Nonsynaptic junctions on myelinating glia promote preferential myelination of electrically active axons.

Authors :: Wake H
Ortiz FC
Woo DH
Lee PR
Angulo MC
Fields RD
Source :: Nature communications [Nat Commun] 2015 Aug 04; Vol. 6, pp. 7844. Date of Electronic Publication: 2015 Aug 04.
Publication Year :: 2015
Abstract: The myelin sheath on vertebrate axons is critical for neural impulse transmission, but whether electrically active axons are preferentially myelinated by glial cells, and if so, whether axo-glial synapses are involved, are long-standing questions of significance to nervous system development, plasticity and disease. Here we show using an in vitro system that oligodendrocytes preferentially myelinate electrically active axons, but synapses from axons onto myelin-forming oligodendroglial cells are not required. Instead, vesicular release at nonsynaptic axo-glial junctions induces myelination. Axons releasing neurotransmitter from vesicles that accumulate in axon varicosities induces a local rise in cytoplasmic calcium in glial cell processes at these nonsynaptic functional junctions, and this signalling stimulates local translation of myelin basic protein to initiate myelination.

Subjects :: Action Potentials
Animals
Calcium
Calcium Signaling
Gene Expression Regulation
In Vitro Techniques
Intercellular Junctions
Mice
Myelin Basic Protein genetics
Neuroglia metabolism
Neurons
Signal Transduction
Axons metabolism
Exocytosis
Myelin Sheath metabolism
Neurotransmitter Agents metabolism
Oligodendroglia metabolism

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