谷胱甘肽的抗线粒体脂质过氧化作用

谷胱革肽是细胞内重要的抗氧化损伤物质之一,以ＮＡＤＨ诱导的牛心肌线粒体脂质过氧化体系为模型,研究了谷胱甘肽的抗氧化作用。结果表明,一定浓度的谷胱甘肽能够部分抑制该体系中线粒体的脂质过氧化,保护组的丙二醛含量为损伤组７２．５％;线粒体的膨胀度较损伤组降低;细胞色素ｃ氧化酶及ＡＴＰ酶活力分别较损伤组提高了１．５及２．２倍。     

d-儿茶精对抗坏血酸和硫酸亚铁诱导鼠肝线粒体损伤的作用

研究证实：ｄ－儿茶精有较强的抗氧化活性,对于鼠肝线粒体膜脂质过氧化损伤具有良好的保护作用。实验采用抗坏血酸和硫酸亚铁为鼠肝线粒体损伤的诱导剂,探讨ｄ－儿茶精对其影响。结果表明;ｄ－儿茶精增加受损伤的线粒体膜脂质流动性,减少脂质过氧化物形成和线粒体膨胀。并降低线粒体经ＡＤＰ刺激后的氧耗量,从而维护了线粒体结构和功能的完整性     

藁本内酯抑制脂质过氧化作用的研究

本文用维生素E为阳性对照,探讨了藁本内酯对不同体系脂质过氧化的抑制作用。结果显示:5、20和80mmol/L的藁本内酯对亚油酸的自发氧化,VitC/Fe2+和NADPH诱导的线粒体氧化,组织匀浆的自发氧化和H2O2诱导氧化,均表现出较强的抑制作用(与空白对照组相比,P<0.05),其浓度与抗氧化活性呈一定的量效关系。藁本内酯的体外抗脂质过氧化作用为进一步探讨其药理作用提供了实验与理论依据。     

竹节参对大强度耐力训练大鼠心肌线粒体抗氧化能力的研究

目的:探讨竹节参对大强度耐力训练大鼠心肌线粒体抗氧化能力的影响,为该药运用于抗运动疲劳提供理论依据。方法:将大鼠随机分为安静对照组,大强度耐力训练组(训练组),大强度耐力训练+竹节人参组(训练加药组),测定心肌线粒体脂质过氧化产物丙二醛(MDA)和过氧化氢(H2O2)的含量以及超氧化物歧化酶(SOD)、谷胱甘肽过氧化物酶(GSH-Px)、过氧化氢酶(CAT)的活性,研究竹节参对大强度耐力训练大鼠心肌线粒体的保护作用。结果:力竭运动引起大鼠心肌线粒体MDA、H2O2含量显著升高(P0.01),心肌线粒体抗氧化酶CAT、GSH-Px、SOD活性显著下降(P0.01);训练加药组大鼠心肌线粒体MDA、H2O2含量明显低于训练组(P0.01),CAT、GSH-Px、SOD活性明显高于训练组。结论:竹节参可明显提高大强度耐力训练大鼠心肌线粒体的抗氧化能力,保护心肌线粒体的氧化损伤。     

微囊藻细胞抽提物亚慢性暴露导致小鼠肝脏氧化应激

研究了微囊藻细胞抽提物亚慢性暴露对小鼠肝脏抗氧化系统的影响.采用腹腔注射进行连续染毒28d,染毒组剂量为3.3μg micmcystins/kg体重.结果显示,超氧化物歧化酶、过氧化氧酶、谷胱甘肽过氧化物酶在第4周时发生显著性升高,提示微囊藻细胞抽提物激活了小鼠肝脏抗氧化系统.谷胱甘肽-S-转移酶和对照组相比也显著提高,表明谷胱甘肽-S-转移酶作为解毒Ⅰ相酶加快了对肝脏微囊藻毒素的清除.脂质过氧化产物丙二醛也显著升高,说明抗氧化系统未能清除微囊藻细胞抽提物对小鼠肝脏的氧化损伤,导致了氧化应激的产生.结果表明低剂量微囊藻细胞抽提物长时间暴露能够导致小鼠肝脏氧化损伤.     

