Cervera-Juanes Rita P, Zimmerman Kip D, Wilhelm Larry J, Lowe Clara Christine, Gonzales Steven W, Carlson Tim, Hitzemann Robert, Ferguson Betsy M, Grant Kathleen A
Department of Translational Neuroscience, School of Medicine, Wake Forest University, Winston-Salem, NC 27157, United States of America; Center for Precision Medicine, School of Medicine, Wake Forest University, Winston-Salem, NC 27157, United States of America.
Center for Precision Medicine, School of Medicine, Wake Forest University, Winston-Salem, NC 27157, United States of America; Department of Internal Medicine, Atrium Health Wake Forest Baptist, Winston-Salem, NC 27157, United States of America.
Neurobiol Dis. 2025 Jun 1;209:106886. doi: 10.1016/j.nbd.2025.106886. Epub 2025 Mar 24.
Alcohol use disorder (AUD) is a highly prevalent, complex, multifactorial and heterogeneous disorder, with 11 % and 30 % of adults meeting criteria for past-year and lifetime AUD, respectively. Identification of the molecular mechanisms underlying risk for AUD would facilitate effective deployment of personalized interventions. Studies using rhesus monkeys and rats, have demonstrated that individuals with low cognitive flexibility and a predisposition towards habitual behaviors show an increased risk for future heavy drinking. Further, low cognitive flexibility is associated with reduced dorsolateral prefrontal cortex (dlPFC) function in rhesus monkeys. To explore the underlying unique molecular signatures that increase risk for chronic heavy drinking, a genome-wide DNA methylation (DNAm) analysis of the alcohol-naïve dlPFC-A46 biopsy prior to chronic alcohol self-administration was conducted. The DNAm profile provides a molecular snapshot of the alcohol-naïve dlPFC, with mapped genes and associated signaling pathways that vary across individuals. The analysis identified 1,463 differentially methylated regions (DMRs) related to unique genes that were strongly associated with average ethanol intake consumed over 6 months of voluntary self-administration. These findings translate behavioral phenotypes into neural markers of risk for AUD, and hold promise for parallel discoveries in risk for other disorders involving impaired cognitive flexibility. SIGNIFICANCE: Alcohol use disorder (AUD) is a highly prevalent and heterogeneous disorder. Prevention strategies to accurately identify individuals with a high risk for AUD, would help reduce the prevalence, and severity of AUD. Our novel epigenomic analysis of the alcohol-naïve nonhuman primate cortex provides a molecular snapshot of the vulnerable brain, pointing to circuitry and molecular mechanisms associated with cortical development, synaptic functions, glutamatergic signaling and coordinated signaling pathways. With a complex disorder like AUD, having the ability to identify the molecular mechanisms underlying AUD risk is critical for better development of personalized effective treatments.
酒精使用障碍(AUD)是一种高度流行、复杂、多因素且异质性的疾病,分别有11%和30%的成年人符合过去一年和终生AUD的标准。确定AUD风险背后的分子机制将有助于有效实施个性化干预措施。使用恒河猴和大鼠的研究表明,认知灵活性低且有习惯性行为倾向的个体未来大量饮酒的风险增加。此外,恒河猴的认知灵活性低与背外侧前额叶皮质(dlPFC)功能降低有关。为了探索增加慢性大量饮酒风险的潜在独特分子特征,在慢性酒精自我给药之前,对未接触过酒精的dlPFC-A46活检组织进行了全基因组DNA甲基化(DNAm)分析。DNAm图谱提供了未接触过酒精的dlPFC的分子快照,其中映射的基因和相关信号通路因人而异。分析确定了1463个与独特基因相关的差异甲基化区域(DMR),这些基因与自愿自我给药6个月期间的平均乙醇摄入量密切相关。这些发现将行为表型转化为AUD风险的神经标志物,并有望在涉及认知灵活性受损的其他疾病风险方面取得平行发现。意义:酒精使用障碍(AUD)是一种高度流行且异质性的疾病。准确识别AUD高风险个体的预防策略将有助于降低AUD的患病率和严重程度。我们对未接触过酒精的非人类灵长类动物皮质进行的新型表观基因组分析提供了脆弱大脑的分子快照,指出了与皮质发育、突触功能、谷氨酸能信号传导和协调信号通路相关的神经回路和分子机制。对于像AUD这样的复杂疾病,能够确定AUD风险背后的分子机制对于更好地开发个性化有效治疗至关重要。
