Morphine regulates astrocyte transcriptional dynamics in the ventral tegmental area by stimulation of glucocorticoid signaling

Opioids are potent analgesics often prescribed for the treatment of chronic pain, a condition affecting millions worldwide. Although pain states increase vulnerability to opioid use disorders, the neural mechanisms underlying this interaction remain incompletely understood. The ventral tegmental area (VTA) is a key site for opioid actions, and emerging evidence suggests that pain states and opioid experience both induce transcriptional, molecular, and circuit adaptations in the VTA that contribute to motivated behaviors. However, the transcriptional responses of distinct VTA cell types to each of these factors (alone or in combination) have not been identified. Here, we employed single-nucleus RNA sequencing to comprehensively define transcriptional alterations in the rat VTA to acute morphine administration in a chronic inflammatory pain model. We report that morphine induces gene expression changes primarily in glial cells and dopamine neurons, with minimal effects in other neuronal cell types. Surprisingly, VTA astrocytes and oligodendrocytes exhibited the most robust transcriptional responses to opioid exposure, despite lacking detectable opioid receptor expression. Among the most highly regulated glial genes was Fkbp5 , which encodes a co-chaperone protein that acts in concert with heat shock proteins to modulate stress responses. Using pharmacological and CRISPR-based approaches in rat glial cells and human astrocytes, we demonstrate that regulation of Fkbp5 is mediated indirectly through glucocorticoid signaling rather than direct opioid receptor activation. These findings reveal that glial cells within reward circuits undergo profound transcriptional reprogramming in response to opioids through indirect, stress-hormone mediated mechanisms, highlighting a previously unappreciated non-neuronal contribution to opioid-induced neural adaptations.