猪基因组选择“两步走”策略的计算机模拟评估

doi:10.3864/j.issn.0578-1752.2021.21.016

中国农业科学 ›› 2021, Vol. 54 ›› Issue (21): 4677-4684.doi: 10.3864/j.issn.0578-1752.2021.21.016

• 畜牧·兽医·资源昆虫 • 上一篇下一篇

猪基因组选择“两步走”策略的计算机模拟评估

唐振双¹(),殷东¹,尹立林¹,马云龙¹,项韬¹,朱猛进¹,余梅¹,刘小磊¹,李新云¹,邱小田^2,^*(),赵书红^1,^*()

¹华中农业大学动物科技学院/农业动物遗传育种与繁殖教育部重点实验室/农业农村部猪遗传育种重点实验室/国家家畜工程技术研究中心,武汉 430070
²全国畜牧总站北京 100107

收稿日期:2020-10-19 接受日期:2021-02-04 出版日期:2021-11-01 发布日期:2021-11-09
通讯作者: 邱小田,赵书红
作者简介:联系方式：唐振双,E-mail： zst@webmail.hzau.edu.cn。
基金资助:
国家自然科学基金面上项目(32072725);国家生猪产业体系(CARS-35);中央高校基本科研业务费专项资金资助项目(662020DKPYCFA006007);猪基因组选择育种创新群体(2020CFA006)

To Evaluate the “Two-Step” Genomic Selection Strategy in Pig by Simulation

TANG ZhenShuang¹(),YIN Dong¹,YIN LiLin¹,MA YunLong¹,XIANG Tao¹,ZHU MengJin¹,YU Mei¹,LIU XiaoLei¹,LI XinYun¹,QIU XiaoTian^2,^*(),ZHAO ShuHong^1,^*()

¹College of Animal Science and Technology, Huazhong Agricultural University /Key Laboratory of Agricultural Animal Genetics, Breeding and Reproduction of Ministry of Education/Key Laboratory of Swine Genetics and Breeding of Ministry of Agriculture and Rural Affairs/National Engineering and Technology Research Center for Livestock, Wuhan 430070
²National Animal Husbandry Service, Beijing 100107

Received:2020-10-19 Accepted:2021-02-04 Online:2021-11-01 Published:2021-11-09
Contact: XiaoTian QIU,ShuHong ZHAO

摘要/Abstract

摘要：

【背景】基因组选择育种自2001年被MEUWISSEN等提出以来,已广泛应用在奶牛、猪等重要家畜的育种中,并显著加快了其重要经济性状的遗传改良速度。2017年,在全国畜牧总站的组织协调下,在全国生猪遗传改良计划框架内,猪全基因组选择育种平台项目正式启动。【目的】尽管基因组选择在种猪选育中取得了良好的效果,基因分型技术的不断升级也带来了成本的持续下降,但对于我国多数核心育种场依然面临着基因芯片分型个体数量不足、基因组选择实施流程不完善等问题,限制了该技术的大规模推广应用。结合我国生猪育种的实际情况,研究提出了一种“终测选择-早期选择”的“两步走”基因组选择策略。“终测选择”指在终测结束后利用一步法基因组BLUP对后备猪进行遗传评估,当群体中芯片分型个体数量达到一定规模后进行“早期选择”。【方法】以杜洛克、长白和大白三个种猪品种真实的50K基因芯片数据作为基础群体对不同品种分别进行大群模拟,共模拟4个世代,前3个世代作为基础群体,第4个世代作为测试群体,每个个体模拟两个性状（中等遗传力性状和低遗传力性状）,利用猪基因组选择育种平台基于HIBLUP软件计算不同品种、不同性状的育种值,比较一步法基因组BLUP和常规BLUP两种方法的预测准确性。根据测试群个体有无终测成绩对其基因组育种值影响大小来评估早期选择效果。【结果】分析表明在3个品种内中等遗传力性状的终测选择效果和早期选择效果均好于低遗传力性状。一步法基因组BLUP的选择准确性均优于常规BLUP的选择准确性,并且随着测试群中芯片分型个体数量的增加、群体规模的扩大,预测准确性越来越高。一步法基因组BLUP的早期选择效果好于常规BLUP,当群体中芯片数量达到2 000张时就可以开展早期选择,阉割排名后30%的个体,可以保证前1%的优秀个体不会被错误淘汰,并且随着芯片数量的增加、早期选择的效果会越来越好。【结论】基因组选择“两步走”的策略符合我国国情、容易在生猪育种中推广实施。当芯片数量较少时,可以开展“终测选择”,一定程度上提高选择的准确性,提高育种效率;当芯片数量较多时,可以开展“早期选择”,对排名靠后的猪只个体进行早期阉割,增加优秀个体的测定量,增大选择强度、加快遗传进展。“两步走”策略符合我国生猪产业基因组选择育种的实际需求,该策略的实施将有利于推动我国猪基因组选择的应用、加快种猪改良进程。

