Spatiotemporal calcium dynamics in single astrocytes and its modulation by neuronal activity

Astrocytes produce a complex repertoire of Ca²⁺ events that coordinate their major functions. The principle of Ca²⁺ events integration in astrocytes, however, is unknown. Here we analyze whole Ca²⁺ events, which were defined as spatiotemporally interconnected transient Ca²⁺ increases. Using such analysis in single hippocampal astrocytes in culture and in slices we found that spreads and durations of Ca²⁺ events follow power law distributions, a fingerprint of scale-free systems. A mathematical model demonstrated that such Ca²⁺ dynamics can arise from intracellular inositol-3-phosphate diffusion. The power law exponent (α) was decreased by activation of metabotropic glutamate receptors (mGluRs) either by specific receptor agonist or by low frequency stimulation of glutamatergic fibers in hippocampal slices. Decrease in α indicated an increase in proportion of large Ca²⁺ events. Notably, mGluRs activation did not increase the frequency of whole Ca²⁺ events. This result suggests that neuronal activity does not trigger new Ca²⁺ events in astrocytes (detectable by our methods), but modulates the properties of existing ones. Thus, our results provide a new perspective on how astrocyte responds to neuronal activity by changing its Ca²⁺ dynamics, which might further affect local network by triggering release of gliotransmitters and by modulating local blood flow.