Exploring Dysregulated Ferroptosis-Related Genes in Septic Myocardial Injury Based on Human Heart Transcriptomes: Evidence and New Insights

• Published in: Journal of inflammation research Vol. 16; pp. 995 - 1015
• Main Authors: Zou, Hua-Xi, Hu, Tie, Zhao, Jia-Yi, Qiu, Bai-Quan, Zou, Chen-Chao, Xu, Qi-Rong, Liu, Ji-Chun, Lai, Song-Qing, Huang, Huang
• Format: Journal Article
• Language: English
• Published: New Zealand Dove Medical Press Limited 01.01.2023; Taylor & Francis Ltd; Dove; Dove Medical Press
• Subjects: Apoptosis; Bioengineering; Bioinformatics; Cell death; Datasets; Drug development; Ethics; Ferroptosis; Genes; Genetic transcription; Health aspects; Heart; heart transcriptome; Homeostasis; Immunosuppressive agents; Intensive care; Intensive care units; Iron; key genes; Kinases; Laboratory animals; Lipid peroxidation; Lipopolysaccharides; Medical diagnosis; Mortality; NOX4 protein; Original Research; p53 Protein; Prognosis; Protein interaction; Protein-protein interactions; PTEN protein; Sepsis; septic myocardial injury; Software; Stat3 protein; Therapeutic targets; Transcriptomes; Tumor necrosis factor-TNF; Tumor proteins; China; United States > US; Switzerland; Japan; database; ferroptosis; heart transcriptome; key genes; septic myocardial injury
• ISSN: 1178-7031; 1178-7031
• DOI: 10.2147/JIR.S400107

Sepsis is currently a common condition in emergency and intensive care units, and is defined as life-threatening organ dysfunction caused by a dysregulated host response to infection. Cardiac dysfunction caused by septic myocardial injury (SMI) is associated with adverse prognosis and has significant economic and human costs. The pathophysiological mechanisms underlying SMI have long been a subject of interest. Recent studies have identified ferroptosis, a form of programmed cell death associated with iron accumulation and lipid peroxidation, as a pathological factor in the development of SMI. However, the current understanding of how ferroptosis functions and regulates in SMI remains limited, particularly in the absence of direct evidence from human heart. We performed a sequential comprehensive bioinformatics analysis of human sepsis cardiac transcriptome data obtained through the GEO database. The lipopolysaccharide-induced mouse SMI model was used to validate the ferroptosis features and transcriptional expression of key genes. We identified widespread dysregulation of ferroptosis-related genes (FRGs) in SMI based on the human septic heart transcriptomes, deeply explored the underlying biological mechanisms and crosstalks, followed by the identification of key functional modules and hub genes through the construction of protein-protein interaction network. Eight key FRGs that regulate ferroptosis in SMI, including HIF1A, MAPK3, NOX4, PPARA, PTEN, RELA, STAT3 and TP53, were identified, as well as the ferroptosis features. All the key FRGs showed excellent diagnostic capability for SMI, part of them was associated with the prognosis of sepsis patients and the immune infiltration in the septic hearts, and potential ferroptosis-modulating drugs for SMI were predicted based on key FRGs. This study provides human septic heart transcriptome-based evidence and brings new insights into the role of ferroptosis in SMI, which is significant for expanding the understanding of the pathobiological mechanisms of SMI and exploring promising diagnostic and therapeutic targets for SMI.