畜禽拷贝数变异研究进展

doi:10.3969/j.issn.1674-7968.2019.10.014

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摘要拷贝数变异(copy number variation, CNV)可能是影响动物表型多样性和进化适应的主要因素之一,通过多种机制对机体进行调节,如基因剂量和转录结构的改变。自首次构建出人类(Homo sapiens)基因组第一代CNV图谱后, CNV在人类和动物中的研究越来越多。研究表明,CNV与人类某些疾病的发病机制、动物的遗传变异以及家畜的重要经济特征有关。本文主要参考国内外相关的研究报道,对CNV的定义、形成机制、检测方法以及畜禽CNV的研究现状进行阐述,总结畜禽CNV研究目前所面临的问题并展望其在遗传育种方面的应用前景,为进一步对CNV的研究提供参考资料。

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关键词 ：拷贝数变异(CNV), 畜禽, 基因组

Abstract：Copy number variation (CNV) might be one main factor that affect the phenotypic diversity and evolutionary adaptation of animals. It uses a variety of mechanisms to regulate the body, such as changes in gene dose and transcription structure. Since the first generation CNV map of the human (Homo sapiens) genome was constructed, CNV has been increasingly studied in humans and animals. At present, studies have shown that CNV is related to the pathogenic mechanism of some human diseases, genetic variation of animals and important economic traits of domestic animals. In this paper, the definition, formation mechanism, detection method and research status of CNV for livestock and poultry were described based on relevant research reports at home and abroad. The problems faced by the research on CNV for livestock and poultry were summarized and the application prospect was prospected. This review provides reference materials for further research on CNV.

Key words： Copy number variation (CNV) Livestock and poultry Genomics

收稿日期: 2019-03-27

ZTFLH:

S823

基金资助:国家肉羊产业技术体系专项(CARS-38)

通讯作者: mxchu@263.net;weicaihong@caas.cn

引用本文:

金美林, 卢曾奎, 李青, 费晓娟, 储明星, 魏彩虹. 畜禽拷贝数变异研究进展[J]. 农业生物技术学报, 2019, 27(10): 1840-1848.
JIN Mei-Lin, LU Zeng-Kui, LI Qing, FEI Xiao-Juan, CHU Ming-Xing, WEI Cai-Hong. Research Progress on Copy Number Variation of Livestock and Poultry. 农业生物技术学报, 2019, 27(10): 1840-1848.

