Control of Action Potential-Induced Ca2+Signaling in the Soma of Hippocampal Neurons by Ca2+Release from Intracellular Stores

Abstract

Stimulus-induced increases in neuronal Ca²⁺concentration are important signaling events for transcriptional regulation and neuronal plasticity. Electrical inputs are thought to mediate Ca²⁺ responses in the soma by triggering action potentials, which in turn open voltage-gated Ca²⁺ channels in the somatic plasma membrane. It is not yet known to what extent internal Ca²⁺ amplification contributes to the somatic Ca²⁺ responses. Here we used fluorescent Ca²⁺measurements in cultured hippocampal neurons and report that the amplitude of the somatic Ca²⁺ increase triggered by field stimulation is independent of the extracellular Ca²⁺concentration as long as the concentration is greater than 50 μm. Furthermore, significantly more La³⁺ has to be added extracellularly for blocking Ca²⁺ responses, as predicted from the reported La³⁺ dependence of voltage-gated Ca²⁺ channels. These measurements suggest that field stimulation-induced somatic Ca²⁺ responses in hippocampal neurons are largely attributable to Ca²⁺release from intracellular stores. Only a small number of Ca²⁺ ions have to enter across the plasma membrane for this intracellular Ca²⁺ amplification process to occur. Rapid fluorescence-imaging measurements showed that the internal Ca²⁺ amplification occurs over 10–15 msec and linearly increases intracellular Ca²⁺ concentrations for up to 40 action potentials. At a fixed number of field pulses, frequencies of 40 Hz were optimal for somatic Ca²⁺ increases. Our studies suggest that the opening of intracellular Ca²⁺ release channels plays a crucial part in shaping the action potential-induced neuronal Ca²⁺ response.