Abstract
The dentate gyrus (DG) is the primary gate of the hippocampus and controls information flow from the cortex to the hippocampus proper. To maintain normal function, granule cells (GCs), the principal neurons in the DG, receive fine-tuned inhibition from local-circuit GABAergic inhibitory interneurons (INs). Abnormalities of GABAergic circuits in the DG are associated with several brain disorders, including epilepsy, autism, schizophrenia, and Alzheimer disease. Therefore, understanding the network mechanisms of inhibitory control of GCs is of functional and pathophysiological importance. GABAergic inhibitory INs are heterogeneous, but it is unclear how individual subtypes contribute to GC activity. Using cell-type-specific optogenetic perturbation, we investigated whether and how two major IN populations defined by parvalbumin (PV) and somatostatin (SST) expression, regulate GC input transformations. We showed that PV-expressing (PV+) INs, and not SST-expressing (SST+) INs, primarily suppress GC responses to single cortical stimulation. In addition, these two IN classes differentially regulate GC responses to θ and γ frequency inputs from the cortex. Notably, PV+ INs specifically control the onset of the spike series, whereas SST+ INs preferentially regulate the later spikes in the series. Together, PV+ and SST+ GABAergic INs engage differentially in GC input-output transformations in response to various activity patterns.
Highlights
Inhibition within the dentate gyrus (DG) circuitry has been identified as a prime mediator of the sparse activation of GCs5,24–27
We used extracellular recording techniques to examine the influence of GABAergic inhibition on the granule cells (GCs) responses to the cortical input, the perforant path (PP)
Spiking of dentate GCs in the rodent hippocampus is primarily regulated by synaptic inhibition originating from local GABAergic INs
Summary
Inhibition within the DG circuitry has been identified as a prime mediator of the sparse activation of GCs5,24–27. A diverse population of GABAergic INs with distinct functions is known to exist in the hippocampus[28,29,30]. Somatostatin-expressing (SST+) inhibitory cells, a major type of dendrite-targeting GABAergic cells, regulate dendritic Na+ or Ca2+ spikes and synaptic plasticity by innervating dendritic domains of principal neurons[32,33]. Right, normalized pSpike area plotted against input strength. Dashed lines indicate the 95% pSpike and the corresponding fEPSP slope (left) or input strength (right). (d) The pSpike area is plotted against fEPSP slope for the experiment illustrated in (c) at three indicated recording sites. (e) The normalized pSpike area is plotted against input strength for the same experiments as in (d). The DG can generate distinct spike outputs during different states of cortical activity
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