Nrf2抗氧化的分子调控机制

Nrf2是调控细胞氧化应激反应的重要转录因子,同时也是维持细胞内氧化还原稳态的中枢调节者。Nrf2通过诱导调控一系列抗氧化蛋白的组成型和诱导型表达,可以减轻活性氧和亲电体引起的细胞损伤,使细胞处于稳定状态,维持机体氧化还原动态平衡。本研究为了从分子层面深入探讨剖析Nrf2发挥抗氧化功能的作用机制,通过查找阅读大量相关文献并进行整理归纳,最终从Nrf2的结构与激活、Nrf2抗氧化功能以及Nrf2抗氧化的分子调控机制三个方面进行了概述分析。其中在对Nrf2抗氧化的分子调控机制的探讨部分,既探析了对Nrf2起激活作用的相关调节因子的作用机制,又分析了Nrf2被激活后对其下游多种抗氧化因子及谷胱甘肽氧化还原系统的诱导调控机制,以期较深入了解Nrf2抵抗机体氧化应激损伤作用及其抗氧化分子调控机制。     

基于蛋氨酸代谢调控的内源性抗氧化分子机制

蛋氨酸是一种含硫必需氨基酸,在蛋白质组成和新陈代谢中都发挥着独特的作用。蛋氨酸具有内源性抗氧化作用,一方面蛋氨酸在蛋氨酸亚砜还原酶(MSR)作用下通过自身氧化还原反应来发挥内源性抗氧化作用,另一方面蛋氨酸可通过代谢途径(GSH合成、Nrf2抗氧化通路等)来增强内源性抗氧化能力。然而目前缺乏对蛋氨酸抗氧化分子机制全面深入的研究报道。因此,本文在蛋氨酸代谢的基础上,对蛋氨酸促进GSH合成、激活MSR抗氧化系统以及调控Nrf2抗氧化通路的分子机制进行综述,并对GSH合成、MSR与Nrf2抗氧化体系之间的关系进行阐述,为全面解析蛋氨酸内源性抗氧化分子机制提供理论依据。     

Nrf2信号通路在复发性外阴阴道念珠菌病发病机制中的作用CSCD

复发性外阴阴道念珠菌病是一种由念珠菌机会感染引起的皮肤黏膜疾病,其发病机制复杂,而念珠菌的侵袭与宿主诱发因素是复发性外阴阴道念珠菌病的主要致病因素。其中,念珠菌可通过多种方式攻击宿主细胞和逃避宿主免疫系统而导致机体损伤。Nrf2信号通路是细胞抗氧化的主要调控机构,同时也是一种重要的免疫调节机构。一方面,Nrf2通路可下调NF-κB通路和促进Th17、Treg、Th1细胞的活化,启动宿主适应性免疫;同时,Nrf2通路可激活树突状细胞介导机体固有免疫。另一方面,Nrf2通路还可通过抗氧化应激损伤来阻止阴道炎的发展。该文对Nrf2通路在复发性念珠菌性阴道炎发病机制中的抗氧化应激和免疫调节作用进行综述,旨在研究Nrf2信号通路与复发性外阴阴道念珠菌病发病机制间的关系,从而指导临床治疗复发性外阴阴道念珠菌病。     

Nrf2信号通路在复发性外阴阴道念珠菌病发病机制中的作用

复发性外阴阴道念珠菌病是一种由念珠菌机会感染引起的皮肤黏膜疾病,其发病机制复杂,而念珠菌的侵袭与宿主诱发因素是复发性外阴阴道念珠菌病的主要致病因素。其中,念珠菌可通过多种方式攻击宿主细胞和逃避宿主免疫系统而导致机体损伤。Nrf2信号通路是细胞抗氧化的主要调控机构,同时也是一种重要的免疫调节机构。一方面,Nrf2通路可下调NF-κB通路和促进Th17、Treg、Th1细胞的活化,启动宿主适应性免疫;同时,Nrf2通路可激活树突状细胞介导机体固有免疫。另一方面,Nrf2通路还可通过抗氧化应激损伤来阻止阴道炎的发展。该文对Nrf2通路在复发性念珠菌性阴道炎发病机制中的抗氧化应激和免疫调节作用进行综述,旨在研究Nrf2信号通路与复发性外阴阴道念珠菌病发病机制间的关系,从而指导临床治疗复发性外阴阴道念珠菌病。     

