Genomic predictions and GWAS for heat tolerance in pigs based on reaction norm models with performance records and data from public weather stations considering alternative temperature thresholds

IF 1.9 3区 农林科学 Q2 AGRICULTURE, DAIRY & ANIMAL SCIENCE Journal of Animal Breeding and Genetics Pub Date : 2023-11-27 DOI:10.1111/jbg.12838
Pedro Henrique F. Freitas, Jay S. Johnson, Francesco Tiezzi, Yijian Huang, Allan P. Schinckel, Luiz F. Brito
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Abstract

Genetic improvement of livestock productivity has resulted in greater production of metabolic heat and potentially greater susceptibility to heat stress. Various studies have demonstrated that there is genetic variability for heat tolerance and genetic selection for more heat tolerant individuals is possible. The rate of genetic progress tends to be greater when genomic information is incorporated into the analyses as more accurate breeding values can be obtained for young individuals. Therefore, this study aimed (1) to evaluate the predictive ability of genomic breeding values for heat tolerance based on routinely recorded traits, and (2) to investigate the genetic background of heat tolerance based on single-step genome-wide association studies for economically important traits related to body composition, growth and reproduction in Large White pigs. Pedigree information was available for 265,943 animals and genotypes for 8686 animals. The studied traits included ultrasound backfat thickness (BFT), ultrasound muscle depth (MDP), piglet weaning weight (WW), off-test weight (OTW), interval between farrowing (IBF), total number of piglets born (TNB), number of piglets born alive (NBA), number of piglets born dead (NBD), number of piglets weaned (WN) and weaning-to-estrus interval (IWE). The number of phenotypic records ranged from 6059 (WN) to 172,984 (TNB). Single-step genomic reaction norm predictions were used to calculate the genomic estimated breeding values for each individual. Predictions of breeding values for the validation population individuals were compared between datasets containing phenotypic records measured in the whole range of temperatures (WR) and datasets containing only phenotypic records measured when the weather station temperature was above 10°C (10C) or 15°C (15C), to evaluate the usefulness of these datasets that may better reflect the within-barn temperature. The use of homogeneous or heterogeneous residual variance was found to be trait-dependent, where homogeneous variance presented the best fit for MDP, BFT, OTW, TNB, NBA, WN and IBF, while the other traits (WW and IWE) had better fit with heterogeneous variance. The average prediction accuracy, dispersion and bias values considering all traits for WR were 0.36 ± 0.05, −0.07 ± 0.13 and 0.76 ± 0.10, respectively; for 10C were 0.39 ± 0.02, −0.05 ± 0.07 and 0.81 ± 0.05, respectively; and for 15C were 0.32 ± 0.05, −0.05 ± 0.11 and 0.84 ± 0.10, respectively. Based on the studied traits, using phenotypic records collected when the outside temperature (from public weather stations) was above 10°C provided better predictions for most of the traits. Forty-three and 62 candidate genomic regions were associated with the intercept (overall performance level) and slope term (specific biological mechanisms related to environmental sensitivity), respectively. Our results contribute to improve genomic predictions using existing datasets and better understand the genetic background of heat tolerance in pigs. Furthermore, the genomic regions and candidate genes identified will contribute to future genomic studies and breeding applications.

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猪耐热性的基因组预测和GWAS基于性能记录的反应规范模型和考虑可选温度阈值的公共气象站数据。
牲畜生产力的遗传改进导致代谢热产量增加,对热应激的潜在易感性增加。各种研究表明,耐热性存在遗传变异性,遗传选择更耐热的个体是可能的。当基因组信息被纳入分析时,遗传进步的速度往往会更快,因为可以为年轻个体获得更准确的育种值。因此,本研究旨在(1)基于常规记录的性状,评估基因组育种价值对耐热性的预测能力;(2)基于与大白猪体组成、生长和繁殖相关的重要经济性状的单步全基因组关联研究,探讨耐热性的遗传背景。获得了265,943只动物的系谱信息和8686只动物的基因型。研究的性状包括超声背膘厚度(BFT)、超声肌深(MDP)、仔猪断奶重(WW)、离试重(OTW)、产仔间隔(IBF)、总产仔数(TNB)、活产仔数(NBA)、死产仔数(NBD)、断奶仔数(WN)和断奶至发情间隔(IWE)。表型记录数从6059 (WN)到172984 (TNB)不等。单步基因组反应规范预测用于计算每个个体的基因组估计育种值。将包含整个温度范围(WR)下测量的表型记录的数据集与仅包含气象站温度高于10°C (10C)或15°C (15C)时测量的表型记录的数据集进行比较,以评估这些数据集的有用性,这些数据集可能更好地反映仓内温度。同质或异质残差方差的使用具有性状依赖性,其中同质方差最适合MDP、BFT、OTW、TNB、NBA、WN和IBF,而其他性状(WW和IWE)最适合异质方差。考虑各性状的平均预测精度、离散度和偏差值分别为0.36±0.05、-0.07±0.13和0.76±0.10;10C分别为0.39±0.02、-0.05±0.07和0.81±0.05;15C分别为0.32±0.05、-0.05±0.11和0.84±0.10。基于所研究的性状,使用外部温度(来自公共气象站)高于10℃时收集的表型记录可以更好地预测大多数性状。43个和62个候选基因组区域分别与截距(总体表现水平)和斜率项(与环境敏感性相关的特定生物机制)相关。我们的研究结果有助于利用现有数据集改进基因组预测,并更好地了解猪耐热性的遗传背景。此外,所确定的基因组区域和候选基因将有助于未来的基因组研究和育种应用。
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来源期刊
Journal of Animal Breeding and Genetics
Journal of Animal Breeding and Genetics 农林科学-奶制品与动物科学
CiteScore
5.20
自引率
3.80%
发文量
58
审稿时长
12-24 weeks
期刊介绍: The Journal of Animal Breeding and Genetics publishes original articles by international scientists on genomic selection, and any other topic related to breeding programmes, selection, quantitative genetic, genomics, diversity and evolution of domestic animals. Researchers, teachers, and the animal breeding industry will find the reports of interest. Book reviews appear in many issues.
期刊最新文献
Genomic Diversity of U.S. Katahdin Hair Sheep. The Effect of Preselection on the Level of Bias and Accuracy in a Broiler Breeder Population, a Simulation Study. Genomic Prediction Using Imputed Whole-Genome Sequence Data in Australian Angus Cattle. Genetic Characterisation of Feeding Patterns in Lactating Holstein Cows and Their Association With Feed Efficiency Traits. Methods of Calculating Prediction Error Variance and Prediction Accuracy for Restricted Best Linear Unbiased Prediction of Breeding Values.
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