启动小鼠平行听觉处理通路的细胞特化的综合分析。

Junzhan Jing, Ming Hu, Tenzin Ngodup, Qianqian Ma, Shu-Ning Natalie Lau, Cecilia Ljungberg, Matthew J McGinley, Laurence O Trussell, Xiaolong Jiang
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引用次数: 0

摘要

耳蜗核复合体(CN)是大脑中所有听觉处理的起点,它包括一套高度专门用于声学信号神经编码的神经元细胞类型。为了研究它们惊人的功能特异性是如何在分子水平上确定的,我们对小鼠CN进行了单核RNA测序,以从分子上定义所有组成细胞类型,然后使用Patch-seq将它们与形态学和电生理学定义的神经元相关联。我们揭示了一组扩展的分子CN细胞类型,包括所有先前描述的主要类型,并在地形和细胞生理特性方面发现了新的亚型。我们的结果定义了CN中一个完整的细胞类型分类,该分类符合解剖位置、形态学、生理学和分子标准。这种对细胞异质性和从分子到电路水平的专门化的高分辨率描述,现在能够以前所未有的特异性对听觉处理和听力障碍进行基因解剖。
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Molecular logic for cellular specializations that initiate the auditory parallel processing pathways.

The cochlear nuclear complex (CN), the starting point for all central auditory processing, comprises a suite of neuronal cell types that are highly specialized for neural coding of acoustic signals, yet molecular logic governing cellular specializations remains unknown. By combining single-nucleus RNA sequencing and Patch-seq analysis, we reveal a set of transcriptionally distinct cell populations encompassing all previously observed types and discover multiple new subtypes with anatomical and physiological identity. The resulting comprehensive cell-type taxonomy reconciles anatomical position, morphological, physiological, and molecular criteria, enabling the determination of the molecular basis of the remarkable cellular phenotypes in the CN. In particular, CN cell-type identity is encoded in a transcriptional architecture that orchestrates functionally congruent expression across a small set of gene families to customize projection patterns, input-output synaptic communication, and biophysical features required for encoding distinct aspects of acoustic signals. This high-resolution account of cellular heterogeneity from the molecular to the circuit level illustrates molecular logic for cellular specializations and enables genetic dissection of auditory processing and hearing disorders with unprecedented specificity.

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