脉络宁抑制氧化应激保护缺血性脑损伤

目的 探讨脉络宁对氧化应激和缺血性脑损伤的影响.方法 健康雄性昆明小鼠126只,分为假手术组(n=18)、生理盐水对照组(n=54)和脉络宁组(n=54).建立大脑中动脉闭塞(middle cerebral artery occlusion,MCAO)模型,脉络宁组和生理盐水对照组MCAO 2 h后分别经尾静脉给予脉络宁注射液和同体积生理盐水,然后每隔24 h重复1次.在MCAO 12、24和72 h分别进行神经功能评分、脑水含量、梗死体积、膜电位以及蛋白质氧化应激代谢产物3-硝基酪氨酸(3-nitrotyrosine,3-NT)、脂质氧化应激代谢产物4-羟基壬烯醛(4-hydroxy-2-nonenal,HNE)和核酸氧化应激代谢产物8-羟基脱氧鸟苷(8-hydroxy-2'-deoxyguanosine,8-OHdG)检测.结果 在脑缺血后不同时间点,脉络宁注射液均可显著改善脑缺血小鼠的神经功能、减轻脑水肿和缩小梗死体积,其中以72 h最为显著;脉络宁注射液可逆转脑皮质和内囊区的线粒体膜电位降低,显著下调缺血后皮质、内囊和血清3-NT、HEN 和8-OHdG的升高,其中以降低HNE效果最为显著.结论 脉络宁注射液能有效保护小鼠缺血性脑损伤,其机制与抑制氧化应激,尤其是抗脂质氧化有关.     

Dexrazoxane (ICRF-187) protects cardiac myocytes against doxorubicin by preventing damage to mitochondria

The clinically approved antioxidant cardioprotective agent dexrazoxane (ICRF-187) was examined for its ability to protect neonatal rat cardiac myocytes from doxorubicin-induced damage. Doxorubicin is thought to induce oxidative stress on the heart muscle, both through reductive activation to its semiquinone form, and by the production of hydroxyl radicals mediated by its complex with iron. Hydrolyzed dexrazoxane metabolites prevent site-specific iron-based oxygen radical damage by displacing iron from doxorubicin and chelating free and loosely bound iron. The mitochondrial stain Mito Tracker Green GM and doxorubicin were shown by epifluorescence microscopy to accumulate in the myocyte mitochondria. An epifluorescence microscopic image analysis method to measure mitochondrial damage was developed using the mitochondrial membrane potential sensing ratiometric dye JC-1. This method was used to show that dexrazoxane protected against doxorubicin-induced depolarization of the myocyte mitochondrial membrane. Dexrazoxane also attenuated doxorubichin-induced oxidation of intracellular dichlorofluorescin. Annexin V-FITC/propidium iodide staining of myocytes was used to demonstrate that, depending on the concentration, doxorubicin caused both apoptotic and necrotic damage. These results suggest that doxorubicin may be cardiotoxic by damaging the mitochondria and dexrazoxane may be protective by preventing iron-based oxidative damage.     

Ursodeoxycholic acid protects against secondary biliary cirrhosis in rats by preventing mitochondrial oxidative stress

Ursodeoxycholic acid (UDCA) improves clinical and biochemical indices in primary biliary cirrhosis and prolongs survival free of liver transplantation. Recently, it was suggested that the cytoprotective mechanisms of UDCA may be mediated by protection against oxidative stress, which is involved in the development of cirrhosis induced by chronic cholestasis. The aims of the current study were 1) to identify the mechanisms involved in glutathione depletion, oxidative stress, and mitochondrial impairment during biliary cirrhosis induced by chronic cholestasis in rats; and 2) to determine the mechanisms associated with the protective effects of UDCA against secondary biliary cirrhosis. The findings of the current study indicate that UDCA partially prevents hepatic and mitochondrial glutathione depletion and oxidation resulting from chronic cholestasis. Impairment of biliary excretion was accompanied by decreased steady-state hepatic levels of gamma-glutamyl cysteine synthetase and gamma-cystathionase messenger RNAs. UDCA treatment led to up-regulation of gamma-glutamyl cysteine synthetase in animals with secondary biliary cirrhosis and prevented the marked increases in mitochondrial peroxide production and hydroxynonenal-protein adduct production that are observed during chronic cholestasis. A population of damaged and primarily apoptotic hepatocytes characterized by dramatic decreases in mitochondrial cardiolipin levels and membrane potential as well as phosphatidylserine exposure evolves in secondary biliary cirrhosis. UDCA treatment prevents the growth of this population along with the decreases in mitochondrial cardiolipin levels and membrane potential that are induced by chronic cholestasis. In conclusion, UDCA treatment enhances the antioxidant defense mediated by glutathione; in doing so, this treatment prevents cardiolipin depletion and cell injury in animals with secondary biliary cirrhosis.     