低氧运动对Nrf2基因敲除大鼠运动能力和氧化应激的影响

Nrf2可调节多种抗氧化酶的表达,Nrf2的缺失可能影响机体的运动能力,而低氧可提高机体的抗氧化能力并改善运动能力。为了考察低氧运动对Nrf2基因敲除大鼠运动能力和氧化应激的影响,本研究分别在常氧和低氧环境(12%氧浓度)中对野生型大鼠和Nrf2敲除大鼠进行4周的跑台运动。研究显示,低氧运动可提高野生型大鼠的跑台运动力竭时间,Nrf2敲除可缩短大鼠的力竭时间;低氧运动可上调大鼠的Nrf2 m RNA表达量;Nrf2敲除明显抑制HIF-1α蛋白表达,而低氧运动可上调野生型和Nrf2敲除大鼠的HIF-1α蛋白表达;Nrf2敲除大鼠的骨骼肌ROS水平明显升高,并且低氧均可降低野生型和Nrf2敲除大鼠骨骼肌ROS水平。低氧运动可上调Nrf2敲除大鼠的CAT和GSH-PX蛋白表达。苏木精和伊红(HE)染色显示,Nrf2敲除大鼠在力竭跑台运动完成后出现更严重的骨骼肌病理改变,而低氧运动可减轻骨骼肌损伤。本研究认为,Nrf2敲除导致了大鼠骨骼肌中抗氧化酶的抑制及ROS的过量累积,从而造成了骨骼肌损伤并降低了运动能力。此外,低氧可通过上调Nrf2的表达,进而激活HIF-1α及抗氧化酶活性,从而提高运动能力,并防止骨骼肌损伤。     

氧化和化学应激的防御性转导通路——Nrf2/ARE

Nrf2/ARE是近年新发现的机体抵抗内外界氧化和化学等刺激的防御性转导通路．生理条件下,NF-E2相关因子2(Nrf2,NF-E2-related factor 2)在细胞质中与Keap1结合处于非活性、易降解的状态.在内外界自由基和化学物质刺激时,Keap1的构象改变或者Nrf2直接被磷酸化,导致Nrf2与Keap1解离而活化．活化的Nrf2进入细胞核,与抗氧化反应元件(ARE)结合,启动ARE下游的Ⅱ相解毒酶、抗氧化蛋白、蛋白酶体/分子伴侣等基因转录和表达以抵抗内外界的有害刺激．MAPK、PI3K/AKT、PKC等信号通路分子广泛参与了Nrf2的活化和核转位过程,但是具体何种通路被激动、何种通路发挥主导作用,取决于刺激物种类、刺激方式和细胞类型．本文就Nrf2分子结构、Nrf2活化机制、Nrf2/ARE调控的下游基因、与Nrf2相关的信号通路分子以及其在肿瘤、炎症、衰老等应用领域的最新进展进行综述．     

Nrf2/ARE通路在抗病原生物感染中的作用研究进展

氧化应激反应是病原生物感染并致病的重要环节,病原生物感染可诱导宿主细胞产生大量的活性氧(ROS)或直接激活Nrf2/ARE通路,产生一系列保护性蛋白,保护宿主细胞抵抗氧化应激损伤。转录因子NF-E2相关因子2(Nrf2)是宿主细胞调节抗氧化应激的一种关键转录因子,可与抗氧化反应元件(ARE)相互作用,诱导抗氧化酶/Ⅱ相解毒酶基因的表达,从而在细胞保护防御中发挥重要作用。Nrf2的表达活性与病原生物感染密切相关,对N rf2/ARE通路在抗病原生物感染中的最新研究进展进行了综述。     

Nrf2及天然产物导向的Nrf2激活剂研究进展

氧化应激能够破坏细胞内氧化还原平衡,造成系统和组织损伤,最终引起一系列疾病的产生.转录因子E2相关因子2(Nrf2),受Kelch样环氧氯丙烷相关蛋白1(Keap1)蛋白的调控,是细胞氧化应激反应中的关键因子,在氧化应激条件下,Nrf2从Keap1中分离,然后进入细胞核与抗氧化反应元件(ARE)结合,增加了Ⅱ相解毒酶的...     