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1 侯成林,王伟,周欢敏,等. 2016. 中国北方绵羊基因组拷贝数变异研究. 中国畜牧兽医, 43(3): 784-790.
(Hou C L, Wang W, Zhou H M, et al.2016. study on genome copy number variation of sheep in northern china[J]. Chinese Animal Husbandry and Veterinary Medicine,43(3): 784-790)
2 黄永震,徐天扬,李丽娟,等. 2018. 牛羊拷贝数变异研究进展[J]. 中国牛业科学,44(4): 55-60.
( Huang Y Z,Xu T Y,Li L J, et al.2018. Research progress of copy number variation of cattle and sheep[J]. China Cattle Science, 44(4): 55-60. )
3 刘和平, 王宏, 陆祖宏, 等. 2003. 一种基于寡核苷酸微阵列芯片的多重可扩增探针杂交技术[J]. 遗传学报, 31(2): 119-124.
(Liu H P, Wang H, Lu Z H, et al.2003. A Novel oligonucleotide arrays-based multiplex amplifiable probe hybridization technology[J]. Acta Genetica Sinica,31(2): 119-124.)
4 刘佳森. 2012. 绵羊全基因组CNV与部分性状的关联分析[D]. 博士学位论文,中国农业科学院,导师: 杜立新,pp. 1.
(Liu J S. 2012. Genome wide CNV association with partial traits in sheep[D]. Thesis for PhD, Chinese Academy of Agricultural Sciences, Suppervisor: Du L X, pp. 1.)
5 卢剑齐, 楼海一, 杨亚军,等. 2014. 中国汉族人群的全基因组CNV分析[C]//中国遗传学会, 遗传学与表观遗传学前沿暨第三届中国青年遗传学家论坛论文摘要汇编, 1.
(Lu J Q, Lou H Y, Yang Y J, et al. 2014. Genome-wide CNV analysis of Chinese han population[C]// Genetics Society of China, Frontier of Genetics and Epigenetics and the Third Session of Chinese young Geneticist BBS, 1.)
6 王维. 2015. 奶山羊扩繁技术_XY精子分选及Y染色体ZNF280BY基因拷贝数变异研究[D]. 博士学位论文,西北农林科技大学,导师: 罗军, pp. 64-71.
(Wang W.2015. Study on breeding techniques, XY sperm sorting, cope number variation of Y-linked ZNF280BY in dairy goat[D]. Thesis for PhD, North West Agriculture and Forestry University, Suppervisor: Luo J, pp. 64-71. )
7 熊业城, 黄永震, 贺花, 等. 2016. 拷贝数变异在动物遗传育种中的研究进展[J]. 中国牛业科学,42(4): 1-5.
(Xiong Y C, Huang Y Z, He H, et al.2016. The research progress of copy number variation in animal genetic breeding[J]. China Cattle Science, 42(4): 1-5. )
8 杨树猛, 岳耀敬, 杨博辉,等. 2011. 应用不对称竞争性PCR技术确定藏羊Agouti基因拷贝重复数[J]. 中国草食动物, 31(5): 5-8.
( Yang S M, Yue Y J, Yang B H,et al.2011. Detecting copy number variations in Agouti gene of tibetan sheep by asymmetric competitive PCR copy number assay[J]. 31(5): 5-8)
9 张成. 2014. 基于高通量测序数据的佩梅病PLP1基因CNV的断点分析[C].//中国遗传学会, 遗传学与表观遗传学前沿暨第三届中国青年遗传学家论坛论文摘要汇编, 1.
(Zhang C.2014. Breakpoint analysis of PLP1 gene CNV of peregrine disease based on high-throughput sequencing data[C].// Genetics Society of China, Frontier of Genetics and Epigenetics and the Third Session of Chinese young Geneticist BBS, 1.)
10 朱才业. 2017. 不同尾型绵羊全基因组关联分析、拷贝数变异及选择信号检测[D]. 博士学位论文,中国农业大学,导师: 杜立新,pp. 10.
(Zhu C Y. 2017. Genome-wide association study, copy number variations and selection signatures detect for the sheep with marketers types of tails[D]. Thesis for PhD, China Agricultural University. Suppervisor: Du L X,pp. 10. )
11 Adams D J, Dermitzakis E T, Cox T, et al.2005. Complex haplotypes, copy number polymorphisms and coding variation in two recently divergent mouse strains[J]. Nature Genetics, 37(5): 532-536.
12 Bae J S, Cheong H S, Kim L H, et al.2010. Identification of copy number variations and common deletion polymorphisms in cattle[J]. BMC Genomics, 11: 232.
13 Bai H, Sun Y, Liu N, et al.2018. Genome-wide detection of CNVs associated with beak deformity in chickens using high-density 600K SNP arrays. Animal Genetics[J], 49: 226-236.
14 Belmont J W, Leal S M.2005. Complex phenotypes and complex genetics: An introduction to genetic studies of complex traits[J]. Current Atherosclerosis Reports,7: 180-187.
15 Chen K, Dong S S, Wu N, et al.2018. A novel multiplex fluorescent competitive PCR for copy number variation detection[J]. Genomics, DOI: 10.1016/j.ygeno.2018.11.029
16 Corbi-Botto C M, Morales-Durand H, Zappa M E, et al.2019. Genomic structural diversity in Criollo Argentino horses: Analysis of copy number variations[J]. Gene, 695: 26-31.
