TMEM232 is required for the formation of sperm flagellum and male fertility in mice.

IF 8.1 1区 生物学 Q1 CELL BIOLOGY Cell Death & Disease Pub Date : 2024-11-08 DOI:10.1038/s41419-024-07200-9
Xinying Cai, Hui Zhang, Shuai Kong, Weilong Xu, Jie Zheng, Ning Wang, Shuai He, Shupei Li, Yiru Shen, Ke Wang, Zengyunou Zhang, Haijian Cai, Fang Ma, Shun Bai, Fuxi Zhu, Fengli Xiao, Fengsong Wang
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Abstract

Asthenoteratozoospermia is a major cause of male infertility. Thus far, the identified related genes can explain only a small share of asthenoteratozoospermia cases, suggesting the involvement of other genes. The transmembrane protein TMEM232 is highly expressed in mouse testes. In the present study, to determine its function of TMEM232 in testes, we constructed a Tmem232-null mouse model using CRISPR-Cas9 technology. Tmem232 knockout (KO) male mice was completely infertile, and their sperm were immotile, with morphological defects of the flagellum. Electron microscopy revealed an aberrant midpiece-principal junction and the loss of the fourth outer microtubule doublet in the sperm of Tmem232-/- mice. Sperm cells presented an 8 + 2 conformation and an irregular arrangement of the mitochondrial sheath. Proteomic analysis revealed altered expression of proteins related to flagellar motility, sperm capacitation, the integrity and stability of sperm structure, especially an upregulated expression of multiple ribosome components in TMEM232-deficient spermatids. Additionally, TMEM232 was observed to be involved in autophagy by interacting with autophagy-related proteins, such as ATG14, to regulate ribosome homeostasis during spermiogenesis. These results suggest that TMEM232, as a potential scaffold protein involving in the correct assembly, distribution, and stability maintenance of certain functional complexes by recruiting key intracellular proteins, is essential for the formation of a highly structured flagellum and plays an important role in the autophagic elimination of cytosolic ribosomes to provide energy for sperm motility.

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小鼠精子鞭毛的形成和雄性生育能力需要 TMEM232。
无精子症是导致男性不育的一个主要原因。迄今为止,已发现的相关基因只能解释一小部分无精子症病例,这表明还有其他基因参与其中。跨膜蛋白 TMEM232 在小鼠睾丸中高度表达。在本研究中,为了确定TMEM232在睾丸中的功能,我们利用CRISPR-Cas9技术构建了Tmem232基因缺失小鼠模型。Tmem232基因敲除(KO)雄性小鼠完全不育,其精子无活力,鞭毛形态缺陷。电子显微镜显示,Tmem232-/-小鼠精子的中段-主连接异常,第四外微管双层缺失。精子细胞呈 8 + 2 构象,线粒体鞘排列不规则。蛋白质组分析表明,与鞭毛运动、精子获能、精子结构的完整性和稳定性有关的蛋白质的表达发生了改变,特别是在TMEM232缺陷的精子中,多种核糖体成分的表达上调。此外,还观察到 TMEM232 与 ATG14 等自噬相关蛋白相互作用,参与了精子发生过程中的自噬,从而调节核糖体的平衡。这些结果表明,TMEM232 作为一种潜在的支架蛋白,通过招募细胞内的关键蛋白参与某些功能复合物的正确组装、分布和稳定性维持,对形成高度结构化的鞭毛至关重要,并在自噬消除细胞质核糖体为精子运动提供能量方面发挥重要作用。
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来源期刊
Cell Death & Disease
Cell Death & Disease CELL BIOLOGY-
CiteScore
15.10
自引率
2.20%
发文量
935
审稿时长
2 months
期刊介绍: Brought to readers by the editorial team of Cell Death & Differentiation, Cell Death & Disease is an online peer-reviewed journal specializing in translational cell death research. It covers a wide range of topics in experimental and internal medicine, including cancer, immunity, neuroscience, and now cancer metabolism. Cell Death & Disease seeks to encompass the breadth of translational implications of cell death, and topics of particular concentration will include, but are not limited to, the following: Experimental medicine Cancer Immunity Internal medicine Neuroscience Cancer metabolism
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