Orbitofrontal cortex populations are differentially recruited to support actions.

The ability to use information from one's prior actions is necessary for decision-making. While orbitofrontal cortex (OFC) has been hypothesized as key for inferences made using cue and value-related information, whether OFC populations contribute to the use of information from volitional actions to guide behavior is not clear. Here, we used a self-paced lever-press hold-down task in which mice infer prior lever-press durations to guide subsequent action performance. We show that the activity of genetically identified lateral OFC (lOFC) subpopulations differentially instantiate current and prior action information during ongoing action execution. Transient state-dependent lOFC circuit disruptions of specified subpopulations reduced the encoding of ongoing press durations but did not disrupt the use of prior action information to guide future action performance. In contrast, a chronic functional loss of lOFC circuit activity resulted in increased reliance on recently executed lever-press durations and impaired contingency reversal, suggesting the recruitment of compensatory mechanisms that resulted in repetitive action control. Our results identify a novel role for lOFC in the integration of action information to guide adaptive behavior.

Effects of chronic alcohol exposure on motivation-based value updating.

Dysfunctional decision-making has been observed in alcohol dependence. However, the specific underlying processes disrupted have yet to be identified. Important to goal-directed decision-making is one's motivational state, which is used to update the value of actions. As ethanol dependence disrupts decision-making processes, we hypothesized that ethanol dependence could alter sensitivity to motivational state and/or value updating, thereby reducing the capability for adaptive behavior. Here we employed a sequential instrumental learning task to examine this hypothesis. In two experiments, mice underwent chronic intermittent ethanol (CIE) or air (Air) vapor exposure and repeated withdrawal procedures to induce ethanol dependence. Mice were then trained on a sequence of distal and proximal lever pressing for sucrose under either mild or more severe food restriction. Half of all Air and CIE mice then underwent a motivational shift to a less hungry state and effects of this motivational shift were evaluated across three days. First, mice were re-exposed to sucrose, and effects of food restriction state and CIE exposure on lick and consummatory behavior were examined in the absence of lever pressing. Over the next two days, mice underwent a brief non-rewarded test and then a rewarded test where the ability to retrieve and infer sucrose value to guide lever pressing was measured. In the sucrose re-exposure session, prior CIE exposure altered sucrose-seeking in mice with a history of mild but not more severe food restriction, suggesting altered motivational sensitivity. During lever press testing, CIE mice were insensitive to decreases in motivational state and did not reduce proximal lever pressing regardless of food restriction state. Mildly restricted CIE mice, but not severely restricted CIE mice, also did not reduce distal pressing to the same degree as Air mice following a downshift in motivational state. Our findings suggest that ethanol dependence may disrupt motivational processes supporting value updating that are important for decision-making.

Conserved immunomodulatory transcriptional networks underlie antipsychotic-induced weight gain.

Although antipsychotics, such as olanzapine, are effective in the management of psychiatric conditions, some patients experience excessive antipsychotic-induced weight gain (AIWG). To illuminate pathways underlying AIWG, we compared baseline blood gene expression profiles in two cohorts of mice that were either prone (AIWG-P) or resistant (AIWG-R) to weight gain in response to olanzapine treatment for two weeks. We found that transcripts elevated in AIWG-P mice relative to AIWG-R are enriched for high-confidence transcriptional targets of numerous inflammatory and immunomodulatory signaling nodes. Moreover, these nodes are themselves enriched for genes whose disruption in mice is associated with reduced body fat mass and slow postnatal weight gain. In addition, we identified gene expression profiles in common between our mouse AIWG-P gene set and an existing human AIWG-P gene set whose regulation by immunomodulatory transcription factors is highly conserved between species. Finally, we identified striking convergence between mouse AIWG-P transcriptional regulatory networks and those associated with body weight and body mass index in humans. We propose that immunomodulatory transcriptional networks drive AIWG, and that these networks have broader conserved roles in whole body-metabolism.