Ischemic preconditioning protects against cold ischemic injury through an oxidative stress dependent mechanism.

BACKGROUND/AIMS: Ischemic injury in cold preserved livers is characterized by sinusoidal endothelial cell (SEC) detachment and matrix metalloproteinase activity. Upon reperfusion reversible ischemic injury becomes permanent with SEC rapidly undergoing apoptosis. Ischemic preconditioning prevents reperfusion injury after normothermic ischemia. We hypothesized that ischemic preconditioning, through an oxygen free radical burst, protects against injury during cold preservation and reperfusion. METHODS: Ischemic preconditioning was achieved in rats by clamping blood supply to the left and median lobes for 10 min followed by 15 min of reperfusion prior to preservation in cold University of Wisconsin solution for 30 h. In a second set of experiments, rats were pretreated with N-acetyl-cysteine (NAC). SEC apoptosis upon reperfusion was assessed in an isolated perfused rat liver (IPRL) model. RESULTS: SEC detachment and activities of matrix metalloproteinase were significantly reduced in preconditioned livers. A decrease of SEC apoptosis after 1h of reperfusion in the IPRL was noted in preconditioned livers compared to controls. Pretreatment with NAC reversed the beneficial effects of ischemic preconditioning on SEC detachment and apoptosis. CONCLUSIONS: Ischemic preconditioning is an effective strategy to prevent injury during cold preservation and after reperfusion. The protective effect is possibly mediated by oxygen free radicals.     

Acute vincristine pretreatment protects adult mouse cardiac myocytes from oxidative stress

Vincristine is a chemotherapeutic agent that disrupts microtubules. We noted that paclitaxel (Taxol), which stabilizes microtubules, protected cultured adult mouse cardiac myocytes from oxidative stress induced by H(2)O(2). We hypothesized that vincristine, which disrupts microtubules, should have the opposite effect. To our surprise, we found that pretreatment with concentrations of vincristine ranging from 30 to 120 micromol/L for 60 min preserved myocyte viability and morphology after incubation with 30 micromol/L of H(2)O(2) for 35 min as measured by trypan blue exclusion. The cardioprotective effects of vincristine were also observed during prolonged hypoxia. With continuous exposure to vincristine, survival lasted for as long as 24 h, but longer periods of exposure up to 42 h resulted in extensive cell death. Despite microtubule disruption evidenced on deconvolution microscopy, vincristine activated a prosurvival pathway resulting in increased phosphorylation of Akt, ERK and GSK-3beta and in reduced cytochrome C release into the cytosol. Pharmacological inhibitors of Akt and Erk attenuated the cardioprotective effect of vincristine. We conclude that short-term pretreatment with vincristine exerts dramatic protective effects in cultured adult mouse myocytes subjected to acute oxidative stress. Despite causing microtubule disruption, vincristine initiates a prosurvival signaling pathway. As vincristine and doxorubicin are often used in conjunction to treat patients, it is possible that vincristine could be used to modify the cardiotoxicity of doxorubicin.     

Exercise and cardiac oxidative stress.

Cardiac muscle is frequently affected by many stimuli responsible for loss of cell homeostasis, including physical exercise. While exercise has been presented as a recommended activity for health reasons, it also provides favorable conditions for additional production of reactive oxygen species. These compounds are associated with fundamental mechanisms of cell metabolism but are also related to the etiology and pathophysiology of some cardiac diseases. Cardiac muscle tissue has a high oxidative metabolic rate and relatively low activity of the main antioxidant enzymes, which could enhance its susceptibility to oxidative injury after acute exercise. However, physical training could be considered an important stimulus for the different antioxidant systems like glutathione and those related to the activity of some important antioxidant enzymes in myocardial protection such as superoxide dismutase and glutathione peroxidase. Endurance training seems to induce up-regulation in some antioxidant defenses, protecting cardiac muscle in potentially harmful situations that induce additional oxidative stress. Nevertheless, the mechanisms related to this cross-tolerance effect of training are not yet well understood.     