关键词: 基因组选择, 猪, 两步走, 终测选择, 早期选择

Abstract:

【Background】 Since genomic selection (GS) was proposed by MEUWISSEN et al. in 2001, it has been widely used in the breeding of dairy cows, pigs, and other livestock, and has significantly improved the speed of genetic gain of various economic traits. In 2017, with the organization and coordination of the National Grazing Headquarter Station and within the framework of the National Swine Improvement Program, the genomic selection platform for pig breeding was officially launched. Although genomic selection has made positive achievements in pig breeding, and the developing of advanced genotyping technology reduced the costs dramatically, some issues were still existed, including the insufficient number of genotyped individuals in majority of core breeding farms and the inappropriate implementation processes has restricted its wide application in practice.【Objective】In combination with the actual situation of domestic pig breeding, the “two-step” strategy for genomic selection was proposed in this study, that is, the off-test evaluation and the early-stage prediction. Off-test evaluation referred to the genetic evaluation of replacement pigs by SSGBLUP after off-test, and early-stage prediction was carried out when the number of chips reached a certain scale. 【Method】 In this study, the 50 K chip datasets of three breeds consisting of Duroc, Landrace, and Yorkshire were used as the base group to simulate the large-scale population of different breeds, respectively. The four generations were simulated: the first three generations were treated as the base population, and the fourth generation as the test population, two traits with medium and low heritability was simulated for each individual. The estimated breeding values of SSGBLUP and traditional BLUP model for different traits were calculated by the pig genomic selection platform based on the HIBLUP software. The predictive performance of early-stage was evaluated according to whether the individual’s testing records have influence their genomic estimated breeding values (GEBV) in test population. 【Result】The results showed that the predictive performance of off-test evaluation and early-stage for traits with medium heritability were better than those with low heritability. The selection accuracy of SSGBLUP was better than traditional BLUP. Moreover, with the increase of the number of chips and the expansion of the population size, the prediction accuracy was higher. The early-stage predictive performance of SSGBLUP was better than that of traditional BLUP, the early-stage prediction could be carried out when the number of genotyped pigs reached about 2 000, and castrating the last 30% individuals according to GEBV could ensure that the top 1% excellent individuals would not be mistakenly eliminated. And the prediction accuracy performance was increasing with the increased number of genotyped pigs. 【Conclusion】 The “two-step” strategy pretty was conformed to the state of domestic breeding program, and was easy to implement and promote the pig breeding in China. When the number of genotyped pigs was small, off-test evaluation could be carried out to improve the accuracy of selection, as well as efficiency, to a certain extent; when the number of genotyped pigs was large, early-stage prediction could be performed by castrating the pigs on the lower rank of GEBV, which could increase the amount of testing for more excellent pigs, and could also strength the selection intensity and accelerate the genetic gain. The “two-step” strategy was in line with the actual requirements of genomic selection in pig industry. The implementation of this strategy could further promote the application of genomic selection and speed up the genetic gain in pig breeding.

Key words: genomic selection, pig, two-step, off-test evaluation, early-stage prediction

唐振双,殷东,尹立林,马云龙,项韬,朱猛进,余梅,刘小磊,李新云,邱小田,赵书红. 猪基因组选择“两步走”策略的计算机模拟评估[J]. 中国农业科学, 2021, 54(21): 4677-4684.

