Oligodendrocyte precursor cells (OPCs) represent the most abundant group of proliferating cells in the adult central nervous system. OPCs serve as progenitors for oligodendrocyte (OLs) throughout the life, and contribute to developmental and adaptive myelination, and myelin repair during diseased state. OPCs make synaptic and extra-synaptic contacts with axons, and detect and respond to neuronal activity. How OPCs translate the information relayed by the neuronal activity into Ca2+ signals, which in turn influence their fate and survival, is less understood. We developed novel transgenic mouse lines expressing a cytosolic and membrane anchored variants of genetically encoded Ca2+ sensors (GCaMP6f or mGCaMP6s) in OPCs, performed 2-photon microscopy in the somatosensory cortex of the awake behaving mice, and simultaneously monitored intracellular Ca2+ signals and their cell-fate progression. We found Ca2+ signals in OPCs mainly occur within processes and confine to micrometer-size segments called Ca2+ microdomains. Microdomain Ca2+ signals enhanced in OPCs when mice engage in exploratory behavior. OPCs exhibit distinct Ca2+ signals while they proliferate to maintain their precursor pool or differentiate to generate new OL. When mice engaged in exploratory behavior, the cortical projections of noradrenergic neurons in locus coeruleus showed increased firing rate and norepinephrine release. Norepinephrine activated all three subtypes of alpha1 adrenergic receptor expressed by OPCs and evoked intracellular Ca2+ increase in OPCs. A chemogenetic activation of noradrenergic neurons, promoted differentiation of cortical OPCs into OL, and at the same time suppressed OPC proliferation rate. Hence, we uncovered that various cell types of oligodendrocyte lineage exhibits unique signatures of Ca2+ activity, which these cells might integrate for making their fate decisions, and norepinephrine signaling can be a potent regulator of OPC fate.
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