Abstract
P/Q-type calcium channels are known to form clusters at the presynaptic membrane where they mediate calcium influx, triggering vesicle fusion. We now report functional P/Q channel clusters in the axolemma of developing central axons that are also associated with sites of vesicle fusion. These channels were activated by axonal action potentials and the resulting calcium influx is well suited to mediate formation of a synaptic style SNARE complex involving SNAP-25, that we show to be located on the axolemma. Vesicular elements within axons were found to be the sole repository of vesicular glutamate in developing white matter. The axonal vesicular elements expressed the glutamate transporter V-ATPase, which is responsible for vesicular glutamate loading. The P/Q channel alpha(1A) subunit was found to be present within the axolemma at early nodes of Ranvier and deleterious mutations of the alpha(1A) subunit, or an associated alpha(2)delta-2 subunit, disrupted the localization of nodal proteins such as voltage-gated sodium channels, beta IV spectrin and CASPR-1. This was associated with the presence of malformed nodes of Ranvier characterized by an accumulation of axoplasmic vesicles under the nodal membrane. The data are consistent with the presence of a vesicular signalling pathway between axons and glial cells that is essential for proper development of the node of Ranvier.
Highlights
Myelinated axons are responsible for the rapid transmission of action potentials around the nervous system
The divalent cation-mediated compound action potential (DCAP) recorded from the neonatal optic nerve was similar to the Na+ action potential in amplitude but was relatively slower conducting (0.1-0.3 m/sec compared to 1-3 m/sec)
Removal of extracellular Na+ will produce a degree of membrane depolarization that will partially counter this effect, while rapid depletion of axoplasmic Na+ will block any effect of Na-Ca exchange (NCX) upon membrane potential or ion fluxes (Stys et al, 1992; Leppanen & Stys, 1997)
Summary
Myelinated axons are responsible for the rapid transmission of action potentials around the nervous system. Mediators of axon-glial interaction such as CASPR-1 form clusters at early node sites before Na+ channels start to aggregate (Rasband et al, 1999), and the whole process is apparently dependent upon a soluble factor released by oligodendrocytes (Kaplan et al, 1997). It is currently unclear what determines where nodes will form or how the aggregation of the components of the node is controlled
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