ABSTRACT
Dynamic interactions of neurons and glia in the ventral midbrain (VM) mediate reward and addiction behavior. We studied gene expression in 212,713 VM single nuclei from 95 human opioid overdose cases and drug-free controls. Chronic exposure to opioids left numerical proportions of VM glial and neuronal subtypes unaltered, while broadly affecting glial transcriptomes, involving 9.5 - 6.2% of expressed genes within microglia, oligodendrocytes, and astrocytes, with prominent activation of the immune response including interferon, NFkB signaling, and cell motility pathways, sharply contrasting with down-regulated expression of synaptic signaling and plasticity genes in VM non-dopaminergic neurons. VM transcriptomic reprogramming in the context of opioid exposure and overdose included 325 genes with genetic variation linked to substance use traits in the broader population, thereby pointing to heritable risk architectures in the genomic organization of the brain's reward circuitry.
ABSTRACT
Dynamic interactions of neurons and glia in the ventral midbrain mediate reward and addiction behavior. We studied gene expression in 212,713 ventral midbrain single nuclei from 95 individuals with history of opioid misuse, and individuals without drug exposure. Chronic exposure to opioids was not associated with change in proportions of glial and neuronal subtypes, however glial transcriptomes were broadly altered, involving 9.5 - 6.2% of expressed genes within microglia, oligodendrocytes, and astrocytes. Genes associated with activation of the immune response including interferon, NFkB signaling, and cell motility pathways were upregulated, contrasting with down-regulated expression of synaptic signaling and plasticity genes in ventral midbrain non-dopaminergic neurons. Ventral midbrain transcriptomic reprogramming in the context of chronic opioid exposure included 325 genes that previous genome-wide studies had linked to risk of substance use traits in the broader population, thereby pointing to heritable risk architectures in the genomic organization of the brain's reward circuitry.
Subject(s)
Opioid-Related Disorders , Transcriptome , Humans , Gene Expression Profiling , Opioid-Related Disorders/genetics , Analgesics, Opioid , MesencephalonABSTRACT
BACKGROUND: A high proportion of opioid drug deaths involve concurrent benzodiazepine use. To reduce the risk of drug overdose, various prescription drug monitoring programs have been implemented. This study examined the impact of concurrent benzodiazepine use on opioid-related deaths, and the utility of the Michigan Automated Prescription System (MAPS) in predicting risk of opioid death. METHODS: Wayne County Medical Examiner's Office cases from 2018 were examined in terms of MAPS data and MAPS-derived drug risk scores, as well as postmortem toxicology. Opioid death cases with concurrent benzodiazepine use were compared to non-drug deaths. RESULTS: For cases with a MAPS history for 6 months preceding death, the incidence of opioid prescriptions filled did not differ between groups. In contrast, significantly more opioid death cases had filled a benzodiazepine prescription; alprazolam prescription was the single best predictor of opioid drug death. Groups differed in MAPS-calculated drug risk scores, though these were less predictive of opioid death than some individual measures of prescription drug use. In terms of postmortem toxicology, fentanyl was the best discriminator between cohorts, with significant associations seen for morphine, benzodiazepine, or cocaine use. Similar results were obtained in the subset of subjects filling a prescription within a month of death, except that MAPS risk scores no longer predicted drug deaths. CONCLUSION: MAPS scores did not adequately predict risk of opioid-related death. Contrary to expectations, prescription opioid use was not correlated with opioid-related death, whereas concurrent use of opioids and benzodiazepines represented a highly significant risk factor.