雌激素膜受体GPER1 通过调节Nrf2 减轻心肌氧化损伤

目的:观察雌激素膜受体GPER1对心肌细胞氧化损伤的保护作用,并探讨其通过PI3K/Akt信号通路上调Nrf2,减轻心肌氧化损伤的机制。方法:H_2O_2处理原代培养的新生大鼠心肌细胞建立氧化损伤模型,分为对照组、H_2O_2处理组,GPER1受体激动剂G1预处理+H_2O_2处理组和GPER1拮抗剂G15+G1预处理+H_2O_2处理组,MTT检测细胞活性,Hoechst33342染色和cleaved caspase-3免疫荧光染色观察细胞凋亡,并检测细胞内氧自由基,总抗氧化能力,超氧化物歧化酶(SOD)和丙二醛(MDA)的水平。Western blot测定细胞中p-Akt和细胞核内Nrf2的水平。结果:G1显著抑制H_2O_2导致细胞活性下降和细胞凋亡,并降低细胞内氧自由基水平,提高总抗氧化能力,增加SOD活性,减少MDA含量,但G15能拮抗G1的上述效应。同时G1能增加细胞内Akt磷酸化水平和细胞核内Nrf2的表达,这些效应可被G15和LY-294002阻断。结论:GPER1通过PI3K/Akt信号通路,调节Nrf2的表达,抑制氧化应激导致的心肌细胞损伤。GPER1可以作为开发心肌缺血损伤保护剂的一个潜在靶点。     

基于模式生物斑马鱼Nrf2的相关研究进展

Nrf2/ARE信号通路是大多数生物体内抗氧化应激反应、抵抗内外界刺激的关键通路,在抗炎症、免疫、抗肿瘤、抗凋亡、神经保护等方面起着重要的作用。斑马鱼作为一种常见的模式动物,广泛地应用于发育生物学、遗传学和毒理学等研究领域。研究表明转录因子NF_E2相关因子2(NF-E2-related factor 2,Nrf2)不仅在哺乳动物体内存在,也在斑马鱼体内存在并且高度保守,并在抗氧化应激反应中发挥着重要作用。本文通过对斑马鱼Nrf2的结构、生物学功能及其信号通路等方面的最新研究进行阐述,以期为Nrf2及其信号通路引发的相关疾病的预防和治疗提供新的思路。     

Rosuvastatin alleviates high-salt and cholesterol diet-induced cognitive impairment in rats via Nrf2–ARE pathway

Objective: The objectives of our study were to investigate the possible effect of rosuvastatin in ameliorating high salt and cholesterol diet (HSCD)-induced cognitive impairment and to also investigate its possible action via the Nrf2-ARE pathway.

Methods: In silico studies were performed to check the theoretical binding of rosuvastatin to the Nrf2 target. HSCD was used to induce cognitive impairment in rats and neurobehavioral studies were performed to evaluate the efficacy of rosuvastatin in enhancing cognition. Biochemical analyses were used to estimate changes in oxidative markers. Western blot and immunohistochemical analyses were done to check Nrf2 translocation. TUNEL and caspase 3 tests were performed to evaluate reversal of apoptosis by rosuvastatin.

Results: Rosuvastatin showed good theoretical affinity to Nrf2, significantly reversed changes in oxidative biomarkers which were induced by HSCD, and also improved the performance of rats in the neurobehavioral test. A rise in nuclear translocation of Nrf2 was revealed through immunohistochemical analysis and western blot. TUNEL staining and caspase 3 activity showed attenuation of apoptosis.

