SRSF1 is crucial for male meiosis through alternative splicing during homologous pairing and synapsis in mice

Dynamic R-loops at centromeres ensure chromosome alignment during oocyte meiotic divisions in mice

R-loops play various roles in many physiological processes, however, their role in meiotic division remains largely unknown. Here we show that R-loops and their regulator RNase H1 are present at centromeres during oocyte meiotic divisions. Proper centromeric R-loops are essential to ensure chromosome alignment in oocytes during metaphase I (MI). Remarkably, both Rnaseh1 knockout and overexpression in oocytes lead to severe spindle assembly defects and chromosome misalignment due to dysregulation of R-loops at centromeres. Furthermore, we find that replication protein A (RPA) is recruited to centromeric R-loops, facilitating the deposition of ataxia telangiectasia-mutated and Rad3-related (ATR) kinase at centromeres by interacting with the ATR-interaction protein (ATRIP). The ATR kinase deposition triggers the activity of CHK1, stimulating the phosphorylation of Aurora B to finally promote proper spindle assembly and chromosome alignment at the equatorial plate. Most importantly, the application of ATR, CHK1, and Aurora B inhibitors could efficiently rescue the defects in spindle assembly and chromosome alignment due to RNase H1 deficiency in oocytes. Overall, our findings uncover a critical role of R-loops during mouse oocyte meiotic divisions, suggesting that dysregulation of R-loops may be associated with female infertility. Additionally, ATR, CHK1, and Aurora B inhibitors may potentially be used to treat some infertile patients.

The RNA Binding Protein Bcas2 is Required for Antibody Class Switch in Activated‐B Cells

In children, hyper‐IgM syndrome type 1 (HIGM1) is a type of severe antibody disorder, the pathogenesis of which remains unclear. The antibody diversity is partially determined by the alternative splicing (AS) in the germline, which is mainly regulated by RNA‐binding proteins, including Breast cancer amplified sequence 2 (Bcas2). However, the effect of Bcas2 on AS and antibody production in activated B cells, the main immune cell type in the germline, remains unknown. To fill this gap, we created a conditional knockout (cKO, B cell‐specific AID‐Cre Bcas2fl/fl) mouse model and performed integrated mechanistic analysis on alternative splicing (AS) and CSR in B cells through the RNA‐sequencing approach, cross‐linking immunoprecipitation and sequencing (CLIP‐seq) analysis, and interactome proteomics. The results demonstrate that Bcas2‐cKO significantly decreased CSR in activated B cells without inhibiting the B cell development. Mechanistically, Bcas2 interacts with SRSF7 at a conservative circular domain, forming a complex to regulate the AS of genes involved in the post‐switch transcription, thereby causing broad‐spectrum changes in antibody production. Importantly, we identified GAAGAA as the binding motif of Bcas2 to RNAs and revealed its essential role in the regulation of Bcas2‐dependent AS and CSR. In addition, we detected a mutation of at the 3’UTR of Bcas2 gene in children with HIGM1 and observed similar patterns of AS events and CSR in the patient that were discovered in the Bcas2‐cKO B cells. Combined, our study elucidates the mechanism by which Bcas2‐mediated AS affects CSR, offering potential insights into the clinical implications of Bcas2 in HIGM1.

BCAS2 and hnRNPH1 orchestrate alternative splicing for DNA double-strand break repair and synapsis in meiotic prophase I

Understanding the intricacies of homologous recombination during meiosis is crucial for reproductive biology. However, the role of alternative splicing (AS) in DNA double-strand breaks (DSBs) repair and synapsis remains elusive. In this study, we investigated the impact of conditional knockout (cKO) of the splicing factor gene Bcas2 in mouse germ cells, revealing impaired DSBs repair and synapsis, resulting in non-obstructive azoospermia (NOA). Employing crosslinking immunoprecipitation and sequencing (CLIP-seq), we globally mapped BCAS2 binding sites in the testis, uncovering its predominant association with 5' splice sites (5'SS) of introns and a preference for GA-rich regions. Notably, BCAS2 exhibited direct binding and regulatory influence on Trp53bp1 (codes for 53BP1) and Six6os1 through AS, unveiling novel insights into DSBs repair and synapsis during meiotic prophase I. Furthermore, the interaction between BCAS2, hnRNPH1, and SRSF3 was discovered to orchestrate Trp53bp1 expression via AS, underscoring its role in meiotic prophase I DSBs repair. In summary, our findings delineate the indispensable role of BCAS2-mediated post-transcriptional regulation in DSBs repair and synapsis during male meiosis. This study provides a comprehensive framework for unraveling the molecular mechanisms governing the post-transcriptional network in male meiosis, contributing to the broader understanding of reproductive biology.

Splicing factor SRSF1 is essential for homing of precursor spermatogonial stem cells in mice

Spermatogonial stem cells (SSCs) are essential for continuous spermatogenesis and male fertility. The underlying mechanisms of alternative splicing (AS) in mouse SSCs are still largely unclear. We demonstrated that SRSF1 is essential for gene expression and splicing in mouse SSCs. Crosslinking immunoprecipitation and sequencing data revealed that spermatogonia-related genes (e.g. Plzf, Id4, Setdb1, Stra8, Tial1/Tiar, Bcas2, Ddx5, Srsf10, Uhrf1, and Bud31) were bound by SRSF1 in the mouse testes. Specific deletion of Srsf1 in mouse germ cells impairs homing of precursor SSCs leading to male infertility. Whole-mount staining data showed the absence of germ cells in the testes of adult conditional knockout (cKO) mice, which indicates Sertoli cell-only syndrome in cKO mice. The expression of spermatogonia-related genes (e.g. Gfra1, Pou5f1, Plzf, Dnd1, Stra8, and Taf4b) was significantly reduced in the testes of cKO mice. Moreover, multiomics analysis suggests that SRSF1 may affect survival of spermatogonia by directly binding and regulating Tial1/Tiar expression through AS. In addition, immunoprecipitation mass spectrometry and co-immunoprecipitation data showed that SRSF1 interacts with RNA splicing-related proteins (e.g. SART1, RBM15, and SRSF10). Collectively, our data reveal the critical role of SRSF1 in spermatogonia survival, which may provide a framework to elucidate the molecular mechanisms of the posttranscriptional network underlying homing of precursor SSCs.