SUMMARY This application is for competitive renewal of a grant that over its 20-year course has elucidated the ways in which the function of the transcription factor CREB and kappa-opioid receptor (KOR) systems within the nucleus accumbens (NAc) are changed by experience, including stress exposure, and how alterations in their function affect behavior. We have shown that (a) stress upregulates NAc CREB and KOR signaling, (b) these effects are sufficient to produce characteristic features of mood and anxiety disorders, and (c) disruption of CREB or blockade of KORs produces antidepressant- and anxiolytic-like effects. Recently we have also shown a role for these systems in sleep and biological (diurnal) rhythms, which are dysregulated across many types of psychiatric illness. Our work has provided a basis for clinical trials of KOR antagonists to treat depression, which thus far show great promise. Major goals for Years 21-25 are to further characterize the ways in which NAc CREB and KOR systems regulate complex behavior and responses to different forms of stressors, including a type of immune stress relevant to the COVID-19 pandemic, while prioritizing the use of endpoints in rodents with improved alignment to those used in humans. In Aim 1, we will examine the mechanisms of CREB-mediated depressive behavior using a new version of a cognitive control task (called the Flanker task) that we developed to enable testing rats and humans using virtually identical procedures. Specifically, we will determine how alterations in NAc CREB function in D1- and/or D2-medium spiny neurons (MSNs) affect task performance and event-related potentials (ERPs)—endpoints known to be aberrant in human depression—in male and female rats. In Aim 2, we will determine if a regimen of early immune activation (EIA) that produces long-lasting depressive-like effects in mice causes persistent alterations in NAc CREB and KOR systems. Specifically, we will use single-nucleus RNA sequencing to comprehensively examine EIA-induced alterations in NAc cell populations, including MSNs and microglia, and compare and contrast effects in males and females. While upregulation of NAc CREB and KOR systems is commonly associated with depressive phenotypes, in Aims 3-4 we will examine possible roles in stress resilience. For Aim 3, we will examine how KORs expressed on microglia, which regulate immune function, affect sensitivity to stress. Specifically, we will examine how ablation of KORs from microglia affects the ability of chronic stress to disrupt sleep and diurnal rhythms of activity and body temperature. Similarly, in Aim 4 we will characterize the effects of altering the function of the CREB target DFosB in D1- or D2-MSNs on stress-induced disruption of sleep and diurnal rhythms, while in parallel examining effects on CREB, DYN, and KOR expression in NAc MSNs and microglia. All of these studies involve endpoints (behavioral, molecular) that can also be studied in humans or human tiss...