Drosophila AK-3, a homolog of human CKMT1B, is essential for spermiogenesis.

IF 3.7 3区生物学 Q1 DEVELOPMENTAL BIOLOGY

Reproduction Pub Date : 2025-03-03 Print Date: 2025-04-01 DOI:10.1530/REP-24-0358

Meng-Yan Chen, Qian Zhao, Ying-Ying Wang, Yue Ren, Zhi-Xian Cao, Bin Mao, Hao-Lin Wang, Yu-Feng Wang

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Abstract

In brief: The assembly and maintenance of axonemal microtubules during spermatogenesis is essential for production of functional sperm. This study shows that arginine kinase 3 (AK-3) (human ortholog CKMT1B) is necessary for Drosophila spermiogenesis and its biological function is conserved from flies to humans.

Abstract: Spermatogenesis is a conserved process across animals, involving the proliferation and maintenance of germ stem cells, haploid spermatid production via meiosis and the generation of mature sperm with unique shapes. Our previous studies revealed that after ocnus (ocn) knockdown in germlines, the male flies Drosophila melanogaster were sterile, and the expression levels of many proteins were significantly changed. Among these proteins, CG4546 (arginine kinase 3, AK-3) was drastically downregulated, implying its crucial role in fly spermatogenesis. Here, we demonstrate that AK-3 was highly expressed in Drosophila testes. Knockdown of the AK-3 in testes leads to scattered nuclear bundles, loss of the central paired microtubule in the flagellar axoneme, disrupted individualization complexes, lack of mature sperm in seminal vesicles and thus resulting in male complete infertility. Notably, Drosophila AK-3 shares homology with human CKMT1B. Expression of human CKMT1B can rescue the defects in late spermatogenesis and male sterility caused by AK-3 knockdown in flies, indicating that this gene is evolutionarily and functionally conserved. These results suggest that AK-3 contributes to the regulation of spermiogenesis, especially the assembly and stabilizing of the axonemal microtubules during the sperm elongation. These data substantiate the importance of arginine kinase during spermatogenesis and its evolutionary conservation, and might provide fundamental information for studying the function of CKMT1B in male fertility in humans.

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果蝇AK-3是人类CKMT1B的同源物，对精子发生至关重要。

精子发生是一个保守的过程，涉及生殖干细胞的增殖和维持，通过减数分裂产生单倍体精子，产生具有独特形状的成熟精子。我们前期的研究发现，在种系中敲低ocnus （ocn）后，雄性果蝇不育，许多蛋白的表达水平显著改变。其中，精氨酸激酶3 （arginine kinase 3, AK-3）表达显著下调，表明其在果蝇精子发生过程中起着重要作用。在这里，我们证明了AK-3在果蝇睾丸中高度表达。AK-3在睾丸中被敲低，导致核束分散，鞭毛轴突中心成对微管丢失，个别化复合物（ICs）被破坏，精囊内缺乏成熟精子，从而导致男性完全不育。值得注意的是，果蝇AK-3与人类CKMT1B具有同源性。人类CKMT1B的表达可以挽救果蝇由于AK-3敲低导致的晚期精子发生缺陷和雄性不育，表明该基因在进化和功能上是保守的。这些结果表明，AK-3参与了精子发生的调控，特别是精子伸长过程中轴突微管的组装和稳定。这些数据证实了精氨酸激酶在精子发生过程中的重要性及其进化保守性，并可能为研究CKMT1B在人类男性生育中的功能提供基础信息。

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

Reproduction 生物-发育生物学

CiteScore

7.40

自引率

2.60%

发文量

199

审稿时长

4-8 weeks

期刊介绍： Reproduction is the official journal of the Society of Reproduction and Fertility (SRF). It was formed in 2001 when the Society merged its two journals, the Journal of Reproduction and Fertility and Reviews of Reproduction. Reproduction publishes original research articles and topical reviews on the subject of reproductive and developmental biology, and reproductive medicine. The journal will consider publication of high-quality meta-analyses; these should be submitted to the research papers category. The journal considers studies in humans and all animal species, and will publish clinical studies if they advance our understanding of the underlying causes and/or mechanisms of disease. Scientific excellence and broad interest to our readership are the most important criteria during the peer review process. The journal publishes articles that make a clear advance in the field, whether of mechanistic, descriptive or technical focus. Articles that substantiate new or controversial reports are welcomed if they are noteworthy and advance the field. Topics include, but are not limited to, reproductive immunology, reproductive toxicology, stem cells, environmental effects on reproductive potential and health (eg obesity), extracellular vesicles, fertility preservation and epigenetic effects on reproductive and developmental processes.