Abstract
SummaryThe spacing of nodes of Ranvier crucially affects conduction properties along myelinated axons. It has been assumed that node position is primarily driven by the growth of myelin sheaths. Here, we reveal an additional mechanism of node positioning that is driven by the axon. We show through longitudinal live imaging of node formation dynamics that stable clusters of the cell adhesion molecule Neurofascin A accumulate at specific sites along axons prior to myelination. While some of these clusters change position upon encounter with growing myelin sheaths, others restrict sheath extension and are therefore predictive of future node position. Animals that lack full-length Neurofascin A showed increased internodal distances and less regular spacing of nodes along single axons. Together, our data reveal the existence of an axonal mechanism to position its nodes of Ranvier that does not depend on regulation of myelin sheath length.
Publisher
Cold Spring Harbor Laboratory
Reference34 articles.
1. Intersectional Gene Expression in Zebrafish Using the Split KalTA4 System;Zebrafish,2015
2. Evidence for Myelin Sheath Remodeling in the CNS Revealed by In&Vivo Imaging;Current Biology,2018
3. Ca 2+ activity signatures of myelin sheath formation and growth in vivo;Nature Neuroscience,2017
4. CNS Myelin Sheath Lengths Are an Intrinsic Property of Oligodendrocytes;Current Biology: CB,2015
5. Biase, L.M.D. , Pucak, M.L. , Kang, S.H. , Rodriguez, S.N. , and Bergles, D.E. (2017). Sparse interaction between oligodendrocyte precursor cells (NG2+ cells) and nodes of Ranvier in the central nervous system. 1–34.