神经网络辅助的 COVID-19 仓鼠转录组数据人性化研究揭示了人类疾病的严重程度匹配状态。

IF 9.7 1区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL EBioMedicine Pub Date : 2024-10-01 Epub Date: 2024-09-23 DOI:10.1016/j.ebiom.2024.105312
Vincent D Friedrich, Peter Pennitz, Emanuel Wyler, Julia M Adler, Dylan Postmus, Kristina Müller, Luiz Gustavo Teixeira Alves, Julia Prigann, Fabian Pott, Daria Vladimirova, Thomas Hoefler, Cengiz Goekeri, Markus Landthaler, Christine Goffinet, Antoine-Emmanuel Saliba, Markus Scholz, Martin Witzenrath, Jakob Trimpert, Holger Kirsten, Geraldine Nouailles
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引用次数: 0

摘要

背景:将动物模型的研究结果转化为人类疾病,对于剖析疾病机制、开发和测试精确的治疗策略至关重要。2019年冠状病毒病(COVID-19)大流行凸显了这一需求,特别是对于显示疾病严重程度依赖性免疫反应的模型:单细胞转录组学(scRNAseq)能够以前所未有的分辨率揭示物种之间在分子和细胞水平上的异同。然而,能够进行详细匹配的计算方法仍然匮乏。在这里,我们提供了一种基于结构化 scRNAseq 的方法,并将其应用于来自人类和患有中度或重度 COVID-19 的仓鼠血液白细胞的 scRNAseq:将 COVID-19 患者的数据与中度(叙利亚仓鼠,Mesocricetus auratus)或重度(罗伯洛夫斯基仓鼠,Phodopus roborovskii)仓鼠模型的数据进行整合,发现大多数细胞状态在不同物种之间是共享的。使用变异自动编码器进行的基于神经网络的分析量化了不同物种和严重程度的总体转录组相似性,结果显示罗伯洛夫斯基仓鼠的中性粒细胞与重度 COVID-19 患者的相似性最高,而叙利亚仓鼠与中度患者的相似性更高,尤其是在经典单核细胞方面。我们进一步使用了转录组差异表达分析,以确定哪些疾病阶段和细胞类型显示出最强的转录变化:仓鼠的单核细胞和中性粒细胞对 COVID-19 的反应与人类最为相似。在所有物种中发现的疾病相关通路与干扰素反应或病毒复制抑制特别相关。对候选基因和特征的分析支持了这些结果。我们的结构化神经网络支持工作流程可应用于其他疾病,从而更好地确定具有跨物种相似病理机制的合适动物模型:这项工作得到了德国联邦教育与研究部(BMBF)的资助,资助编号为:01ZX1304B、01ZX1604B、01ZX1906A、01ZX1906B、01KI2124、01IS18026B,以及德国研究基金会(DFG)的资助,资助编号为:14933180、431232613。
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Neural network-assisted humanisation of COVID-19 hamster transcriptomic data reveals matching severity states in human disease.

Background: Translating findings from animal models to human disease is essential for dissecting disease mechanisms, developing and testing precise therapeutic strategies. The coronavirus disease 2019 (COVID-19) pandemic has highlighted this need, particularly for models showing disease severity-dependent immune responses.

Methods: Single-cell transcriptomics (scRNAseq) is well poised to reveal similarities and differences between species at the molecular and cellular level with unprecedented resolution. However, computational methods enabling detailed matching are still scarce. Here, we provide a structured scRNAseq-based approach that we applied to scRNAseq from blood leukocytes originating from humans and hamsters affected with moderate or severe COVID-19.

Findings: Integration of data from patients with COVID-19 with two hamster models that develop moderate (Syrian hamster, Mesocricetus auratus) or severe (Roborovski hamster, Phodopus roborovskii) disease revealed that most cellular states are shared across species. A neural network-based analysis using variational autoencoders quantified the overall transcriptomic similarity across species and severity levels, showing highest similarity between neutrophils of Roborovski hamsters and patients with severe COVID-19, while Syrian hamsters better matched patients with moderate disease, particularly in classical monocytes. We further used transcriptome-wide differential expression analysis to identify which disease stages and cell types display strongest transcriptional changes.

Interpretation: Consistently, hamsters' response to COVID-19 was most similar to humans in monocytes and neutrophils. Disease-linked pathways found in all species specifically related to interferon response or inhibition of viral replication. Analysis of candidate genes and signatures supported the results. Our structured neural network-supported workflow could be applied to other diseases, allowing better identification of suitable animal models with similar pathomechanisms across species.

Funding: This work was supported by German Federal Ministry of Education and Research, (BMBF) grant IDs: 01ZX1304B, 01ZX1604B, 01ZX1906A, 01ZX1906B, 01KI2124, 01IS18026B and German Research Foundation (DFG) grant IDs: 14933180, 431232613.

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来源期刊
EBioMedicine
EBioMedicine Biochemistry, Genetics and Molecular Biology-General Biochemistry,Genetics and Molecular Biology
CiteScore
17.70
自引率
0.90%
发文量
579
审稿时长
5 weeks
期刊介绍: eBioMedicine is a comprehensive biomedical research journal that covers a wide range of studies that are relevant to human health. Our focus is on original research that explores the fundamental factors influencing human health and disease, including the discovery of new therapeutic targets and treatments, the identification of biomarkers and diagnostic tools, and the investigation and modification of disease pathways and mechanisms. We welcome studies from any biomedical discipline that contribute to our understanding of disease and aim to improve human health.
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