Abstract
Communication between neurons and developing oligodendrocytes (OLs) leading to OL Ca2+ rise is critical for axon myelination and OL development. Here, we investigate signaling factors and sources of Ca2+ rise in OLs in the mouse brainstem. Glutamate puff or axon fiber stimulation induces a Ca2+ rise in pre-myelinating OLs, which is primarily mediated by Ca2+ -permeable AMPA receptors. During glutamate application, inward currents via AMPA receptors and elevated extracellular K+ caused by increased neuronal activity collectively lead to OL depolarization, triggering Ca2+ influx via P/Q- and L-type voltage-gated Ca2+ (Cav ) channels. Thus, glutamate is a key signaling factor in dynamic communication between neurons and OLs that triggers Ca2+ transients via AMPARs and Cav channels in developing OLs. The results provide a mechanism for OL Ca2+ dynamics in response to neuronal input, which has implications for OL development and myelination.