NDNF interneurons in layer 1 gain-modulate whole cortical columns according to an animal's behavioral state.

Processing of sensory information in neural circuits is modulated by an animal's behavioral state, but the underlying cellular mechanisms are not well understood. Focusing on the mouse visual cortex, here we analyze the role of GABAergic interneurons that are located in layer 1 and express Ndnf (L1 NDNF INs) in the state-dependent control over sensory processing. We find that the ongoing and sensory-evoked activity of L1 NDNF INs is strongly enhanced when an animal is aroused and that L1 NDNF INs gain-modulate local excitatory neurons selectively during high-arousal states by inhibiting their apical dendrites while disinhibiting their somata via Parvalbumin -expressing interneurons. Because active NDNF INs are evenly spread in L1 and can affect excitatory neurons across all cortical layers, this indicates that the state-dependent activation of L1 NDNF INs and the subsequent shift of inhibition in excitatory neurons toward their apical dendrites gain-modulate sensory processing in whole cortical columns. [Display omitted] • Arousal strongly enhances the activity and sensory-evoked responses of L1 NDNF INs • L1 NDNF INs gain-modulate local EXC neurons selectively during high-arousal states • L1 NDNF INs inhibit the apical dendrites of EXC neurons and disinhibit their somata • Active NDNF INs are evenly spread across L1 and can affect EXC neurons in all layers Cohen-Kashi Malina et al. show that visual cortex L1 NDNF INs are strongly driven by arousal. Active NDNF INs are evenly spread in L1 and gain-modulate local excitatory neurons in all cortical layers during high-arousal states by directly inhibiting their apical dendrites while disinhibiting their somata via Parvalbumin -expressing interneurons. [ABSTRACT FROM AUTHOR]