大鼠全身照射后红细胞膜脂氧化速率、维生素E和硒-谷胱甘肽过氧化物酶活力的变化

<正> 组织细胞存在天然的抗氧化系统——抗氧化剂和抗氧化酶,以保护机体免受膜脂过氧化损伤。在抗氧化酶中,晒-谷胱甘肽过氧化物酶(se-CSHPX)既能参加阻断脂质过氧化的一级引发作用,又能阻断二级引发作用。抗氧化剂VE既是自由基的清除剂,又是脂质过氧化链式反应的阻断剂,它和Se-GSHPX协同地中断和终止脂质过氧化作用。     

双歧杆菌三联活菌胶囊辅助治疗对2型糖尿病患者血糖波动及脂质过氧化损伤的影响

目的探讨双歧杆菌三联活菌胶囊辅助治疗对2型糖尿病(T2DM)患者血糖波动及脂质过氧化损伤的影响,为该类患者的治疗提供参考。方法选取2019年1月至8月我院内科门诊治疗的84例T2DM患者,随机分为观察组和对照组各42例。两组患者均给予饮食控制和适当运动锻炼等基础治疗。对照组患者给予甘精胰岛素与阿卡波糖控制血糖。观察组患者在对照组基础加用双歧杆菌三联活菌胶囊630 mg/次,2次/d,温开水服用。两组患者连用12周。观察两组患者治疗前后血糖波动指标[日平均血糖波动幅度(MAGE)、血糖标准差(SDBG)和最大血糖波动幅度(LAGE)]及脂质过氧化指标[谷胱甘肽过氧化物酶(GSH-PX)、脂质过氧化氢(LHP)、活性氧类物质(ROS)和总抗氧化能力(T-AOC)]水平的变化。结果治疗12周后,两组患者血清MAGE、SDBG和LAGE水平较治疗前明显下降,且观察组下降幅度大于对照组(均P0.05);同时两组患者血清GSH-PX和T-AOC水平较治疗前显著上升,血清LHP和ROS水平均较治疗前显著下降,且观察组变化幅度大于对照组(均P0.05)。结论双歧杆菌三联活菌胶囊辅助治疗T2DM患者可改善其糖代谢指标水平,减少血糖波动程度,机制可能与其能减轻脂质过氧化损伤相关。     

竹红菌乙素（乙醇胺）修饰物对于鼠肝线粒体光敏损伤研究

竹红菌乙素与乙醇胺进行化学结构的修饰,可以得到红光性能更加优良的新型光敏剂（简称ＨＢ－Ｅ）,为此,我们作了以下几方面的研究：１．对线粒体膜脂质过氧化损伤的光敏作用;２．对线粒体膜巯基蛋白光敏损伤;３．对ＡＴＰ酶的失活;４．损伤机理的探讨;５．不同光敏剂光敏能力的对比;从以上研究可以看到ＨＢ－Ｅ光敏作用对于线粒体的损伤十分明明;从损伤的机理角度证明了氧自由基的作用是存在的;对于体系中产生超氧阴离的来     

四氯化碳亚急性染毒大鼠肝脏脂质过氧化的分析

本文观察了经腹腔注射四氯化碳（每次４００ｍｇ／ｋｇｂ．ｗ,每周三次）亚急性染毒大鼠注药１、２、３周时肝脏的超氧化物歧化酶、谷胱甘肽过氧化物酶活力及脂质过氧化物—丙二醛含量的变化,结果发现四氯化碳亚急性染毒大鼠肝脏中上述的抗氧化酶活性在三个时间组均比对照组低（Ｐ＜０．０１）,同时,丙二醛含量均高于对照组（Ｐ＜０．０１及０．０５）,提示四氯化碳亚急性染毒大鼠肝脏抗氧化酶活性受四氯化碳毒性所抑制,同时出现肝脏脂质过氧化并造成肝损害     

