{"title":"将代谢组学融入繁殖:猪的精子代谢和繁殖力提高。","authors":"","doi":"10.1016/j.anireprosci.2024.107539","DOIUrl":null,"url":null,"abstract":"<div><div><span><span><span>The last decades of research have revealed that many other factors besides gamete genomes are able to determine the reproductive outcomes. Indeed, paternal factors have been observed to be capable of modulating multiple crucial features of the reproductive process, such as </span>sperm physiology<span>, the maternal environment and, even, the offspring health. These recent advances have been encompassed with the emergence of OMICS technologies, as they comprehensively characterise the molecular composition of biological systems. The present narrative review aimed to take a closer look at the potential of these technologies in the field of reproductive biology. This literature revision shows that most studies up to date have followed a non-targeted approach to screen mammalian seminal plasma (SP) and sperm metabolite composition through different </span></span>metabolome platforms. These studies have proposed metabolites of multiple natures as potential </span><em>in vivo</em><span><span><span><span> fertility biomarkers. Yet, targeted approaches can be used to answer specific biological question, and their power is exemplified herein. For instance, metabolomic studies have uncovered not only that glycolysis is the main ATP energy source of </span>pig sperm, but also that sperm metabolism can trigger DNA damage, hence compromise </span>embryo development. In conclusion, this review shows the potential of both non-targeted and targeted metabolomics for the discovery of cell pathways that govern the reproductive process. Understanding these systems could help make progress in different areas, including </span>livestock efficient breeding, the improvement of artificial reproductive technologies, and the development of biomarkers for infertility detection.</span></div></div>","PeriodicalId":7880,"journal":{"name":"Animal Reproduction Science","volume":"269 ","pages":"Article 107539"},"PeriodicalIF":2.2000,"publicationDate":"2024-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Integrating metabolomics into reproduction: Sperm metabolism and fertility enhancement in pigs\",\"authors\":\"\",\"doi\":\"10.1016/j.anireprosci.2024.107539\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><div><span><span><span>The last decades of research have revealed that many other factors besides gamete genomes are able to determine the reproductive outcomes. Indeed, paternal factors have been observed to be capable of modulating multiple crucial features of the reproductive process, such as </span>sperm physiology<span>, the maternal environment and, even, the offspring health. These recent advances have been encompassed with the emergence of OMICS technologies, as they comprehensively characterise the molecular composition of biological systems. The present narrative review aimed to take a closer look at the potential of these technologies in the field of reproductive biology. This literature revision shows that most studies up to date have followed a non-targeted approach to screen mammalian seminal plasma (SP) and sperm metabolite composition through different </span></span>metabolome platforms. These studies have proposed metabolites of multiple natures as potential </span><em>in vivo</em><span><span><span><span> fertility biomarkers. Yet, targeted approaches can be used to answer specific biological question, and their power is exemplified herein. For instance, metabolomic studies have uncovered not only that glycolysis is the main ATP energy source of </span>pig sperm, but also that sperm metabolism can trigger DNA damage, hence compromise </span>embryo development. In conclusion, this review shows the potential of both non-targeted and targeted metabolomics for the discovery of cell pathways that govern the reproductive process. 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引用次数: 0
摘要
过去几十年的研究表明,除了配子基因组之外,还有许多其他因素能够决定生殖结果。事实上,人们已经观察到父系因素能够调节生殖过程的多个关键特征,如精子生理、母体环境甚至后代健康。这些最新进展与 OMICS 技术的出现密不可分,因为它们能全面描述生物系统的分子组成。本综述旨在仔细研究这些技术在生殖生物学领域的潜力。文献综述显示,迄今为止的大多数研究都采用非靶向方法,通过不同的代谢组平台筛选哺乳动物精浆(SP)和精子的代谢物组成。这些研究提出将多种性质的代谢物作为潜在的体内生育能力生物标志物。然而,有针对性的方法可用于回答特定的生物学问题,本文将举例说明这些方法的威力。例如,代谢组学研究不仅发现糖酵解是猪精子的主要 ATP 能量来源,还发现精子代谢可引发 DNA 损伤,从而影响胚胎发育。总之,本综述显示了非靶向和靶向代谢组学在发现支配生殖过程的细胞通路方面的潜力。了解这些系统有助于在不同领域取得进展,包括家畜高效育种、人工繁殖技术的改进以及不育症检测生物标志物的开发。
Integrating metabolomics into reproduction: Sperm metabolism and fertility enhancement in pigs
The last decades of research have revealed that many other factors besides gamete genomes are able to determine the reproductive outcomes. Indeed, paternal factors have been observed to be capable of modulating multiple crucial features of the reproductive process, such as sperm physiology, the maternal environment and, even, the offspring health. These recent advances have been encompassed with the emergence of OMICS technologies, as they comprehensively characterise the molecular composition of biological systems. The present narrative review aimed to take a closer look at the potential of these technologies in the field of reproductive biology. This literature revision shows that most studies up to date have followed a non-targeted approach to screen mammalian seminal plasma (SP) and sperm metabolite composition through different metabolome platforms. These studies have proposed metabolites of multiple natures as potential in vivo fertility biomarkers. Yet, targeted approaches can be used to answer specific biological question, and their power is exemplified herein. For instance, metabolomic studies have uncovered not only that glycolysis is the main ATP energy source of pig sperm, but also that sperm metabolism can trigger DNA damage, hence compromise embryo development. In conclusion, this review shows the potential of both non-targeted and targeted metabolomics for the discovery of cell pathways that govern the reproductive process. Understanding these systems could help make progress in different areas, including livestock efficient breeding, the improvement of artificial reproductive technologies, and the development of biomarkers for infertility detection.
期刊介绍:
Animal Reproduction Science publishes results from studies relating to reproduction and fertility in animals. This includes both fundamental research and applied studies, including management practices that increase our understanding of the biology and manipulation of reproduction. Manuscripts should go into depth in the mechanisms involved in the research reported, rather than a give a mere description of findings. The focus is on animals that are useful to humans including food- and fibre-producing; companion/recreational; captive; and endangered species including zoo animals, but excluding laboratory animals unless the results of the study provide new information that impacts the basic understanding of the biology or manipulation of reproduction.
The journal''s scope includes the study of reproductive physiology and endocrinology, reproductive cycles, natural and artificial control of reproduction, preservation and use of gametes and embryos, pregnancy and parturition, infertility and sterility, diagnostic and therapeutic techniques.
The Editorial Board of Animal Reproduction Science has decided not to publish papers in which there is an exclusive examination of the in vitro development of oocytes and embryos; however, there will be consideration of papers that include in vitro studies where the source of the oocytes and/or development of the embryos beyond the blastocyst stage is part of the experimental design.