的。方法：本研究旨在通过基于单步基因组反应规范模型的全基因组关联研究（GWAS），确定与Nellore牛干物质采食量（DMI）和剩余采食量（RFI）相关的基因组区域，该模型考虑了基因型-环境相互作用（G×E）。在301项饲料效率试验中收集了23,170头公牛和小母牛的表型数据。在每个性状的反应规范的截距和斜率分量中，都确定了解释总直接加性遗传方差超过1%的基因组窗口。结果：对于RFI， 10个和11个基因组窗口分别解释了超过1%的遗传变异的截距和斜率。对于DMI，确定了12个窗口用于截距，17个窗口用于斜率。在这些区域内，多个蛋白质编码基因被注释(RFI：截距为66，斜率为47；DMI：截距为107，斜率为109)，它们参与胰岛素、瘦素、葡萄糖、蛋白质和脂质代谢等关键生物过程；能量平衡;热应激反应；摄食行为;消化;还有营养吸收。讨论：研究结果突出了与饲料效率有关的基因的功能多样性及其对环境变化的动态响应。虽然某些基因在各种环境中仍然处于中心位置，但其他基因在更具挑战性的条件下尤为重要，这强调了G×E在调节这些特征中的作用。此外，SNP效应的大小和方向随环境梯度而变化，这加强了G×E的相关性。因此，DMI和RFI的基因组育种估计值在不同的极端环境中也存在差异。这些发现强调了遗传网络对环境变化的适应性，对于改进策略以提高内洛牛的饲料效率至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Frontiers in Genetics Biochemistry, Genetics and Molecular Biology-Molecular Medicine

CiteScore

5.50

自引率

8.10%

发文量

3491

审稿时长

14 weeks

期刊介绍： Frontiers in Genetics publishes rigorously peer-reviewed research on genes and genomes relating to all the domains of life, from humans to plants to livestock and other model organisms. Led by an outstanding Editorial Board of the world’s leading experts, this multidisciplinary, open-access journal is at the forefront of communicating cutting-edge research to researchers, academics, clinicians, policy makers and the public. The study of inheritance and the impact of the genome on various biological processes is well documented. However, the majority of discoveries are still to come. A new era is seeing major developments in the function and variability of the genome, the use of genetic and genomic tools and the analysis of the genetic basis of various biological phenomena.