An emerging multi-omic understanding of the genetics of opioid addiction

Opioid misuse, addiction, and associated overdose deaths remain global public health crises. Despite the tremendous need for pharmacological treatments, current options are limited in number, use, and effectiveness. Fundamental leaps forward in our understanding of the biology driving opioid addicti...

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Bibliographic Details
Published in:The Journal of clinical investigation 2024-10, Vol.134 (20), p.1-11
Main Authors: Johnson, Eric O, Fisher, Heidi S, Sullivan, Kyle A, Corradin, Olivia, Sanchez-Roige, Sandra, Gaddis, Nathan C, Sami, Yasmine N, Townsend, Alice, Teixeira Prates, Erica, Pavicic, Mirko, Kruse, Peter, Chesler, Elissa J, Palmer, Abraham A, Troiani, Vanessa, Bubier, Jason A, Jacobson, Daniel A, Maher, Brion S
Format: Article
Language:English
Subjects:
Addictions
Animals
Biology
Brain
Brain - metabolism
Brain - pathology
Brain research
DNA methylation
Drug abuse
Drug development
Drug overdose
Drug therapy
Drug use
Drugs
Functional plasticity
G protein-coupled receptors
Gene expression
Genes
Genetic aspects
Genetics
Genome-Wide Association Study
Genomes
Genotype & phenotype
Hispanic Americans
Histones
Humans
Legalization
MAP kinase
Medical research
Medicine, Experimental
Meta-analysis
Methadone
Multiomics
Narcotics
Neurons
Neurophysiology
Neurosciences
Opioid receptors
Opioid-Related Disorders - genetics
Opioid-Related Disorders - metabolism
Opioid-Related Disorders - pathology
Orexins
Overdose
Prescription drugs
Public health
Receptors, Opioid, mu - genetics
Receptors, Opioid, mu - metabolism
Review Series
Signal transduction
Substance abuse treatment
Substance use disorder
Synaptic plasticity
Tissues
γ-Aminobutyric acid B receptors
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Summary:Opioid misuse, addiction, and associated overdose deaths remain global public health crises. Despite the tremendous need for pharmacological treatments, current options are limited in number, use, and effectiveness. Fundamental leaps forward in our understanding of the biology driving opioid addiction are needed to guide development of more effective medication-assisted therapies. This Review focuses on the omics-identified biological features associated with opioid addiction. Recent GWAS have begun to identify robust genetic associations, including variants in OPRM1, FURIN, and the gene cluster SCAI/PPP6C/RABEPK. An increasing number of omics studies of postmortem human brain tissue examining biological features (e.g., histone modification and gene expression) across different brain regions have identified broad gene dysregulation associated with overdose death among opioid misusers. Drawn together by meta-analysis and multi-omic systems biology, and informed by model organism studies, key biological pathways enriched for opioid addiction-associated genes are emerging, which include specific receptors (e.g., GABAB receptors, GPCR, and Trk) linked to signaling pathways (e.g., Trk, ERK/MAPK, orexin) that are associated with synaptic plasticity and neuronal signaling. Studies leveraging the agnostic discovery power of omics and placing it within the context of functional neurobiology will propel us toward much-needed, field-changing breakthroughs, including identification of actionable targets for drug development to treat this devastating brain disease.
ISSN:1558-8238
0021-9738
1558-8238
DOI:10.1172/JCI172886