Nolan Matthew F, Malleret Gaël, Lee Ka Hung, Gibbs Emma, Dudman Joshua T, Santoro Bina, Yin Deqi, Thompson Richard F, Siegelbaum Steven A, Kandel Eric R, Morozov Alexei
Center for Neurobiology and Behavior, Columbia University, New York, NY 10032, USA.
Cell. 2003 Nov 26;115(5):551-64. doi: 10.1016/s0092-8674(03)00884-5.
In contrast to our increasingly detailed understanding of how synaptic plasticity provides a cellular substrate for learning and memory, it is less clear how a neuron's voltage-gated ion channels interact with plastic changes in synaptic strength to influence behavior. We find, using generalized and regional knockout mice, that deletion of the HCN1 channel causes profound motor learning and memory deficits in swimming and rotarod tasks. In cerebellar Purkinje cells, which are a key component of the cerebellar circuit for learning of correctly timed movements, HCN1 mediates an inward current that stabilizes the integrative properties of Purkinje cells and ensures that their input-output function is independent of the previous history of their activity. We suggest that this nonsynaptic integrative function of HCN1 is required for accurate decoding of input patterns and thereby enables synaptic plasticity to appropriately influence the performance of motor activity.
与我们对突触可塑性如何为学习和记忆提供细胞基础的理解日益详细形成对比的是,神经元的电压门控离子通道如何与突触强度的可塑性变化相互作用以影响行为,这一点尚不清楚。我们利用全身性和区域性基因敲除小鼠发现,HCN1通道的缺失会在游泳和转棒试验中导致严重的运动学习和记忆缺陷。在小脑浦肯野细胞中,这是小脑回路中学习正确定时运动的关键组成部分,HCN1介导一种内向电流,该电流稳定浦肯野细胞的整合特性,并确保其输入-输出功能独立于其先前的活动历史。我们认为,HCN1的这种非突触整合功能对于准确解码输入模式是必需的,从而使突触可塑性能够适当地影响运动活动的表现。