NQO1-dependent redox cycling of idebenone: effects on cellular redox potential and energy levels

Short-chain quinones are described as potent antioxidants and in the case of idebenone have already been under clinical investigation for the treatment of neuromuscular disorders. Due to their analogy to coenzyme Q10 (CoQ10), a long-chain quinone, they are widely regarded as a substitute for CoQ10. However, apart from their antioxidant function, this provides no clear rationale for their use in disorders with normal CoQ10 levels. Using recombinant NAD(P)H:quinone oxidoreductase (NQO) enzymes, we observed that contrary to CoQ10 short-chain quinones such as idebenone are good substrates for both NQO1 and NQO2. Furthermore, the reduction of short-chain quinones by NQOs enabled an antimycin A-sensitive transfer of electrons from cytosolic NAD(P)H to the mitochondrial respiratory chain in both human hepatoma cells (HepG2) and freshly isolated mouse hepatocytes. Consistent with the substrate selectivity of NQOs, both idebenone and CoQ1, but not CoQ10, partially restored cellular ATP levels under conditions of impaired complex I function. The observed cytosolic-mitochondrial shuttling of idebenone and CoQ1 was also associated with reduced lactate production by cybrid cells from mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (MELAS) patients. Thus, the observed activities separate the effectiveness of short-chain quinones from the related long-chain CoQ10 and provide the rationale for the use of short-chain quinones such as idebenone for the treatment of mitochondrial disorders.     

Autophagy of Mitochondria: A Promising Therapeutic Target for Neurodegenerative Disease

The autophagic process is the only known mechanism for mitochondrial turnover and it has been speculated that dysfunction of autophagy may result in mitochondrial error and cellular stress. Emerging investigations have provided new understanding of how autophagy of mitochondria (also known as mitophagy) is associated with cellular oxidative stress and its impact on neurodegeneration. This impaired autophagic function may be considered as a possible mechanism in the pathogenesis of several neurodegenerative disorders including Parkinson’s disease, Alzheimer’s disease, multiple sclerosis, amyotrophic lateral sclerosis, and Huntington disease. It can be suggested that autophagy dysfunction along with oxidative stress is considered main events in neurodegenerative disorders. New therapeutic approaches have now begun to target mitochondria as a potential drug target. This review discusses evidence supporting the notion that oxidative stress and autophagy are intimately associated with neurodegenerative disease pathogenesis. This review also explores new approaches that can prevent mitochondrial dysfunction, improve neurodegenerative etiology, and also offer possible cures to the aforementioned neurodegenerative diseases.     

Importance of mitochondrial dysfunction in oxidative stress response: A comparative study of gene expression profiles

Mitochondria are considered to play an important role in oxidative stress response since they are a source of reactive oxygen species and are also targeted by these species. This study examined the mitochondrial conditions in cells of epithelial origin that were exposed to H(2)O(2) and found a decline in the membrane potential along with a specific loss of UQCRC1, a sub-unit of complex III, suggesting that mitochondrial dysfunction occurs upon exposure to oxidative stress. This observation led to the hypothesis that certain cellular responses to oxidative stress occurred because of mitochondrial dysfunction. When mitochondria-less (pseudo ρ0) cells were examined as a model of mitochondrial dysfunction, striking similarities were found in their cellular responses compared with those found in cells exposed to oxidative stress, including changes in gene expression and gelatinolytic enzyme activities, thus suggesting that cellular responses to oxidative stress were partly mediated by mitochondrial dysfunction. This possibility was further validated by microarray analysis, which suggested that almost one-fourth of the cellular responses to oxidative stress were mediated by mitochondrial dysfunction that accompanies oxidative stress, thereby warranting a therapeutic strategy that targets mitochondria for the treatment of oxidative stress-associated diseases.     

