幼鱼期斑马鱼的小脑依赖型学习。
Cerebellar-dependent learning in larval zebrafish.
机构信息
California Institute of Technology, Division of Biology, Pasadena, California 91125, USA.
出版信息
J Neurosci. 2011 Jun 15;31(24):8708-12. doi: 10.1523/JNEUROSCI.6565-10.2011.
Abstract
Understanding how neuronal network activity contributes to memory formation is challenged by the complexity of most brain circuits and the restricted ability to monitor the activity of neuronal populations in vivo. The developing zebrafish (Danio rerio) is an animal model that circumvents these problems, because zebrafish larvae possess a rich behavioral repertoire and an accessible brain. Here, we developed a classical conditioning paradigm in which 6- to 8-d-old larvae develop an enhanced motor response to a visual stimulus (conditioned stimulus, CS) when it is paired with touch (unconditioned stimulus, US). Using in vivo calcium imaging we demonstrate that CS and US activate different subsets of neurons in the cerebellum; their activity, modulated by learning two-photon laser ablation, revealed that the cerebellum is involved in acquisition and extinction, but not the retention, of this memory.
摘要
理解神经元网络活动如何有助于记忆形成,这受到大多数大脑回路的复杂性以及在体内监测神经元群体活动的受限能力的挑战。发育中的斑马鱼(Danio rerio)是一种动物模型,可以规避这些问题,因为斑马鱼幼虫具有丰富的行为表现和可进入的大脑。在这里,我们开发了一种经典的条件反射范式,其中 6 至 8 天大的幼虫在视觉刺激(条件刺激,CS)与触摸(非条件刺激,US)配对时会对其产生增强的运动反应。使用体内钙成像,我们证明 CS 和 US 激活小脑内不同的神经元亚群;通过学习双光子激光消融来调节它们的活动,揭示小脑参与了记忆的获得和消退,但不参与记忆的保留。
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