Discussion: We have investigated a novel mechanism of action for rosuvastatin (via the Nrf2–ARE pathway) and demonstrated that it has the potential to be used in the treatment of cognitive impairment.     

Ferrous Iron Induces Nrf2 Expression in Mouse Brain Astrocytes to Prevent Neurotoxicity

Free radical damage caused by ferrous iron is involved in the pathogenesis of secondary brain injury after intracerebral hemorrhage (ICH). NF‐E2‐related factor 2 (Nrf2), a major phase II gene regulator that binds to antioxidant response element, represents an important cellular cytoprotective mechanism against oxidative damage. We hypothesized that Nrf2 might protect astrocytes from damage by Fe²⁺. Therefore, we examined cytotoxicity in primary astrocytes induced by iron overload and evaluated the effects of Fe²⁺ on Nrf2 expression. The results demonstrated that 24‐h Fe²⁺ exposure exerted time‐ and concentration‐dependent cytotoxicity in astrocytes. Furthermore, Fe²⁺ exposure in astrocytes resulted in time‐ and concentration‐dependent increases in Nrf2 expression, which preceded Fe²⁺ toxicity. Nrf2‐specific siRNA further knocked down Nrf2 levels, resulting in greater Fe²⁺‐induced astrocyte cytotoxicity. These data indicate that induction of Nrf2 expression could serve as an adaptive self‐defense mechanism, although it is insufficient to completely protect primary astrocytes from Fe²⁺‐induced neurotoxicity.     

Possible differences in the mechanism of malignant transformation of HaCaT cells by arsenite and its dimethyl metabolites,particularly dimethylthioarsenics

Background: As a confirmed human carcinogen, arsenic can cause skin cancer, lung cancer, etc. However, its carcinogenic mechanism is still unclear. In recent years, the oxidative stress hypothesis has become widely accepted. In mammals it has been found that arsenic can be converted to dimethylarsinous acid (DMA^III) and dimethylmonothioarsinic acid (DMMTA^V) through a series of methylation and redox reactions. DMA^III and DMMTA^V are highly toxic.Methods: Human keratinocytes (HaCaT) were exposed to different concentrations of NaAsO₂ (IAs^III), DMMTA^V and DMA^III for 24 h. Reactive oxygen species (hydrogen peroxide and superoxide), oxidative damage markers (8-hydroxydeoxyguanosine and malondialdehyde), and antioxidant markers (glutathione and superoxide dismutase) were measured. In addition, sulfane sulfurs were measured in HaCaT cells and a cell-free system.Results: In the DMMTA^V and DMA^III treatment groups, the levels of hydrogen peroxide and superoxide in HaCaT cells were higher than in the IAs^III treatment groups at the same dose. Levels of 8−OHdG and MDA in the DMMTA^V and DMA^III treatment groups were also higher than those in the IAs^III treatment groups at the same dose. However, in the DMMTA^V and DMA^III treatment groups, the levels of GSH and SOD activity were lower than that in the IAs^III treatment groups. In DMMTA^V-treated HaCaT cells, sulfane sulfurs were produced. Further, it was found that DMMTA^V could react with DMDTA^V to form persulfide in the cell-free system, which may explain the mechanism of the formation of sulfane sulfurs in DMMTA^V-treated HaCaT cells.Conclusions: DMMTA^V and DMA^III more readily induce reactive oxygen species (ROS) and cause oxidative damage in HaCaT cells than inorganic arsenic. Further, the persulfide formed by the reaction of DMMTA^V and DMDTA^V produced from the metabolism of DMMTA^V may induce a stronger reductive defense mechanism than GSH against the intracellular oxidative stress of DMMTA^V. However, the cells exposed to arsenite are transformed by the continuous nuclear translocation of Nrf2 due to oxidative stress, and the persulfide from dimethylthioarsenics may promote Nrf2 by the combination with thiol groups, especially redox control key protein, Keap1, eventually cause nuclear translocation of sustained Nrf2.