Neuroscience Graduate Program, University of Colorado School of Medicine, Aurora, CO, USA.
Medical Scientist Training Program, University of Colorado School of Medicine, Aurora, CO, USA.
Nat Neurosci. 2023 Jun;26(6):1068-1079. doi: 10.1038/s41593-023-01347-y. Epub 2023 May 29.
The cerebellum is hypothesized to refine movement through online adjustments. We examined how such predictive control may be generated using a mouse reach paradigm, testing whether the cerebellum uses within-reach information as a predictor to adjust reach kinematics. We first identified a population-level response in Purkinje cells that scales inversely with reach velocity, pointing to the cerebellar cortex as a potential site linking kinematic predictors and anticipatory control. Next, we showed that mice can learn to compensate for a predictable reach perturbation caused by repeated, closed-loop optogenetic stimulation of pontocerebellar mossy fiber inputs. Both neural and behavioral readouts showed adaptation to position-locked mossy fiber perturbations and exhibited aftereffects when stimulation was removed. Surprisingly, position-randomized stimulation schedules drove partial adaptation but no opposing aftereffects. A model that recapitulated these findings suggests that the cerebellum may decipher cause-and-effect relationships through time-dependent generalization mechanisms.
小脑被假设通过在线调整来完善运动。我们通过使用鼠标抓握范式来检验这种预测控制如何产生,测试小脑是否使用在抓握范围内的信息作为预测器来调整抓握运动学。我们首先在浦肯野细胞中识别出一种与抓握速度呈反比的群体水平反应,这表明小脑皮层可能是将运动学预测器和预期控制联系起来的潜在部位。接下来,我们表明,老鼠可以学习补偿由于重复闭环光遗传学刺激桥脑小脑苔藓纤维输入而引起的可预测的抓握扰动。神经和行为读数都显示出对位置锁定的苔藓纤维扰动的适应,并且在刺激去除时表现出后效。令人惊讶的是,位置随机化的刺激方案导致部分适应,但没有相反的后效。一个再现这些发现的模型表明,小脑可能通过依赖时间的泛化机制来破译因果关系。
