Mitochondrial dysfunction in rat with nonalcoholic fatty liver: Involvement of complex I, reactive oxygen species and cardiolipin

Mitochondrial dysfunction and oxidative stress play a central role in the pathophysiology of nonalcoholic fatty liver disease (NAFLD). This study aimed to elucidate the mechanism(s) responsible for mitochondrial dysfunction in nonalcoholic fatty liver. Fatty liver was induced in rats with a choline-deficient (CD) diet for 30 days. We examined the effect of CD diet on various parameters related to mitochondrial function such as complex I activity, oxygen consumption, reactive oxygen species (ROS) generation and cardiolipin content and oxidation. The activity of complex I was reduced by 35% in mitochondria isolated from CD livers compared with the controls. These changes in complex I activity were associated with parallel changes in state 3 respiration. Hydrogen peroxide (H₂O₂) generation was significantly increased in mitochondria isolated from CD livers. The mitochondrial content of cardiolipin, a phospholipid required for optimal activity of complex I, decreased by 38% as function of CD diet, while there was a significantly increase in the level of peroxidized cardiolipin. The lower complex I activity in mitochondria from CD livers could be completely restored to the level of control livers by exogenously added cardiolipin. This effect of cardiolipin could not be replaced by other phospholipids nor by peroxidized cardiolipin. It is concluded that CD diet causes mitochondrial complex I dysfunction which can be attributed to ROS-induced cardiolipin oxidation. These findings provide new insights into the alterations underlying mitochondrial dysfunction in NAFLD.     

动物线粒体核质基因互作的研究进展

线粒体是重要的细胞器,为细胞的生命活动提供能量,线粒体的正常功能是核基因和线粒体基因共同作用维持的结果。线粒体DNA是动物细胞内唯一存在的核外遗传物质,线粒体DNA与核基因的相互作用维持着线粒体和线粒体内膜呼吸链氧化磷酸化的正常功能状态。本文就线粒体核质基因互作在人类疾病、衰老、细胞凋亡、氯霉素抗性、ANT、MnSOD、mtTFA的研究进展进行了综述。 Abstract：Mitochondria is the essential element for a cell,in which generates energy.The normal functions of a mitochondria are controlled by both mitochondrial genome and nuclear genome.Mitochondrial DNA is the only genome in the cytoplasmy of a cell,it encodes essential components of oxidative phosphorylation(OXPHOS)in mitochondrial inner membrane,generating cellular energy in the main form of adenosine triphosphate(ATP).In this paper,we reviewed the research development on interactions of nuclear and mitochondrial genes,including human disease and aging,apoptosis,chloromycetin resistance,ANT,MnSOD and mtTFA.     

非酒精性脂肪肝病形成机制:补体和线粒体在其形成中的作用

非酒精性脂肪肝病(nonalcoholic fatty liver disease,NAFLD)作为一种流行性代谢疾病,一直是研究热点之一.NAFLD的形成涉及线粒体功能障碍、胰岛素抵抗、氧化应激、炎症反应等机制,而线粒体与补体在其中占据重要位置.然而,线粒体与补体在NAFLD形成过程中的内在关联及协同作用目前尚不十分...     

人类线粒体tRNA生物合成与线粒体疾病

线粒体是普遍存在于真核细胞中的一类细胞器.每个线粒体含有多个拷贝的闭合环状双链DNA. 人类线粒体DNA (mitochondrial DNA, mtDNA)共编码22种线粒体tRNA(mitochondrial tRNA,mt tRNA), 2种rRNA 及13种多肽.mt tRNA独特的结构特点决定了它们与具有典型三叶草结构的细胞质 tRNA不同.编码mt tRNA的基因突变频率较高,这可能是引起线粒体功能障碍的主要原因之一. 同时 ,这与很多病理现象相关.目前发现,大量与mt tRNA生物代谢和功能相关的核因子包括加工内切酶、 tRNA修饰酶和氨酰-tRNA合成酶.这些核因子的异常导致了疾病相关的tRNA致病突变.由此可见mt tRNA功能对于线粒体活性的重要性.     

