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寻找跨亚型、区域和物种的神经元放电率适应性的转录组学关联:一项膜片钳测序分析

In Search of Transcriptomic Correlates of Neuronal Firing-Rate Adaptation across Subtypes, Regions and Species: A Patch-seq Analysis.

作者信息

Meng John Hongyu, Kang Yijie, Lai Alan, Feyerabend Michael, Inoue Wataru, Martinez-Trujillo Julio, Rudy Bernardo, Wang Xiao-Jing

机构信息

Center for Neural Science, New York University, New York, 10003, NY, United States.

Current address: Graduate School, Stony Brook University, Stony Brook, 11794, NY, United States.

出版信息

bioRxiv. 2024 Dec 10:2024.12.05.627057. doi: 10.1101/2024.12.05.627057.

DOI:10.1101/2024.12.05.627057
PMID:39713292
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11661064/
Abstract

Can the transcriptomic profile of a neuron predict its physiological properties? Using a Patch-seq dataset of the primary visual cortex, we addressed this question by focusing on spike rate adaptation (SRA), a well-known phenomenon that depends on small conductance calcium (Ca)-dependent potassium (SK) channels. We first show that in parvalbumin-expressing (PV) and somatostatin-expressing (SST) interneurons (INs), expression levels of genes encoding the ion channels underlying action potential generation are correlated with the half-width (HW) of spikes. Surprisingly, the SK encoding gene is not correlated with the degree of SRA (dAdap). Instead, genes that encode proteins upstream from the SK current are correlated with dAdap, a finding validated by a different dataset from the mouse's primary motor cortex that includes pyramidal cells and interneurons, as well as physiological datasets from multiple regions of macaque monkeys. Finally, we construct a minimal model to reproduce observed heterogeneity across cells, with testable predictions.

摘要

神经元的转录组图谱能否预测其生理特性?利用初级视觉皮层的Patch-seq数据集,我们通过聚焦于放电率适应(SRA)来解决这个问题,SRA是一种依赖于小电导钙(Ca)依赖性钾(SK)通道的著名现象。我们首先表明,在表达小白蛋白(PV)和生长抑素(SST)的中间神经元(INs)中,编码动作电位产生所涉及离子通道的基因表达水平与尖峰的半高宽(HW)相关。令人惊讶的是,编码SK的基因与SRA的程度(dAdap)不相关。相反,编码SK电流上游蛋白质的基因与dAdap相关,这一发现通过来自小鼠初级运动皮层的不同数据集得到验证,该数据集包括锥体细胞和中间神经元,以及来自猕猴多个区域的生理数据集。最后,我们构建了一个最小模型来重现观察到的细胞间异质性,并给出了可检验的预测。

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