Exocyst complex component 1 (Exoc1) loss in dormant oocyte disrupts c-KIT and growth differentiation factor (GDF9) subcellular localization and causes female infertility in mice.

IF 6.1 2区生物学 Q1 CELL BIOLOGY

Cell Death Discovery Pub Date : 2025-01-20 DOI:10.1038/s41420-025-02291-5

Chi Lieu Kim Nguyen, Yumeno Kuba, Hoai Thu Le, Hossam Hassan Shawki, Natsuki Mikami, Madoka Aoki, Nanako Yasuhara, Hayate Suzuki, Saori Mizuno-Iijima, Shinya Ayabe, Yuki Osawa, Tomoyuki Fujiyama, Tra Thi Huong Dinh, Miyuki Ishida, Yoko Daitoku, Yoko Tanimoto, Kazuya Murata, Woojin Kang, Masatsugu Ema, Yuji Hirao, Atsuo Ogura, Satoru Takahashi, Fumihiro Sugiyama, Seiya Mizuno

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引用次数: 0

Abstract

A limited number of female germ cells support reproduction in many mammals. The follicle, composed of oocytes and supporting granulosa cells, forms the basis of oogenesis. Crosstalk between oocytes and granulosa cells is essential for the formation, dormancy, re-awakening, and maturation of oocytes. The oocyte expresses c-KIT and growth differentiation factor-9 (GDF-9), which are major factors in this crosstalk. The downstream signalling pathways of c-KIT and GDF-9 have been well-documented; however, their intra-oocyte trafficking pathway remains unclear. Our study reveals that the exocyst complex, a heterotetrameric protein complex important for tethering in vesicular transport, is important for proper intra-oocyte trafficking of c-KIT and GDF9 in mice. We found that depletion of oocyte-specific EXOC1, a component of the exocyst complex, impaired oocyte re-awakening and cyst breakdown, and inhibited granulosa cell proliferation during follicle growth. The c-KIT receptor is localised on the oocyte plasma membrane. The oocyte-specific Kit conditional knockout mice were reported to exhibit impaired oocyte re-awakening and reduced oocyte cyst breakdown. GDF9 is a protein secreted extracellularly in the oocyte. Previous studies have shown that Gdf9 knockout mice impaired proliferation and granulosa cell multilayering in growing follicles. We found that both c-KIT and GDF9 abnormally stuck in the EXOC1-depleted oocyte cytoplasm. These abnormal phenotypes were also observed in oocytes depleted of exocyst complex members EXOC3 and EXOC7. These results clearly show that the exocyst complex is essential for proper intra-oocyte trafficking of c-KIT and GDF9. Inhibition of this complex causes complete loss of female fertility in mice. Our findings build a platform for research related to trafficking mechanisms of vital crosstalk factors for oogenesis.

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小鼠休眠卵母细胞中Exoc1复合物组分（Exoc1）的丢失破坏了c-KIT和生长分化因子（GDF9）亚细胞定位，导致雌性不育。

在许多哺乳动物中，数量有限的雌性生殖细胞支持生殖。卵泡由卵母细胞和辅助性颗粒细胞组成，是卵子发生的基础。卵母细胞和颗粒细胞之间的串扰对卵母细胞的形成、休眠、再唤醒和成熟至关重要。卵母细胞表达c-KIT和生长分化因子-9 (GDF-9)，它们是这种串扰的主要因子。c-KIT和GDF-9的下游信号通路已被充分记录；然而，它们在卵母细胞内的运输途径尚不清楚。我们的研究表明，胞囊复合体是一种异四聚体蛋白复合体，在囊泡运输中对系住很重要，对小鼠卵母细胞内c-KIT和GDF9的适当运输很重要。我们发现，卵母细胞特异性EXOC1（胞囊复合体的一个组成部分）的缺失会损害卵母细胞的重新觉醒和囊肿破裂，并抑制卵泡生长过程中的颗粒细胞增殖。c-KIT受体定位于卵母细胞质膜上。据报道，卵母细胞特异性Kit条件敲除小鼠表现出卵母细胞重新觉醒受损和卵母细胞囊肿破裂减少。GDF9是一种在卵母细胞外分泌的蛋白。先前的研究表明，Gdf9基因敲除小鼠会损害生长卵泡的增殖和颗粒细胞的多层性。我们发现c-KIT和GDF9都异常地停留在exoc1缺失的卵母细胞细胞质中。在囊胞复合体EXOC3和EXOC7成员缺失的卵母细胞中也观察到这些异常表型。这些结果清楚地表明，胞囊复合物对于c-KIT和GDF9在卵母细胞内的适当运输至关重要。抑制这种复合物会导致雌性小鼠完全丧失生育能力。我们的发现为研究与卵子发生相关的重要相声因子的传输机制建立了一个平台。

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

Cell Death Discovery Biochemistry, Genetics and Molecular Biology-Cell Biology

CiteScore

8.30

自引率

1.40%

发文量

468

审稿时长

9 weeks

期刊介绍： Cell Death Discovery is a multidisciplinary, international, online-only, open access journal, dedicated to publishing research at the intersection of medicine with biochemistry, pharmacology, immunology, cell biology and cell death, provided it is scientifically sound. The unrestricted access to research findings in Cell Death Discovery will foster a dynamic and highly productive dialogue between basic scientists and clinicians, as well as researchers in industry with a focus on cancer, neurobiology and inflammation research. As an official journal of the Cell Death Differentiation Association (ADMC), Cell Death Discovery will build upon the success of Cell Death & Differentiation and Cell Death & Disease in publishing important peer-reviewed original research, timely reviews and editorial commentary. Cell Death Discovery is committed to increasing the reproducibility of research. To this end, in conjunction with its sister journals Cell Death & Differentiation and Cell Death & Disease, Cell Death Discovery provides a unique forum for scientists as well as clinicians and members of the pharmaceutical and biotechnical industry. It is committed to the rapid publication of high quality original papers that relate to these subjects, together with topical, usually solicited, reviews, editorial correspondence and occasional commentaries on controversial and scientifically informative issues.