Carvedilol decreases elevated oxidative stress in human failing myocardium

BACKGROUND: Oxidative stress has been implicated in the pathogenesis of heart failure. However, direct evidence of oxidative stress generation in the human failing myocardium has not been obtained. Furthermore, the effect of carvedilol, a vasodilating beta-blocker with antioxidant activity, on oxidative stress in human failing hearts has not been assessed. This study was therefore designed to determine whether levels of lipid peroxides are elevated in myocardia of patients with dilated cardiomyopathy (DCM) and whether carvedilol reduces the lipid peroxidation level. Methods and Results- Endomyocardial biopsy samples obtained from 23 patients with DCM and 13 control subjects with normal cardiac function were studied immunohistochemically for the expression of 4-hydroxy-2-nonenal (HNE)-modified protein, which is a major lipid peroxidation product. Expression of HNE-modified protein was found in all myocardial biopsy samples from patients with DCM. Expression was distinct in the cytosol of cardiac myocytes. Myocardial HNE-modified protein levels in patients with DCM were significantly increased compared with the levels in control subjects (P<0.0001). Endomyocardial biopsy samples from 11 patients with DCM were examined before and after treatment (mean, 9+/-4 months) with carvedilol (5 to 30 mg/d; mean dosage, 22+/-8 mg/d). After treatment with carvedilol, myocardial HNE-modified protein levels decreased by 40% (P<0.005) along with amelioration of heart failure. CONCLUSIONS: Oxidative stress is elevated in myocardia of patients with heart failure. Administration of carvedilol resulted in a decrease in the oxidative stress level together with amelioration of cardiac function.     

Telomerase,mitochondria and oxidative stress

Telomerase plays an important role in cellular proliferation capacity and survival under conditions of stress. A large part of this protective function is due to telomere capping and maintenance. Thus it contributes to cellular immortality in stem cells and cancer. Recently, evidence has accumulated that telomerase can contribute to cell survival and stress resistance in a largely telomere-independent manner. Telomerase has been shown to shuttle dynamically between different cellular locations. Under increased oxidative stress telomerase is excluded from the nucleus and can be found within the mitochondria. This phenotype correlates with decreased oxidative stress within telomerase expressing cells and improved mitochondrial function by currently largely unknown mechanisms. Our data suggest that mitochondrial protection could be an important non-canonical function for telomerase in cell survival and ageing. This review summarises briefly our knowledge about extra-telomeric functions of telomerase and discusses the potential significance of its mitochondrial localisation.     

Escherichia coli iron superoxide dismutase targeted to the mitochondria of yeast cells protects the cells against oxidative stress.

A gene encoding a fusion protein consisting of Escherichia coli iron superoxide dismutase (FeSOD) with the mitochondrial targeting presequence of yeast manganese superoxide dismutase (MnSOD) was cloned and expressed in E. coli and in Saccharomyces cerevisiae DL1Mn- yeast cells deficient in MnSOD. In the yeast cells the fusion protein was imported into the mitochondrial matrix. However, the presequence was not cleaved. In a control set of experiments, the E. coli FeSOD gene without the yeast MnSOD leader sequence was also cloned and expressed in S. cerevisiae DL1Mn- cells. In this case the FeSOD was located in the cytosol and was not imported into the mitochondrial matrix. E. coli FeSOD, with and without the yeast MnSOD presequence, proved to be active in yeast, but, whereas the FeSOD targeted to the mitochondria of yeast cells deficient in MnSOD protected the cells from the toxic effects of oxidative stress, FeSOD without the yeast MnSOD presequence did not protect the yeast cells deficient in MnSOD against oxidative stress.     

Carvedilol inhibits pressure-induced increase in oxidative stress in coronary smooth muscle cells.

The cellular mechanisms by which hypertension enhances atherosclerosis are still not known in detail. Recently, evidence has been obtained that oxidative stress plays a role in the pathogenesis of pressure-induced atherosclerosis. We examined the effects of pressure on oxidative stress in cultured human coronary smooth muscle cells (SMCs). Application of increased pressure (+100 mmHg) with He gas for 48 h increased oxidative stress of measured by flow cytometry by 71% and F2-isopretane by 77%. Increased pressure also increased the activities of phospholipase D (PLD), and particulate protein kinase C (PKC). The PLD inhibitor suramin 100 micromol/l, 1-butanol 40 mmol/l, and the PKC inhibitors chelerythrine 1 micromol/l and calphostin C 100 nmol/l and completely blocked the increase in oxidative stress induced by pressure. Carvedilol 1 micromol/l but not propranolol 1 micromol/l blocked pressure-induced increases in oxidative stress in cultured SMCs. These findings suggest that pressure increases oxidative stress and that carvedilol significantly inhibits pressure-induced increase in oxidative stress in cultured human coronary smooth muscle cells.     

