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Homeostatic mechanisms regulate distinct aspects of cortical circuit dynamics.体内平衡机制调节皮质电路动力学的不同方面。
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Autism-Associated Shank3 Is Essential for Homeostatic Compensation in Rodent V1.自闭症相关 Shank3 对于啮齿动物 V1 的体内平衡补偿是必需的。
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Rapid and active stabilization of visual cortical firing rates across light-dark transitions.快速且活跃的视觉皮层在光暗转换中放电频率的稳定化。
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使用 CaMPARI2 进行体内活动标记揭示了具有高和低发放率设定点的神经元之间的内在和突触差异。

Activity labeling in vivo using CaMPARI2 reveals intrinsic and synaptic differences between neurons with high and low firing rate set points.

机构信息

Department of Biology, Brandeis University, Waltham, MA 02453, USA.

Department of Biology, Brandeis University, Waltham, MA 02453, USA.

出版信息

Neuron. 2021 Feb 17;109(4):663-676.e5. doi: 10.1016/j.neuron.2020.11.027. Epub 2020 Dec 16.

DOI:10.1016/j.neuron.2020.11.027
PMID:33333001
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7897300/
Abstract

Neocortical pyramidal neurons regulate firing around a stable mean firing rate (FR) that can differ by orders of magnitude between neurons, but the factors that determine where individual neurons sit within this broad FR distribution are not understood. To access low- and high-FR neurons for ex vivo analysis, we used Ca- and UV-dependent photoconversion of CaMPARI2 in vivo to permanently label neurons according to mean FR. CaMPARI2 photoconversion was correlated with immediate early gene expression and higher FRs ex vivo and tracked the drop and rebound in ensemble mean FR induced by prolonged monocular deprivation. High-activity L4 pyramidal neurons had greater intrinsic excitability and recurrent excitatory synaptic strength, while E/I ratio, local output strength, and local connection probability were not different. Thus, in L4 pyramidal neurons (considered a single transcriptional cell type), a broad mean FR distribution is achieved through graded differences in both intrinsic and synaptic properties.

摘要

新皮层锥体神经元围绕稳定的平均发放率(FR)进行调节,不同神经元之间的 FR 差异可达数量级,但决定单个神经元在这个广泛的 FR 分布中所处位置的因素尚不清楚。为了获得用于离体分析的低 FR 和高 FR 神经元,我们使用 Ca 和 UV 依赖性 CaMPARI2 光转化在体内根据平均 FR 永久标记神经元。CaMPARI2 光转化与即时早期基因表达和体外更高的 FR 相关,并跟踪了长时间单眼剥夺引起的整体平均 FR 的下降和反弹。高活性 L4 锥体神经元具有更高的内在兴奋性和复发性兴奋性突触强度,而 E/I 比、局部输出强度和局部连接概率则没有差异。因此,在 L4 锥体神经元(被认为是单一转录细胞类型)中,通过内在和突触特性的逐渐差异来实现广泛的平均 FR 分布。