公牛精原干细胞生物学:分离、培养和移植方法的发展及其对牛生产的潜在影响。

J. Oatley
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引用次数: 18

摘要

人工授精作为一种育种方法的广泛采用,已经允许扩大使用特定品种的理想基因,并极大地影响了全世界奶牛种群的生产性状。事实上,2009年美国平均每头奶牛的产奶量是1940年人工授精商业化开始时的4.5倍。虽然许多因素促成了牛奶产量水平的快速增长,但通过扩大利用来自特定奶牛的种系而获得的遗传增益是一个主要贡献。相比之下,由于实施成功所需的集约化管理战略的挑战,在肉牛种群中人工授精的使用受到限制。因此,需要替代生殖工具,以扩大在肉牛工业中使用理想的雄性遗传学。精子产生的过程,称为精子发生,是由组织特异性干细胞群称为精原干细胞(ssc)支持的。这些独特的细胞在移植后具有无限自我更新和长期再生精子的能力。在啮齿类动物中,已经设计了分离、培养和移植ssc的方法。对于肉牛来说,将从供体雄性中分离的ssc移植到供体雄性的睾丸中,从而发生供体来源的精子发生,并通过自然育种产生具有供体遗传的后代,作为人工授精的替代方案具有很大的潜力。这种潜在的生殖策略将允许从理想的品种中广泛使用遗传学,从而克服人工授精的后勤挑战。将啮齿类动物的方法转化为牛的方法是发展的前沿。设计从供体睾丸中分离ssc富集细胞的方法和确定支持牛ssc在体外长期维持和增殖的条件是两种工具,这将大大加快移植成为养牛业商业上可行选择的步伐。最近的研究表明,ssc表达THY1在啮齿动物和牛之间是一种保守的表型,从供体睾丸中选择THY1 +片段可用于分离富含ssc的生殖细胞群体。此外,为扩大体外培养啮齿动物间充质干细胞数量而设计的条件继续作为开发支持牛间充质干细胞条件的基础。有了这些工具,未来十年将在开发可实施的带有ssc的用于商业牛生产的生殖工具方面取得重大进展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Spermatogonial stem cell biology in the bull: development of isolation, culture, and transplantation methodologies and their potential impacts on cattle production.
Widespread adoption of artificial insemination as a breeding practice has allowed for expanded use of desirable genetics from specific sires and greatly influenced production traits in dairy cattle populations worldwide. In fact, the average dairy cow in the US in 2009 produced 4.5 times more milk than in 1940 when commercialization of artificial insemination began. While many factors have contributed to this rapid increase in levels of milk production, genetic gain through expanded utilization of germlines from specific sires has been a major contribution. In comparison, use of artificial insemination in beef cattle populations has been limited due to challenges with implementing intensive management strategies required for success. Thus, there is need for alternative reproductive tools to expand use of desirable male genetics in the beef cattle industry. The process of sperm production, termed spermatogenesis, is supported by a tissue-specific stem cell population referred to as spermatogonial stem cells (SSCs). These unique cells have the capacity for infinite self-renewal and long-term regeneration of spermatogenesis following transplantation. In rodents, methods for isolating, culturing, and transplanting SSCs have been devised. For beef cattle, transplanting SSCs isolated from a donor male into the testes of recipient males in which donor-derived spermatogenesis occurs and offspring with donor genetics are produced from natural breeding has great potential as an alternative to artificial insemination. This potential reproductive strategy would allow for expansive use of genetics from desirable sires that overcomes the logistical challenges of artificial insemination. Translation of the methods devised for rodents to cattle is at the forefront of development. Devising means for isolating an SSC-enriched cell fraction from donor testes and identifying conditions that support long-term maintenance and proliferation of bovine SSCs in vitro are two tools that would greatly accelerate the pace at which transplantation will become a commercially viable option for cattle industries. Recent studies showed that expression of THY1 by SSCs is a conserved phenotype between rodents and cattle, and selection of the THY1 + fraction from donor testes can be used for isolating an SSC-enriched germ cell population. In addition, the conditions devised for expanding the number of rodent SSCs in vitro continues to serve as the basis for developing conditions that support bovine SSCs. With these tools in hand major advances in developing implementable reproductive tools with SSCs for commercial cattle production will be made in the coming decade.
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