Epimorphin protects hepatocytes from oxidative stress by inhibiting mitochondrial injury

Background and Aims: Many investigations have demonstrated that cell injuries caused by generation of reactive oxygen species (ROS) is a common mechanism of various hepatic disorders. Recently, we have demonstrated that epimorphin, originally cloned as a mesenchymal protein, protects cultured intestinal epithelial cells from ROS. We therefore examine whether epimorphin protects primary cultured hepatocytes from ROS‐induced cell injury. Methods: We explored the cell viability and the intracellular ROS levels of purified murine hepatocytes after exposure to 0.5 mM H₂O₂ with or without pretreatment of epimorphin. Then, we observed mitochondrial permeability transition (MPT) and depolarization using confocal microscopy to make clear the mechanism that epimorphin inhibited cell injuries after exposure to H₂O₂. In addition, to clarify the signaling pathways related to cell survival, we carried out Western blotting analysis with phosphorylated stress‐activated protein kinase/c‐Jun N‐terminal kinase (SAPK/JNK) polyclonal antibody to evaluate the inhibition of JNK by epimorphin. Finally, we evaluated the cell viability in hepatocytes administered JNK inhibitor. Results: Epimorphin protected primary cultured hepatocytes from H₂O₂‐induced cell injuries independent of intracellular ROS levels. Epimorphin also inhibited onset of MPT, depolarization of the mitochondrial membrane potential, and eventually cell killing. The cell protective function of epimorphin after exposure to H₂O₂ was not dependent on Akt signaling but on JNK signaling. Conclusion: Epimorphin can protect hepatocytes from MPT‐dependent cell injury induced by ROS. Since hepatic disorders could be caused by MPT‐dependent cell injuries with excessive ROS, epimorphin might open a new therapeutic avenue for hepatic disorders.     

Trimetazidine reduces oxidative stress in cardiac surgery.

BACKGROUND: Trimetazidine is an anti-ischemic agent that is used to treat angina and it has cardioprotective effects without inducing any significant hemodynamic changes. It inhibits the long-chain mitochondrial 3-ketoacyl coenzyme A thiolase enzyme in the myocyte and can improve cardiac mitochondrial metabolism, as well as scavenge free radicals. The aim of this double-blind prospective randomized study was to investigate the effect of preoperative use of trimetazidine on the reduction of oxidative stress during coronary artery bypass grafting (CABG) under cardiopulmonary bypass (CPB). METHODS AND RESULTS: The study group (group T) and the control group (group C) each comprised 12 patients. Pretreatment began 2 weeks before CABG with trimetazidine (60 mg/day po); the control group did not receive any medication. Serial blood samples were collected before and after CPB for measurement of the serum concentrations of these major endogenous antioxidant enzyme systems, which are markers for oxidative degradation of the cellular membranes; postoperative levels were significantly different between the groups (p<0.05). There were no significant difference in hemodynamic values. CONCLUSION: The findings suggest that pretreatment with trimetazidine alleviates malondialdehyde production and preserves endogenous antioxidant capacity during CABG with CPB and cardioplegic arrest.     

Cyclic GMP protects endothelial progenitors from oxidative stress

Endothelial progenitor cells (EPCs) play a critical role in the repair of damaged blood vessels and/or in the growth of new ones in ischemic tissues. Elevated levels of oxygen radicals, which accumulate in the ischemic tissue, could compromise the angiogenic potential of EPCs. To determine if oxidative stress alters the angiogenic response of EPCs and to identify possible cellular targets that protect EPCs from the damaging effects of oxidative stress, we have investigated vascular development in embryonic bodies (EBs) under hyperoxic conditions. Murine EBs at differentiaton day 2 were cultured for 3 days under normoxic (21% O₂) or hyperoxic (60% O₂) conditions. Hyperoxic EBs showed a moderate reduction in Pecam-1, Vegfr-2, eNOS and Tie2 mRNA levels compared to normoxic EBs. However, immunostaining of hyperoxic EBs with antibodies against PECAM-1 after 1 week recovery at room air revealed a defective vasculature completely deficient in branches, while normoxic EBs developed a normal vascular plexus. Oxygen-induced defective vascular development correlated with a dramatic decrease in soluble guanylyl cyclase, phosphodiesterase (Pde) 4B and Pde4C mRNAs. Oxidative stress did not affect the expression of adenylyl cyclase 6 and Pde5. The abnormal vascular development caused by hyperoxia was reverted by pharmacological treatments that increased cGMP levels, such as 8-bromo-cGMP or 4-{[3′,4′-(methylenedioxy)benzyl]amino}-6-methoxyquinazoline, a specific inhibitor of PDE5. These results indicated that oxidative stress inhibits vascular development from EPCs through its effects on levels of cyclic nucleotides and suggested that therapies that target cyclic nucleotide turnover may be useful in protecting vascular repair under oxidative conditions.     