Epigallocatechin-3-gallate prevents oxidative phosphorylation deficit and promotes mitochondrial biogenesis in human cells from subjects with Down's syndrome

A critical role for mitochondrial dysfunction has been proposed in the pathogenesis of Down's syndrome (DS), a human multifactorial disorder caused by trisomy of chromosome 21, associated with mental retardation and early neurodegeneration. Previous studies from our group demonstrated in DS cells a decreased capacity of the mitochondrial ATP production system and overproduction of reactive oxygen species (ROS) in mitochondria. In this study we have tested the potential of epigallocatechin-3-gallate (EGCG) – a natural polyphenol component of green tea – to counteract the mitochondrial energy deficit found in DS cells. We found that EGCG, incubated with cultured lymphoblasts and fibroblasts from DS subjects, rescued mitochondrial complex I and ATP synthase catalytic activities, restored oxidative phosphorylation efficiency and counteracted oxidative stress. These effects were associated with EGCG-induced promotion of PKA activity, related to increased cellular levels of cAMP and PKA-dependent phosphorylation of the NDUFS4 subunit of complex I. In addition, EGCG strongly promoted mitochondrial biogenesis in DS cells, as associated with increase in Sirt1-dependent PGC-1α deacetylation, NRF-1 and T-FAM protein levels and mitochondrial DNA content.In conclusion, this study shows that EGCG is a promoting effector of oxidative phosphorylation and mitochondrial biogenesis in DS cells, acting through modulation of the cAMP/PKA- and sirtuin-dependent pathways. EGCG treatment promises thus to be a therapeutic approach to counteract mitochondrial energy deficit and oxidative stress in DS.     

Importance of mitochondrial dysfunction in oxidative stress response: A comparative study of gene expression profiles

Abstract

Mitochondria are considered to play an important role in oxidative stress response since they are a source of reactive oxygen species and are also targeted by these species. This study examined the mitochondrial conditions in cells of epithelial origin that were exposed to H₂O₂ and found a decline in the membrane potential along with a specific loss of UQCRC1, a sub-unit of complex III, suggesting that mitochondrial dysfunction occurs upon exposure to oxidative stress. This observation led to the hypothesis that certain cellular responses to oxidative stress occurred because of mitochondrial dysfunction. When mitochondria-less (pseudo ρ0) cells were examined as a model of mitochondrial dysfunction, striking similarities were found in their cellular responses compared with those found in cells exposed to oxidative stress, including changes in gene expression and gelatinolytic enzyme activities, thus suggesting that cellular responses to oxidative stress were partly mediated by mitochondrial dysfunction. This possibility was further validated by microarray analysis, which suggested that almost one-fourth of the cellular responses to oxidative stress were mediated by mitochondrial dysfunction that accompanies oxidative stress, thereby warranting a therapeutic strategy that targets mitochondria for the treatment of oxidative stress-associated diseases.     

Differential protective effects of quercetin, resveratrol, rutin and epigallocatechin gallate against mitochondrial dysfunction induced by indomethacin in Caco-2 cells

The beneficial effects of dietary polyphenols on health are due not only to their antioxidant properties but also to their antibacterial, anti-inflammatory and/or anti-tumoral activities. It has recently been proposed that protection of mitochondrial function (which is altered in several diseases such as Alzheimer, Parkinson, obesity and diabetes) by these compounds, may be important in explaining the beneficial effects of polyphenols on health. The aim of this study was to evaluate the protective effects of dietary polyphenols quercetin, rutin, resveratrol and epigallocatechin gallate against the alterations of mitochondrial function induced by indomethacin (INDO) in intestinal epithelial Caco-2 cells, and to address the mechanism involved in such damaging effect by INDO, which generates oxidative stress. INDO concentration dependently decreases cellular ATP levels and mitochondrial membrane potential in Caco-2 cells after 20min of incubation. INDO also inhibits the activity of mitochondrial complex I and causes accumulation of NADH; leading to overproduction of mitochondrial O(2)()(-), since it is prevented by pyruvate. Quercetin (0.01mg/ml), resveratrol (0.1mg/ml) and rutin (1mg/ml) protected Caco-2 cells against INDO-induced mitochondrial dysfunction, while no protection was observed with epigallocatechin gallate. Quercetin was the most efficient in protecting against mitochondrial dysfunction; this could be due to its ability to enter cells and accumulate in mitochondria. Additionally its structural similarity with rotenone could favor its binding to the ubiquinone site of complex I, protecting it from inhibitors such as INDO or rotenone. These findings suggest a possible new protective role for dietary polyphenols for mitochondria, complementary of their antioxidant property. This new role might expand the preventive and/or therapeutic use of PPs in conditions involving mitochondrial dysfunction and associated with increased oxidative stress at the cellular or tissue levels.     

