TFEB/3 govern repair Schwann cell generation and function following peripheral nerve injury.

ABSTRACT

TFEB and TFE3 (TFEB/3), key regulators of lysosomal biogenesis and autophagy, play diverse roles depending on cell type. This study highlights a hitherto unrecognized role of TFEB/3 crucial for peripheral nerve repair. Specifically, they promote the generation of progenitor-like repair Schwann cells after axonal injury. In Schwann cell-specific TFEB/3 double knock-out mice of either sex, the TFEB/3 loss disrupts the transcriptomic reprogramming that is essential for the formation of repair Schwann cells. Consequently, mutant mice fail to populate the injured nerve with repair Schwann cells and exhibit defects in axon-regrowth, target reinnervation, and functional recovery. TFEB/3 deficiency inhibits the expression of injury-responsive repair Schwann cell genes, despite the continued expression of c-Jun, a previously identified regulator of repair Schwann cell function. TFEB/3 binding motifs are enriched in the enhancer regions of injury-responsive genes, suggesting their role in repair gene activation. Autophagy-dependent myelin breakdown is not impaired despite TFEB/3 deficiency. These findings underscore a unique role of TFEB/3 in adult Schwann cells that is required for proper peripheral nerve regeneration.Significance Statement Peripheral nerves have been recognized for their efficient regenerative capabilities compared to the central nervous system neurons. This is due to the remarkable ability of Schwann cells to undergo a reprogramming process, transforming into progenitor-like repair Schwann cells that actively contribute to axon regeneration and overall nerve repair. However, the specific transcriptional regulators responsible for initiating this transformation in the adult peripheral nerve have remained elusive. Our study elucidates a previously undescribed, injury-responsive function of TFEB/3 in adult Schwann cells, showcasing its ability to promote tissue repair. Our findings hold important implications for enhancing nerve regeneration by bolstering the regenerative capacity of glial cells, thereby contributing to advancements in the field of neural tissue repair.