Resistance exercise training attenuates alcohol-induced cardiac oxidative stress.

BACKGROUND: Myocardial oxidative stress is believed to play an important role in the pathogenesis of alcoholic cardiomyopathy. Strenuous physical exercise has been shown to increase or decrease myocardial oxidative stress depending on the mode and duration of the exercise intervention. Given the possibility of individuals to engage in both alcohol consumption and weight-training exercise, we have examined the effect of resistance exercise training and chronic alcohol consumption on myocardial oxidative stress in rats. METHODS: Forty Sprague-Dawley rats were randomly assigned to one of four experimental groups: sedentary, sedentary plus alcohol treatment, resistance training, or resistance training plus alcohol treatment. Rats in the alcohol groups received a liquid diet containing alcohol (35% of kilocalorie intake) for 6 weeks. Non-alcohol groups were pair-fed the same liquid diet supplemented with a maltose dextrin caloric substitute. Rats in the resistance training groups were trained to rise onto their hind limbs while wearing lead-weighted vests 30 times per training session, 3 days per week during the 6 week experimental period. RESULTS: Alcohol treatment in the sedentary animals resulted in greater levels of cardiac malondialdehyde, a marker of lipid peroxidation, and a depressed index of myocardial antioxidant potential compared with all other groups (P<0.05). Hearts from the resistance training plus alcohol animals exhibited malondialdehyde and antioxidant levels similar to sedentary controls, suggesting that resistance training protected against the alcohol-induced myocardial stress. CONCLUSION: These results suggest that resistance training may attenuate the damaging effects of alcohol on the heart and preserve myocardial antioxidant capacity.     

EGFR inhibition protects cardiac damage and remodeling through attenuating oxidative stress in STZ-induced diabetic mouse model

Diabetes mellitus is strongly associated with cardiomyopathy. The underlying mechanisms for the development of diabetic cardiomyopathy are complex and not completely understood. Recent studies showed that epidermal growth factor receptors (EGFRs) are involved in diabetes-induced cardiac injury. However, the role of EGFR in the diabetic heart has yet to be confirmed. The aim of the present study is to further determine the role of EGRF in the pathogenesis of diabetic heart injury. The type 1 diabetic mice induced by streptozotocin were treated with EGFR inhibitors (AG1478 and 451) for 8 weeks, respectively. It was observed that diabetes induced phospohorylation of EGFR and AKT, increased cardiac ROS levels, and ultimately led to cardiac remodeling including cardiac hypertrophy, disorganization, apoptosis, and fibrosis, while all these molecular and pathological alterations were attenuated by the treatment with EGFR inhibitors. In vitro, either pharmacological inhibition of EGFR/AKT or sh-RNA silencing of EGFR significantly inhibited high concentration glucose (HG)-induced ROS generation and subsequently cell apoptosis in both cardiac H9C2 cells and primary rat cardiomyocytes, respectively. The ROS reduction by EGFR inhibitor was associated with the decreased NADPH oxidase activity and expression in H9c2 cells. HG-induced cardiomyocyte injuries were also reduced by NAC, an inhibitor of ROS. This study provides evidence that EGFR has a key role in the pathogenesis of STZ-induced diabetic cardiac damage and remodeling via ROS generation, and suggests that EGFR may be a potential target in treating diabetic cardiomyopathy.     

Recombinant activity-dependent neuroprotective protein protects cells against oxidative stress

Activity-dependent neuroprotective protein (ADNP) is essential for brain formation. Here, we investigated the potential neuroprotective effects of recombinant ADNP under stress conditions. The human ADNP cDNA was sub-cloned into a vector that contains VP22, a Herpes virus protein that may allow penetration of fused proteins through cellular membranes. When incubated with pheochromocytoma (PC12) cells, a neuronal model, VP22-ADNP was associated with the cells after a 25-min incubation period. Pre-incubation with VP22-ADNP enriched protein fractions protected against beta amyloid peptide toxicity and oxidative stress (H2O2) in PC12 cells. VP22 by itself was devoid of protective activity. Furthermore, the pro-apoptotic protein p53 increased by 3.5-fold from control levels in the presence of H2O2, while treatment with VP22-ADNP prior to H2O2 exposure significantly reduced the p53 protein levels. ADNP expression was previously shown to oscillate as a function of the estrus cycle in the mouse arcuate nucleus, these oscillations are now correlated with increased cellular protection.     