Therapeutic attenuation of mitochondrial dysfunction and oxidative stress in neurotoxin models of Parkinson's disease

Parkinson's disease (PD) is a progressive neurodegenerative disorder for which there is no current therapy preventing cumulative neuronal loss. There is substantial evidence that mitochondrial dysfunction, oxidative stress, and associated caspase activity underlie the neurodegeneration observed. One potential drug therapy is the potent free radical scavenger and antioxidant cystamine, which has demonstrated significant clinical potential in models of neurodegenerative disorders and human neurological disease. This study examined the oral efficacy of cystamine in the MPTP and 6-hydroxydopamine neurotoxin models of PD. The neuroprotective effects of cystamine treatment significantly ameliorated nigral neuronal loss, preserved striatal dopaminergic projections, and improved striatal dopamine and metabolite levels, as compared to MPTP alone. Cystamine normalized striatal 8-hydroxy-2'-deoxyguanosine levels and ATP concentrations, consistent with reduced oxidative stress and improved mitochondrial function. Cystamine also protected against MPTP-induced mitochondrial loss, as identified by mitochondrial heat shock protein 70 and superoxide dismutase 2, with concomitant reductions in cytochrome c and caspase-3 activities. The neuroprotective value of cystamine was confirmed in the 6-hydroxydopamine model. Together these findings show cystamine's therapeutic benefit to reduce neuronal loss through attenuation of oxidative stress and mitochondrial dysfunction, providing the rationale for human clinical trials in PD patients.     

Mitochondrial Involvement in Brain Function and Dysfunction: Relevance to Aging,Neurodegenerative Disorders and Longevity

It is becoming increasingly evident that the mitochondrial genome may play a key role in neurodegenerative diseases. Mitochondrial dysfunction is characteristic of several neurodegenerative disorders, and evidence for mitochondria being a site of damage in neurodegenerative disorders is partially based on decreases in respiratory chain complex activities in Parkinson's disease, Alzheimer's disease, and Huntington's disease. Such defects in respiratory complex activities, possibly associated with oxidant/antioxidant balance perturbation, are thought to underlie defects in energy metabolism and induce cellular degeneration. Efficient functioning of maintenance and repair process seems to be crucial for both survival and physical quality of life. This is accomplished by a complex network of the so-called longevity assurance processes, which are composed of genes termed vitagenes. A promising approach for the identification of critical gerontogenic processes is represented by the hormesis-like positive effect of stress. In the present review, we discuss the role of energy thresholds in brain mitochondria and their implications in neurodegeneration. We then review the evidence for the role of oxidative stress in modulating the effects of mitochondrial DNA mutations on brain age-related disorders and also discuss new approaches for investigating the mechanisms of lifetime survival and longevity.     

Oxidation-reduction and reactive oxygen species homeostasis in mutant plants with respiratory chain complex I dysfunction

Mutations in a mitochondrial or nuclear gene encoding respiratory chain complex I subunits lead to decreased or a total absence of complex I activity. Plant mutants with altered or lost complex I activity adapt their respiratory metabolism by inducing alternative pathways of the respiratory chain and changing energy metabolism. Apparently, complex I is a crucial component of the oxidation-reduction (redox) regulatory system in photosynthetic cells, and alternative NAD(P)H dehydrogenases of the mitochondrial electron transport chain (mtETC) cannot fully compensate for its impairment. In most cases, dysfunction of complex I is associated with lowered or unchanged hydrogen peroxide (H(2)O(2)) concentrations, but increased superoxide (O(2)(-)) levels. Higher production of reactive oxygen species (ROS) by mitochondria in the mosaic (MSC16) cucumber mutant may be related to retrograde signalling. Different effects of complex I dysfunction on H(2)O(2) and O(2)(-) levels in described mutants might result from diverse regulation of processes involved in H(2)O(2) and O(2)(-) production. Often, dysfunction of complex I did not lead to oxidative stress, but increased the capacity of the antioxidative system and enhanced stress tolerance. The new cellular homeostasis in mutants with dysfunction of complex I allows growth and development, reflecting the plasticity of plant metabolism.     