枯草芽孢杆菌对草鱼肝脏脂质代谢的调节作用

为研究益生枯草芽孢杆菌(Bacillus subtilis)对草鱼(Ctenopharyngodon idella)肝脏脂质代谢及抗氧化功能的影响, 实验设置对照组(Con组)、Aeromonas hydrophila组(Ah组)、Aeromonas hydrophila+Bacillus subtilis组(Ah+Bs组)、Bacillus subtilis+Aeromonas hydrophila组(Bs+Ah组), 三个实验组均腹腔注射1×105 CFU/fish嗜水气单胞菌(Aeromonas hydrophila), 枯草芽孢杆菌饲料含菌量为1×107 CFU/g, 实验周期为56d, 并于第28和第56天取样。结果表明, 与Ah组相比, 投喂枯草芽孢杆菌饲料后, (1)体增重率、特定生长率显著增加(P<0.05); (2) 28d时肝脏油红O染色脂滴面积及脂肪含量显著下降(P<0.05); (3)调节血脂代谢及缓解肝脏损伤: 血清胆固醇、甘油三酯、高密度脂蛋白胆固醇、低密度脂蛋白胆固醇含量升高, 谷草转氨酶和谷丙转氨酶活性显著降低(P<0.05); (4)调节脂质代谢: 28d时乙酰辅酶A羧化酶的表达水平下调, 脂蛋白脂酶及脂肪甘油三酯脂肪酶的表达水平上调; (5)增强肝脏抗氧化能力、减少脂质过氧化的发生: 肝脏超氧化物歧化酶、过氧化氢酶、谷胱甘肽、总抗氧化能力提高; 丙二醛及过氧化氢含量降低。综上, 在饲料中添加益生枯草芽孢杆菌可以增强草鱼的抗氧化能力, 缓解机体因嗜水气单胞菌感染造成的肝脏损伤, 调节肝脏脂质代谢功能, 减少脂质在肝脏中的积累, 并促进草鱼的生长。     

The inhibitory effect of reduced glutathione on the lipid peroxidation of the microsomal fraction and mitochondria

1. GSH efficiently inhibited the ascorbate-stimulated lipid peroxidation of the unsaturated fatty acids in the fresh microsomal fraction and mitochondria of rat liver, whereas the peroxidation in heat-denatured particles was little inhibited. 2. Cysteamine and diethyldithiocarbamate inhibited the peroxidation in both fresh and boiled particles. Thioglycollate and 2-mercaptoethanol had no inhibiting effect. Cysteine and homocysteine both stimulated the lipid peroxidation even in the absence of ascorbate. 3. The added GSH disappeared at nearly the same rate in the presence of fresh and of boiled particles to which ascorbate had been added, although considerably more malonaldehyde was formed in the boiled particles. In the absence of ascorbate little GSH disappeared. 4. It is suggested that the protective effect of GSH against lipid peroxidation depends on the preservation of heat-labile structures in the microsomal fraction and mitochondria.     

Lipid Peroxidation in Choline-Methionine Deficiency

A deficiency of choline and methionine is hepatocarcinogenic and is associated with an apparent increase in lipid peroxidation. In this study the susceptibility of microsomes and nuclei to ferritin-dependent lipid peroxidation is examined together with the status of the peroxidation- protective systems. Choline-methionine deficiency caused an increase in Se-independent GSH peroxidases (GSH transferase subunit 2) and membrane vitamin E but a decrease in Se-dependent GSH peroxidase and microsomal GSH peroxidase activity. Choline-methionine deficient microsomes and nuclei were 4-fold more susceptible to lipid peroxidation induced in vitro by physiological concentrations of ferritin/ascorbate/ADP; and the peroxidation was less effectively inhibited by GSH and soluble GSH peroxidases than controls. The results indicate that a decreased level of Se-dependent and membrane GSH peroxidases is involved in the increase in lipid peroxidation observed in choline-methionine deficiency.     