Mitochondrial involvement in non-alcoholic steatohepatitis

Non-alcoholic steatohepatitis (NASH) is an increasing recognized condition that may progress to end-stage liver disease. There are consistent evidences that mitochondrial dysfunction plays a central role in NASH whatever its origin. Mitochondria are the key controller of fatty acids removal and this is part of an intensive gene program that modifies hepatocytes to counteract the excessive fat storage. Mitochondrial dysfunction participates at different levels in NASH pathogenesis since it impairs fatty liver homeostasis and induces overproduction of ROS that in turn trigger lipid peroxidation, cytokines release and cell death. In this review we briefly recall the role of mitochondria in fat metabolism and energy homeostasis and focus on the role of mitochondrial impairment and uncoupling proteins in the pathophysiology of NASH progression. We suggest that mitochondrial respiratory chain, UCP2 and redox balance cooperate in a common pathway that permits to set down the mitochondrial redox pressure, limits the risk of oxidative damage, and allows the maximal rate of fat removal. When the environmental conditions change and high energy supply occurs, hepatocytes are unable to replace their ATP store and steatosis progress to NASH and cirrhosis. The beneficial effects of some drugs on mitochondrial function are also discussed.     

Mitochondrial Contributions to Cancer Cell Physiology: Redox Balance, Cell Cycle, and Drug Resistance

Alterations in the biochemistry of mitochondria have been associated with cell transformation and the acquisition of drug resistance to certain chemotherapeutic agents, suggesting that mitochondria may play a supportive role for the cancer cell phenotype. Mitochondria are multifunctional organelles that contribute to the cellular adenosine triphosphate (ATP) pool and cellular redox balance through the production of reactive oxygen intermediates (ROI). Our laboratory has focused on these mitochondrial functions in the context of cancer cell physiology to evaluate the potential role of mitochondria as controllers of tumour cell proliferation. Low concentrations of ROI have been implicated as messengers in intracellular signal transduction mechanisms; thus an imbalance of ROI production from the mitochondria may support cancer cell growth. In addition, suppression of mitochondrial ATP production can halt cell cycle progression at two energetic checkpoints, suggesting that the use of tumor-selective agents to reduce ATP production may offer a therapeutic target for cancer growth control.     

Mitochondrial adaptations to obesity-related oxidant stress

It is not known why viable hepatocytes in fatty livers are vulnerable to necrosis, but associated mitochondrial alterations suggest that reactive oxygen species (ROS) production may be increased. Although the mechanisms for ROS-mediated lethality are not well understood, increased mitochondrial ROS generation often precedes cell death, and hence, might promote hepatocyte necrosis. The aim of this study is to determine if liver mitochondria from obese mice with fatty hepatocytes actually produce increased ROS. Secondary objectives are to identify potential mechanisms for ROS increases and to evaluate whether ROS increase uncoupling protein (UCP)-2, a mitochondrial protein that promotes ATP depletion and necrosis. Compared to mitochondria from normal livers, fatty liver mitochondria have a 50% reduction in cytochrome c content and produce superoxide anion at a greater rate. They also contain 25% more GSH and demonstrate 70% greater manganese superoxide dismutase activity and a 35% reduction in glutathione peroxidase activity. Mitochondrial generation of H(2)O(2) is increased by 200% and the activities of enzymes that detoxify H(2)O(2) in other cellular compartments are abnormal. Cytosolic glutathione peroxidase and catalase activities are 42 and 153% of control values, respectively. These changes in the production and detoxification of mitochondrial ROS are associated with a 300% increase in the mitochondrial content of UCP-2, although the content of beta-1 ATP synthase, a constitutive mitochondrial membrane protein, is unaffected. Supporting the possibility that mitochondrial ROS induce UCP-2 in fatty hepatocytes, a mitochondrial redox cycling agent that increases mitochondrial ROS production upregulates UCP-2 mRNAs in primary cultures of normal rat hepatocytes by 300%. Thus, ROS production is increased in fatty liver mitochondria. This may result from chronic apoptotic stress and provoke adaptations, including increases in UCP-2, that potentiate necrosis.     

