Cellular-resolution gene expression mapping reveals organization in the head ganglia of the gastropod, Berghia stephanieae

IF 2.3 4区医学 Q3 NEUROSCIENCES

Journal of Comparative Neurology Pub Date : 2024-06-09 DOI:10.1002/cne.25628

M. Desmond Ramirez, Thi N. Bui, Paul S. Katz

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Abstract

Gastropod molluscs such as Aplysia, Lymnaea, and Tritonia have been important for determining fundamental rules of motor control, learning, and memory because of their large, individually identifiable neurons. Yet only a small number of gastropod neurons have known molecular markers, limiting the ability to establish brain-wide structure–function relations. Here we combine high-throughput, single-cell RNA sequencing with in situ hybridization chain reaction in the nudibranch Berghia stephanieae to identify and visualize the expression of markers for cell types. Broad neuronal classes were characterized by genes associated with neurotransmitters, like acetylcholine, glutamate, serotonin, and GABA, as well as neuropeptides. These classes were subdivided by other genes including transcriptional regulators and unannotated genes. Marker genes expressed by neurons and glia formed discrete, previously unrecognized regions within and between ganglia. This study provides the foundation for understanding the fundamental cellular organization of gastropod nervous systems.

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细胞分辨率基因表达图谱揭示腹足类动物头部神经节的组织结构

腹足类软体动物（如 Aplysia、Lymnaea 和 Tritonia）因其庞大且可单独识别的神经元，对于确定运动控制、学习和记忆的基本规则非常重要。然而，只有少数腹足类神经元有已知的分子标记，这限制了建立全脑结构-功能关系的能力。在这里，我们将高通量单细胞 RNA 测序与原位杂交连锁反应相结合，在裸鳃亚纲的 Berghia stephanieae 中识别和观察细胞类型标记物的表达。通过与乙酰胆碱、谷氨酸、5-羟色胺和 GABA 等神经递质以及神经肽相关的基因，确定了神经元大类的特征。这些类别又被其他基因（包括转录调节因子和未注释基因）细分。神经元和神经胶质细胞表达的标记基因在神经节内部和神经节之间形成了以前未识别的离散区域。这项研究为了解腹足类神经系统的基本细胞组织奠定了基础。

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来源期刊

Journal of Comparative Neurology 医学-动物学

CiteScore

5.80

自引率

8.00%

发文量

158

审稿时长

3-6 weeks

期刊介绍： Established in 1891, JCN is the oldest continually published basic neuroscience journal. Historically, as the name suggests, the journal focused on a comparison among species to uncover the intricacies of how the brain functions. In modern times, this research is called systems neuroscience where animal models are used to mimic core cognitive processes with the ultimate goal of understanding neural circuits and connections that give rise to behavioral patterns and different neural states. Research published in JCN covers all species from invertebrates to humans, and the reports inform the readers about the function and organization of nervous systems in species with an emphasis on the way that species adaptations inform about the function or organization of the nervous systems, rather than on their evolution per se. JCN publishes primary research articles and critical commentaries and review-type articles offering expert insight in to cutting edge research in the field of systems neuroscience; a complete list of contribution types is given in the Author Guidelines. For primary research contributions, only full-length investigative reports are desired; the journal does not accept short communications.