Characterizing dysregulations via cell-cell communications in Alzheimer's brains using single-cell transcriptomes.

IF 2.4 4区医学 Q3 NEUROSCIENCES

BMC Neuroscience Pub Date : 2024-05-13 DOI:10.1186/s12868-024-00867-y

Che Yu Lee, Dylan Riffle, Yifeng Xiong, Nadia Momtaz, Yutong Lei, Joseph M Pariser, Diptanshu Sikdar, Ahyeon Hwang, Ziheng Duan, Jing Zhang

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引用次数: 0

Abstract

Background: Alzheimer's disease (AD) is a devastating neurodegenerative disorder affecting 44 million people worldwide, leading to cognitive decline, memory loss, and significant impairment in daily functioning. The recent single-cell sequencing technology has revolutionized genetic and genomic resolution by enabling scientists to explore the diversity of gene expression patterns at the finest resolution. Most existing studies have solely focused on molecular perturbations within each cell, but cells live in microenvironments rather than in isolated entities. Here, we leveraged the large-scale and publicly available single-nucleus RNA sequencing in the human prefrontal cortex to investigate cell-to-cell communication in healthy brains and their perturbations in AD. We uniformly processed the snRNA-seq with strict QCs and labeled canonical cell types consistent with the definitions from the BRAIN Initiative Cell Census Network. From ligand and receptor gene expression, we built a high-confidence cell-to-cell communication network to investigate signaling differences between AD and healthy brains.

Results: Specifically, we first performed broad communication pattern analyses to highlight that biologically related cell types in normal brains rely on largely overlapping signaling networks and that the AD brain exhibits the irregular inter-mixing of cell types and signaling pathways. Secondly, we performed a more focused cell-type-centric analysis and found that excitatory neurons in AD have significantly increased their communications to inhibitory neurons, while inhibitory neurons and other non-neuronal cells globally decreased theirs to all cells. Then, we delved deeper with a signaling-centric view, showing that canonical signaling pathways CSF, TGFβ, and CX3C are significantly dysregulated in their signaling to the cell type microglia/PVM and from endothelial to neuronal cells for the WNT pathway. Finally, after extracting 23 known AD risk genes, our intracellular communication analysis revealed a strong connection of extracellular ligand genes APP, APOE, and PSEN1 to intracellular AD risk genes TREM2, ABCA1, and APP in the communication from astrocytes and microglia to neurons.

Conclusions: In summary, with the novel advances in single-cell sequencing technologies, we show that cellular signaling is regulated in a cell-type-specific manner and that improper regulation of extracellular signaling genes is linked to intracellular risk genes, giving the mechanistic intra- and inter-cellular picture of AD.

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利用单细胞转录组表征阿尔茨海默氏症大脑中细胞间通讯失调的特征。

背景：阿尔茨海默病（AD）是一种破坏性神经退行性疾病，影响着全球 4400 万人，导致认知能力下降、记忆力减退和日常功能严重受损。最近的单细胞测序技术使科学家们能够以最精细的分辨率探索基因表达模式的多样性，从而彻底改变了遗传和基因组分辨率。现有的大多数研究只关注每个细胞内的分子扰动，但细胞生活在微环境中，而不是孤立的实体。在这里，我们利用大规模公开的人类前额叶皮层单核 RNA 测序来研究健康大脑中细胞间的交流以及它们在 AD 中的扰动。我们以严格的质量控制统一处理 snRNA-seq，并按照 BRAIN Initiative 细胞普查网络的定义标注了标准细胞类型。通过配体和受体基因表达，我们建立了一个高置信度的细胞间通讯网络，以研究AD和健康大脑之间的信号差异：具体来说，我们首先进行了广泛的通讯模式分析，以强调正常大脑中与生物相关的细胞类型在很大程度上依赖于重叠的信号网络，而AD大脑则表现出细胞类型和信号通路的不规则混合。其次，我们以细胞类型为中心进行了更有针对性的分析，发现AD患者的兴奋性神经元与抑制性神经元之间的通讯显著增加，而抑制性神经元和其他非神经元细胞与所有细胞之间的通讯全面减少。然后，我们以信号传导为中心进行了深入研究，结果显示，CSF、TGFβ和CX3C等典型信号传导通路与小胶质细胞/PVM等细胞类型之间的信号传导以及WNT通路从内皮细胞到神经细胞之间的信号传导均出现了明显失调。最后，在提取了23个已知的AD风险基因后，我们的细胞内通讯分析表明，在从星形胶质细胞和小胶质细胞到神经元的通讯过程中，细胞外配体基因APP、APOE和PSEN1与细胞内AD风险基因TREM2、ABCA1和APP存在紧密联系：总之，借助单细胞测序技术的新进展，我们发现细胞信号传导是以细胞类型特异性的方式进行调控的，细胞外信号传导基因的不当调控与细胞内风险基因相关联，从而揭示了AD的细胞内和细胞间机理。

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

BMC Neuroscience 医学-神经科学

CiteScore

3.90

自引率

0.00%

发文量

审稿时长

16 months

期刊介绍： BMC Neuroscience is an open access, peer-reviewed journal that considers articles on all aspects of neuroscience, welcoming studies that provide insight into the molecular, cellular, developmental, genetic and genomic, systems, network, cognitive and behavioral aspects of nervous system function in both health and disease. Both experimental and theoretical studies are within scope, as are studies that describe methodological approaches to monitoring or manipulating nervous system function.