The role of the CD39–CD73–adenosine pathway in liver disease

Extracellular adenosine triphosphate (ATP) is a danger signal released by dying and damaged cells, and it functions as an immunostimulatory signal that promotes inflammation. The ectonucleotidases CD39/ectonucleoside triphosphate diphosphohydrolase‐1 and CD73/ecto‐5′‐nucleotidase are cell‐surface enzymes that breakdown extracellular ATP into adenosine. This drives a shift from an ATP‐driven proinflammatory environment to an anti‐inflammatory milieu induced by adenosine. The CD39–CD73–adenosine pathway changes dynamically with the pathophysiological context in which it is embedded. Accumulating evidence suggests that CD39 and CD73 play important roles in liver disease as critical components of the extracellular adenosinergic pathway. Recent studies have shown that the modification of the CD39–CD73–adenosine pathway alters the liver's response to injury. Moreover, adenosine exerts different effects on the pathophysiology of the liver through different receptors. In this review, we aim to describe the role of the CD39–CD73–adenosine pathway and adenosine receptors in liver disease, highlighting potential therapeutic targets in this pathway, which will facilitate the development of therapeutic strategies for the treatment of liver disease.     

Mitochondrial dysfunction in rat with nonalcoholic fatty liver Involvement of complex I, reactive oxygen species and cardiolipin

Mitochondrial dysfunction and oxidative stress play a central role in the pathophysiology of nonalcoholic fatty liver disease (NAFLD). This study aimed to elucidate the mechanism(s) responsible for mitochondrial dysfunction in nonalcoholic fatty liver. Fatty liver was induced in rats with a choline-deficient (CD) diet for 30 days. We examined the effect of CD diet on various parameters related to mitochondrial function such as complex I activity, oxygen consumption, reactive oxygen species (ROS) generation and cardiolipin content and oxidation. The activity of complex I was reduced by 35% in mitochondria isolated from CD livers compared with the controls. These changes in complex I activity were associated with parallel changes in state 3 respiration. Hydrogen peroxide (H(2)O(2)) generation was significantly increased in mitochondria isolated from CD livers. The mitochondrial content of cardiolipin, a phospholipid required for optimal activity of complex I, decreased by 38% as function of CD diet, while there was a significantly increase in the level of peroxidized cardiolipin. The lower complex I activity in mitochondria from CD livers could be completely restored to the level of control livers by exogenously added cardiolipin. This effect of cardiolipin could not be replaced by other phospholipids nor by peroxidized cardiolipin. It is concluded that CD diet causes mitochondrial complex I dysfunction which can be attributed to ROS-induced cardiolipin oxidation. These findings provide new insights into the alterations underlying mitochondrial dysfunction in NAFLD.     

Hydrogen sulfide attenuates homocysteine-induced osteoblast dysfunction by inhibiting mitochondrial toxicity

Homocysteine (Hcy) is detrimental to bone health in a mouse model of diet-induced hyperhomocysteinemia (HHcy). However, little is known about Hcy-mediated osteoblast dysfunction via mitochondrial oxidative damage. Hydrogen sulfide (H₂S) has potent antioxidant, anti-inflammatory, and antiapoptotic effects. In this study, we hypothesized that the H₂S mediated recovery of osteoblast dysfunction by maintaining mitochondrial biogenesis in Hcy-treated osteoblast cultures in vitro. MC3T3-E1 osteoblastic cells were exposed to Hcy treatment in the presence or absence of an H₂S donor (NaHS). Cell viability, osteogenic differentiation, reactive oxygen species (ROS) production were determined. Mitochondrial DNA copy number, adenosine triphosphate (ATP) production, and oxygen consumption were also measured. Our results demonstrated that administration of Hcy increases the intracellular Hcy level and decreases intracellular H₂S level and expression of the cystathionine β-synthase/Cystathionine γ-lyase system, thereby inhibiting osteogenic differentiation. Pretreatment with NaHS attenuated Hcy-induced mitochondrial toxicity (production of total ROS and mito-ROS, ratio of mitochondrial fission (DRP-1)/fusion (Mfn-2)) and restored ATP production and mitochondrial DNA copy numbers as well as oxygen consumption in the osteoblast as compared with the control, indicating its protective effects against Hcy-induced mitochondrial toxicity. In addition, NaHS also decreased the release of cytochrome c from the mitochondria to the cytosol, which induces cell apoptosis. Finally, flow cytometry confirmed that NaHS can rescue cells from apoptosis induced by Hcy. Our studies strongly suggest that NaHS has beneficial effects on mitochondrial toxicity, and could be developed as a potential therapeutic agent against HHcy-induced mitochondrial dysfunction in cultured osteoblasts in vitro.     

