Realistic mossy fiber input patterns to unipolar brush cells evoke a continuum of temporal responses comprised of components mediated by different glutamate receptors.

IF 6.4 1区生物学 Q1 BIOLOGY

eLife Pub Date : 2025-01-17 DOI:10.7554/eLife.102618

Vincent Huson, Wade G Regehr

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Abstract

Unipolar brush cells (UBCs) are excitatory interneurons in the cerebellar cortex that receive mossy fiber (MF) inputs and excite granule cells. The UBC population responds to brief burst activation of MFs with a continuum of temporal transformations, but it is not known how UBCs transform the diverse range of MF input patterns that occur in vivo. Here, we use cell-attached recordings from UBCs in acute cerebellar slices to examine responses to MF firing patterns that are based on in vivo recordings. We find that MFs evoke a continuum of responses in the UBC population, mediated by three different types of glutamate receptors that each convey a specialized component. AMPARs transmit timing information for single stimuli at up to 5 spikes/s, and for very brief bursts. A combination of mGluR2/3s (inhibitory) and mGluR1s (excitatory) mediates a continuum of delayed, and broadened responses to longer bursts, and to sustained high frequency activation. Variability in the mGluR2/3 component controls the time course of the onset of firing, and variability in the mGluR1 component controls the duration of prolonged firing. We conclude that the combination of glutamate receptor types allows each UBC to simultaneously convey different aspects of MF firing. These findings establish that UBCs are highly flexible circuit elements that provide diverse temporal transformations that are well suited to contribute to specialized processing in different regions of the cerebellar cortex.

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苔藓纤维对单极刷状细胞的真实输入模式引起了由不同谷氨酸受体介导的组分组成的连续时间反应。

单极刷细胞（ubc）是小脑皮层的兴奋性中间神经元，接受苔藓纤维（MF）输入并兴奋颗粒细胞。UBC种群通过连续的时间转换对MFs的短暂突发激活做出反应，但目前尚不清楚UBC如何转换体内发生的各种MF输入模式。在这里，我们使用急性小脑切片中ubc的细胞附着记录来检查基于体内记录的中频放电模式的反应。我们发现MFs在UBC人群中引起连续的反应，由三种不同类型的谷氨酸受体介导，每种受体都传递一种专门的成分。ampar以高达5个尖峰/秒的速度传输单个刺激的定时信息，并且非常短的脉冲。mGluR2/3s（抑制性）和mGluR1s（兴奋性）的组合介导了连续的延迟反应，并对更长的爆发和持续的高频激活产生了反应。mGluR2/3组分的可变性控制了放电开始的时间过程，而mGluR1组分的可变性控制了延长放电的持续时间。我们得出结论，谷氨酸受体类型的组合允许每个UBC同时传递MF放电的不同方面。这些发现表明，ubc是高度灵活的电路元件，提供不同的时间转换，非常适合于在小脑皮层的不同区域进行专门的处理。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

eLife BIOLOGY-

CiteScore

12.90

自引率

3.90%

发文量

3122

审稿时长

17 weeks

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