Jie Gan, Long Yang, Shu-Han Yang, Wen-Wen Gu, Yan Gu, Yan Shi, Jia-Xin Shi, Hao-Ran Xu, Ya-Wei Xin, Xuan Zhang, Jian Wang
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引用次数: 0
摘要
目的:复发性流产(RM)是一种令人痛苦和复杂的妊娠不良结局。人们普遍认为,去个体化不足可能导致RM,但个体损伤的分子机制仍未完全了解。因此,本研究旨在鉴定可能参与RM的新的关键基因,并探讨其在子宫内膜去个体化中的作用。方法:首先,对蜕膜和中期分泌子宫内膜转录组进行组合分析,以发现与RM病因有关的枢纽基因。并在原代蜕膜间质细胞(DSCs)和蜕膜组织中检测hub基因的表达水平。随后,使用永生化的人子宫内膜细胞系T-HESCs,研究FXYD1过表达是否通过调节Na/ k - atp酶活性影响去细胞化。结果:通过多种生物信息学方法,FXYD结构域含离子转运调节因子1 (FXYD1)被确定为RM发病的枢纽基因。与正常组相比,RM患者的dsc和蜕膜组织中FXYD1表达异常升高。此外,FXYD1的过表达明显抑制了体外脱体细胞化。此外,Na/ k - atp酶活性在去个体化过程中显著升高,而FXYD1的过表达降低了Na/ k - atp酶活性。蟾毒灵是一种Na/ k - atp酶抑制剂,对去个别化具有有效的抑制作用。结论:总的来说,FXYD1是与RM相关的枢纽基因,其在RM患者中的表达水平显著上调。FXYD1表达增加可能通过降低Na/K-ATPase活性导致去个体化缺陷,这为RM提供了一个新的前瞻性治疗靶点。
FXYD1 was identified as a hub gene in recurrent miscarriage and involved in decidualization via regulating Na/K-ATPase activity.
Purpose: Recurrent miscarriage (RM) is a distressing and complicated adverse pregnancy outcome. It is commonly recognized that insufficient decidualization could result in RM, but the molecular mechanisms of decidual impairment are still not fully understood. Thus, this study aimed to identify novel key genes potentially involved in RM and explore their roles played in endometrial decidualization.
Methods: Initially, a combinative analysis of decidual and mid-secretory endometrial transcriptomes was performed to discover hub genes involved in the etiology of RM. And the expression levels of hub genes were evaluated in both primary decidual stromal cells (DSCs) and decidual tissues. Subsequently, the immortalized human endometrial cell line, T-HESCs, was used to investigate whether FXYD1 overexpression affects decidualization by regulating Na/K-ATPase activity.
Results: FXYD domain containing ion transport regulator 1 (FXYD1) was identified as a hub gene in the pathogenesis of RM through various bioinformatic methods. Abnormally increased FXYD1 expression was observed in DSCs and decidual tissues from RM patients compared to that of the normal group. Furthermore, in vitro decidualization was obviously inhibited by the overexpression of FXYD1. Additionally, Na/K-ATPase activity was significantly elevated during decidualization, whereas overexpression of FXYD1 reduced Na/K-ATPase activity. Bufalin, a Na/K-ATPase inhibitor, showed an effectively inhibitory effect on decidualization.
Conclusions: Collectively, FXYD1 was discovered as a hub gene associated with RM, and its expression levels in RM patients were significantly upregulated. Increased FXYD1 expression might lead to decidualization defects by reducing Na/K-ATPase activity, of which presented a novel prospective treatment target for RM.
期刊介绍:
The Journal of Assisted Reproduction and Genetics publishes cellular, molecular, genetic, and epigenetic discoveries advancing our understanding of the biology and underlying mechanisms from gametogenesis to offspring health. Special emphasis is placed on the practice and evolution of assisted reproduction technologies (ARTs) with reference to the diagnosis and management of diseases affecting fertility. Our goal is to educate our readership in the translation of basic and clinical discoveries made from human or relevant animal models to the safe and efficacious practice of human ARTs. The scientific rigor and ethical standards embraced by the JARG editorial team ensures a broad international base of expertise guiding the marriage of contemporary clinical research paradigms with basic science discovery. JARG publishes original papers, minireviews, case reports, and opinion pieces often combined into special topic issues that will educate clinicians and scientists with interests in the mechanisms of human development that bear on the treatment of infertility and emerging innovations in human ARTs. The guiding principles of male and female reproductive health impacting pre- and post-conceptional viability and developmental potential are emphasized within the purview of human reproductive health in current and future generations of our species.
The journal is published in cooperation with the American Society for Reproductive Medicine, an organization of more than 8,000 physicians, researchers, nurses, technicians and other professionals dedicated to advancing knowledge and expertise in reproductive biology.
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