Salinity up-regulates the antioxidative system in root mitochondria and peroxisomes of the wild salt-tolerant tomato species Lycopersicon pennellii

The effect of salinity on the antioxidative system of root mitochondria and peroxisomes of a cultivated tomato Lycopersicon esculentum (Lem) and its wild salt-tolerant related species L. pennellii (Lpa) was studied. Salt stress induced oxidative stress in Lem mitochondria, as indicated by the increased levels of lipid peroxidation and H(2)O(2). These changes were associated with decreased activities of superoxide dismutase (SOD) and guaiacol peroxidases (POD) and contents of ascorbate (ASC) and glutathione (GSH). By contrast, in mitochondria of salt-treated Lpa plants both H(2)O(2) and lipid peroxidation levels decreased while the levels of ASC and GSH and activities of SOD, several isoforms of ascorbate peroxidase (APX), and POD increased. Similarly to mitochondria, peroxisomes isolated from roots of salt-treated Lpa plants exhibited also decreased levels of lipid peroxidation and H(2)O(2) and increased SOD, ascorbate peroxidase (APX), and catalase (CAT) activities. In spite of the fact that salt stress decreased activities of antioxidant enzymes in Lem peroxisome, oxidative stress was not evident in these organelles.     

Effects of Oxidative Stress Caused by Hyperoxia and Diquat. A Study in Isolated Hepatocytes

The effects of oxidative stress caused by hyperoxia or administration of the redox active compound diquat were studied in isolated hepatocytes, and the relative contribution of lipid peroxidation, glutathione (GSH) depletion, and NADPH oxidation to the cytotoxicity of active oxygen species was investigated.

The redox cycling of diquat occurred primarily in the microsomal fraction since diquat was found not ' to penetrate into the mitochondria. Depletion of intracellular GSH by pretreatment of the animals with diethyl maleate promoted lipid peroxidation and sensitized the cells to oxidative stress. Diquat toxicity was also greatly enhanced when glutathione reductase was inhibited by pretreatment of the cells with 1,3-bis(2-chloroethyI)-1-nitrosourea. Despite extensive lipid peroxidation, loss of cell viability was not observed, with either hyperoxia or diquat, until the GSH level had fallen below ≈ 6 nmol/10⁶ cells.

The iron chelator desferrioxamine provided complete protection against both diquat-induced lipid peroxidation and loss of cell viability. In contrast, the antioxidant a-tocopherol inhibited lipid peroxidation but provided only partial protection from toxicity. The hydroxy! radical scavenger α-keto-γ-methiol butyric acid, finally, also provided partial protection against diquat toxicity but had no effect on lipid peroxidation.

The results indicate that there is a critical GSH level above which cell death due to oxidative stress is not observed. As long as the glutathione peroxidase – glutathione reductase system is unaffected, even relatively low amounts of GSH can protect the cells by supporting glutathione peroxidase-mediated metabolism of H₂O₂ and lipid hydroperoxides.     

Glutathione-dependent protection by rat liver microsomal protein against lipid peroxidation

GSH is an important cellular defense against oxidant injury. Its effect in the rat liver microsomal lipid peroxidation system has been examined. Incubation of fresh rat liver microsomes with ascorbic acid and ADP-chelated iron leads to the peroxidation of microsomal lipids (production of thiobarbituric acid-reactive substances and destruction of polyunsaturated fatty acids) following a 2 to 5 min lag. Addition of 0.1 mM GSH to the system lengthened the lag period by 5 to 15 min without affecting the rate or the extent of lipid peroxidation. GSH could not be replaced in prolonging the lag by cysteine, mercaptoethanol, dithiothreitol, propylthiouracil, or GSSG. The GSH effect on the lag was abolished by heating or trypsin digestion of the microsomes, indicating that microsomal protein is required for its expression. Progressively longer lags were observed as the GSH concentration was increased from 0.1 to 5 mM, but there was no evidence of GSH oxidation as a consequence of the protection against lipid peroxidation. GSH protected against heat inactivation of the microsomal protein responsible for the GSH effect. Experiments with an oxygen electrode revealed that the GSH protection did not alter the ratio of O₂ consumed to thiobarbituric acid-reactive substances produced. This implicated free radical scavenging as the mechanism of protection. These results indicate the existence of a GSH-dependent rat liver microsomal protein which scavenges free radical. This protein may be an important defense against free radical injury to the microsomal membrane.     

