China Dairy ›› 2021, Vol. 0 ›› Issue (6): 16-22.doi: 10.12377/1671-4393.21.06.03

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40 Years of Bovine IVF in the Context of Genome Selection

CAI Gaozhan1, ZHANG Rumei1, WANG Yaqin2, HUANG Guofeng3, LI Junting4, LIU Xiaotao5, YAO Wenlong6, ZHOU Hao4, LI Jianbin1, ZHONG Jifeng1,*   

  1. 1Institute of animal husbandry and veterinary medicine,Academy of Agricultural Sciences,Jinan Shandong 250100;
    2Agricultural village Bureau,Ningbo Zhejiang 315033;
    3Agricultural and rural Office of Lubu Town,Yuyao Zhejiang 315420;
    4Agricultural and rural Bureau of Yinzhou District,Ningbo Zhejiang 315100;
    5Ningbo Milk Group Co.,Ltd,Ningbo Zhejiang 315033;
    6Yingshan cattle farm,Zhanqi Town,Yinzhou District,Ningbo Zhejiang 315100
  • Online:2021-06-25 Published:2021-07-08

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Abstract: The development of complex technologies such as in vitro fertilization (IVF) needs many years of experiments,sometimes it is necessary to compare several species,to understand how to create a suitable in vitro environment for oocytes,sperm and early embryos.The physiological function of gametes and gamete interaction are recently evolved traits,which must be analyzed in the context of each species.In the past 40 years after Louis Brown was born,IVF technology has made great progress and has been applied in a variety of domestic and non domestic animal species all over the world. However,this does not mean that the technology is completely mature or satisfactory.There are still many problems to be solved and some programs to be optimized.Since IVF technology was allowed to be commercialized,the development of cow IVF has attracted special attention.Its scale of use is comparable to that of human IVF (millions of newborns).The combination of genomic selection,sex identification and cryopreservation of calves and even embryos is pushing IVF into a new era.This paper reviews the success and shortcomings of IVF in cattle in the past 40 years, and describes the challenges to be overcome in the next few years.

Key words: genome selection, in vitro fertilization, cow, progress

[1] Hasler, John F.Forty years of embryo transfer in cattle: A review focusing on the journal Theriogenology, the growth of the industry in North America, and personal reminisces[J]. Theriogenology. 2014, 81(1): 152-169.
[2] Daub K, Lindemann S, Langer H, et al.The history of assisted human conception with especial reference to endocrinology.[J]. Experimental & Clinical Endocrinology & Diabetes. 1996, 104(03): 183-204.
[3] Brackett B G, Daniel B, Boice M L, et al.Normal development following in vitro fertilization in the cow.[J]. Biology of Reproduction. 1982(1): 147-158.
[4] Parrish, John J.Bovine in vitro fertilization: in vitro oocyte maturation and sperm capacitation with heparin.[J]. Theriogenology. 2014, 81(1): 67-73.
[5] Parrish J J, Susko-Parrish J L, Leibfried-Rutledge M L, et al. Bovine in vitro fertilization with frozen-thawed semen[J]. Theriogenology. 1986, 25(4): 591-600.
[6] Edwards R G.Maturation in vitro of Mouse, Sheep, Cow, Pig, Rhesus Monkey and Human Ovarian Oocytes[J]. Nature. 1965, 208(5008): 349-351.
[7] Felmer R N, Arias M E, Mu Oz G A, et al. Effect of different sequential and two-step culture systems on the development, quality, and RNA expression profile of bovine blastocysts produced in vitro.[J]. Molecular Reproduction & Development. 2011, 78(6): 403-414.
[8] Lu K H, Gordon I, Gallagher M, et al.Pregnancy established in cattle by transfer of embryos derived from in vitro fertilisation of oocytes matured in vitro.[J]. Veterinary Record. 1987, 121(11): 259.
[9] Ball G D, Leibfried M L, Ax R L, et al.Maturation and fertilization of bovine oocytes in vitro[J]. Journal of Dairy Science. 1984, 67(11): 2775-2785.
[10] Leemans B, Gadella B M, Stout T, et al.Why doesn't conventional IVF work in the horse? The equine oviduct as a microenvironment for capacitation/fertilization[J]. Reproduction. 2016, 152(6): R233.
[11] Douville G, Sirard M A.Changes in granulosa cells gene expression associated with growth, plateau and atretic phases in medium bovine follicles[J]. Journal of Ovarian Research. 2014, 7.
[12] Dias F, Khan M, Sirard M A, et al.Differential gene expression of granulosa cells after ovarian superstimulation in beef cattle.[J]. Reproduction. 2013, 146(2): 181-191.
[13] Nivet A L, Bunel A, Labrecque R, et al.FSH withdrawal improves developmental competence of oocytes in the bovine model[J]. Reproduction. 2012, 143(2): 165-171.
[14] Khan D R, Landry D A, Fournier É, et al.Transcriptome meta-analysis of three follicular compartments and its correlation with ovarian follicle maturity and oocyte developmental competence in cows[J]. Physiological Genomics. 2016, 48(8): 633-643.
[15] Lonergan P, Fair T.In vitro-produced bovine embryos: dealing with the warts.[J]. Theriogenology. 2008, 69(1): 17-22.
[16] Cagnone G, Sirard M A.The embryonic stress response to in vitro culture: insight from genomic analysis[J]. Reproduction. 2016: 16-391.
[17] Sirard A. M.The influence of in vitro fertilization and embryo culture on the embryo epigenetic constituents and the possible consequences in the bovine model[J]. Journal of Developmental Origins of Health & Disease. 2017: 1.
[18] Yum S Y, Youn K Y, Choi W J, et al.Development of genome engineering technologies in cattle: from random to specific[J]. Journal of Animal Science & Biotechnology. 2018, 9(1): 16.
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