Integrated transcriptomic and regulatory RNA profiling reflects complex pathophysiology and uncovers a conserved gene signature in end stage heart failure

IF 2.2

Journal of molecular and cellular cardiology plus Pub Date : 2025-01-03 DOI:10.1016/j.jmccpl.2025.100282

Amit Anand , Julius Punnen , U.M. Nagamalesh , Sabariya Selvam , Madhusudhan Bysani , Ramya Venkatesh , Kriti Nawin , Shilpa Garg , Bagirath Raghuraman , Varun Shetty , Senthil Kumaran , Manoj Dokania , Pradeep Narayan , Ankita Udwadia , Kushan Gunawardhana , David Gordon , Manjunath Ramarao , Lei Zhao , Jyoti Gulia

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Abstract

Background

Heart failure (HF) is a complex syndrome. Despite availability of multiple treatment options, the mortality remains high and the quality of life poor. Better understanding of the underlying pathophysiological processes can lead to development of novel therapies. Multiple comparative transcriptomics studies, which revealed gene level changes in the key pathophysiological pathways in failing hearts, point towards heterogeneity from interplay of disease stage, etiologies and ethnicity. Transcriptomic characterization of HF in patients from different ethnicities can potentially help in understanding the heterogeneity imparted by various factors and the core elements in heart failure.

Methods & results

An integrated analysis of bulk transcriptome and microRNA sequencing from the cardiac tissues of 30 South Asian (SA) patients having HF with reduced ejection fraction (HFrEF) and 19 control subjects was conducted. Plasma miRNAs from a subset of HFrEF and control patients were also sequenced to understand their biomarker potential. The altered transcriptome from the myocardium of SA HFrEF patients reflected cardiac muscle contraction, cellular energetics, altered immune signaling and extracellular matrix remodelling as predominant pathophysiological mechanisms. The SA HFrEF patients also showed dysregulation of multiple microRNAs in cardiac tissue like miR-216, miR-217, miR-184 and miR-9983. Many of these miRNAs, such as miR184 and few others, showed altered levels in both the plasma and cardiac tissue of HFrEF patients suggesting their biomarker potential. The diversity in the HFrEF transcriptomes from published studies led us to examine the core HF genes in our cohort. A gene signature generated using machine learning (ML) from the top dysregulated genes in SA HFrEF cohort stratified HF from controls in other cohorts. The sensitivity of the HF gene signature was further improved when union of two cohorts was used as a training set. Our ML analyses developed a core HF gene signature consisting of 21 genes that can stratify HF patients from controls with 98 % sensitivity in all the tested cohorts.

Conclusions

This study reveals molecular changes underlying the pathophysiology as reflected by coding and regulatory non-coding components of transcriptome from South Asian patients and uncovers a conserved gene signature for HF.

Abstract Image

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综合转录组学和调控RNA分析反映了复杂的病理生理，揭示了终末期心力衰竭的保守基因特征

心衰（HF）是一种复杂的综合征。尽管有多种治疗选择，但死亡率仍然很高，生活质量也很差。更好地了解潜在的病理生理过程可以导致新疗法的发展。多项比较转录组学研究揭示了心力衰竭中关键病理生理途径的基因水平变化，指出了疾病阶段、病因和种族相互作用的异质性。不同种族患者心衰的转录组学特征可能有助于理解各种因素和心衰核心因素所带来的异质性。方法,结果对30例南亚（SA） HF伴射血分数降低（HFrEF）患者和19例对照者的心脏组织进行了大量转录组和microRNA测序的综合分析。HFrEF患者和对照患者的血浆mirna也进行了测序，以了解其生物标志物潜力。SA HFrEF患者心肌转录组的改变反映了心肌收缩、细胞能量学、免疫信号改变和细胞外基质重塑是主要的病理生理机制。SA HFrEF患者还表现出心脏组织中miR-216、miR-217、miR-184和miR-9983等多种microrna的失调。许多这些mirna，如miR184和少数其他mirna，在HFrEF患者的血浆和心脏组织中显示出改变的水平，这表明它们的生物标志物潜力。来自已发表研究的HFrEF转录组的多样性促使我们在我们的队列中检查核心HF基因。使用机器学习（ML）从SA HFrEF队列中顶部失调基因生成的基因签名将其他队列中的对照HF分层。采用两组队列联合作为训练集，进一步提高了HF基因标记的敏感性。我们的ML分析开发了一个由21个基因组成的核心HF基因标记，可以在所有测试队列中以98%的灵敏度将HF患者与对照组进行分层。结论本研究揭示了南亚HF患者转录组编码和调控非编码成分所反映的病理生理基础的分子变化，并揭示了HF的保守基因特征。

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

Journal of molecular and cellular cardiology plus Cardiology and Cardiovascular Medicine

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审稿时长

31 days