前馈抑制通路内的兴奋和抑制延迟调节小鼠小脑浦肯野细胞输出

Francesca Binda, Ludovic Spaeth, Arvind Kumar, P. Isope
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摘要

小脑皮层通过输入阶段颗粒细胞层和输出阶段浦肯野细胞层之间的前馈抑制(FFI)微电路计算来自许多大脑区域的感觉运动信息。尽管FFI在其他脑区具有精确的兴奋与抑制时间相关性,但最近在小脑中的发现强调了gc -分子层中间神经元(MLI) -PC通路的更复杂行为。为了解剖这条小脑FFI通路的时间组织,我们将雄性小鼠PCs的离体膜片钳记录与基于病毒的策略结合起来,在苔藓纤维(MFs)的一个亚群中表达Channelrhodopsin2, MFs是GCs的主要兴奋性输入。我们发现,虽然光介导的MF激活在PCs中引发了成对的兴奋性和抑制性突触后电流,但来自GCs的兴奋(E)和来自MLIs的抑制(I)在不同的时间延迟范围内到达PCs。然而,当直接刺激GCs时,观察到E/I延迟的低变异性。我们的研究结果表明,在许多记录中,MF刺激招募了触发E和/或I的不同组的GCs,并扩大了PC颞叶突触的整合。最后,使用FFI路径的计算模型,我们表明这种时间扩展可能强烈影响pc如何整合GC输入。我们的研究结果表明,特定的E/I延迟可能有助于pc编码特定的MF输入。意义陈述感觉运动信息通过苔藓状纤维传递到小脑皮层。苔藓纤维输入激活颗粒细胞,激发分子间神经元和浦肯野细胞,浦肯野细胞是小脑皮层的唯一输出,导致浦肯野细胞的突触兴奋和抑制序列,从而定义了前馈抑制途径。通过电生理记录、光遗传刺激和数学建模,我们证明了不同组的颗粒细胞可以引起浦肯野细胞突触的兴奋和抑制,并具有不同的潜伏期。这种时间变异性控制颗粒细胞如何影响浦肯野细胞放电,并可能支持小脑皮层的时间编码。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Excitation and Inhibition Delays within a Feedforward Inhibitory Pathway Modulate Cerebellar Purkinje Cell Output in Mice
The cerebellar cortex computes sensorimotor information from many brain areas through a feedforward inhibitory (FFI) microcircuit between the input stage, the granule cell (GC) layer, and the output stage, the Purkinje cells (PCs). Although in other brain areas FFI underlies a precise excitation versus inhibition temporal correlation, recent findings in the cerebellum highlighted more complex behaviors at GC–molecular layer interneuron (MLI)–PC pathway. To dissect the temporal organization of this cerebellar FFI pathway, we combined ex vivo patch-clamp recordings of PCs in male mice with a viral-based strategy to express Channelrhodopsin2 in a subset of mossy fibers (MFs), the major excitatory inputs to GCs. We show that although light-mediated MF activation elicited pairs of excitatory and inhibitory postsynaptic currents in PCs, excitation (E) from GCs and inhibition (I) from MLIs reached PCs with a wide range of different temporal delays. However, when GCs were directly stimulated, a low variability in E/I delays was observed. Our results demonstrate that in many recordings MF stimulation recruited different groups of GCs that trigger E and/or I, and expanded PC temporal synaptic integration. Finally, using a computational model of the FFI pathway, we showed that this temporal expansion could strongly influence how PCs integrate GC inputs. Our findings show that specific E/I delays may help PCs encoding specific MF inputs. SIGNIFICANCE STATEMENT Sensorimotor information is conveyed to the cerebellar cortex by mossy fibers. Mossy fiber inputs activate granule cells that excite molecular interneurons and Purkinje cells, the sole output of the cerebellar cortex, leading to a sequence of synaptic excitation and inhibition in Purkinje cells, thus defining a feedforward inhibitory pathway. Using electrophysiological recordings, optogenetic stimulation, and mathematical modeling, we demonstrated that different groups of granule cells can elicit synaptic excitation and inhibition with various latencies onto Purkinje cells. This temporal variability controls how granule cells influence Purkinje cell discharge and may support temporal coding in the cerebellar cortex.
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