Long-range inhibitory intersection of a retrosplenial thalamocortical circuit by apical tuft-targeting CA1 neurons

Abstract

AbstractDorsal hippocampus, retrosplenial cortex (RSC), and anterior thalamic nuclei (ATN) interact to mediate diverse cognitive functions, but the cellular basis for these interactions is unclear. We hypothesized a long-range circuit converging in layer 1 (L1) of RSC, based on the pathway anatomy of GABAergic CA1 retrosplenial-projecting (CA1-RP) neurons and thalamo-restrosplenial projections from ATN. We find that CA1→RSC projections stem from GABAergic neurons with a distinct morphology, electrophysiology, and molecular profile, likely corresponding to recently described Ntng1-expressing hippocampal interneurons. CA1-RP neurons monosynaptically inhibit L5 pyramidal neurons, principal outputs of RSC, via potent GABAergic synapses onto apical tuft dendrites in L1. These inhibitory inputs align precisely with L1-targeting thalamocortical excitatory inputs from ATN, particularly the anteroventral nucleus, forming a convergent circuit whereby CA1 inhibition can intercept ATN excitation to co-regulate RSC activity. Excitatory axons from subiculum, in contrast, innervate proximal dendrites in deeper layers. Short-term synaptic plasticity differs at each connection. Chemogenetically abrogating inhibitory CA1→RSC or excitatory ATN→RSC connections oppositely affects the encoding of contextual fear memory. Collectively, our findings identify multiple cellular mechanisms underlying hippocampo-thalamo-retrosplenial interactions, establishing CA1 RSC-projecting neurons as a distinct class with long-range axons that target apical tuft dendrites, and delineating an unusual cortical circuit in the RSC specialized for integrating long-range inhibition and thalamocortical excitation.