瑞马唑仑调控Nrf2/HO-1信号通路对哮喘小鼠气道炎症的影响*

doi:10.3870/j.issn.1672-0741.25.06.023

摘要/Abstract

摘要： 目的探讨瑞马唑仑对卵清蛋白(OVA)诱导的支气管哮喘小鼠气道炎症及氧化应激的作用及其可能机制。方法将40只SPF级雄性BALB／c小鼠(6～8周龄,体重18～20 g),随机分为4组(n=10):对照组(Control组)、哮喘组(OVA组)、瑞马唑仑干预组(OVA+RMZL组)、地塞米松(DEX)干预组(OVA+DEX组)。采用卵清蛋白(OVA)致敏和激发两个阶段建立哮喘小鼠模型。在每次激发前1 h,腹腔注射瑞马唑仑(10 mg／kg),Control组用PBS(pH 7.4)代替。肺功能仪检测小鼠气道压力;以HE染色和PAS染色检测各组小鼠肺组织病理变化和黏液分泌水平,ELISA法检测支气管肺泡灌洗液(BALF)中IL-4、IL-5、IL-13及INF-γ和小鼠血清OVA特异性IgE浓度;以活性氧(SOD)、丙二醛(MDA)、超氧化物歧化酶(SOD)和还原型谷胱甘肽(GSH)试剂盒检测各组小鼠肺组织MDA、SOD、GSH水平;RT-PCR法检测小鼠肺组织中核转录因子E2相关因子2(Nrf2)及血红素加氧酶-1(HO-1)的蛋白表达水平和mRNA的表达水平。免疫组织化学检测小鼠肺组织中Nrf2核转移。结果与Control组比较,哮喘模型组小鼠的气道压力、肺组织炎症和黏液分泌评分、BALF中Th2细胞因子(包括IL-4、IL-5、IL-13)及血浆中特异性IgE水平、ROS和MDA含量、Nrf2和HO-1的mRNA表达水平和Nrf2、HO-1和NQO1蛋白表达水平显著升高(均P<0.05),而Th1细胞因子(INF-γ)表达水平、SOD和GSH水平显著降低(均P<0.05);与OVA组比较,RMZL和DEX干预组小鼠的气道压力、肺组织炎症和黏液分泌评分、肺泡灌洗液BALF中Th2细胞因子(包括IL-4、IL-5、IL-13)及血浆中特异性IgE水平、ROS和MDA含量显著降低(均P<0.05),而Th1细胞因子(INF-γ)表达水平、SOD和GSH水平、Nrf2和HO-1的mRNA表达水平和Nrf2、HO-1和NQO1蛋白表达水平均显著升高(均P<0.05)。结论瑞马唑仑能够减轻哮喘小鼠气道炎症,改善哮喘小鼠肺组织氧化应激反应,其机制可能与瑞马唑仑增强Nrf2/HO-1信号通路有关。

