MAP7-driven cytoskeletal cross-talk establishes Sertoli cell polarity crucial for germ cell meiotic progression

Sertoli cells form a unique apical domain crucial for organizing the seminiferous epithelium and supporting germ cell development, though the underlying molecular mechanisms remain unclear. We identified MAP7, a microtubule-associated protein, as a key regulator of cytoskeletal integration essential for apical domain formation. MAP7 localizes to apical microtubules without overlapping stable, acetylated tubulin. Loss of MAP7 prevents lumen formation during the first wave of spermatogenesis due to disrupted apical domain architecture and ectopic expansion of tight junctions. Overall microtubule intensity remains largely unchanged in Map7 -deficient Sertoli cells, but their organization is severely perturbed, indicating MAP7 facilitates dynamic remodeling for apical and epithelial organization. Proteomic analysis revealed that MAP7 forms a complex with non-muscle myosin II heavy chains MYH9 and MYH10. MYH9 normally concentrates at luminal regions where microtubules and F-actin converge, but in Map7 -deficient cells it is diffusely distributed, indicating MAP7 mediates spatial integration of microtubules and actomyosin for localized remodeling. Single-cell RNA sequencing showed Sertoli cell differentiation largely persists without MAP7, whereas germ cells in Map7 -deficient testes exhibit delayed meiotic progression, marked by expansion of pachytene subtypes. These findings establish MAP7 as a cytoskeletal integrator linking epithelial polarity to germline progression, providing insight into how tissue organization sustains fertility.