Cholinergic regulation of dendritic Ca 2+ spikes controls firing mode of hippocampal CA3 pyramidal neurons.

Active dendritic integrative mechanisms such as regenerative dendritic spikes enrich the information processing abilities of neurons and fundamentally contribute to behaviorally relevant computations. Dendritic Ca ²⁺ spikes are generally thought to produce plateau-like dendritic depolarization and somatic complex spike burst (CSB) firing, which can initiate rapid changes in spatial coding properties of hippocampal pyramidal cells (PCs). However, here we reveal that a morpho-topographically distinguishable subpopulation of rat and mouse hippocampal CA3PCs exhibits compound apical dendritic Ca ²⁺ spikes with unusually short duration that do not support the firing of sustained CSBs. These Ca ²⁺ spikes are mediated by L-type Ca ²⁺ channels and their time course is restricted by A- and M-type K ⁺ channels. Cholinergic activation powerfully converts short Ca ²⁺ spikes to long-duration forms, and facilitates and prolongs CSB firing. We propose that cholinergic neuromodulation controls the ability of a CA3PC subtype to generate sustained plateau potentials, providing a state-dependent dendritic mechanism for memory encoding and retrieval.
Competing Interests: Competing interests statement:The authors declare no competing interest.