Somatic Transthyretin-Related Proteins in C. elegans Govern Reproductive Longevity by Sustaining Sperm Integrity and Timely Ovulation

bioRxiv - Developmental Biology Pub Date : 2024-09-15 DOI:10.1101/2024.09.13.612966

Tingshan Wu, Haochen Lyu, Zhao Wang, Zhaoyang Jiang, Yingchuan B. Qi

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Abstract

The decline in reproductive capability during adult life is critical for health, but its mechanism is elusive. We systematically analyzed the developmental role of an expanded TTR family of proteins, structurally analogous to mammalian thyroid hormone-transporting Transthyretin, and identified three paralogous proteins, TTR-15, TTR-16, and TTR-17, differentially expressed in somatic cells of the gonads and secreted around gametes in C. elegans. Simultaneous inactivation of TTR-15, TTR-16, and TTR-17 leads to a rapid reduction in reproductive capacity in middle age. While oocyte and sperm production remain unaffected in the triple mutants, late-onset infertility results from stalled ovulation. Mechanistically, the absence of TTR-15, TTR-16, and TTR-17 causes sperm to prematurely deplete the cytoplasmic pool of major sperm protein (MSP), released via non-conventional vesicle budding as a signal for ovulation. We propose that the somatic gonads play a central role in maintaining sperm integrity post-production and determining the duration of the reproductive age.

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秀丽隐杆线虫体细胞转甲状腺素相关蛋白通过维持精子完整性和适时排卵调节生殖寿命

成年后生殖能力的下降对健康至关重要，但其机制却难以捉摸。我们系统分析了结构类似于哺乳动物甲状腺激素转运蛋白Transthyretin的TTR家族扩增蛋白的发育作用，并发现了三个同族蛋白TTR-15、TTR-16和TTR-17，它们在优雅鼠的性腺体细胞中不同程度地表达，并在配子周围分泌。TTR-15、TTR-16 和 TTR-17 同时失活会导致中年生殖能力迅速下降。虽然三重突变体的卵母细胞和精子生成不受影响，但排卵停滞会导致晚期不育。从机理上讲，TTR-15、TTR-16 和 TTR-17 的缺失会导致精子过早耗尽细胞质中的主要精子蛋白（MSP），而主要精子蛋白是通过非常规囊泡萌发作为排卵信号释放的。我们提出，体细胞性腺在维持精子生成后的完整性和决定生殖年龄的持续时间方面发挥着核心作用。

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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bioRxiv - Developmental Biology

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