Individual Neuronal Subtypes Exhibit Diversity in CNS Myelination Mediated by Synaptic Vesicle Release

Koudelka, Sigrid; Voas, Matthew G.; Almeida, Rafael; Baraban, Marion; Soetaert, Jan; Meyer, Martin P.; Talbot, William S.; Lyons, David A.

doi:10.1016/j.cub.2016.03.070

Cited by 158 publications

(228 citation statements)

References 41 publications

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“…Following up on pioneering work (Barres & Raff, 1994; Demerens et al, 1996), electrical axonal activity and release of synaptic vesicles have been proposed recently as a major axonal signal modulating oligodendrogenesis, regulating the numbers and lengths of internodes generated, guiding the selection of axons to be myelinated, and adjusting the growth of myelin sheaths (Gibson et al, 2014; Hines, Ravanelli, Schwindt, Scott, & Appel, 2015; Koudelka et al, 2016; Mensch et al, 2015; Wake et al, 2015; Wake, Lee, & Fields, 2011). The molecular players underlying such activity‐dependent myelination are not univocally defined.…”

Section: Myelination and Mtormentioning

confidence: 99%

Myelination and mTOR

Figlia

Gerber

Suter

2017

Glia

136

120

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Myelinating cells surround axons to accelerate the propagation of action potentials, to support axonal health, and to refine neural circuits. Myelination is metabolically demanding and, consistent with this notion, mTORC1—a signaling hub coordinating cell metabolism—has been implicated as a key signal for myelination. Here, we will discuss metabolic aspects of myelination, illustrate the main metabolic processes regulated by mTORC1, and review advances on the role of mTORC1 in myelination of the central nervous system and the peripheral nervous system. Recent progress has revealed a complex role of mTORC1 in myelinating cells that includes, besides positive regulation of myelin growth, additional critical functions in the stages preceding active myelination. Based on the available evidence, we will also highlight potential nonoverlapping roles between mTORC1 and its known main upstream pathways PI3K‐Akt, Mek‐Erk1/2, and AMPK in myelinating cells. Finally, we will discuss signals that are already known or hypothesized to be responsible for the regulation of mTORC1 activity in myelinating cells.

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Section: Myelination and Mtormentioning

confidence: 99%

Myelination and mTOR

Figlia

Gerber

Suter

2017

Glia

136

120

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“…Multiple studies have shown that myelin deposition is not static, but far more dynamic than initially thought, with adaptive changes in myelin driven by changes in neuronal activity (myelin plasticity) (6,(20)(21)(22)(23)(24)(25). These changes, e.g., induced by optogenetic stimulation or stimulated through learning of complex motor skills, promote oligodendrogenesis and the deposition of new myelin sheaths along the axons.…”

Section: Introductionmentioning

confidence: 99%

Oligodendroglia: metabolic supporters of neurons

Philips¹,

Rothstein²

2017

Journal of Clinical Investigation

260

192

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“…Given that neuronal activity can regulate multiple stages of oligodendrocyte lineage 499 behaviour through myelination as well as axonal structure, it is likely that myelinated axon plasticity 500 plays a central role in many aspects of the formation and function of neuronal circuits that remain to 501 be discovered. activity-regulated myelination has been shown to be a property of only specific neuronal subtypes 514 (Koudelka et al, 2016). It will be important to define which neurons and circuits exhibit myelinatedaxon plasticity throughout life, and in response to experience.…”

mentioning

confidence: 99%

On Myelinated Axon Plasticity and Neuronal Circuit Formation and Function

Almeida¹,

Lyons²

2017

J. Neurosci.

187

180

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Studies of activity-driven nervous system plasticity have primarily focused on the gray matter. However, MRI-based imaging studies have shown that white matter, primarily composed of myelinated axons, can also be dynamically regulated by activity of the healthy brain. Myelination in the CNS is an ongoing process that starts around birth and continues throughout life. Myelin in the CNS is generated by oligodendrocytes and recent evidence has shown that many aspects of oligodendrocyte development and myelination can be modulated by extrinsic signals including neuronal activity. Because modulation of myelin can, in turn, affect several aspects of conduction, the concept has emerged that activity-regulated myelination represents an important form of nervous system plasticity. Here we review our increasing understanding of how neuronal activity regulates oligodendrocytes and myelinated axonsin vivo, with a focus on the timing of relevant processes. We highlight the observations that neuronal activity can rapidly tune axonal diameter, promote re-entry of oligodendrocyte progenitor cells into the cell cycle, or drive their direct differentiation into oligodendrocytes. We suggest that activity-regulated myelin formation and remodeling that significantly change axonal conduction properties are most likely to occur over timescales of days to weeks. Finally, we propose that precise fine-tuning of conduction along already-myelinated axons may also be mediated by alterations to the axon itself. We conclude that future studies need to analyze activity-driven adaptations to both axons and their myelin sheaths to fully understand how myelinated axon plasticity contributes to neuronal circuit formation and function.

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Individual Neuronal Subtypes Exhibit Diversity in CNS Myelination Mediated by Synaptic Vesicle Release

Cited by 158 publications

References 41 publications

Myelination and mTOR

Myelination and mTOR

Oligodendroglia: metabolic supporters of neurons

On Myelinated Axon Plasticity and Neuronal Circuit Formation and Function

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