2025
Neuron

Distinct dendritic integration strategies control dynamics of inhibition in the neocortex

Authors:

Annunziato Morabito, Yann Zerlaut, Dhanasak Dhanasobhon, Cibele Martins Pinho, Alexandra Tzilivaki, Gael Moneron, Laurence Cathala, Panayiota Poirazi, Alberto Bacci, David A. DiGregorio, Joana Lourenço, Nelson Rebola

Keywords:

GABAergic interneurons; neocortex; dendritic integration; NMDA receptors; visual cortex; synapse distributions

Abstract:

Dendrites critically influence single-neuron computations, but their role in neocortical GABAergic interneurons (INs) remains poorly understood. We found that the two major cortical IN subtypes—somatostatin (SST)- and parvalbumin (PV)-expressing cells—use distinct strategies for distributing and integrating excitatory synaptic inputs along their dendrites. SST-INs exhibit NMDAR-dependent supralinear integration and a uniform distribution of synapses, whereas PV-INs show sublinear integration with a higher density of synapses on proximal dendrites with low NMDAR expression. Compartmental modeling revealed that, while both strategies enhance synaptic efficacy, passive integration and proximally biased inputs enable precise tracking of fast-changing signals in PV-INs, whereas NMDARs in SST-INs promote broader temporal integration, supporting sustained activity tuned to slower input variations. Consistent with these predictions, in vivo measurements showed differentially shaped dynamic visual responses in PV- and SST-INs. Therefore, the heterogeneity of dendritic mechanisms strongly influences the spatiotemporal dynamics of IN-specific inhibition in cortical circuits.