Lay Belinda P P, Koya Eisuke, Hope Bruce T, Esber Guillem R, Iordanova Mihaela D
Center for Studies in Behavioural Neurobiology, Department of Psychology, Concordia University, Montreal, Québec, Canada.
Sussex Neuroscience, School of Psychology, University of Sussex, Falmer, United Kingdom.
Biol Psychiatry. 2023 Feb 15;93(4):300-308. doi: 10.1016/j.biopsych.2022.07.021. Epub 2022 Aug 5.
Adaptive behavior depends on the delicate and dynamic balance between acquisition and extinction memories. Disruption of this balance, particularly when the extinction of memory loses control over behavior, is the root of treatment failure of maladaptive behaviors such as substance abuse or anxiety disorders. Understanding this balance requires a better understanding of the underlying neurobiology and its contribution to behavioral regulation.
We microinjected Daun02 in Fos-lacZ transgenic rats following a single extinction training episode to delete extinction-recruited neuronal ensembles in the basolateral amygdala (BLA) and central nucleus of the amygdala (CN) and examined their contribution to behavior in an appetitive Pavlovian task. In addition, we used immunohistochemistry and neuronal staining methods to identify the molecular markers of activated neurons in the BLA and CN during extinction learning or retrieval.
CN neurons were preferentially engaged following extinction, and deletion of these extinction-activated ensembles in the CN but not the BLA impaired the retrieval of extinction despite additional extinction training and promoted greater levels of behavioral restoration in spontaneous recovery and reinstatement. Disrupting extinction processing in the CN in turn increased activity in the BLA. Our results also show a specific role for CN PKCδ+ neurons in behavioral inhibition but not during initial extinction learning.
We showed that the initial extinction-recruited CN ensemble is critical to the acquisition-extinction balance and that greater behavioral restoration does not mean weaker extinction contribution. These findings provide a novel avenue for thinking about the neural mechanisms of extinction and for developing treatments for cue-triggered appetitive behaviors.
适应性行为取决于习得性记忆和消退性记忆之间微妙而动态的平衡。这种平衡的破坏,尤其是当记忆的消退失去对行为的控制时,是药物滥用或焦虑症等适应不良行为治疗失败的根源。理解这种平衡需要更好地了解其潜在的神经生物学及其对行为调节的作用。
在单次消退训练后,我们向Fos-lacZ转基因大鼠脑内微量注射柔红霉素以删除杏仁核基底外侧核(BLA)和杏仁核中央核(CN)中参与消退的神经元集群,并在一个经典条件性味觉厌恶任务中检测它们对行为的影响。此外,我们使用免疫组织化学和神经元染色方法来识别在消退学习或提取过程中BLA和CN中被激活神经元的分子标记。
在消退后,CN神经元优先被激活,删除CN而非BLA中这些被消退激活的集群,尽管进行了额外的消退训练,仍损害了消退的提取,并在自发恢复和重新激活中促进了更高水平的行为恢复。破坏CN中的消退过程反过来增加了BLA中的活性。我们的结果还表明CN中PKCδ+神经元在行为抑制中具有特定作用,但在初始消退学习期间并非如此。
我们发现,最初参与消退的CN集群对于习得-消退平衡至关重要,而且更高水平的行为恢复并不意味着消退的作用更弱。这些发现为思考消退的神经机制以及开发针对线索触发的条件性味觉厌恶行为的治疗方法提供了一条新途径。