17 da Silva J M, Giachetto P F, da Silva L O, et al.2016. Genome-wide copy number variation (CNV) detection in Nelore cattle reveals highly frequent variants in genome regions harboring QTLs affecting production traits[J]. BMC Genomics,17: 454.
18 Dong Y, Zhang X L, Xie M, et al.2015. Reference genome of wild goat (Capra aegagrus) and sequencing of goat breeds provide insight into genic basis of goat domestication[J]. BMC Genomics,16: 431.
19 Fadista J, Nygaard M, Holm L E, et al.2008. A snapshot of CNVs in the pig genome[J]. PloS One, 3(12): e3916.
20 Feuk L, Carson A R, Scherer S W.2006. Structural variation in the human genome[J]. Nature Reviews, 7: 85-97.
21 Fontanesi L, Beretti F, Martelli P L, et al.2011. A first comparative map of copy number variations in the sheep genome[J]. Genomics, 97: 158-165.
22 Fontanesi L, Martelli P L, Beretti F, et al.2010. An initial comparative map of copy number variations in the goat (Capra hircus) genome[J]. BMC Genomics,11: 639.
23 Meyre D, Delplanque J, Chevre J C, et al.2009. Genome-wide association study for early-onset and morbid adult obesity identifies three new risk loci in European populations[J]. Nature Genetics, 41(2): 157-159.
24 Gu W L, Zhang F, Lupski J R.2008. Mechanisms for human genomic rearrangements[J]. Pathogenetics,1: 4.
25 Guryev V, Saar K, Adamovic T, et al.2008. Distribution and functional impact of DNA copy number variation in the rat[J]. Nature Genetic, 40(5): 538-545.
26 Hastings P J, Lupski J R, Rosenberg S M, et al.2009. Mechanisms of change in gene copy number[J]. Nature Reviews Genetics, 10(8): 551-564.
27 Huang T, Cheng S, Feng Y, et al.2018. A copy number variation generated by complicated organization of PCDHA gene cluster is associated with egg performance traits in Xinhua E-strain[J]. Poult Sci, 97(10): 3435-3445.
28 Iafrate A J, Feuk L, Rivera M N, et al.2004. Detection of large-scale variation in the human genome[J]. Nature Genetics, 36(9): 949-951.
29 Itsara A, Cooper G M, Baker C, et al.2009. Population analysis of large copy number variants and hotspots of human genetic disease[J]. The American Journal of Human Genetics, 84: 148-161.
30 Jenkins G M, Goddard M E, Black M A, et al.2016. Copy number variants in the sheep genome detected using multiple approaches[J]. BMC Genomics,17: 441.
31 Kato M, Nakamura Y, Tsunoda T.2008. An algorithm for inferring complex haplotypes in a region of copy-number variation[J]. The American Journal of Human Genetics, 83: 157-169.
32 Kijas J W, Barendse W, Barris W, et al.2011. Analysis of copy number variants in the cattle genome[J]. Gene, 482: 73-77.
33 Lee J A, Carvalho C M, Lupski J R.et al.2007. A DNA replication mechanism for generating nonrecurrent rearrangements associated with genomic disorders[J]. Cell,131: 1235-1247.
34 Li W L, Bickhart D M, Ramunno L G, et al.2018. Genomic structural differences between cattle and River buffalo identified through comparative genomic and transcriptomic analysis[J]. Data in Brief, 19: 236-239.
35 Lin S D, Lin X R, Zhang Z H, et al.2018. Copy number variation in SOX6 contributes to chicken muscle development[J]. Genes, 9(1): 42.
36 Liu G E, Bickhart D M.2012. Copy number variation in the cattle genome[J]. Functional & Integrative Genomics, 12: 609-624.
37 Liu G E, van Tassel C P, Sonstegard T S, et al.2008. Detection of germline and somatic copy number variations in cattle[J]. Developments in Biologicals, 132: 231-237.
38 Liu J S, Zhang L, Xu L Y, et al.2013. Analysis of copy number variations in the sheep genome using 50K SNP BeadChip array[J]. BMC Genomics, 14: 229.
39 Liu M, Zhou Y, Rosen B D, et al.2019. Diversity of copy number variation in the worldwide goat population[J]. Heredity, 122(5): 636-646.
40 Lye Z N, Purugganan M D.2019. Copy number variation in domestication[J]. Trends in Plant Science, 24(4): 352-365.
41 Ma Q, Liu X X, Pan J F, et al.2017. Genome-wide detection of copy number variation in Chinese indigenous sheep using an ovine high-density 600?K SNP array[J]. Scientific Reports, 7(1): 912.
