Neuronal activity in vivo enhances functional myelin repair
Fernando C. Ortiz, … , Brahim Nait Oumesmar, María Cecilia Angulo
Fernando C. Ortiz, … , Brahim Nait Oumesmar, María Cecilia Angulo
Published March 21, 2019
Citation Information: JCI Insight. 2019;4(9):e123434. https://doi.org/10.1172/jci.insight.123434.
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Research Article Neuroscience

Neuronal activity in vivo enhances functional myelin repair

Abstract

In demyelinating diseases, such as multiple sclerosis, demyelination of neuronal fibers impairs impulse conduction and causes axon degeneration. Although neuronal activity stimulates oligodendrocyte production and myelination in normal conditions, it remains unclear whether the activity of demyelinated axons restores their loss of function in a harmful environment. To investigate this question, we established a model to induce a moderate optogenetic stimulation of demyelinated axons in the corpus callosum at the level of the motor cortex in which cortical circuit activation and locomotor effects were reduced in adult freely moving mice. We demonstrate that a moderate activation of demyelinated axons enhances the differentiation of oligodendrocyte precursor cells onto mature oligodendrocytes but only under a repeated stimulation paradigm. This activity-dependent increase in the oligodendrocyte pool promotes an extensive remyelination and functional restoration of conduction, as revealed by ultrastructural analyses and compound action potential recordings. Our findings reveal the need for preserving an appropriate neuronal activity in the damaged tissue to promote oligodendrocyte differentiation and remyelination, likely by enhancing axon-oligodendroglia interactions. Our results provide new perspectives for translational research using neuromodulation in demyelinating diseases.

Authors

Fernando C. Ortiz, Chloé Habermacher, Mariana Graciarena, Pierre-Yves Houry, Akiko Nishiyama, Brahim Nait Oumesmar, María Cecilia Angulo

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Figure 5

Repeated photostimulation in vivo promotes functional recovery in demyelinated lesions.

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Repeated photostimulation in vivo promotes functional recovery in demyel...
(A) Representative CAPs for NAWM, control, and repeated photostimulated lesions at 14 dpi. CAPs were obtained after subtracting average traces before and after application of 1 μM TTX (19). Note that the first peak corresponding to myelinated fibers disappeared in control LPC-induced lesions but was rescued after repeated stimulation. The time of stimulation is indicated (gray arrowheads). The stimulation artifacts were blanked for visibility. (B) Dot plots of conduction velocity (top), normalized area under the curve (AUC; middle) for the fast component, and amplitude ratio between fast and slow components of CAPs (fastAmp/slowAmp; bottom). Note that only 5 out of 17 recordings in control LPC-induced lesions had a fast component (n = 17 recordings for NAWM and control, and n = 18 recordings for repeated; n = 3 mice per condition; Welch’s t-corrected test value [W-t] = 0.43 and df = 41, W-t st. = 2.94, and df = 17, W-t st. = 2.62, and df = 20, respectively, for conduction velocity; Welch’s t-corrected test; Kruskal-Wallis statistics = 18.40 for normalized AUC, and Kruskal-Wallis statistics = 20.85 for fastAmp/slowAmp; Kruskal-Wallis test followed by Bonferroni’s multiple comparison). Data shown as mean ±SEM.