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Microglia-neuron interaction at nodes of Ranvier depends on neuronal activity through potassium release and contributes to remyelination

Rémi Ronzano, Thomas Le Roux, Melina Thétiot, Marie‐Stéphane Aigrot, Laurence Richard, François‐Xavier Lejeune, Elisa Mazuir, Jean‐Michel Vallat, Catherine Lubetzki, Anne Desmazières

2021Nature Communications117 citationsDOIOpen Access PDF

Abstract

Abstract Microglia, the resident immune cells of the central nervous system, are key players in healthy brain homeostasis and plasticity. In neurological diseases, such as Multiple Sclerosis, activated microglia either promote tissue damage or favor neuroprotection and myelin regeneration. The mechanisms for microglia-neuron communication remain largely unkown. Here, we identify nodes of Ranvier as a direct site of interaction between microglia and axons, in both mouse and human tissues. Using dynamic imaging, we highlight the preferential interaction of microglial processes with nodes of Ranvier along myelinated fibers. We show that microglia-node interaction is modulated by neuronal activity and associated potassium release, with THIK-1 ensuring their microglial read-out. Altered axonal K + flux following demyelination impairs the switch towards a pro-regenerative microglia phenotype and decreases remyelination rate. Taken together, these findings identify the node of Ranvier as a major site for microglia-neuron interaction, that may participate in microglia-neuron communication mediating pro-remyelinating effect of microglia after myelin injury.

Topics & Concepts

RemyelinationNeuroscienceMicrogliaPotassiumNeuronMyelin sheathBiologyChemistryCell biologyMyelinCentral nervous systemInflammationImmunologyOrganic chemistryNeuroinflammation and Neurodegeneration MechanismsNeurogenesis and neuroplasticity mechanismsNeuroscience and Neuropharmacology Research
Microglia-neuron interaction at nodes of Ranvier depends on neuronal activity through potassium release and contributes to remyelination | Litcius