H2S regulation of iron homeostasis by IRP1 improves vascular smooth muscle cell functions

Identifying key targets and immune environment in wound healing based on iron overload-related genes

Wound healing (WH) poses a significant socio-economic burden due to its high incidence and recurrence rates. Iron overload (IO) could be a factor leading to delayed WH. This study thus analyzed IO-related genes (IORGs) in WH, offering possibilities for developing new therapeutic strategies. Differential gene expression (DEGs) analysis was conducted between the WH group and intact skin (IS) group, intersected with IORGs to obtain differentially expressed IORGs (DE-IORGs). Functional enrichment analysis and potential drug screening were performed on DE-IORGs. A protein-protein interaction (PPI) network of DE-IORGs was constructed, and hub genes were identified using CytoHubba and MCODE methods. ROC curves of hub genes were plotted, and their expression levels in WH and IS groups as well as inter-gene correlations were analyzed. Additionally, immune infiltration variances in WH and IS groups, along with miRNA and TFs of hub genes, were examined. Finally, the effect of EGFR on skin wound healing was verified by scratch healing assay. 39 DE-IORGs were predominantly enriched in signaling pathways like HIF-1 signaling pathway and Th17 cell differentiation. Potential drugs for treating WH (e.g., felbamate, SA-94315, GANT-58, rucaparib) were identified. Three hub genes related to IO in WH were pinpointed (HIF1A, CDKN2A, EGFR) with diagnostic value. Immune infiltration analysis showed higher levels of immune cells like endothelial cells and macrophages in the WH group. Additionally, 55 miRNAs (e.g., hsa-mir-200a-3p, hsa-mir-218-5p) and 2 TFs (L3MBTL2, ZNF76) regulating the three hub genes were predicted. Cell experiments showed that EGFR could promote skin wound healing. The study suggested HIF1A, CDKN2A, and EGFR as potential diagnostic biomarkers for effective WH diagnosis, offering new insights into identifying potenti1al therapeutic targets for WH treatment.

Ferroptosis in age-related vascular diseases: Molecular mechanisms and innovative therapeutic strategies

Aging, an inevitable aspect of human existence, serves as one of the predominant risk factors for vascular diseases. Delving into the mystery of vascular disease's pathophysiology, the profound involvement of programmed cell death (PCD) has been extensively demonstrated. PCD is a fundamental biological process that plays a crucial role in both normal physiology and pathology, including a recently discovered form, ferroptosis. Ferroptosis is characterized by its reliance on iron and lipid peroxidation, and its significant involvement in vascular disease pathophysiology has been increasingly acknowledged. This phenomenon not only offers a promising therapeutic target but also deepens our understanding of the complex relationship between ferroptosis and age-related vascular diseases. Consequently, this article aims to thoroughly review the mechanisms that enable the effective control and inhibition of ferroptosis. It focuses on genetic and pharmacological interventions, with the goal of developing innovative therapeutic strategies to combat age-related vascular diseases.

H2S Protects from Rotenone-Induced Ferroptosis by Stabilizing Fe-S Clusters in Rat Cardiac Cells

Hydrogen sulfide (H2S) has been recently recognized as an important gasotransmitter with cardioprotections, and iron is vital for various cellular activities. This study explored the regulatory role of H2S on iron metabolism and mitochondrial functions in cultured rat cardiac cells. Rotenone, a mitochondrial complex I inhibitor, was used for establishing an in vitro model of ischemic cell damage. It was first found that rotenone induced oxidative stress and lipid peroxidation and decreased mitochondrial membrane potential and ATP generation, eventually causing cell death. The supplement of H2S at a physiologically relevant concentration protected from rotenone-induced ferroptotic cell death by reducing oxidative stress and mitochondrial damage, maintaining GPx4 expression and intracellular iron level. Deferiprone, an iron chelator, would also protect from rotenone-induced ferroptosis. Further studies demonstrated that H2S inhibited ABCB8-mediated iron efflux from mitochondria to cytosol and promoted NFS1-mediated Fe-S cluster biogenesis. It is also found that rotenone stimulated iron-dependent H2S generation. These results indicate that H2S would protect cardiac cells from ischemic damage through preserving mitochondrial functions and intracellular Fe-S cluster homeostasis.