Depletion of glutathione up-regulates mitochondrial complex I expression in glial cells

Glutathione deficiency is commonly associated with mitochondrial complex I dysfunction and loss of viability in neurones, but not in glia. In order to address the possible mechanism responsible for this cellular difference, the regulation of mitochondrial complex I expression by glutathione depletion was investigated in glial cells. Incubation of rat-cultured astrocytes and C6 glioma cells with the specific gamma-glutamylcysteine synthetase inhibitor L-buthionine-(S:,R:)-sulfoximine (L-BSO; 0.1-1 mM) decreased the total specific content of glutathione in a dose- and time-dependent fashion. Northern blot analyses revealed that glutathione deficiency caused by L-BSO (0.1 mM) was associated with a twofold enhancement in complex I regulatory subunit ND6 (mitochondrially encoded) mRNA expression after 24-72 h. This effect was accompanied by a twofold increase in complex-I activity at 72 h in L-BSO-treated cells, as compared with control cells, but complex II-III, complex IV and citrate synthase activities were unaltered. It is suggested that the oxidative stress caused by glutathione depletion in glial cells would up-regulate complex-I activity by enhancing the expression of the mitochondrially encoded regulatory subunit. These results could offer further insight into the different degree of cellular susceptibility observed in glial vs. neuronal cells against oxidative stress.     

帕金森病黑质多巴胺神经元易损伤性的内在因素

帕金森病（Parkinson’s disease,PD）主要症状是由中脑黑质致密部（substantia nigra compact,SNc）的多巴胺（dopamine,DA）神经元死亡引起。帕金森病发病过程中,路易小体病理（Lewy pathology,LP）和线粒体功能障碍最为突出,但SNc 多巴胺神经元为什么特别易遭受这两种病理损害尚不清楚。研究表明,与脑内其他神经元相比,SNc 多巴胺神经元具有特殊的解剖形态、生理和生化表型。SNc 多巴胺神经元具有高分支无髓鞘轴突和众多的突触终端,突触末梢物质和能量代谢的高要求需要大量的线粒体,巨大突触终端增加了突触蛋白质的表达、转运和降解的负担。SNc 多巴胺神经元具有独特的自主起搏电活动和缓慢钙振荡特性,Cav1-3钙通道活动及后续的级联反应增加了SNc 多巴胺神经元线粒体负担,增加了基础氧化应激、线粒体损伤和自噬,降低了处理错误折叠蛋白质的能力。SNc 多巴胺神经元特有的神经递质——多巴胺易被氧化成为反应性醌,具有潜在毒性,可破坏葡糖脑苷脂酶导致其活性降低,引起线粒体氧化应激和溶酶体功能障碍。总之,SNc 多巴胺神经元具有的这些内在因素综合起来,可能导致了其对线粒体功能障碍和路易小体病理损伤的易感性,并且SNc 多巴胺神经元所处的神经网络障碍也促使了帕金森病的进展。认识到这些特征会对研究帕金森病相关病理学机制和阻止疾病进展创造新的机会。     

The potential role of mitochondrial dysfunction in seizure-associated cell death in the hippocampus and epileptogenesis

Epilepsy is considered one of the most common neurological disorders worldwide. The burst firing neurons associated with prolonged epileptic discharges could lead to a large number of changes with events of cascades at the cellular level. From its role as the cellular powerhouse, mitochondria also play a crucial role in the mechanisms of cell death. Emerging evidence has shown that prolonged seizures may result in mitochondrial dysfunction and increase of oxidative and nitrosative stress in the hippocampus that precede neuronal cell death and cause subsequent epileptogenesis. The selective dysfunction of mitochondrial respiratory chain Complex I has been suggested to be a biochemical hallmark of seizure-induced neuronal cell death and epileptogenesis. Therefore, protection of mitochondria from bioenergetic failure and oxidative stress in the hippocampus may open a new vista to the development of effective neuroprotective strategies against seizure-induced brain damage and to the design of novel treatment perspectives against therapy-resistant forms of epilepsy.     