TANG ZhenShuang,YIN Dong,YIN LiLin,MA YunLong,XIANG Tao,ZHU MengJin,YU Mei,LIU XiaoLei,LI XinYun,QIU XiaoTian,ZHAO ShuHong. To Evaluate the “Two-Step” Genomic Selection Strategy in Pig by Simulation[J]. Scientia Agricultura Sinica, 2021, 54(21): 4677-4684.

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参考文献 27

[1]	彭中镇. 《全国生猪遗传改良计划》解读及实施中有关问题的讨论(待续). 猪业科学, 2011, 28(8):100-103. doi: 10.3969/j.issn.1673- 5358.2011.08.037. doi: 10.3969/j.issn.1673- 5358.2011.08.037
	PENG Z Z. Discussion on the relevant issues in the interpretation and implementation of the “National Swine Improvement Program”. Swine Industry Science, 2011, 28(8):100-103. doi: 10.3969/j.issn.1673-5358.2011.08.037. (in Chinese) doi: 10.3969/j.issn.1673- 5358.2011.08.037
[2]	KNOL E. ASAS-EAAP Exchange Speaker Talk: Is genomic selection beneficial for the pig industry? Journal of Animal Science, 2019, 97l(1):1-7.
[3]	CESARANI A, GASPA G, CORREDDU F, CELLESI M, DIMAURO C, MACCIOTTA N P P. Genomic selection of milk fatty acid composition in Sarda dairy sheep: Effect of different phenotypes and relationship matrices on heritability and breeding value accuracy. Journal of Dairy Science, 2019, 102l(4):3189-3203.
[4]	MRODE R, OJANGO J M K, OKEYO A M, MWACHARO J M. Genomic selection and use of molecular tools in breeding programs for indigenous and crossbred cattle in developing countries: Current status and future prospects. Frontiers in Genetics, 2018, 9:694. doi: 10.3389/fgene.2018.00694. doi: 10.3389/fgene.2018.00694
[5]	丁向东, 邱小田, 王志刚, 杨红杰, 陈瑶生, 张勤. 全国生猪遗传改良计划(2009—2020)给我国生猪种业带来的变化和未来工作建议. 中国畜牧杂志, 2020(6):169-174.
	DING X D, QIU X T, WANG Z G, YANG H J, CHEN Y S, ZHANG Q. The changes and suggestions brought by the National Pig Genetic Improvement Program (2009-2020) for pig breeding industry in China. Chinese Journal of Animal Science, 2020(6):169-174. (in Chinese)
[6]	HAZEL L N, LUSH J L. The efficiency of three methods of selection. Journal of Heredity, 1942, 33l(11):393-399.
[7]	HENDERSON. Inverse of a matrix of relationships due to sires and maternal grandsires. Elsevier, 1975, 58l(12):1917-1921.
[8]	尹立林, 马云龙, 项韬, 朱猛进, 余梅, 李新云, 刘小磊, 赵书红. 全基因组选择模型研究进展及展望. 畜牧兽医学报, 2019, 50(2):233-242.
	YIN L L, MA Y L, XIANG T, ZHU M J, YU M, LI X Y, LIU X L, ZHAO S H. The progress and prospect of genomic selection models. Acta Veterinaria et Zootechnica Sinica, 2019, 50(2):233-242. (in Chinese)
[9]	VANRADEN P M. Efficient methods to compute genomic predictions. Journal of Dairy Science, 2008, 91(11):4414-4423. doi: 10.3168/jds.2007-0980. doi: 10.3168/jds.2007-0980
[10]	FERNANDO R L, GROSSMAN M. Marker assisted selection using best linear unbiased prediction. Genetics Selection Evolution, 1989, 21l(4):467.
[11]	GODDARD M E, HAYES B J. Mapping genes for complex traits in domestic animals and their use in breeding programmes. Nature Reviews Genetics, 2009, 10(6):381-391. doi: 10.1038/nrg2575. doi: 10.1038/nrg2575
[12]	MEUWISSEN T H E, HAYES B J, GODDARD M E. Prediction of total genetic value using genome-wide dense marker maps. Genetics, 2001, 1571(4):1819-1829.
[13]	WRAY N R, YANG J, HAYES B J, PRICE A L, GODDARD M E, VISSCHER P M. Pitfalls of predicting complex traits from SNPs. Nature Reviews Genetics, 2013, 14(7):507-515. doi: 10.1038/nrg3457. doi: 10.1038/nrg3457
[14]	HICKEY J M, CHIURUGWI T, MACKAY I, POWELL W, HENDRE P. Genomic prediction unifies animal and plant breeding programs to form platforms for biological discovery. Nature Genetics, 2017, 491(9):1297-1303.
