出生时间、神经线路与小脑颗粒细胞生理反应特性的关系

S. A. Shuster, M. Wagner, Nathan Pan-Doh, Jing Ren, Sophie M. Grutzner, Kevin T. Beier, T. H. Kim, M. Schnitzer, L. Luo
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引用次数: 11

摘要

小脑颗粒细胞(GrCs)构成哺乳动物大脑中所有神经元的大部分,通常被认为是一种统一的细胞类型。然而,单个GrCs的出生时间决定了它们轴突的投射位置。使用病毒遗传技术,我们发现早出生和晚出生的GrCs从同一组输入区域接收不同比例的输入。早出生和晚出生的GrCs轴突的体内多深度双光子Ca2+成像显示,这两个种群代表不同的任务变量和刺激,轴突在编码运动和奖励参数子集的比例上存在微小差异。这些结果表明,出生时间对GrCs的输入选择和生理反应特性有一定的影响。小脑颗粒细胞(GrCs)通常被认为是一种统一的细胞类型,它通过整合苔藓纤维输入的不同组合来共同扩展小脑的编码空间。因此,在单个小脑区域内稳定的分子或生理定义的GrC亚型尚未报道。唯一已知的区分同质GrC的细胞特性是GrC出生时间与其轴突投射的分子层深度之间的对应关系。为了确定出生时间在GrC连接和功能中所起的作用,我们开发了遗传策略来获取早出生和晚出生的GrC。我们从对照(出生时间不受限制)、早生和晚生GrCs开始逆行单突触狂犬病毒追踪,揭示了蚓部第6小叶和单纯性GrCs以及蚓部第6小叶早生和晚生GrCs的苔藓纤维输入模式的不同:感觉和运动核向早生GrCs提供更多输入,而基底桥脑和小脑核向晚生GrCs提供更多输入。早出生和晚出生的GrCs轴突的体内多深度双光子Ca2+成像揭示了两种群体对不同任务变量和刺激的表征,在编码运动、奖励预期和奖励消耗的比例上存在适度差异。我们的研究结果表明,苔藓纤维→GrC电路既不是有组织的并行处理,也不是完全随机组织,而是出生时间对GrC布线和编码的适度影响。我们的成像数据也提供了证据,表明除了最近描述的奖励表征外,GrCs还可以表征对厌恶刺激的广义反应。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The relationship between birth timing, circuit wiring, and physiological response properties of cerebellar granule cells
Significance Cerebellar granule cells (GrCs) comprise the majority of all neurons in the mammalian brain and are usually regarded as a uniform cell type. However, the birth timing of individual GrCs dictates where their axons project. Using viral-genetic techniques, we find that early- and late-born GrCs receive different proportions of inputs from the same set of input regions. In vivo multidepth two-photon Ca2+ imaging of axons of early- and late-born GrCs reveals that both populations represent diverse task variables and stimuli, with small differences in the proportions of axons in encoding of a subset of movement and reward parameters. These results indicate that birth timing makes a modest contribution to the input selection and physiological response properties of GrCs. Cerebellar granule cells (GrCs) are usually regarded as a uniform cell type that collectively expands the coding space of the cerebellum by integrating diverse combinations of mossy fiber inputs. Accordingly, stable molecularly or physiologically defined GrC subtypes within a single cerebellar region have not been reported. The only known cellular property that distinguishes otherwise homogeneous GrCs is the correspondence between GrC birth timing and the depth of the molecular layer to which their axons project. To determine the role birth timing plays in GrC wiring and function, we developed genetic strategies to access early- and late-born GrCs. We initiated retrograde monosynaptic rabies virus tracing from control (birth timing unrestricted), early-born, and late-born GrCs, revealing the different patterns of mossy fiber input to GrCs in vermis lobule 6 and simplex, as well as to early- and late-born GrCs of vermis lobule 6: sensory and motor nuclei provide more input to early-born GrCs, while basal pontine and cerebellar nuclei provide more input to late-born GrCs. In vivo multidepth two-photon Ca2+ imaging of axons of early- and late-born GrCs revealed representations of diverse task variables and stimuli by both populations, with modest differences in the proportions encoding movement, reward anticipation, and reward consumption. Our results suggest neither organized parallel processing nor completely random organization of mossy fiber→GrC circuitry but instead a moderate influence of birth timing on GrC wiring and encoding. Our imaging data also provide evidence that GrCs can represent generalized responses to aversive stimuli, in addition to recently described reward representations.
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