A glial cell derived pathway directs regenerating optic nerve axons toward the optic chiasm

After optic nerve injury, several retinal ganglion cell (RGC) intrinsic signaling pathways have been shown to enhance RGC survival and RGC axonal growth. In contrast, few extrinsic cues have been identified that guide regenerating RGC axons toward and across the optic chiasm. Here, we use live-cell imaging in larval zebrafish to show that regrowing RGC axons initiate growth toward the midline and extend along a trajectory similar to their original projection. From a candidate genetic screen, we identify the glycosyltransferase Lh3 (also referred to as Plod3) to be required to direct regrowing RGC axons toward the midline during active regeneration. Moreover, we show that transgenic lh3 expression in sox10+ presumptive olig2 + oligodendrocytes located near the optic chiasm restores directed axonal growth in lh3 mutants. Finally, we find that mutants in collagen 18a1 (col18a1), a putative Lh3 substrate, display RGC axonal misguidance phenotypes similar to lh3 mutants, suggesting that lh3 may act through col18a1 during regeneration. Combined, these data identify lh3 as part of a glial derived molecular pathway critical for guiding in vivo regenerating RGC axons toward and across the optic chiasm.