Synaptic mechanisms underlying the network state-dependent recruitment of VIP-expressing interneuron-specific interneurons in the CA1 hippocampus

Abstract

SUMMARYIn the hippocampus, a highly specialized population of vasoactive intestinal peptide (VIP)-expressing interneuron-specific (IS) inhibitory cells provides local circuit disinhibition via preferential innervation of different types of GABAergic interneurons. While disinhibition can be critical in modulating network activity and different forms of hippocampal learning, the synaptic and integrative properties of IS cells and their recruitment during network oscillations remain unknown. Using a combination of patch-clamp recordings, photostimulation, computational modelling as well as recordings of network oscillations simultaneously with two-photon Ca2+-imaging in awake mice in vivo, we identified synaptic mechanisms that can control the firing of IS cells, and explored their impact on the cell recruitment during theta oscillations and sharp-wave-associated ripples. We found that IS cells fire spikes in response to both the Schaffer collateral and the temporoammonic pathway activation. Moreover, integrating their intrinsic and synaptic properties into computational models predicted recruitment of these cells during the rising to peak phases of theta oscillations and during ripples depending on inhibitory contributions. In vivo Ca2+-imaging in awake mice confirmed in part the theoretical predictions, revealing a significant speed modulation of IS cells and their preferential albeit delayed recruitment during theta-run epochs, with firing at the rising phase to peak of the theta cycle. However, it also uncovered that IS cells are not activated during ripples. Thus, given the preferential theta-modulated firing of IS cells in awake hippocampus, we postulate that these cells may be important for information gating during spatial navigation and memory encoding.