[15]	HILL W G. Applications of population genetics to animal breeding, from wright, fisher and lush to genomic prediction. Genetics, 2014, 196(1):1-16. doi: 10.1534/genetics.112.147850. doi: 10.1534/genetics.112.147850
[16]	CHRISTENSEN O F, LUND M S. Genomic prediction when some animals are not genotyped. Genetics Selection Evolution, 2010, 42l(1):2.
[17]	AGUILAR I, MISZTAL I, JOHNSON D L, LEGARRA A, TSURUTA S, LAWLOR T J. Hot topic: A unified approach to utilize phenotypic, full pedigree, and genomic information for genetic evaluation of Holstein final score. Journal of Dairy Science, 2010, 931(2):743-752.
[18]	GUO X, CHRISTENSEN O F, OSTERSEN T, WANG Y, LUND M S, SU G. Improving genetic evaluation of litter size and piglet mortality for both genotyped and nongenotyped individuals using a single-step method. Journal of Animal Science, 2015, 93(2):503-512. doi: 10. 2527/jas.2014-8331. doi: 10. 2527/jas.2014-8331
[19]	周磊, 杨华威, 赵祖凯, 杨红杰, 刘剑锋. 基因组选择在我国种猪育种中应用的探讨. 中国畜牧杂志, 2018, 54(3):4-8. doi: 10.19556/j.0258-7033.2018-03-004. doi: 10.19556/j.0258-7033.2018-03-004
	ZHOU L, YANG H W, ZHAO Z K, YANG H J, LIU J F. The application of genomic selection in Chinese pig breeding industry. Chinese Journal of Animal Science, 2018, 54(3):4-8. doi: 10.19556/j.0258-7033.2018-03-004. (in Chinese) doi: 10.19556/j.0258-7033.2018-03-004
[20]	ANTONIO R, RICHARD C, NABEEL A, ANDREIA A, ALAN A, JONATHAN B, CHRISTIAN B, CAROL C, RICHARD C, PATRICK D, et al. Design of a high density SNP genotyping assay in the pig using SNPs identified and characterized by next generation sequencing technology. PLoS ONE, 2009, 4l(8):e6524.
[21]	YIN L L, ZHANG H H, TANG Z S, XU J Y, YIN D, ZHANG Z W, YUAN X H, ZHU M J, ZHAO S H, LI X Y, LIU X L. rMVP: A Memory-efficient, Visualization-enhanced, and Parallel-accelerated tool for Genome-Wide Association Study. bioRxiv, 2020, 2020.08. 20.258491.
[22]	MISZTAL I, LEGARRA A. Invited review: Efficient computation strategies in genomic selection. Animal, 2017, 11(5):731-736. doi: 10.1017/s1751731116002366. doi: 10.1017/s1751731116002366
[23]	MISZTAL I, AGGREY S E, MUIR W M. Experiences with a single- step genome evaluation. Poultry Science, 2013, 92(9):2530-2534. doi: 10.3382/ps.2012-02739. doi: 10.3382/ps.2012-02739
[24]	Nielsen Bjarne, Ostersen Tage, Guosheng Su, Christensen O, Henryon M. Use Of Genomic SNP Information In Pig Breeding, 2010.
[25]	彭潇, 尹立林, 梅全顺, 王海燕, 刘小磊, 朱猛进, 李新云, 付亮亮, 赵书红. 猪主要经济性状的基因组选择研究. 畜牧兽医学报, 2019, 50(2):439-445. doi: 10.11843/j.issn.0366-6964.2019.02.023. doi: 10.11843/j.issn.0366-6964.2019.02.023
	PENG X, YIN L L, MEI Q S, WANG H Y, LIU X L, ZHU M J, LI X Y, FU L L, ZHAO S H. A study of genome selection based on the porcine major economic traits. Acta Veterinaria et Zootechnica Sinica, 2019, 50(2):439-445. doi: 10.11843/j.issn.0366-6964.2019.02.023. (in Chinese) doi: 10.11843/j.issn.0366-6964.2019.02.023
[26]	ZHANG H, YIN L, WANG M, YUAN X, LIU X. Factors affecting the accuracy of genomic selection for agricultural economic traits in maize, cattle, and pig populations. Frontiers in Genetics, 2019, 10:189. doi: 10.3389/fgene.2019.00189. doi: 10.3389/fgene.2019.00189
[27]	张金鑫, 唐韶青, 宋海亮, 高虹, 蒋尧, 江一凡, 弥世荣, 孟庆利, 于凡, 肖炜, 云鹏, 张勤, 丁向东. 北京地区大白猪基因组联合育种研究. 中国农业科学, 2019, 52(12):2161-2170. doi: 10.3864/j.issn.0578-1752.2019.12.013. doi: 10.3864/j.issn.0578-1752.2019.12.013
	ZHANG J X, TANG S Q, SONG H L, GAO H, JIANG Y, JIANG Y F, MI S R, MENG Q L, YU F, XIAO W, YUN P, ZHANG Q, DING X D. Joint genomic selection of Yorkshire in Beijing. Scientia Agricultura Sinica, 2019, 52(12):2161-2170. doi: 10.3864/j.issn.0578-1752.2019.12.013. (in Chinese) doi: 10.3864/j.issn.0578-1752.2019.12.013