关键词: 瑞马唑仑, 哮喘, 氧化应激, 核转录因子E2相关因子2, 血红素加氧酶-1

Abstract: Objective To investigate the effects of remimazolam on airway inflammation and oxidative stress in a mouse model of ovalbumin(OVA)-induced bronchial asthma and explore the potential underlying mechanism of this effect. Methods Forty specific pathogen-free(SPF)male BALB/c mice(6-8 weeks old,18-20 g)were randomly divided into 4 groups(n=10 per group):control group,OVA-induced asthma group(OVA group),remimazolam intervention group(OVA+RMZL group),and dexamethasone(DEX)positive control group(OVA+DEX group).The bronchial asthma model was established via OVA sensitization followed by OVA challenge.One hour prior to each challenge,the mice in the OVA+RMZL group received an intraperitoneal injection of remimazolam(10 mg/kg),whereas the mice in the control group were administered phosphate-buffered saline(PBS,pH 7.4)instead.Airway pressure was measured via a lung function analyzer.Hematoxylin-eosin(HE)staining and periodic acid-Schiff(PAS)staining were performed to assess pathological changes and mucus secretion in lung tissues,respectively.An enzyme-linked immunosorbent assay(ELISA)was used to determine the concentrations of interleukin(IL)-4,IL-5,IL-13,and interferon-γ(IFN-γ)in bronchoalveolar lavage fluid(BALF),and OVA-specific immunoglobulin E(IgE)in serum.The levels of malondialdehyde(MDA),superoxide dismutase(SOD),and reduced glutathione(GSH)in lung tissues were detected via commercial assay kits.Reverse transcription-polymerase chain reaction(RT-PCR)and Western blotting were employed to measure the mRNA and protein expression levels of nuclear factor erythroid 2-related factor 2(Nrf2)and heme oxygenase-1(HO-1),respectively,in lung tissues.Additionally,immunohistochemistry was used to evaluate the nuclear translocation of Nrf2 in lung tissues. Results Compared with the control group,the OVA group presented a significant increase in airway pressure,scores of lung inflammation and mucus secretion,levels of T helper 2(Th2)cytokines(IL-4,IL-5,IL-13)in BALF,serum OVA-specific IgE concentration,contents of reactive oxygen species(ROS)and MDA,as well as the mRNA and protein expression levels of Nrf2,HO-1,and NAD(P)H:quinone oxidoreductase 1(NQO1)(all P<0.05).In contrast,the OVA group presented significant decreases in the BALF IFN-γ level,SOD activity,and GSH content(all P<0.05).Compared with the OVA group,both the OVA+RMZL and OVA+DEX groups presented significant reductions in airway pressure,scores of lung inflammation and mucus secretion,levels of Th2 cytokines(IL-4,IL-5,IL-13)in BALF,serum OVA-specific IgE concentration,and contents of ROS and MDA(all P<0.05).Conversely,these two intervention groups presented significant increases in the IFN-γ level,SOD activity,GSH content,and Nrf2,HO-1,and NQO1 mRNA and protein expression levels(all P<0.05). Conclusion Remimazolam can alleviate airway inflammation and ameliorate oxidative stress in the lung tissues of OVA-induced asthmatic mice.The protective effect of remimazolam may be attributed to its ability to activate the Nrf2/HO-1 signaling pathway.

Key words: Remimazolam, asthma, oxidative stress, Nrf2, HO-1

中图分类号:

R562.25

张琼, 张涛, 李娜, 吴志林. 瑞马唑仑调控Nrf2/HO-1信号通路对哮喘小鼠气道炎症的影响^*[J]. 华中科技大学学报（医学版）, 2026, 55(1): 20-26.

Zhang Qiong, Zhang Tao, Li Na et al. Effect of Remimazolam on Airway Inflammation in Asthmatic Mice via the Regulation of the Nrf2/HO-1 Signaling Pathway[J]. Acta Medicinae Universitatis Scientiae et Technologiae Huazhong, 2026, 55(1): 20-26.

