Edited by Yaming Jiu The differentiation of a round spermatid into a streamlined sperm cell involves a series of remarkable morphological changes,such as sperm head shaping and flagellum formation.However,the underlyi...Edited by Yaming Jiu The differentiation of a round spermatid into a streamlined sperm cell involves a series of remarkable morphological changes,such as sperm head shaping and flagellum formation.However,the underlying mechanism of spermatid shaping remains unclear.In this study,we find that CCDC92 deficiency in mice leads to severe abnormalities of the sperm head and flagellum and causes male infertility.Ultrastructural analyses of testicular elongating Ccdc92 knockout spermatids reveal severely deformed manchette structures.The manchette defects impair the subsequent sperm nucleus elongation and acrosome anchoring,resulting in misshapen rod-like nuclei and detached acrosomes.Molecularly,CCDC92 interacts with intraflagellar transport(IFT)complex components and colocalizes with IFT proteins at the manchette in developing spermatids.Quantitative proteomics further reveals the requirement of CCDC92 for proper flagellar distribution of axonemal microtubule inner proteins.Our findings demonstrate an essential role of CCDC92 in regulating spermatid shaping and provide novel insights into the pathology of male infertility.展开更多
基金supported by grants from the National Natural Science Foundation of China(32270807 and 31900538)Shandong Natural Science Foundation(2022HWYQ-075 and ZR2024MC136)the Taishan Scholar Foundation of Shandong Province(tsqn202211109).
文摘Edited by Yaming Jiu The differentiation of a round spermatid into a streamlined sperm cell involves a series of remarkable morphological changes,such as sperm head shaping and flagellum formation.However,the underlying mechanism of spermatid shaping remains unclear.In this study,we find that CCDC92 deficiency in mice leads to severe abnormalities of the sperm head and flagellum and causes male infertility.Ultrastructural analyses of testicular elongating Ccdc92 knockout spermatids reveal severely deformed manchette structures.The manchette defects impair the subsequent sperm nucleus elongation and acrosome anchoring,resulting in misshapen rod-like nuclei and detached acrosomes.Molecularly,CCDC92 interacts with intraflagellar transport(IFT)complex components and colocalizes with IFT proteins at the manchette in developing spermatids.Quantitative proteomics further reveals the requirement of CCDC92 for proper flagellar distribution of axonemal microtubule inner proteins.Our findings demonstrate an essential role of CCDC92 in regulating spermatid shaping and provide novel insights into the pathology of male infertility.