Activation of Class I histone deacetylases contributes to mitochondrial dysfunction in cardiomyocytes with altered complex activities

Histone deacetylases (HDACs) play vital roles in the pathophysiology of heart failure, which is associated with mitochondrial dysfunction. Tumor necrosis factor-α (TNF-α) contributes to the genesis of heart failure and impairs mitochondria. This study evaluated the role of HDACs in TNF-α-induced mitochondrial dysfunction and investigated their therapeutic potential and underlying mechanisms. We measured mitochondrial oxygen consumption rate (OCR) and ATP production using Seahorse XF24 extracellular flux analyzer and bioluminescent assay in control and TNF-α (10 ng/ml, 24 h)-treated HL-1 cells with or without HDAC inhibition. TNF-α increased Class I and II (but not Class IIa) HDAC activities (assessed by Luminescent) with enhanced expressions of Class I (HDAC1, HDAC2, HDAC3, and HDAC8) but not Class IIb HDAC (HDAC6 and HDAC10) proteins in HL-1 cells. TNF-α induced mitochondrial dysfunction with impaired basal, ATP-linked, and maximal respiration, decreased cellular ATP synthesis, and increased mitochondrial superoxide production (measured by MitoSOX red fluorescence), which were rescued by inhibiting HDACs with MPT0E014 (1 μM, a Class I and IIb inhibitor), or MS-275 (1 μM, a Class I inhibitor). MPT0E014 reduced TNF-α-decreased complex I and II enzyme (but not III or IV) activities (by enzyme activity microplate assays). Our results suggest that Class I HDAC actions contribute to TNF-α-induced mitochondrial dysfunction in cardiomyocytes with altered complex I and II enzyme regulation. HDAC inhibition improves dysfunctional mitochondrial bioenergetics with attenuation of TNF-α-induced oxidative stress, suggesting the therapeutic potential of HDAC inhibition in cardiac dysfunction.     

Mitochondrial dysfunction and oxidative stress: cause and consequence of epileptic seizures

Mitochondrial dysfunction has been implicated as a contributing factor in diverse acute and chronic neurological disorders. However, its role in the epilepsies has only recently emerged. Animal studies show that epileptic seizures result in free radical production and oxidative damage to cellular proteins, lipids, and DNA. Mitochondria contribute to the majority of seizure-induced free radical production. Seizure-induced mitochondrial superoxide production, consequent inactivation of susceptible iron–sulfur enzymes, e.g., aconitase, and resultant iron-mediated toxicity may mediate seizure-induced neuronal death. Epileptic seizures are a common feature of mitochondrial dysfunction associated with mitochondrial encephalopathies. Recent work suggests that chronic mitochondrial oxidative stress and resultant dysfunction can render the brain more susceptible to epileptic seizures. This review focuses on the emerging role of oxidative stress and mitochondrial dysfunction both as a consequence and as a cause of epileptic seizures.     

High-fat diet induces an initial adaptation of mitochondrial bioenergetics in the kidney despite evident oxidative stress and mitochondrial ROS production

