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小脑颗粒细胞- climbing 纤维计算以学习跟踪长时间间隔。

A cerebellar granule cell-climbing fiber computation to learn to track long time intervals.

机构信息

National Institute of Neurological Disorders & Stroke, National Institutes of Health, Bethesda, MD 20894, USA.

Department of Biology and Howard Hughes Medical Institute, Stanford University, Stanford, CA 94305, USA.

出版信息

Neuron. 2024 Aug 21;112(16):2749-2764.e7. doi: 10.1016/j.neuron.2024.05.019. Epub 2024 Jun 12.

DOI:10.1016/j.neuron.2024.05.019
PMID:38870929
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11343686/
Abstract

In classical cerebellar learning, Purkinje cells (PkCs) associate climbing fiber (CF) error signals with predictive granule cells (GrCs) that were active just prior (∼150 ms). The cerebellum also contributes to behaviors characterized by longer timescales. To investigate how GrC-CF-PkC circuits might learn seconds-long predictions, we imaged simultaneous GrC-CF activity over days of forelimb operant conditioning for delayed water reward. As mice learned reward timing, numerous GrCs developed anticipatory activity ramping at different rates until reward delivery, followed by widespread time-locked CF spiking. Relearning longer delays further lengthened GrC activations. We computed CF-dependent GrC→PkC plasticity rules, demonstrating that reward-evoked CF spikes sufficed to grade many GrC synapses by anticipatory timing. We predicted and confirmed that PkCs could thereby continuously ramp across seconds-long intervals from movement to reward. Learning thus leads to new GrC temporal bases linking predictors to remote CF reward signals-a strategy well suited for learning to track the long intervals common in cognitive domains.

摘要

在经典的小脑学习中,浦肯野细胞(PkC)将 climbing fiber(CF)的误差信号与预测性颗粒细胞(GrC)相关联,这些细胞在之前(约 150ms)处于活跃状态。小脑还参与了具有更长时间尺度的行为。为了研究 GrC-CF-PkC 回路如何学习长达数秒的预测,我们对延迟水奖励的前肢操作性条件反射进行了多天的 GrC-CF 活动成像。当老鼠学习奖励时间时,许多 GrC 以不同的速度逐渐产生预期活动,直到奖励送达,随后是广泛的时间锁定的 CF 尖峰。重新学习更长的延迟进一步延长了 GrC 的激活。我们计算了 CF 依赖性的 GrC→PkC 可塑性规则,证明了奖励诱发的 CF 尖峰足以通过预期的时间来分级许多 GrC 突触。我们预测并证实,PkC 可以从运动到奖励连续跨越数秒长的间隔进行斜坡运动。因此,学习导致新的 GrC 时间基础将预测器与远程 CF 奖励信号联系起来——这是一种非常适合学习跟踪认知领域中常见的长间隔的策略。

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