Fibroblast-derived tenascin-C promotes Schwann cell migration through β1-integrin dependent pathway during peripheral nerve regeneration

Peripheral nerve regeneration requires precise coordination and dynamic interaction among various types of cells in the tissue. It remains unclear, however, whether the cellular crosstalk between fibroblasts and Schwann cells (SCs) is related to phenotype modulation of SCs, a critical cellular process after peripheral nerve injury. In this study, microarray analysis revealed that a total of 6,046 genes were differentially expressed in the proximal nerve segment after sciatic nerve transection in rats, and bioinformatics analysis further identified tenascin‐C (TNC), an extracellular matrix (ECM) protein, as a key gene regulator. TNC was abundantly produced by nerve fibroblasts accumulating at the lesion site, rather than by SCs as usually expected. TNC significantly promoted SC migration without effects on SC proliferation in primary culture. In co‐culture of fibroblasts and SCs, inhibition of TNC expression either by siRNA transfection or antibody blockade could suppress SC migration, while TNC‐stimulated SC migration was mediated by TNC binding to β1‐integrin receptor in SCs through activation of Rac1 effectors. The in vivo evidence showed that exogenous TNC protein enhanced SC migration and axonal regrowth. Our results highlight that TNC‐mediated cellular interaction between fibroblasts and SCs may regulate SC migration through β1‐integrin‐dependent pathway during peripheral nerve regeneration. GLIA 2016;64:374–385 Main Points Microarray‐based bioinformatics analysis identified tenascin‐C (TNC) as a key gene regulator during peripheral nerve injury and regeneration; In vitro and in vivo evidence showed the promoting function of fibroblast‐derived tenascin‐C on SC migration and corresponding mechanism.