O'Neill Karla M, Edgar Kevin S, Pun Shun Hay, Campbell David C, Toh Tinrui, Wong Xin N, Botezatu Bianca, Kandel Jyoti, McCoy Una, Nicell Jennifer, McClintock Catherine, McLoughlin Kiran J, Wu Yuxin, Madishetti Vinuthna Vani, Moez Arya, Alsaggaf Mohammed, Gill Eleanor K, Abudalo Rawan A, O'Neill Christina L, Pedrini Edoardo, Guduric-Fuchs Jasenka, Brunssen Coy, Morawietz Henning, Dunne Philip D, Watson Chris J, Medina Reinhold J, Grieve David J
Wellcome-Wolfson Institute for Experimental Medicine, Queen's University Belfast, Belfast, UK.
Faculty of Pharmaceutical Sciences, The Hashemite University, Zarqa, Jordan.
Stem Cell Res Ther. 2025 Jun 2;16(1):275. doi: 10.1186/s13287-025-04393-4.
Progenitor endothelial colony forming cells (ECFCs) are critical for vascular homeostasis and hold therapeutic potential for ischaemic cardiovascular disease (CVD). As angiogenic capacity and efficacy within diseased tissues is particularly impacted in diabetic patients, who show high incidence of ischaemic CVD, targeting of critical ECFC pathways in this setting represents an innovative focus towards enhancing intrinsic vasoreparative function. We previously reported that NADPH oxidase 4 (NOX4)-derived reactive oxygen species promote cord blood-derived ECFC (CB-ECFC) pro-angiogenic response, whilst NOX4 overexpression (OE) enhances revascularisation capacity. Here, we aimed to investigate specific influence of NOX4-dependent signalling on CB-ECFC angiogenic dysfunction observed upon exposure to both experimental and clinical diabetes to define whether NOX4 may represent a viable therapeutic target in this context.
CB-ECFCs were cultured in high glucose (D-glucose, 25 mmol/L) or control media (5 mmol/L) ± phorbol 12-myristate 13- acetate (PMA, 500 nmol/L) for 72 h with assessment of migratory/tubulogenic capacity and NOX4 mRNA expression (qRT-PCR). Detailed analysis of angiogenic function and signalling (Western blot, RNA sequencing) was performed in CB-ECFCs isolated from donors with gestational diabetes prior to NOX4 plasmid OE to define rescue potential and key mechanistic pathways (network analysis, proteome profiling). Statistical significance was determined using one-way ANOVA with Bonferroni post-host testing or paired/unpaired Student's t-test, as appropriate.
PMA-stimulated CB-ECFC migration and tube-forming capacity observed in control cells was suppressed in experimental diabetes in parallel with reduced NOX4 expression and rescued by plasmid NOX4OE. As direct evidence of clinical relevance, CB-ECFCs from gestational diabetic donors showed reduced angiogenic potential associated with attenuated NOX4, eNOS activity and downregulation of key vasoreparative signalling. Furthermore, NOX4OE rescued angiogenic function in chronically diabetic CB-ECFCs via modulation of downstream signalling involving both direct and indirect enhancement of pro-angiogenic protein expression (endoglin/SERPINE1/E2F1) linked to reduced p53 phosphorylation.
Taken together, these data indicate for the first time that reduced NOX4 expression plays a pivotal role in CB-ECFC angiogenic dysfunction linked with diabetes whilst highlighting NOX4-dependent signalling as a potential target to protect and augment their intrinsic vasoreparative capacity towards addressing current translational barriers.
祖细胞内皮集落形成细胞(ECFCs)对血管稳态至关重要,对缺血性心血管疾病(CVD)具有治疗潜力。由于患病组织内的血管生成能力和功效在糖尿病患者中受到特别影响,糖尿病患者缺血性CVD发病率高,在这种情况下靶向关键的ECFC途径代表了增强内在血管修复功能的创新重点。我们先前报道,烟酰胺腺嘌呤二核苷酸磷酸(NADPH)氧化酶4(NOX4)衍生的活性氧促进脐带血来源的ECFC(CB-ECFC)促血管生成反应,而NOX4过表达(OE)增强血管再生能力。在这里,我们旨在研究NOX4依赖性信号传导对实验性和临床糖尿病暴露后观察到的CB-ECFC血管生成功能障碍的具体影响,以确定在这种情况下NOX4是否可能代表一个可行的治疗靶点。
将CB-ECFCs在高糖(D-葡萄糖,25 mmol/L)或对照培养基(5 mmol/L)中培养72小时,并添加或不添加佛波醇12-肉豆蔻酸酯13-乙酸酯(PMA,500 nmol/L),评估其迁移/成管能力和NOX4 mRNA表达(qRT-PCR)。在NOX4质粒OE之前,对从妊娠期糖尿病供体分离的CB-ECFCs进行血管生成功能和信号传导的详细分析(蛋白质印迹、RNA测序),以确定挽救潜力和关键机制途径(网络分析、蛋白质组分析)。使用单因素方差分析和Bonferroni事后检验或配对/非配对学生t检验确定统计学意义,视情况而定。
在对照细胞中观察到的PMA刺激的CB-ECFC迁移和成管能力在实验性糖尿病中受到抑制,同时NOX4表达降低,并通过质粒NOX4OE挽救。作为临床相关性的直接证据,来自妊娠期糖尿病供体的CB-ECFCs显示血管生成潜力降低,与NOX4、内皮型一氧化氮合酶(eNOS)活性减弱以及关键血管修复信号的下调有关。此外,NOX4OE通过调节下游信号传导挽救慢性糖尿病CB-ECFCs的血管生成功能,该信号传导涉及直接和间接增强与p53磷酸化降低相关的促血管生成蛋白表达(内皮糖蛋白/SERPINE1/E2F1)。
综上所述,这些数据首次表明,NOX4表达降低在与糖尿病相关的CB-ECFC血管生成功能障碍中起关键作用,同时突出了NOX4依赖性信号传导作为保护和增强其内在血管修复能力以克服当前转化障碍的潜在靶点。
