Abstract
During axonal ensheathment, noncompact myelin channels formed at lateral edges of the myelinating process become arranged into tight paranodal spirals that resemble loops when cut in cross section. These adhere to the axon, concentrating voltage-dependent sodium channels at nodes of Ranvier and patterning the surrounding axon into distinct molecular domains. The signals responsible for forming and maintaining the complex structure of paranodal myelin are poorly understood. Here, we test the hypothesis that the planar cell polarity determinant Vangl2 organizes paranodal myelin. We show that Vangl2 is concentrated at paranodes and that, following conditional knockout of Vangl2 in oligodendrocytes, the paranodal spiral loosens, accompanied by disruption to the microtubule cytoskeleton and mislocalization of autotypic adhesion molecules between loops within the spiral. Adhesion of the spiral to the axon is unaffected. This results in disruptions to axonal patterning at nodes of Ranvier, paranodal axon diameter and conduction velocity. When taken together with our previous work showing that loss of the apico-basal polarity protein Scribble has the opposite phenotype-loss of axonal adhesion but no effect on loop-loop autotypic adhesion-our results identify a novel mechanism by which polarity proteins control the shape of nodes of Ranvier and regulate conduction in the CNS.
Highlights
Myelination in the CNS provides electrical insulation along the length of the sheath and enables rapid conduction by restricting the voltage-dependent sodium channels responsible for propagating action potentials to the small gaps between adjacent sheaths - the nodes of Ranvier
To ask whether Vangl2 plays a role in organising the myelin sheath, we first examined its distribution within oligodendroglia and in CNS myelin
Vangl2 is localized to cell bodies and processes in wild-type oligodendrocytes but is excluded from myelin-like membrane sheets (Fig. 2A,B)
Summary
The resulting tight axo-glial adhesion at the paranodal domain acts as a physical and electrical barrier separating the voltage-gated sodium channels required for saltatory conduction from the delayed rectifier potassium channels at the juxtaparanode (reviewed by reviewed by reviewed by reviewed by reviewed by reviewed by reviewed by reviewed by Zollinger, Baalman, & Rasband, 2015) Another distinct set of adhesion proteins hold adjacent turns of the spiral together (so maintaining a tight spiral), including the tight junction protein Claudin and gap junction protein Connexin-32 (Cx32), which are both essential for normal conduction in the CNS (Fig. 1B, Devaux & Gow, 2008; Sargiannidou et al, 2009). While essential for the complex three-dimensional organization and stability of the myelin sheath, the mechanisms responsible for the precise localization of the distinct sets of adhesion proteins within the paranodal channel and its resultant polarization (Fig. 1C, arrow) are unknown
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