Neural network connectivity following opioid dependence is altered by a common genetic variant in the mu-opioid receptor,OPRM1A118G

Yihan Xie, J. Brynildsen, Kyle Windisch, J. Blendy
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Abstract

Opioid use disorder is a chronic, relapsing disease associated with persistent changes in brain plasticity. A common single nucleotide polymorphism (SNP) in the mu-opioid receptor gene,OPRM1A118G, is associated with altered vulnerability to opioid addiction. Reconfiguration of neuronal connectivity may explain dependence risk in individuals with this SNP. Mice with the equivalentOprm1variant, A112G, demonstrate sex-specific alterations in the rewarding properties of morphine and heroin. To determine whether this SNP influences network-level changes in neuronal activity we compared FOS expression in male and female mice that were opioid-naïve or opioid-dependent. Network analyses identified significant differences between the AA and GGOprm1genotypes. Based on several graph theory metrics, including small-world analysis and degree centrality, we show that GG females in the opioid-dependent state exhibit distinct patterns of connectivity compared to other groups of the same genotype. Using a network control theory approach, we identified key cortical brain regions that drive the transition between opioid-naïve and opioid-dependent brain states; however, these regions are less influential in GG females leading to 6-fold higher average minimum energy needed to transition from the acute to the dependent state. In addition, we found that the opioid-dependent brain state is significantly less stable in GG females compared to other groups. Collectively, our findings demonstrate sex and genotype-specific modifications in local, mesoscale, and global properties of functional brain networks following opioid exposure and provide a framework for identifying genotype differences in specific brain regions that play a role in opioid dependence.Significance StatementOpioid use disorder is moderately heritable, and the common mu-opioid receptor variant (OPRM1A118G) has been repeatedly associated with this disease. Opioid use liability is often higher in individuals with a history of chronic exposure and can be moderated by this SNP. Using a mouse model of theOprm1SNP, our work revealed opioid-induced differences in network connectivity between sexes and opioid dependence states in AA and GGOprm1mice. We also identified six (predominantly cortical) brain regions that strongly influence the transition to an opioid-dependent brain state. These data suggest potential brain regions that may be targeted using non-invasive therapeutic approaches such as repetitive Transcranial Magnetic Stimulation (rTMS) and could be useful to inform personalized treatment.
μ-阿片受体(OPRM1A118G)的一个常见基因变异改变了阿片依赖后的神经网络连通性
阿片类药物使用障碍是一种慢性、复发性疾病,与大脑可塑性的持续变化有关。阿片受体基因OPRM1A118G中常见的单核苷酸多态性(SNP)与阿片成瘾易感性的改变有关。神经元连接的重新配置可能解释了这种SNP个体的依赖风险。携带相同oprm1变体A112G的小鼠在吗啡和海洛因的奖励特性上表现出性别特异性的改变。为了确定这种SNP是否影响神经元活动的网络水平变化,我们比较了opioid-naïve或阿片类药物依赖的雄性和雌性小鼠的FOS表达。网络分析发现AA和ggoprm1基因型之间存在显著差异。基于几个图论指标,包括小世界分析和度中心性,我们发现,与其他相同基因型的群体相比,阿片依赖状态下的GG女性表现出不同的连接模式。使用网络控制理论方法,我们确定了驱动opioid-naïve和阿片类药物依赖大脑状态之间过渡的关键大脑皮层区域;然而,这些区域对GG女性的影响较小,导致从急性状态过渡到依赖状态所需的平均最小能量高6倍。此外,我们发现,与其他组相比,GG女性的阿片类药物依赖大脑状态明显不稳定。总的来说,我们的研究结果表明,在阿片类药物暴露后,功能性脑网络的局部、中尺度和全局特性发生了性别和基因型特异性改变,并为识别在阿片类药物依赖中起作用的特定大脑区域的基因型差异提供了一个框架。阿片类药物使用障碍具有中度遗传性,常见的mu-阿片类受体变异(OPRM1A118G)多次与该疾病相关。有慢性阿片类药物暴露史的个体往往更容易使用阿片类药物,并且可以通过该SNP来调节。使用oprm1snp的小鼠模型,我们的工作揭示了阿片类药物诱导的AA和ggoprm1小鼠的性别和阿片类药物依赖状态之间的网络连接差异。我们还确定了六个(主要是皮质)大脑区域,它们强烈影响向阿片类药物依赖的大脑状态的过渡。这些数据表明,可以使用非侵入性治疗方法(如重复经颅磁刺激(rTMS))靶向潜在的大脑区域,并可能有助于个性化治疗。
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