Vanderbilt Brain Institute, Vanderbilt University, Nashville, TN, 37232, USA.
Medical Scientist Training Program, Vanderbilt University, Nashville, TN, 37232, USA.
Psychopharmacology (Berl). 2021 Apr;238(4):1121-1131. doi: 10.1007/s00213-021-05759-1. Epub 2021 Jan 16.
Cannabinoid type 1 receptors (CB1Rs) are widely expressed within the brain's reward circuits and are implicated in regulating drug induced behavioral adaptations. Understanding how CB1R signaling in discrete circuits and cell types contributes to drug-related behavior provides further insight into the pathology of substance use disorders.
We sought to determine how cell type-specific expression of CB1Rs within striatal circuits contributes to cocaine-induced behavioral plasticity, hypothesizing that CB1R function in distinct striatal neuron populations would differentially impact behavioral outcomes. We crossed conditional Cnr1 mice and striatal output pathway cre lines (Drd1a -cre; D1, Adora2a -cre; A2a) to generate cell type-specific CB1R knockout mice and assessed their performance in cocaine locomotor and associative behavioral assays.
Both knockout lines retained typical locomotor activity at baseline. D1-Cre x Cnr1 mice did not display hyperlocomotion in response to acute cocaine dosing, and both knockout lines exhibited blunted locomotor activity across repeated cocaine doses. A2a-cre Cnr1, mice did not express a preference for cocaine paired environments in a two-choice place preference task.
This study aids in mapping CB1R-dependent cocaine-induced behavioral adaptations onto distinct striatal neuron subtypes. A reduction of cocaine-induced locomotor activation in the D1- and A2a-Cnr1 knockout mice supports a role for CB1R function in the motor circuit. Furthermore, a lack of preference for cocaine-associated context in A2a-Cnr1 mice suggests that CB1Rs on A2a-neuron inhibitory terminals are necessary for either reward perception, memory consolidation, or recall. These results direct future investigations into CB1R-dependent adaptations underlying the development and persistence of substance use disorders.
大麻素 1 型受体(CB1R)在大脑的奖励回路中广泛表达,并被认为参与调节药物引起的行为适应。了解离散电路和细胞类型中的 CB1R 信号如何有助于与药物相关的行为,为物质使用障碍的病理学提供了进一步的见解。
我们试图确定纹状体回路中 CB1R 的细胞类型特异性表达如何促进可卡因引起的行为可塑性,假设 CB1R 在不同的纹状体神经元群体中的功能将对行为结果产生不同的影响。我们交叉了条件性 Cnr1 小鼠和纹状体输出途径 cre 线(Drd1a-cre;D1、Adora2a-cre;A2a),以产生细胞类型特异性 CB1R 敲除小鼠,并评估它们在可卡因运动和联想行为测定中的表现。
两种敲除系在基线时都保留了典型的运动活性。D1-Cre x Cnr1 小鼠对急性可卡因给药没有表现出过度运动,两种敲除系在重复可卡因剂量下都表现出运动活性减弱。A2a-cre Cnr1 小鼠在双选择位置偏好任务中没有表现出对可卡因配对环境的偏好。
这项研究有助于将 CB1R 依赖性可卡因诱导的行为适应映射到不同的纹状体神经元亚型上。D1 和 A2a-Cnr1 敲除小鼠中可卡因诱导的运动激活减少支持 CB1R 功能在运动回路中的作用。此外,A2a-Cnr1 小鼠中缺乏对可卡因相关环境的偏好表明,A2a 神经元抑制性末端的 CB1R 对于奖励感知、记忆巩固或回忆是必要的。这些结果指导了未来对物质使用障碍发展和持续的 CB1R 依赖性适应的研究。