Reduced glutathione protection against rat liver microsomal injury by carbon tetrachloride. Dependence on O2.

Rat liver microsomal membranes contain a reduced-glutathione-dependent protein(s) that inhibits lipid peroxidation in the ascorbate/iron microsomal lipid peroxidation system. It appears to exert its protective effect by scavenging free radicals. The present work was carried out to assess the effect of this reduced-glutathione-dependent mechanism on carbon tetrachloride-induced microsomal injury and on carbon tetrachloride metabolism because they are known to involve free radicals. Rat liver microsomes were incubated at 37 degrees C with NADPH, EDTA and carbon tetrachloride. The addition of 1 mM-reduced glutathione (GSH) markedly inhibited lipid peroxidation and glucose 6-phosphatase inactivation and, to a lesser extent, inhibited cytochrome P-450 destruction. GSH also inhibited covalent binding of [14C]carbon tetrachloride-derived 14C to microsomal protein. These results indicate that a GSH-dependent mechanism functions to protect the microsomal membrane against free-radical injury in the carbon tetrachloride system as well as in the iron-based systems. Under anaerobic conditions, GSH had no effect on chloroform formation, carbon tetrachloride-induced destruction of cytochrome P-450 or covalent binding of [14C]carbon tetrachloride-derived 14C to microsomal protein. Thus, the GSH protective mechanism appears to be O2-dependent. This suggests that it may be specific for O2-based free radicals. This O2-dependent GSH protective mechanism may partly underlie the observed protection of hyperbaric O2 against carbon tetrachloride-induced lipid peroxidation and hepatotoxicity.     

Toxicity by pyruvate in HepG2 cells depleted of glutathione: role of mitochondria.

Several studies have shown that pyruvate can scavenge H(2)O(2) and protect from H(2)O(2)-mediated cell injury. Mitochondria are critical participants in the control of apoptotic and necrotic cell death. Mitochondrial GSH plays an important role in the maintenance of cell functions and viability by metabolism of oxygen free radicals generated by the respiratory chain. Since loss of GSH, especially mitochondrial GSH, is associated with increased production of reactive oxygen species and cell toxicity, the ability of pyruvate to protect against these actions was evaluated. Adding pyruvate to HepG2 cells depleted of GSH by treatment with l-buthionine sulfoximine (BSO) surprisingly caused loss of viability after 24 and 48 h of incubation. Anoxia, treatment with antioxidants, and infection with cytosolic catalase, and interestingly, catalase expressed in the mitochondrial compartment were able to rescue the HepG2 cells from this pyruvate plus BSO injury, suggesting a key role for H(2)O(2), and lipid peroxides as mediators in the cytotoxicity. This toxicity and cell death observed was linked to damage to the mitochondria as evidenced by the increased lipid peroxidation in total homogenate and mitochondrial fraction, loss of mitochondrial membrane potential, and a decrease in protein-sulfhydryl groups. The type of cell death observed under these conditions was a mixture of apoptosis and necrosis. These results suggest that the protective ability of pyruvate against oxidant damage requires a functional GSH pool, especially in the mitochondrial compartment, and that in the absence of GSH, pyruvate increases cell injury by damaging the mitochondria, presumably as a consequence of enhanced electron flow and reactive oxygen production by the respiratory chain.     

