Animal Science Department, Goiás Federal University, 74690-900 Goiânia, GO, Brazil; Embrapa Rice and Beans, GO-462, km 12, 75375-000 Santo Antônio de Goiás, GO, Brazil.
Animal Science Department, São Paulo State University - Júlio de Mesquita Filho (UNESP), Prof. Paulo Donato Castelane, 14884-900 Jaboticabal, SP, Brazil.
Animal. 2021 Feb;15(2):100085. doi: 10.1016/j.animal.2020.100085. Epub 2020 Dec 24.
There is a growing interest to improve feed efficiency (FE) traits in cattle. The genomic selection was proposed to improve these traits since they are difficult and expensive to measure. Up to date, there are scarce studies about the implementation of genomic selection for FE traits in indicine cattle under different scenarios of pseudo-phenotypes, models, and validation strategies on a commercial large scale. Thus, the aim was to evaluate the feasibility of genomic selection implementation for FE traits in Nelore cattle applying different models and pseudo-phenotypes under validation strategies. Phenotypic and genotypic information from 4 329 and 3 467 animals were used, respectively, which were tested for residual feed intake, DM intake, feed efficiency, feed conversion ratio, residual BW gain, and residual intake and BW gain. Six prediction methods were used: single-step genomic best linear unbiased prediction, Bayes A, Bayes B, Bayes Cπ, Bayesian least absolute shrinkage and selection operator (BLASSO), and Bayes R. Phenotypes adjusted for fixed effects (Y*), estimated breeding value (EBV), and EBV deregressed (DEBV) were used as pseudo-phenotypes. The validation approaches used were: (1) random: the data was randomly divided into ten subsets and the validation was done in each subset at a time; (2) age: the partition into training and testing sets was based on year of birth and testing animals were born after 2016; and (3) EBV accuracy: the data was split into two groups, being animals with accuracy above 0.45 the training set; and below 0.45 the validation set. In the analyses that used the Y* as pseudo-phenotype, prediction ability (PA) was obtained by dividing the correlation between pseudo-phenotype and genomic EBV (GEBV) by the square root of the heritability of the trait. When EBV and DEBV were used as the pseudo-phenotype, the simple correlation of this quantity with the GEBV was considered as PA. The prediction methods show similar results for PA and bias. The random cross-validation presented higher PA (0.17) than EBV accuracy (0.14) and age (0.13). The PA was higher for Y* than for EBV and DEBV (30.0 and 34.3%, respectively). Random validation presented the highest PA, being indicated for use in populations composed mainly of young animals and traits with few generations of data recording. For high heritability traits, the validation can be done by age, enabling the prediction of the next-generation genetic merit. These results would support breeders to identify genomic approaches that are more viable for genomic prediction for FE-related traits.
人们越来越关注提高牛的饲料效率(FE)性状。由于这些性状难以测量且成本高昂,因此提出了基因组选择来改善这些性状。截至目前,关于在不同的拟表型、模型和验证策略情景下,在商业大规模范围内对印度牛实施 FE 性状的基因组选择,相关研究甚少。因此,本研究旨在评估在纳罗尔牛中实施 FE 性状的基因组选择的可行性,应用不同的模型和拟表型,并采用不同的验证策略。使用了分别来自 4329 头和 3467 头动物的表型和基因型信息,对剩余饲料摄入量、干物质摄入量、饲料效率、饲料转化率、剩余体重增益和剩余摄入量与体重增益进行了测试。使用了六种预测方法:单步基因组最佳线性无偏预测、贝叶斯 A、贝叶斯 B、贝叶斯 Cπ、贝叶斯最小绝对收缩和选择算子(BLASSO)和贝叶斯 R。调整了固定效应(Y*)、估计育种值(EBV)和去回归 EBV(DEBV)的表型被用作拟表型。采用了以下三种验证方法:(1)随机:将数据随机分为十个子集,每次在一个子集中进行验证;(2)年龄:训练和测试集的划分基于出生年份,测试动物在 2016 年后出生;(3)EBV 准确性:将数据分为两组,准确性高于 0.45 的为训练集,低于 0.45 的为验证集。在使用 Y作为拟表型的分析中,预测能力(PA)通过将拟表型与基因组 EBV(GEBV)的相关性除以性状的遗传力的平方根来获得。当 EBV 和 DEBV 用作拟表型时,将此数量与 GEBV 的简单相关系数视为 PA。对于 PA 和偏差,预测方法的结果相似。随机交叉验证的 PA(0.17)高于 EBV 准确性(0.14)和年龄(0.13)。Y的 PA 高于 EBV 和 DEBV(分别为 30.0%和 34.3%)。随机验证的 PA 最高,表明其适用于主要由年轻动物和数据记录世代较少的性状组成的群体。对于高遗传力性状,可以通过年龄进行验证,从而预测下一代的遗传优势。这些结果将有助于饲养员确定更适合 FE 相关性状基因组预测的基因组方法。
