Transcriptomic and multi-scale network analyses reveal key drivers of cardiovascular disease

bioRxiv - Genomics Pub Date : 2024-09-16 DOI:10.1101/2024.09.11.612437

Bat-Ider Tumenbayar, Khanh Pham, John C Biber, Rhonda Drewes, Yongho Bae

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Abstract

Cardiovascular diseases (CVDs) and pathologies are often driven by changes in molecular signaling and communication, as well as in cellular and tissue components, particularly those involving the extracellular matrix (ECM), cytoskeleton, and immune response. The fine-wire vascular injury model is commonly used to study neointimal hyperplasia and vessel stiffening, but it is not typically considered a model for CVDs. In this paper, we hypothesize that vascular injury induces changes in gene expression, molecular communication, and biological processes similar to those observed in CVDs at both the transcriptome and protein levels. To investigate this, we analyzed gene expression in microarray datasets from injured and uninjured femoral arteries in mice two weeks post-injury, identifying 1,467 significantly and differentially expressed genes involved in several CVDs such as including vaso-occlusion, arrhythmia, and atherosclerosis. We further constructed a protein-protein interaction network with seven functionally distinct clusters, with notable enrichment in ECM, metabolic processes, actin-based process, and immune response. Significant molecular communications were observed between the clusters, most prominently among those involved in ECM and cytoskeleton organizations, inflammation, and cell cycle. Machine Learning Disease pathway analysis revealed that vascular injury-induced crosstalk between ECM remodeling and immune response clusters contributed to aortic aneurysm, neovascularization of choroid, and kidney failure. Additionally, we found that interactions between ECM and actin cytoskeletal reorganization clusters were linked to cardiac damage, carotid artery occlusion, and cardiac lesions. Overall, through multi-scale bioinformatic analyses, we demonstrated the robustness of the vascular injury model in eliciting transcriptomic and molecular network changes associated with CVDs, highlighting its potential for use in cardiovascular research.

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转录组和多尺度网络分析揭示心血管疾病的关键驱动因素

心血管疾病（CVD）和病理变化通常是由分子信号和通讯以及细胞和组织成分的变化所驱动的，特别是那些涉及细胞外基质（ECM）、细胞骨架和免疫反应的变化。细丝血管损伤模型常用于研究新内膜增生和血管硬化，但通常不被认为是心血管疾病的模型。在本文中，我们假设血管损伤会诱导基因表达、分子通讯和生物过程发生变化，这些变化在转录组和蛋白质水平上与心血管疾病中观察到的变化相似。为了研究这一点，我们分析了受伤两周后小鼠受伤和未受伤股动脉微阵列数据集中的基因表达，确定了 1467 个与血管闭塞、心律失常和动脉粥样硬化等几种心血管疾病有关的显著差异表达基因。我们进一步构建了一个蛋白质-蛋白质相互作用网络，其中有七个功能不同的群组，在 ECM、代谢过程、基于肌动蛋白的过程和免疫反应方面有明显的富集。在这些集群之间观察到了显著的分子交流，其中最突出的是那些参与 ECM 和细胞骨架组织、炎症和细胞周期的集群。机器学习疾病通路分析表明，血管损伤诱导的 ECM 重塑和免疫反应集群之间的串联导致了主动脉瘤、脉络膜新生血管和肾衰竭。此外，我们还发现 ECM 和肌动蛋白细胞骨架重组集群之间的相互作用与心脏损伤、颈动脉闭塞和心脏病变有关。总之，通过多尺度生物信息学分析，我们证明了血管损伤模型在引发与心血管疾病相关的转录组和分子网络变化方面的稳健性，突出了其在心血管研究中的应用潜力。

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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bioRxiv - Genomics

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