PT  - JOURNAL ARTICLE
AU  - James Bigelow
AU  - Ryan J. Morrill
AU  - Jefferson Dekloe
AU  - Andrea R. Hasenstaub
TI  - Movement and VIP Interneuron Activation Differentially Modulate Encoding in Mouse Auditory Cortex
AID  - 10.1523/ENEURO.0164-19.2019
DP  - 2019 Sep 01
TA  - eneuro
PG  - ENEURO.0164-19.2019
VI  - 6
IP  - 5
4099  - http://www.eneuro.org/content/6/5/ENEURO.0164-19.2019.short
4100  - http://www.eneuro.org/content/6/5/ENEURO.0164-19.2019.full
SO  - eNeuro2019 Sep 01; 6
AB  - Information processing in sensory cortex is highly sensitive to nonsensory variables such as anesthetic state, arousal, and task engagement. Recent work in mouse visual cortex suggests that evoked firing rates, stimulus–response mutual information, and encoding efficiency increase when animals are engaged in movement. A disinhibitory circuit appears central to this change: inhibitory neurons expressing vasoactive intestinal peptide (VIP) are activated during movement and disinhibit pyramidal cells by suppressing other inhibitory interneurons. Paradoxically, although movement activates a similar disinhibitory circuit in auditory cortex (ACtx), most ACtx studies report reduced spiking during movement. It is unclear whether the resulting changes in spike rates result in corresponding changes in stimulus–response mutual information. We examined ACtx responses evoked by tone cloud stimuli, in awake mice of both sexes, during spontaneous movement and still conditions. VIP+ cells were optogenetically activated on half of trials, permitting independent analysis of the consequences of movement and VIP activation, as well as their intersection. Movement decreased stimulus-related spike rates as well as mutual information and encoding efficiency. VIP interneuron activation tended to increase stimulus-evoked spike rates but not stimulus–response mutual information, thus reducing encoding efficiency. The intersection of movement and VIP activation was largely consistent with a linear combination of these main effects: VIP activation recovered movement-induced reduction in spike rates, but not information transfer.