参考文献

[1] Habib N,Pasha M A,Tang D D.Current understanding of asthma pathogenesis and biomarkers[J].Cells,2022,11(17):4321-4335.
[2] Athari S S.Targeting cell signaling in allergic asthma[J].Signal Transduct Target Ther,2019,4(45):1-19.
[3] Gans M D,Gavrilova T.Understanding the immunology of asthma:Pathophysiology,biomarkers,and treatments for asthma endotypes[J].Paediatr Respir Rev,2020,36:118-127.
[4] Zhou J,Iwasaki S,Watanabe A,et al.Synergic bronchodilator effects of a phosphodiesterase 3 inhibitor olprinone with a volatile anaesthetic sevoflurane in ovalbumin-sensitised guinea pigs[J].Eur J Anaesthesiol,2011,28(7):519-524.
[5] Keam S J.Remimazolam:First approval[J].Drugs,2020,80(6):625-633.
[6] Fang H,Zhang Y,Wang J,et al.Remimazolam reduces sepsis-associated acute liver injury by activation of peripheral benzodiazepine receptors and p38 inhibition of macrophages[J].Int Immunopharmacol,2021,101(Pt B):108331.
[7] Shi M,Chen J,Liu T,et al.Protective effects of remimazolam on cerebral ischemia/reperfusion injury in rats by inhibiting of NLRP3 inflammasome-dependent pyroptosis[J].Drug Des Devel Ther,2022,16:413-423.
[8] Xu H,Chen Y,Xie P,et al.Remimazolam attenuates myocardial ischemia-reperfusion injury by inhibiting the NF-κB pathway of macrophage inflammation[J].Eur J Pharmacol,2024,965:176276.
[9] Zhang W,Nie Y,Chong L,et al.PI3K and Notch signal pathways coordinately regulate the activation and proliferation of T lymphocytes in asthma[J].Life Sci,2013,92(17/18/19):890-895.
[10] Komlosi Z I,van de Veen W,Kovacs N,et al.Cellular and molecular mechanisms of allergic asthma[J].Mol Aspects Med,2022,85:100995.
[11] Hammad H,Lambrecht B N.The basic immunology of asthma[J].Cell,2021,184(6):1469-1485.
[12] Papadopoulos N G,Miligkos M,Xepapadaki P.A current perspective of allergic asthma:From mechanisms to management[J].Handb Exp Pharmacol,2022,268:69-93.
[13] Mattes J,Yang M,Mahalingam S,et al.Intrinsic defect in T cell production of interleukin(IL)-13 in the absence of both IL-5 and eotaxin precludes the development of eosinophilia and airways hyperreactivity in experimental asthma[J].J Exp Med,2002,195(11):1433-1444.
[14] Lambrecht B N,Hammad H,Fahy J V.The cytokines of asthma[J].Immunity,2019,50(4):975-991.
[15] Meli A P,Fontes G,Leung Soo C,et al.T follicular helper cell-derived IL-4 is required for IgE production during intestinal helminth infection[J].J Immunol,2017,199(1):244-252.
[16] O′Byrne P M.Cytokines or their antagonists for the treatment of asthma[J].Chest,2006,130(1):244-250.
[17] Matera M G,Ora J,Calzetta L,et al.Investigational anti IL-13 asthma treatments:A 2023 update[J].Expert Opin Investig Drugs,2023,32(5):373-386.
[18] Gowthaman U,Chen J S,Zhang B,et al.Identification of a T follicular helper cell subset that drives anaphylactic IgE[J].Science,2019,365(6456):1034-1039.
[19] Kobayashi T,Iijima K,Dent A L,et al.Follicular helper T cells mediate IgE antibody response to airborne allergens[J].J Allergy Clin Immunol,2017,139(1):300-313.e7.
[20] Sahiner U M,Birben E,Erzurum S,et al.Oxidative stress in asthma:Part of the puzzle[J].Pediatr Allergy Immunol,2018,29(8):789-800.
[21] Michaeloudes C,Abubakar-Waziri H,Lakhdar R,et al.Molecular mechanisms of oxidative stress in asthma[J].Mol Aspects Med,2022,85:101026.
[22] Cho Y S,Moon H B.The role of oxidative stress in the pathogenesis of asthma[J].Allergy Asthma Immunol Res,2010,2(3):183-187.
[23] Zhang H X,Liu S J,Tang X L,et al.H2 S attenuates LPS-induced acute lung injury by reducing oxidative/nitrative stress and inflammation[J].Cell Physiol Biochem,2016,40(6):1603-1612.
[24] Sanchez-Ortega M,Carrera A C,Garrido A.Role of NRF2 in lung cancer[J].Cells,2021,10(8),1879;
[25] Choi G,Ju H Y,Bok J,et al.NRF2 is a spatiotemporal metabolic hub essential for the polyfunctionality of Th2 cells[J].Proc Natl Acad Sci U S A,2024,121(28):e2319994121.
[26] Rangasamy T,Guo J,Mitzner W A,et al.Disruption of Nrf2 enhances susceptibility to severe airway inflammation and asthma in mice[J].J Exp Med,2005,202(1):47-59.
[27] Kuramoto K,Morishima Y,Yoshida K,et al.Nrf2 deficiency accelerates IL-17-dependent neutrophilic airway inflammation in asthmatic mice[J].Antioxidants(Basel),2024,13(7):818.
[28] 倪文昌,艾奎,刘婷,等.基于Notch通路探讨黄连素对哮喘小鼠Th1/Th2失衡的影响[J].华中科技大学学报:医学版,2024,53(6):773-777,801.
Ni W C,Ai K,Liu T,et al.Effects of berberine on Th1/Th2 imbalance in asthmatic mice based on Notch pathway[J].Acta Med Univ Sci Technol Huzhong,2024,53(6):773-777,801.
[29] 朱丽萍,赵红玉,邓艳.盐酸青藤碱对支气管哮喘小鼠Nrf2/HO-1信号通路的影响[J].临床肺科杂志,2024,29(9):1373-1379.
Zhu L P,Zhao H Y,Deng Y.Effect of sinomenine hydrochloride on Nrf2/HO-1 signaling pathway in mice with bronchial asthma[J].J Clin Pulm Med,2024,29(9):1373-1379.