类型 Type	参数Parameter
遗传力Heritability	性状1为0.3,性状2为0.1 Trait 1 is 0.3, trait 2 is 0.1
QTN的数目及效应 The number of QTN and effect	100个QTNs,正态分布 100 QTNS, normal distribution
留种率Fraction selected	杜洛克：母猪15%、公猪1% Duroc: dam 15%, sire 1% 长白：母猪10%、公猪1% Landrace: dam 10%, sire 1% 大白：母猪10%、公猪1% Yorkshire: dam 10%, sire 1%
每窝公母猪比例 Ratio of sires and dams per litter	1:1
产仔数Litter size	杜洛克：8头;长白：13头;大白：14头 Duroc: 8; Landrace: 13; Yorkshire: 14
群体更新率Population renewal rate	母猪为60%,公猪为100% Dam: 60%, Sire: 100%
群体结构Population structure N1 N2 N3 N4（待选）To be selected	杜洛克母猪：1000头;长白母猪：500头;大白母猪：2000头;各品种公猪：30头 The dam number of Duroc, Landrace, Yorkshire is 1000, 500, 2000; The sire number of all breeds is 30 杜洛克母猪：1000头;长白母猪：500头;大白母猪：2000头;各品种公猪：30头 The dam number of Duroc, Landrace, Yorkshire is 1000, 500, 2000; The sire number of all breeds is 30 杜洛克母猪：1000头;长白母猪：500头;大白母猪：2000头;各品种公猪：30头 The dam number of Duroc, Landrace, Yorkshire is 1000, 500, 2000; The sire number of all breeds is 30 杜洛克：8000头;长白：6500头;大白：28000头 The number of Duroc, Landrace, Yorkshire is 8000, 6500, 28000
表型个体 Phenotype	N1—N3 每个世代抽取50%的个体,N4世代 The 50% individuals in 1-3 generation and all individuals in 4 generation
基因型个体 Genotype	N1—N3世代共抽取1000头或3000头,N4世代抽取10%或30%的个体 Total 1000 or 3000 individuals 1-3 generation and 10% or 30% individuals in 4 generation

品种 Breed	表型Phenotype		系谱Pedigree		基因型Genotype
品种 Breed	基础群体 Base population	测试群体 Test population	基础群体 Base population	测试群体 Test population	基础群体 Base population	测试群体 Test population
杜洛克Duroc	10500	7000	22030	8802	1000/3000	700/2100
长白Landrace	9000	6000	18530	6906	1000/3000	600/1800
大白Yorkshire	22500	15000	47018	29559	1000/3000	1500/4500

猪基因组选择“两步走”策略的计算机模拟评估

To Evaluate the “Two-Step” Genomic Selection Strategy in Pig by Simulation

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