Changes in Calcium Signaling During Postembryonic Dendritic Growth inManduca sexta

Abstract

Activity-dependent Ca²⁺influx plays crucial roles in adult and developing nervous systems through its influence on signal processing, synaptic plasticity, and neuronal differentiation. The responses to internal Ca²⁺elevations vary depending on the spatial distribution of Ca²⁺accumulation in different cell compartments. In this study, the mechanisms and the distribution of Ca²⁺accumulation are addressed by in situ Ca²⁺imaging of an identified insect motoneuron, MN5, at critical stages of postembryonic life. During metamorphosis of Manduca sexta, MN5 undergoes extensive dendritic regression followed by regrowth. The time course, amplitude, and distribution of Ca²⁺accumulation within MN5 change during development. During the initial stage of rapid dendritic growth and branching, dendritic growth cones are present, and voltage-dependent Ca²⁺currents are small. At this stage, activity-induced elevations of internal Ca²⁺are largest in the distal dendrites, suggesting that the density of voltage-gated Ca²⁺channels is highest in these regions. Later phases of dendritic growth are accompanied by the transient occurrence of prominent Ca²⁺spikes. Single Ca²⁺spikes cause robust Ca²⁺influx of similar amplitudes and time courses in all central compartments of MN5. The resting Ca²⁺levels also increase during development. Ca²⁺-induced Ca²⁺release from intracellular stores did not contribute to the elevations measured at either stage, although Ca²⁺stores are present in the dendrites. These developmental changes of the internal Ca²⁺signaling are consistent with a regulatory role for activity-dependent Ca²⁺influx in postembryonic dendritic growth.