瑞马唑仑调控Nrf2/HO-1信号通路对哮喘小鼠气道炎症的影响^*

Effect of Remimazolam on Airway Inflammation in Asthmatic Mice via the Regulation of the Nrf2/HO-1 Signaling Pathway

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	高国财, 郑宏, 潘丹萍, 白朝辉, 韩雪. 基于网络药理学和实验研究探讨仙鹤草治疗支气管哮喘的作用机制^*[J]. 华中科技大学学报（医学版）, 2026, 55(1): 45-52.
[2]	傅青雯, 尤浩军, 雷静. Nrf2通路在常见周围神经病中抗氧化应激的作用机制^*[J]. 华中科技大学学报（医学版）, 2026, 55(1): 140-145.
[3]	王卓, 胡乃范, 江琦, 钟荣, 田剑波, 缪小平△ , 朱颖△. 氧化应激在环境双酚类物质暴露与肝功能关系中的中介效应[J]. 华中科技大学学报（医学版）, 2025, 54(6): 874-883.
[4]	马丽娜, 王伟, 汪丽云△. 炎症和脂代谢紊乱在肝纤维化中的作用机制[J]. 华中科技大学学报（医学版）, 2025, 54(6): 908-915.
[5]	赵琦, 陈萍, 杨丽萍, 孙建华. IGF-1与氧化应激在多囊卵巢综合征中的作用机制[J]. 华中科技大学学报（医学版）, 2025, 54(5): 750-755.
[6]	武小杰, 杨硕, 查干, 王爱利. Danthron通过靶向GRIM-12影响Nrf2/HO-1通路缓解COPD中的氧化应激和炎症反应[J]. 华中科技大学学报（医学版）, 2025, 54(1): 1-7.
[7]	倪文昌, 艾奎, 刘婷, 边俊梅, 王丽艳. 基于Notch通路探讨黄连素对哮喘小鼠Th1/Th2失衡的影响[J]. 华中科技大学学报（医学版）, 2024, 53(6): 773-777.
[8]	刘禹杉, 张仪霖, 杨树森, 惠毅, 闫曙光, 周永学. NAD+调节细胞衰老机制与特发性肺纤维化疾病的研究进展[J]. 华中科技大学学报（医学版）, 2024, 53(6): 852-857.
[9]	桑碧敏, 孔春雪, 曹静蕾, 梁景仪, 卢芳菲, 张国薇, 李金泉, 李平, 周婷. 肌苷单磷酸脱氢酶在卵清蛋白诱导过敏性哮喘中的作用[J]. 华中科技大学学报（医学版）, 2024, 53(5): 578-585.
[10]	曹津萌, 卿吉琳, 朱莉雅, 魏燕, 赵艺莲, 叶超, 陈治中. TIM-1-Fc融合蛋白对哮喘小鼠Th1/Th2和Th17/Treg免疫失衡的调节[J]. 华中科技大学学报（医学版）, 2024, 53(4): 479-486.
[11]	雷蕾, 夏桂玲, 李璐, 胡鳞方, 袁露, 杨辉. circ_0038467靶向 miR-495/NF-κB通路调控血管紧张素Ⅱ诱导的心肌细胞损伤[J]. 华中科技大学学报（医学版）, 2023, 52(6): 810-815.
[12]	莫亮, 王章正, 马超, 何伟, 周驰, 刘予豪 . 基于生信分析构建骨质疏松氧化应激相关miRNA-mRNA调控网络[J]. 华中科技大学学报（医学版）, 2023, 52(5): 641-648.
[13]	王璐, 何恒, 蔡晓敏, 钟荣, 田剑波, 朱颖, 缪小平. 氧化应激在环境酚类暴露与估计肾小球滤过率关联中的中介效应[J]. 华中科技大学学报（医学版）, 2023, 52(4): 431-438.
[14]	韩雪, 张新敏, 陈岱莉, 曹君, 黄晓雷. 有氧运动通过调节FoxO3a磷酸化及亚细胞定位减轻小肠缺血再灌注损伤[J]. 华中科技大学学报（医学版）, 2023, 52(4): 439-444.
[15]	张瑶, 杨少娟, 薛佳佳, 江燕丽, 刘侃玲. SGLT2i通过HIF1α/NRF2/HO-1通路对缺氧-复氧心肌细胞老化的保护作用[J]. 华中科技大学学报（医学版）, 2023, 52(3): 301-306.