Mechanism of 3-nitropropionic acid-induced membrane permeability transition of isolated mitochondria and its suppression by L-carnitine

3-Nitropropionic acid (3NP) functions as an irreversible inhibitor of succinic acid dehydrogenase (complex II) and induces neuronal disorders in rats similar to those in patients with Huntington's disease. It is well known that L-carnitine (LC), a carrier of long chain fatty acid into the mitochondrial matrix, attenuates the neuronal degeneration in 3NP-treated rats. From these findings it has been suggested that 3NP induces certain neuronal cell death through mitochondrial dysfunction and that LC preserves the neurons against the dysfunction of mitochondria caused by 3NP. However, the detailed mechanism of cell death by 3NP and the protective actions of LC against the mitochondrial dysfunction have not been fully elucidated yet. Thus, we studied the molecular mechanism of the effects of 3NP and LC on isolated rat liver mitochondria. 3NP inhibited succinate respiration and the decreased respiratory control ratio of isolated mitochondria without affecting oxidative phosphorylation. 3NP induced a membrane permeability transition (MPT), which plays an important role in the mechanism of apoptotic cell death. 3NP stimulated Ca2+ release from mitochondria, decreased membrane potential, induced mitochondrial swelling, and stimulated cytochrome c release from mitochondria. 3NP-induced swelling was suppressed by bovine serum albumin, inhibitors of phospholipase A(2) and by an inhibitor of classic MPT, cyclosporin A. Furthermore, LC suppressed the changes brought about by 3NP in mitochondrial functions in the presence of ATP. These results suggest that MPT underlies the mechanism of 3NP-induced cell death, and that LC attenuates mitochondrial MPT by decreasing long chain fatty acids generated by phospholipase A(2).     

Invited review: the mitochondrion in osteoarthritis

In a variety of tissues, cumulative oxidative stress, disrupted mitochondrial respiration, and mitochondrial damage promote aging, cell death, and ultimately, functional failure and degeneration. Because articular cartilage chondroyctes are highly glycolytic, mitochondrially mediated pathogenesis has not been previously applied in models for pathogenesis of osteoarthritis (OA), a cartilage degenerative disease that increases markedly in aging. However, chondrocyte mitochondria respire in vitro and they demonstrate swelling and changes in number in situ in the course of OA. Normal chondrocyte mitochondrial function is hypothesized to critically support adenosine triphosphate (ATP) reserves in functional stressed chondrocytes during OA evolution. In this model, disruption of chondrocyte respiration by nitric oxide, a mediator markedly up-regulated in OA cartilage, is centrally involved in chondrocyte functional compromise. Furthermore, mitochondrial dysfunction can mediate several specific pathogenic pathways implicated in OA. These include oxidative stress, inadequacy of chondrocyte biosynthetic and growth responses, up-regulated chondrocyte cytokine-induced inflammation and matrix catabolism, increased chondrocyte apoptosis, and pathologic cartilage matrix calcification. In addition, the direct, sublethal impairment of chondrocyte mitochondrial ATP synthesis in vitro decreases matrix synthesis and increases matrix calcification ('disease in a dish'). The weight of evidence reviewed herein strongly supports chondrocyte mitochondrial impairment as a mediator of the establishment and progression of OA.     

