Sox2-dependent fibronectin fibrillogenesis controls directional collective migration of Schwann cells

The extracellular matrix is essential for tissue formation and regeneration through the control of cellular behavior. Deregulation of extracellular matrix components is associated to disease, including neurodegeneration. After peripheral nerve injury, Schwann cells guide regrowing axons to their targets. These glial cells migrate collectively and provide an extracellular environment to enable neural repair. How this occurs remains poorly understood. Here, we show that Sox2 controls fibronectin fibrillogenesis in Schwann cells to provide a highly oriented extracellular matrix, which supports their rapid collective migration with a continuous cellular flow. Sox2 directly activates fibronectin expression in Schwann cells, leading to an increase in fibrillogenesis and cellular huddling. Accordingly, loss of fibrillogenesis leads to glial disassembly and disorganized axon regrowth. In vivo, 7 days post nerve injury, we found that pro-regenerative Schwann cells co-express Sox2 and the EIIIA-containing fibronectin splicing isoform. This mechanism is conserved in mammals, including humans, but absent in zebrafish. Taken together, our results demonstrate that Sox2 directly controls fibrillogenesis and provide a novel mechanism for the modification of the environmental architecture by glial cells during neuronal repair. To identify Sox2 target genes and pathways with a focus on extracellular matrix (ECM) we measured expression arrays of two different clones of Sox2-positive Schwann cells (i.e. three replicates of RSC96_Sox2+ cells for each clone) and control cells (i.e. three replicates of RSC96 cells)