The dynamics of ciliogenesis in prepubertal mouse meiosis reveal new clues about testicular maturation during puberty

The primary cilium, a solitary and non-motile extension of the plasma membrane, has recently been identified in adult male mouse spermatocytes. However, very little is known about when these cilia emerge during testicular maturation and what their function is. In the context of fertility establishment during puberty, this study investigates the dynamics of ciliogenesis in prepubertal mouse spermatocytes. Our findings reveal that primary cilia are not an intrinsic feature of spermatocytes during the first wave of meiosis, which initiates at 8 days post-partum (dpp). Instead, cilia begin polymerizing at 20 dpp, after first meiotic wave has been completed, and are present in spermatocytes across all stages of prophase I. Thus, no direct correlation between cilia polymerization and the initiation of synapsis or desynapsis was found, although chemical ablation of cilia may delay DNA repair during prophase I. Typical adult cilia features, which are shorter and restricted to zygotene spermatocytes, are settled upon acquisition of sexual maturity. This study also highlights that the emergence of ciliated spermatocytes in prepuberal mice coincides with the onset of flagellogenesis, hinting at a potential link between the regulation of the formation of both types of axonemes within the tissue developing environment. Proteomic analyses further identify temporal regulators of axoneme assembly, providing valuable targets for future research to unravel the molecular pathways underlying ciliogenesis, flagellogenesis, and their roles in spermatogenesis. We explored distinct regulatory mechanisms of ciliogenesis during the first meiotic wave and found that Aurora kinase A (AURKA) is a critical regulator of cilia disassembly during late diplotene, with evidence suggesting that centrosome migration and cilia depolymerization are mutually exclusive events during meiosis. In summary, this study provides the first detailed characterization of primary cilia dynamics during early testicular maturation in mice, revealing their spatiotemporal regulation, candidate molecular mediators, and potential roles during meiosis. These findings lay the groundwork for understanding the physiological relevance of meiotic cilia in spermatogenesis and testicular development.