Obesity and metabolic syndrome are associated with an increased risk for several diabetic complications, including diabetic nephropathy and chronic kidney diseases. Oxidative stress and mitochondrial dysfunction are often proposed mechanisms in various organs in obesity models, but limited data are available on the kidney. Here, we fed a lard-based high-fat diet to mice to investigate structural changes, cellular and subcellular oxidative stress and redox status, and mitochondrial biogenesis and function in the kidney. The diet induced characteristic changes, including glomerular hypertrophy, fibrosis, and interstitial scarring, which were accompanied by a proinflammatory transition. We demonstrate evidence for oxidative stress in the kidney through 3-nitrotyrosine and protein radical formation on high-fat diet with a contribution from iNOS and NOX-4 as well as increased generation of mitochondrial oxidants on carbohydrate- and lipid-based substrates. The increased H(2)O(2) emission in the mitochondria suggests altered redox balance and mitochondrial ROS generation, contributing to the overall oxidative stress. No major derailments were observed in respiratory function or biogenesis, indicating preserved and initially improved bioenergetic parameters and energy production. We suggest that, regardless of the oxidative stress events, the kidney developed an adaptation to maintain normal respiratory function as a possible response to an increased lipid overload. These findings provide new insights into the complex role of oxidative stress and mitochondrial redox status in the pathogenesis of the kidney in obesity and indicate that early oxidative stress-related changes, but not mitochondrial bioenergetic dysfunction, may contribute to the pathogenesis and development of obesity-linked chronic kidney diseases.     

Mitochondrial free radical overproduction due to respiratory chain impairment in the brain of a mouse model of Rett syndrome: protective effect of CNF1

Rett syndrome (RTT) is a pervasive neurodevelopmental disorder mainly caused by mutations in the X-linked MECP2 gene associated with severe intellectual disability, movement disorders, and autistic-like behaviors. Its pathogenesis remains mostly not understood and no effective therapy is available. High circulating levels of oxidative stress markers in patients and the occurrence of oxidative brain damage in MeCP2-deficient mouse models suggest the involvement of oxidative stress in RTT pathogenesis. However, the molecular mechanism and the origin of the oxidative stress have not been elucidated. Here we demonstrate that a redox imbalance arises from aberrant mitochondrial functionality in the brain of MeCP2-308 heterozygous female mice, a condition that more closely recapitulates that of RTT patients. The marked increase in the rate of hydrogen peroxide generation in the brain of RTT mice seems mainly produced by the dysfunctional complex II of the mitochondrial respiratory chain. In addition, both membrane potential generation and mitochondrial ATP synthesis are decreased in RTT mouse brains when succinate, the complex II respiratory substrate, is used as an energy source. Respiratory chain impairment is brain area specific, owing to a decrease in either cAMP-dependent phosphorylation or protein levels of specific complex subunits. Further, we investigated whether the treatment of RTT mice with the bacterial protein CNF1, previously reported to ameliorate the neurobehavioral phenotype and brain bioenergetic markers in an RTT mouse model, exerts specific effects on brain mitochondrial function and consequently on hydrogen peroxide production. In RTT brains treated with CNF1, we observed the reactivation of respiratory chain complexes, the rescue of mitochondrial functionality, and the prevention of brain hydrogen peroxide overproduction. These results provide definitive evidence of mitochondrial reactive oxygen species overproduction in RTT mouse brain and highlight CNF1 efficacy in counteracting RTT-related mitochondrial defects.     

Mitochondrial dysfunction and oxidative stress in diabetic wound

Diabetic wounds nowadays have become a major health challenge with the changes of the disease spectrum. Mitochondria are closely associated with stubborn nonhealing diabetic wounds for their vital role in energy metabolism, redox homeostasis, and signal transduction. There is significant mitochondrial dysfunction and oxidative stress in diabetic wounds. However, the contribution of mitochondrial dysfunction in oxidative stress induced nonhealing diabetic wound is still not fully understood. In this review, we will briefly summarize the current knowledge of the reported signaling pathways and therapeutic strategies involved in mitochondrial dysfunction in diabetic wounds. The findings provide further understanding of strategies that focus on mitochondria in diabetic wound treatment.     