TNFα protects cardiac mitochondria independently of its cell surface receptors

Our novel proposal is that TNFα exerts a direct effect on mitochondrial respiratory function in the heart, independently of its cell surface receptors. TNFα-induced cardioprotection is known to involve reactive oxygen species (ROS) and sphingolipids. We therefore further propose that this direct mitochondrial effect is mediated via ROS and sphingolipids. The protective concentration of TNFα (0.5 ng/ml) was added to isolated heart mitochondria from black 6 × 129 mice (WT) and double TNF receptor knockout mice (TNFR1&2^−/−). Respiratory parameters and inner mitochondrial membrane potential were analyzed in the presence/absence of two antioxidants, N-acetyl-l-cysteine or N-tert-butyl-α-(2-sulfophenyl)nitrone or two antagonists of the sphingolipid pathway, N-oleoylethanolamine (NOE) or imipramine. In WT, TNFα reduced State 3 respiration from 279.3 ± 3 to 119.3 ± 2 (nmol O₂/mg protein/min), increased proton leak from 15.7 ± 0.6% (control) to 36.6 ± 4.4%, and decreased membrane potential by 20.5 ± 3.1% compared to control groups. In TNFR1&2^−/− mice, TNFα reduced State 3 respiration from 205.2 ± 4 to 75.7 ± 1 (p < 0.05 vs. respective control). In WT mice, both antioxidants added with TNFα restored State 3 respiration to 269.2 ± 2 and 257.6 ± 2, respectively. Imipramine and NOE also restored State 3 respiration to 248.4 ± 2 and 249.0 ± 2, respectively (p < 0.01 vs. TNFα alone). Similarly, both antioxidant and inhibitors of the sphingolipid pathway restored the proton leak to pre-TNF values. TNFα-treated mitochondria or isolated cardiac muscle fibers showed an increase in respiration after anoxia–reoxygenation, but this effect was lost in the presence of an antioxidant or NOE. Similar data were obtained in TNFR1&2^−/− mice. TNFα exerts a protective effect on respiratory function in isolated mitochondria subjected to an anoxia–reoxygenation insult. This effect appears to be independent of its cell surface receptors, but is likely to be mediated by ROS and sphingolipids.     

Regulatory role of mitochondria in oxidative stress and atherosclerosis

Mitochondrial physiology and biogenesis play a crucial role in the initiation and progression of cardiovascular disease following oxidative stress-induced damage such as atherosclerosis (AST). Dysfunctional mitochondria caused by an increase in mitochondrial reactive oxygen species (ROS) production, accumulation of mitochondrial DNA damage, and respiratory chain deficiency induces death of endothelial/smooth muscle cells and favors plaque formation/rupture via the regulation of mitochondrial biogenesis-related genes such as peroxisome proliferator-activated receptor γ coactivator (PGC-1), although more detailed mechanisms still need further study. Based on the effect of healthy mitochondria produced by mitochondrial biogenesis on decreasing ROS-mediated cell death and the recent finding that the regulation of PGC-1 involves mitochondrial fusion-related protein (mitofusin), we thus infer the regulatory role of mitochondrial fusion/fission balance in AST pathophysiology. In this review, the first section discusses the possible association between AST-inducing factors and the molecular regulatory mechanisms of mitochondrial biogenesis and dynamics, and explains the role of mitochondria-dependent regulation in cell apoptosis during AST development. Furthermore, nitric oxide has the Janus-faced effect by protecting vascular damage caused by AST while being a reactive nitrogen species (RNS) which act together with ROS to damage cells. Therefore, in the second section we discuss mitochondrial ATP-sensitive K(+) channels, which regulate mitochondrial ion transport to maintain mitochondrial physiology, involved in the regulation of ROS/RNS production and their influence on AST/cardiovascular diseases (CVD). Through this review, we can further appreciate the multi-regulatory functions of the mitochondria involved in AST development. The understanding of these related mechanisms will benefit drug development in treating AST/CVD through targeted biofunctions of mitochondria.