Genomic selection through single-step genomic best linear unbiased prediction improves the accuracy of evaluation in Hanwoo cattle.

IF 2.2 2区农林科学

Asian-Australasian Journal of Animal Sciences Pub Date : 2020-10-01 Epub Date: 2019-11-12 DOI:10.5713/ajas.18.0936

Mi Na Park, Mahboob Alam, Sidong Kim, Byoungho Park, Seung Hwan Lee, Sung Soo Lee

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引用次数: 10

Abstract

Objective: Genomic selection (GS) is becoming popular in animals' genetic development. We, therefore, investigated the single-step genomic best linear unbiased prediction (ssGBLUP) as tool for GS, and compared its efficacy with the traditional pedigree BLUP (pedBLUP) method.

Methods: A total of 9,952 males born between 1997 and 2018 under Hanwoo proven-bull selection program was studied. We analyzed body weight at 12 months and carcass weight (kg), backfat thickness, eye muscle area, and marbling score traits. About 7,387 bulls were genotyped using Illumina 50K BeadChip Arrays. Multiple-trait animal model analyses were performed using BLUPF90 software programs. Breeding value accuracy was calculated using two.

Methods: i) Pearson's correlation of genomic estimated breeding value (GEBV) with EBV of all animals (rM1) and ii) correlation using inverse of coefficient matrix from the mixed-model equations (rM2). Then, we compared these accuracies by overall population, info-type (PHEN, phenotyped-only; GEN, genotyped-only; and PH+GEN, phenotyped and genotyped), and bull-types (YBULL, young male calves; CBULL, young candidate bulls; and PBULL, proven bulls).

Results: The rM1 estimates in the study were between 0.90 and 0.96 among five traits. The rM1 estimates varied slightly by population and info-type, but noticeably by bull-type for traits. Generally average rM2 estimates were much smaller than rM1 (pedBLUP, 0.40 to0.44; ssGBLUP, 0.41 to 0.45) at population level. However, rM2 from both BLUP models varied noticeably across info-types and bull-types. The ssGBLUP estimates of rM2 in PHEN, GEN, and PH+ GEN ranged between 0.51 and 0.63, 0.66 and 0.70, and 0.68 and 0.73, respectively. In YBULL, CBULL, and PBULL, the rM2 estimates ranged between 0.54 and 0.57, 0.55 and 0.62, and 0.70 and 0.74, respectively. The pedBLUP based rM2 estimates were also relatively lower than ssGBLUP estimates. At the population level, we found an increase in accuracy by 2.0% to 4.5% among traits. Traits in PHEN were least influenced by ssGBLUP (0% to 2.0%), whereas the highest positive changes were in GEN (8.1% to 10.7%). PH+GEN also showed 6.5% to 8.5% increase in accuracy by ssGBLUP. However, the highest improvements were found in bull-types (YBULL, 21% to 35.7%; CBULL, 3.3% to 9.3%; PBULL, 2.8% to 6.1%).

Conclusion: A noticeable improvement by ssGBLUP was observed in this study. Findings of differential responses to ssGBLUP by various bulls could assist in better selection decision making as well. We, therefore, suggest that ssGBLUP could be used for GS in Hanwoo provenbull evaluation program.

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通过单步基因组最佳线性无偏预测进行基因组选择，提高了汉宇牛评估的准确性。

目的:基因组选择在动物遗传发育中越来越受欢迎。因此，我们研究了单步基因组最佳线性无偏预测(ssGBLUP)作为GS的工具，并将其与传统系谱BLUP (pedBLUP)方法的效果进行了比较。方法:对1997 ~ 2018年在韩宇公牛选拔计划下出生的9952只雄性进行研究。我们分析了12月龄体重、胴体重(kg)、背膘厚度、眼肌面积和大理石纹评分性状。使用Illumina 50K头芯片阵列对7387头公牛进行了基因分型。采用BLUPF90软件进行多性状动物模型分析。用2计算育种值精度。方法:i)所有动物的基因组估计育种值(GEBV)与EBV的Pearson相关性(rM1)和ii)使用混合模型方程的系数矩阵逆进行相关性(rM2)。然后，我们通过总体、信息型(PHEN，仅表型;创,genotyped-only;PH+GEN，表现型和基因型)和公牛型(YBULL，年轻雄性小牛;CBULL，年轻的候选人公牛;和PBULL，被证明是公牛)。结果:5个性状的rM1估计值在0.90 ~ 0.96之间。rM1估计值因种群和信息类型而略有不同，但因性状而显著不同。一般平均rM2估计值远小于rM1 (pedBLUP, 0.40至0.44;ssGBLUP为0.41 ~ 0.45)。然而，两个BLUP模型的rM2在信息类型和公牛类型之间有显著差异。PHEN、GEN和PH+ GEN中rM2的ssGBLUP估计值分别在0.51 - 0.63、0.66 - 0.70和0.68 - 0.73之间。在YBULL, CBULL和PBULL中，rM2估计值分别介于0.54和0.57,0.55和0.62以及0.70和0.74之间。基于pedBLUP的rM2估计值也相对低于ssGBLUP估计值。在群体水平上，我们发现性状之间的准确率提高了2.0%至4.5%。ssGBLUP对PHEN性状影响最小(0% ~ 2.0%)，对GEN性状影响最大(8.1% ~ 10.7%)。PH+GEN的准确性也被ssGBLUP提高了6.5%至8.5%。然而，在公牛类型中发现了最高的改进(YBULL, 21%至35.7%;CBULL, 3.3% - 9.3%;PBULL, 2.8%至6.1%)。结论:ssGBLUP在本研究中观察到明显的改善。不同品种公牛对ssGBLUP的不同反应也有助于更好的选择决策。因此，我们建议ssGBLUP可用于韩宇证明牛评价程序中的GS。

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

Asian-Australasian Journal of Animal Sciences AGRICULTURE, DAIRY & ANIMAL SCIENCE-

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： Asian-Australasian Journal of Animal Sciences (AJAS) aims to publish original and cutting-edge research results and reviews on animal-related aspects of the life sciences. Emphasis will be placed on studies involving farm animals such as cattle, buffaloes, sheep, goats, pigs, horses, and poultry. Studies for the improvement of human health using animal models may also be publishable. AJAS will encompass all areas of animal production and fundamental aspects of animal sciences: breeding and genetics, reproduction and physiology, nutrition, meat and milk science, biotechnology, behavior, welfare, health, and livestock farming systems.