Abstract
Neuronal activity is established as a driver of oligodendrocyte (OL) differentiation and myelination. The concept of activity-dependent myelin plasticity, and its role in cognition and disease, is gaining support. Methods capable of resolving changes in the morphology of individual myelinating OL would advance our understanding of myelin plasticity and injury, thus we adapted a labelling approach involving Semliki Forest Virus (SFV) vectors to resolve and quantify the 3-D structure of OL processes and internodes in cerebellar slice cultures. We first demonstrate the utility of the approach by studying changes in OL morphology after complement-mediated injury. SFV vectors injected into cerebellar white matter labelled transitional OL (TOL), whose characteristic mixture of myelinating and non-myelinating processes exhibited significant degeneration after complement injury. The method was also capable of resolving finer changes in morphology related to neuronal activity. Prolonged suppression of neuronal activity, which reduced myelination, selectively decreased the length of putative internodes, and the proportion of process branches that supported them, while leaving other features of process morphology unaltered. Overall this work provides novel information on the morphology of TOL, and their response to conditions that alter circuit function or induce demyelination.
Highlights
Neuronal activity is established as a driver of oligodendrocyte (OL) differentiation and myelination
The results provide new information on the morphology and activity-dependent development of transitional OL (TOL), an intermediate stage of maturation linking pre-myelinating OL, in which all process branches (PB) are non-myelinating (NMPB)[20], and mature myelinating OL (MOL), in which it is expected that all PB are myelinating (MPB)
Considering the variability in internode number and length obtained from Semliki Forest Virus (SFV) labelled OL (Fig. 3G,H), we examined the effect of a longer reduction in neuronal activity after incubation in TTX for 7 days
Summary
Neuronal activity is established as a driver of oligodendrocyte (OL) differentiation and myelination. The speed of information transfer in axons is enhanced by myelination, with processing speed rising as axonal ensheathment increases[1,2] These gains in signal transmission arise as a result of alterations in the electrical properties of myelinated nerve fibres, including reduced transmembrane capacitance and increased resistance. We report the morphological analysis of neonatal white matter OL within a system amenable to prolonged pharmacological manipulations capable of either modulating neuronal activity or inducing OL myelin injury To achieve this we adapted an approach involving the gliotropic subtype of the Semliki Forest Virus (SFVA7(74) (SFV)[18], previously used for labelling OL in cultured hippocampal s lices[19], to label OL in the white matter of neonatal cerebellar slice cultures. TOL are defined as cells possessing a mixture of NMPB and MPB19,20, and the term myelinating OL is used generically to include both TOL and MOL
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