Anti-Mullerian hormone (AMH) protects ovarian follicle loss by downregulating granulosa cell function in in vitro and in vivo models.

IF 3.2 3区医学 Q2 GENETICS & HEREDITY

Journal of Assisted Reproduction and Genetics Pub Date : 2025-06-01 Epub Date: 2025-04-08 DOI:10.1007/s10815-025-03473-x

Laura Detti, Michael C Mari, Michael P Diamond, Ghassan M Saed

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引用次数: 0

Abstract

Purpose: AMH inhibits hormone production in luteinized granulosa cells (GCs) and stalls ovarian follicle development in vitro and in vivo. We sought to confirm AMH's mechanism of action through SMAD activation and investigate AMH inhibition of follicle development and function, in vitro and in vivo.

Methods: A primary culture of GCs isolated from follicular fluid was used, and cells were treated with recombinant AMH (rAMH) or placebo for 24 h. For the mouse model, 18-weeks old C57BL female mice were either euthanized at the beginning or treated with rAMH or normal saline for 3 weeks. Primordial (PDF), primary follicle (PRF), secondary (SEF), and tertiary follicles (TEF) were calculated. Real-time RT-PCR and ELISA were performed to quantify GC gene expression and protein translation of human SMAD 1, 5, and 8, FSH-R and mouse FSH-R, inhibin B, caspase 3, Ki67, BMP15, GDF9, and the epigenetic regulators miRNAa and b.

Results: In vitro, rAMH-treated GC showed activation of the SMAD 1, 5 and downregulation of SMAD 8, with greater magnitude at increasing rAMH doses (p < 0.04) and consequential control of downstream regulators. In vivo, the rAMH-treated mice showed increased SEFs and decreased PRFs while PDFs, TEFs, were unchanged compared with baseline. Compared with Placebo, the rAMH group showed increased PDFs, while PRFs, and TEFs were significantly decreased, and SEFs were unchanged.

Conclusions: AMH caused SMAD activation in a dose-dependent manner, with downstream downregulation of cell function and replication, also through activation of miRNAs. These mechanisms were confirmed by the in vivo findings with ultimate downregulation of follicular development and preservation of the ovarian follicle number. Counteracting follicular depletion, AMH could be used to protect the ovarian follicle reservoir.

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在体外和体内模型中，抗苗勒管激素（AMH）通过下调颗粒细胞功能来保护卵巢卵泡丢失。

目的：在体外和体内研究AMH抑制黄体化颗粒细胞（GCs）中激素的产生，并延缓卵巢卵泡的发育。我们试图通过激活SMAD来证实AMH的作用机制，并在体外和体内研究AMH对卵泡发育和功能的抑制作用。方法：采用从卵泡液中分离的GCs原代培养，用重组AMH （rAMH）或安慰剂处理细胞24 h。小鼠模型采用18周龄C57BL雌性小鼠开始安乐死或rAMH或生理盐水处理3周。计算原始卵泡（PDF）、初级卵泡（PRF）、次级卵泡（SEF）和第三次卵泡（TEF）。采用Real-time RT-PCR和ELISA技术，定量测定了人SMAD 1、5和8、FSH-R和小鼠FSH-R、抑制素B、caspase 3、Ki67、BMP15、GDF9以及表观遗传调控因子miRNAa和B的GC基因表达和蛋白翻译。结果：rAMH处理的GC在体外表现出SMAD 1、5的激活和SMAD 8的下调，且rAMH剂量越大，下游调控因子越低（p < 0.04）。在体内，ramh处理小鼠的SEFs增加，PRFs降低，而pdf和TEFs与基线相比没有变化。与安慰剂相比，rAMH组的pdf增加，而prf和tef显著降低，sef不变。结论：AMH以剂量依赖的方式引起SMAD的激活，并通过mirna的激活，下游下调细胞功能和复制。这些机制被体内研究结果证实，最终下调卵泡发育并保留卵巢卵泡数量。对抗卵泡衰竭，AMH可用于保护卵巢卵泡库。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Assisted Reproduction and Genetics 医学-妇产科学

CiteScore

5.70

自引率

9.70%

发文量

286

审稿时长

1 months

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.