Intercellular Ca2+ waves in rat hippocampal slice and dissociated glial–neuron cultures mediated by nitric oxide

Nitric oxide (NO) may participate in cell–cell communication in the brain by generating intercellular Ca2+ waves. In hippocampal organotypic and dissociated glial–neuron (>80% glia) cultures local applications of aqueous NO induced slowly propagating intercellular Ca2+ waves. In glial cultures, Ca2+ waves and Mn2+ quench of cytosolic fura‐2 fluorescence mediated by NO were inhibited by nicardipine, indicating that NO induces Ca2+ influx in glia which is dihydropyridine‐sensitive. As NO treatments also depolarised the plasma membrane potential of glia, the nicardipine‐sensitive Ca2+ influx might be due to the activation of dihydropyridine‐sensitive L‐type Ca2+ channels. Both nicardipine‐sensitive intercellular Ca2+ waves and propagating cell depolarisation induced by mechanical stress of individual glia were inhibited by pretreating cultures with either an NO scavenger or N G‐methyl‐L‐arginine. Results demonstrate that NO can induce Ca2+ waves in hippocampal slice cultures, and that Ca2+ influx coupled to NO‐mediated membrane depolarisation might assist in fashioning their spatio‐temporal dynamics.

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