42 MacDonald J R, Ziman R, Yuen R K C, et al.2013. The database of genomic variants: A curated collection of structural variation in the human genome[J]. Nucleic Acids Research, 42: D986-D992.
43 Matukumalli L K, Lawley C T, Schnabel R D, et al.2009. Development and characterization of a high density SNP genotyping assay for cattle[J]. PloS One, 4(4): e5350.
44 Menzi F, Keller I, Reber I, et al.2016. Genomic amplification of the caprine EDNRA locus might lead to a dose dependent loss of pigmentation[J].Scientific Reports, 6: 28438.
45 Meurens F, Summerfield A, Nauwynck H, et al.2012. The pig: A model for human infectious diseases[J]. Trends in Microbiology, 20(1): 50-57.
46 Pinkel D, Segraves R, Sudar D, et al.1998a. High resolution analysis of DNA copy number variation using comparative genomic hybridization to microarrays[J]. Nature Genetics, 20(2): 207-211.
47 Pinkel D., Segraves R., Sudar D.,et al.1998b. High resolution analysis of DNA copy number variation using comparative genomic hybridization to microarrays[J]. Nature Genetics, 20, 207EP.
48 Ramayo-Caldas Y, Castelló A, Pena R N, et al.2010. Copy number variation in the porcine genome inferred from a 60 k SNP BeadChip[J]. BMC Genomics,11: 593.
49 Ran X Q, Pan H, Huang S H, et al.2018. Copy number variations of MTHFSD gene across pig breeds and its association with litter size traits in Chinese indigenous Xiang pig[J]. Journal of Animal Physiology and Animal Nutrition, 102: 1320-1327.
50 Redon R, Ishikawa S, Fitch K R, et al.2006. Global variation in copy number in the human genome[J]. Nature, 444(7118): 444-454.
51 Rincon G, Weber K L, Eenennaam A L, et al.2011. Hot topic: Performance of bovine high-density genotyping platforms in Holsteins and Jerseys[J]. Journal of Dairy Science, 94(12): 6116-6121.
52 Wang C, Chen H, Wang X, et al.2019a. Identification of copy number variations using high density whole-genome SNP markers in Chinese Dongxiang spotted pigs[J]. Asian-Australas J Anim Sci.
53 Wang H, Chai Z, Hu D, et al.2019b. A global analysis of CNVs in diverse yak populations using whole-genome resequencing. BMC Genomics, 20(1): 61.
54 Wang J, Jiang J, Wang H, et al.2015. Improved detection and characterization of copy number variations among diverse pig breeds by array CGH[J]. 6(5): 1253-1261.
55 Wang X, Byers S.2014. Copy number variation in chickens: A review and future prospects[J]. Microarrays, 3(1): 24-38.
56 Wang X, Nahashon S, Feaster T K, et al.2010. An initial map of chromosomal segmental copy number variations in the chicken[J]. BMC Genomics,11: 351.
57 Xu J W, Zheng L, Li L J, et al.2019. Novel copy number variation of the KLF3 gene is associated with growth traits in beef cattle[J]. Gene, 680: 99-104.
58 Yan J C, Blair H T, Liu M, et al.2017. Genome-wide detection of autosomal copy number variants in several sheep breeds using Illumina OvineSNP50 Bead Chips[J]. Small Ruminant Research, 155: 24-32.
59 Yang L, Xu L, Zhu B, et al.2017. Genome-wide analysis reveals differential selection involved with copy number variation in diverse Chinese cattle[J]. Scientific Reports, 7(1): 14299.
60 Yang L, Xu L, Zhou Y, et al.2018. Diversity of copy number variation in a worldwide population of sheep[J]. Genomics, 110(3): 143-148.
61 Zhang R Q, Wang J J, Zhang T, et al.2019. Copy-number variation in goat genome sequence: A comparative analysis of the different litter size trait groups[J]. Gene, 696: 40-46.
62 Zhu C, Fan H, Yuan Z, et al.2016. Genome-wide detection of CNVs in Chinese indigenous sheep with different types of tails using ovine high-density 600K SNP arrays[J]. Scientific Reports, 6: 27822.
63 Zimin A V, Delcher A L, Florea L, et al.2009. A whole-genome assembly of the domestic cow, Bos taurus[J]. Genome Biology, 10(4): R42.