Role of glutathione, lipid peroxidation and antioxidants on acute bile-duct obstruction in the rat

The aim of this work was to evaluate the role of lipid peroxidation and glutathione on liver damage induced by 7-day biliary obstruction in the rat. Male Wistar rats were bile-duct-ligated and divided in groups of 10 animals. Groups received vitamin E (400 IU/rat, p.o., daily) or trolox (50 mg/kg, p.o., daily) or both. Lipid peroxidation increased significantly in the livers of bile-duct-ligated rats. Vitamin E and trolox prevented lipid peroxidation. GSH was oxidized in the BDL group and the GSH/GSSG ratio decreased as a consequence. However, total glutathione content increased in liver and blood indicating a possible induction in de novo synthesis of GSH. Antioxidants preserved the normal GSH/GSSG ratio. Despite the observation that antioxidants verted lipid peroxidation and oxidation of GSH, liver injury (as assessed by serum enzyme activities, bilirubin concentration, liver glycogen content and histology) was not affected by the treatments. These results suggest that drugs that inhibit lipid peroxidation and oxidation of glutathione have no effect on conventional biochemical markers of liver injury and on liver histology of bile-duct-ligated rats for 7 days. It seems more likely that the detergent action of bile salts is responsible for solubilization of plasma membranes and cell death, which in turn may lead to oxidative stress, GSH oxidation and lipid peroxidation.     

Relations Between Tocopherol Depletion and Coenzyme Q During Lipid Peroxidation in rat Liver Mitochondria

In order to evaluate different mitochondrial antioxidant systems, the depletion of alpha-tocopherol and the levels of the reduced and oxidized forms of CoQ were measured in rat liver mitochondria during Fe⁺⁺/ascorbate and NADPH/ADP/Fe⁺⁺ induced lipid peroxidation. During the induction phase of malondialdehyde formation, alpha-tocopherol declined moderately to about 80% of initial contents, whereas the total CoQ pool remained nearly unchanged, but reduced CoQ9 continuously declined. At the start of massive malondialdehyde formation, CoQ9 reaches its fully oxidized state. At the same time alpha-tocopherol starts to decline steeply, but never becomes fully exhausted in both experimental systems. Evidently the oxidation of the CoQ9 pool constitutes a prerequisite for the onset of massive lipid peroxidation in mitochondria and for the subsequent depletion of alpha-tocopherol. Trapping of the GSH by addition of dinitrochlorbenzene (a substrate of the GSH transferase), results in a moderate acceleration of lipid peroxidation, but alpha-tocopherol and ubiquinol levels remained unchanged when compared with the controls. Addition of succinate to GSH depleted mitochondria effectively suppressed MDA formation as well as alpha-tocopherol and ubiquinol depletion. The data support the assumption that the protective effect of respiratory substrates against lipid peroxidation in the absence of mitochondrial GSH is mediated by the regeneration of the lipid soluble antioxidants CoQ and alpha-tocopherol.     

Relations Between Tocopherol Depletion and Coenzyme Q During Lipid Peroxidation in rat Liver Mitochondria

In order to evaluate different mitochondrial antioxidant systems, the depletion of alpha-tocopherol and the levels of the reduced and oxidized forms of CoQ were measured in rat liver mitochondria during Fe⁺⁺/ascorbate and NADPH/ADP/Fe⁺⁺ induced lipid peroxidation. During the induction phase of malondialdehyde formation, alpha-tocopherol declined moderately to about 80% of initial contents, whereas the total CoQ pool remained nearly unchanged, but reduced CoQ9 continuously declined. At the start of massive malondialdehyde formation, CoQ9 reaches its fully oxidized state. At the same time alpha-tocopherol starts to decline steeply, but never becomes fully exhausted in both experimental systems. Evidently the oxidation of the CoQ9 pool constitutes a prerequisite for the onset of massive lipid peroxidation in mitochondria and for the subsequent depletion of alpha-tocopherol. Trapping of the GSH by addition of dinitrochlorbenzene (a substrate of the GSH transferase), results in a moderate acceleration of lipid peroxidation, but alpha-tocopherol and ubiquinol levels remained unchanged when compared with the controls. Addition of succinate to GSH depleted mitochondria effectively suppressed MDA formation as well as alpha-tocopherol and ubiquinol depletion. The data support the assumption that the protective effect of respiratory substrates against lipid peroxidation in the absence of mitochondrial GSH is mediated by the regeneration of the lipid soluble antioxidants CoQ and alpha-tocopherol.