Mitochondria and ubiquitin-proteasomal system interplay: relevance to Parkinson's disease

The cellular mechanisms that may underlie the death of dopaminergic neurons in Parkinson's disease are ubiquitin-proteasomal system (UPS) impairment, mitochondrial dysfunction, and oxidative stress. The goal of this work was to elucidate the correlation between mitochondrial dysfunction and UPS impairment, focusing on the role of oxidative stress. Our data revealed that mitochondria-DNA-depleted cells (rho0) are compromised at the mitochondrial and UPS levels and also show an alteration of the oxidative status. In parental cells (rho+), MPP(+) induced a clear inhibition of complex I activity, as well as an increase in ubiquitinylated protein levels, which was not observed in cells treated with lactacystin. Moreover, MPP(+) induced a decreased in the 20S chymotrypsin-like and peptidyl-glutamyl peptide hydrolytic-like proteolytic activities after 24 h of exposure. ROS production was increased in rho+ cells treated with MPP(+) or lactacystin, at early treatment periods. MPP(+) induced an increase in carbonyl group formation in rho+ cells. The results suggest that a mitochondrial alteration leads to an imbalance in the cellular oxidative status, inducing a proteasomal deregulation, which may exacerbate protein aggregation, and consequently degenerative events.     

Autophagy, mitochondria and oxidative stress: cross-talk and redox signalling

Reactive oxygen and nitrogen species change cellular responses through diverse mechanisms that are now being defined. At low levels, they are signalling molecules, and at high levels, they damage organelles, particularly the mitochondria. Oxidative damage and the associated mitochondrial dysfunction may result in energy depletion, accumulation of cytotoxic mediators and cell death. Understanding the interface between stress adaptation and cell death then is important for understanding redox biology and disease pathogenesis. Recent studies have found that one major sensor of redox signalling at this switch in cellular responses is autophagy. Autophagic activities are mediated by a complex molecular machinery including more than 30 Atg (AuTophaGy-related) proteins and 50 lysosomal hydrolases. Autophagosomes form membrane structures, sequester damaged, oxidized or dysfunctional intracellular components and organelles, and direct them to the lysosomes for degradation. This autophagic process is the sole known mechanism for mitochondrial turnover. It has been speculated that dysfunction of autophagy may result in abnormal mitochondrial function and oxidative or nitrative stress. Emerging investigations have provided new understanding of how autophagy of mitochondria (also known as mitophagy) is controlled, and the impact of autophagic dysfunction on cellular oxidative stress. The present review highlights recent studies on redox signalling in the regulation of autophagy, in the context of the basic mechanisms of mitophagy. Furthermore, we discuss the impact of autophagy on mitochondrial function and accumulation of reactive species. This is particularly relevant to degenerative diseases in which oxidative stress occurs over time, and dysfunction in both the mitochondrial and autophagic pathways play a role.     

帕金森病黑质多巴胺神经元易损伤性的内在因素

帕金森病（Parkinson’s disease,PD）主要症状是由中脑黑质致密部（substantia nigra compact,SNc）的多巴胺（dopamine,DA）神经元死亡引起。帕金森病发病过程中,路易小体病理（Lewy pathology,LP）和线粒体功能障碍最为突出,但SNc 多巴胺神经元为什么特别易遭受这两种病理损害尚不清楚。研究表明,与脑内其他神经元相比,SNc 多巴胺神经元具有特殊的解剖形态、生理和生化表型。SNc 多巴胺神经元具有高分支无髓鞘轴突和众多的突触终端,突触末梢物质和能量代谢的高要求需要大量的线粒体,巨大突触终端增加了突触蛋白质的表达、转运和降解的负担。SNc 多巴胺神经元具有独特的自主起搏电活动和缓慢钙振荡特性,Cav1-3钙通道活动及后续的级联反应增加了SNc 多巴胺神经元线粒体负担,增加了基础氧化应激、线粒体损伤和自噬,降低了处理错误折叠蛋白质的能力。SNc 多巴胺神经元特有的神经递质--多巴胺易被氧化成为反应性醌,具有潜在毒性,可破坏葡糖脑苷脂酶导致其活性降低,引起线粒体氧化应激和溶酶体功能障碍。总之,SNc 多巴胺神经元具有的这些内在因素综合起来,可能导致了其对线粒体功能障碍和路易小体病理损伤的易感性,并且SNc 多巴胺神经元所处的神经网络障碍也促使了帕金森病的进展。认识到这些特征会对研究帕金森病相关病理学机制和阻止疾病进展创造新的机会。