Zhu Xuwei, Yu Gaoxiang, Lv Ya, Yang Ningning, Zhao Yinuo, Li Feida, Zhao Jiayi, Chen Zhuliu, Lai Yingying, Chen Liang, Wang Xiangyang, Xiao Jian, Cai Yuepiao, Feng Yongzeng, Ding Jian, Gao Weiyang, Zhou Kailiang, Xu Hui
Department of Orthopaedics, The Second Affiliated Hospital and Yuying Children's Hospital of Wenzhou Medical University, No. 109 West Xueyuan Road, Lucheng District, Wenzhou 325027, China.
Zhejiang Provincial Key Laboratory of Orthopaedics, No. 109 West Xueyuan Road, Lucheng District, Wenzhou 325027, China.
Burns Trauma. 2024 Jun 9;12:tkae035. doi: 10.1093/burnst/tkae035. eCollection 2024.
Ensuring the survival of the distal end of a random flap during hypoperfusion (ischaemia) is difficult in clinical practice. Effective prevention of programmed cell death is a potential strategy for inhibiting ischaemic flap necrosis. The activation of stimulator of interferon genes (STING) pathway promotes inflammation and leads to cell death. The epidermal growth factor family member neuregulin-1 (NRG1) reduces cell death by activating the protein kinase B (AKT) signalling pathway. Moreover, AKT signalling negatively regulates STING activity. We aimed to verify the efficacy of NRG1 injection in protecting against flap necrosis. Additionally, we investigated whether NRG1 effectively enhances ischemic flap survival by inhibiting pyroptosis and necroptosis through STING suppression.
A random-pattern skin flap model was generated on the backs of C57BL/6 mice. The skin flap survival area was determined. The blood supply and vascular network of the flap was assessed by laser Doppler blood flow analysis. Cluster of differentiation 34 immunohistochemistry (IHC) and haematoxylin and eosin (H&E) staining of the flap sections revealed microvessels. Transcriptome sequencing analysis revealed the mechanism by which NRG1 promotes the survival of ischaemic flaps. The levels of angiogenesis, oxidative stress, necroptosis, pyroptosis and indicators associated with signalling pathways in flaps were examined by IHC, immunofluorescence and Western blotting. Packaging adeno-associated virus (AAV) was used to activate STING in flaps.
NRG1 promoted the survival of ischaemic flaps. An increased subcutaneous vascular network and neovascularization were found in ischaemic flaps after the application of NRG1. Transcriptomic gene ontology enrichment analysis and protein level detection indicated that necroptosis, pyroptosis and STING activity were reduced in the NRG1 group. The phosphorylation of AKT and forkhead box O3a (FOXO3a) were increased after NRG1 treatment. The increased expression of STING in flaps induced by AAV reversed the therapeutic effect of NRG1. The ability of NRG1 to phosphorylate AKT-FOXO3a, inhibit STING and promote flap survival was abolished after the application of the AKT inhibitor MK2206.
NRG1 inhibits pyroptosis and necroptosis by activating the AKT-FOXO3a signalling pathway to suppress STING activation and promote ischaemic flap survival.
在临床实践中,确保随意皮瓣远端在低灌注(缺血)期间存活是困难的。有效预防程序性细胞死亡是抑制缺血皮瓣坏死的一种潜在策略。干扰素基因刺激物(STING)通路的激活会促进炎症并导致细胞死亡。表皮生长因子家族成员神经调节蛋白-1(NRG1)通过激活蛋白激酶B(AKT)信号通路减少细胞死亡。此外,AKT信号通路对STING活性具有负调节作用。我们旨在验证注射NRG1在预防皮瓣坏死方面的疗效。此外,我们研究了NRG1是否通过抑制STING来抑制细胞焦亡和坏死性凋亡,从而有效提高缺血皮瓣的存活率。
在C57BL/6小鼠背部建立随意型皮瓣模型。测定皮瓣存活面积。通过激光多普勒血流分析评估皮瓣的血供和血管网络。皮瓣切片的分化簇34免疫组化(IHC)和苏木精-伊红(H&E)染色显示微血管。转录组测序分析揭示了NRG1促进缺血皮瓣存活的机制。通过IHC、免疫荧光和蛋白质印迹法检测皮瓣中血管生成、氧化应激、坏死性凋亡、细胞焦亡以及与信号通路相关指标的水平。使用包装腺相关病毒(AAV)激活皮瓣中的STING。
NRG1促进了缺血皮瓣的存活。应用NRG1后,缺血皮瓣中皮下血管网络增加且有新血管形成。转录组基因本体富集分析和蛋白质水平检测表明,NRG1组中坏死性凋亡、细胞焦亡和STING活性降低。NRG1处理后,AKT和叉头框O3a(FOXO3a)的磷酸化增加。AAV诱导的皮瓣中STING表达增加逆转了NRG1的治疗效果。应用AKT抑制剂MK2206后,NRG1磷酸化AKT-FOXO3a、抑制STING并促进皮瓣存活的能力被消除。
NRG1通过激活AKT-FOXO3a信号通路抑制细胞焦亡和坏死性凋亡,从而抑制STING激活并促进缺血皮瓣存活。
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