High vulnerability of the heart and liver to 3‐hydroxypalmitic acid–induced disruption of mitochondrial functions in intact cell systems

Patients affected by long‐chain 3‐hydroxyacyl‐CoA dehydrogenase (LCHAD) deficiency predominantly present severe liver and cardiac dysfunction, as well as neurological symptoms during metabolic crises, whose pathogenesis is still poorly known. In this study, we demonstrate for the first time that pathological concentrations of 3‐hydroxypalmitic acid (3HPA), the long‐chain hydroxyl fatty acid (LCHFA) that most accumulates in LCHAD deficiency, significantly decreased adenosine triphosphate‐linked and uncoupled mitochondrial respiration in intact cell systems consisting of heart fibers, cardiomyocytes, and hepatocytes, but less intense in diced forebrain. 3HPA also significantly reduced mitochondrial Ca²⁺ retention capacity and membrane potential in Ca²⁺‐loaded mitochondria more markedly in the heart and the liver, with mild or no effects in the brain, supporting a higher susceptibility of the heart and the liver to the toxic effects of this fatty acid. It is postulated that disruption of mitochondrial energy and Ca²⁺ homeostasis caused by the accumulation of LCHFA may contribute toward the severe cardiac and hepatic clinical manifestations observed in the affected patients.     

How Does Inflammation‐Induced Hyperglycemia Cause Mitochondrial Dysfunction in Immune Cells?

Inflammatory mediators have an established role in inducing insulin resistance and promoting hyperglycemia. In turn, hyperglycemia has been argued to drive immune cell dysfunction as a result of mitochondrial dysfunction. Here, the authors review the evidence challenging this view. First, it is pointed out that inflammatory mediators are known to induce altered mitochondrial function. In this regard, critical care patients suffer both an elevated inflammatory tone as well as hyperglycemia, rendering it difficult to distinguish between the effects of inflammation and hyperglycemia. Second, emerging evidence indicates that a decrease in mitochondrial respiration and an increase in reactive oxygen species (ROS) production are not necessarily manifestations of pathology, but adaptations taking shape as the mitochondria is abdicating its adenosine triphosphate (ATP)‐producing function (which is taken over by glycolysis) and instead becomes “retooled” for an immunological role. Collectively, these observations challenge the commonly held belief that acute hyperglycemia induces mitochondrial damage leading to immune cell dysfunction.     

L-Carnitine suppresses oleic acid-induced membrane permeability transition of mitochondria

Membrane permeability transition (MPT) of mitochondria has an important role in apoptosis of various cells. The classic type of MPT is characterized by increased Ca(2+) transport, membrane depolarization, swelling, and sensitivity to cyclosporin A. In this study, we investigated whether L-carnitine suppresses oleic acid-induced MPT using isolated mitochondria from rat liver. Oleic acid-induced MPT in isolated mitochondria, inhibited endogenous respiration, caused membrane depolarization, and increased large amplitude swelling, and cytochrome c (Cyt. c) release from mitochondria. L-Carnitine was indispensable to beta-oxidation of oleic acid in the mitochondria, and this reaction required ATP and coenzyme A (CoA). In the presence of ATP and CoA, L-carnitine stimulated oleic acid oxidation and suppressed the oleic acid-induced depolarization, swelling, and Cyt. c release. L-Carnitine also contributed to maintaining mitochondrial function, which was decreased by the generation of free fatty acids with the passage of time after isolation. These results suggest that L-carnitine acts to maintain mitochondrial function and suppresses oleic acid-mediated MPT through acceleration of beta-oxidation.     

线粒体功能障碍参与动脉粥样硬化的分子机制

以往认为,线粒体的主要功能是提供能量,目前发现线粒体还是调节细胞氧化应激与凋亡的关键部位,并且与毗邻的细胞器－内质网保持密切联系。线粒体功能障碍时可通过加重机体氧化应激、炎症反应、细胞凋亡及胆固醇蓄积等病理过程影响动脉粥样硬化( atherosclerosis, AS)的发生发展。本综述首先简单介绍了线粒体的基本功能,然后重点分析线粒体功能障碍参与AS的最新证据及其分子机制。此方面研究提示线粒体可能是AS的潜在治疗靶点。     

Mitochondria as determinant of nucleotide pools and chromosomal stability

Mitochondrial function plays an important role in multiple human diseases and mutations in the mitochondrial genome have been detected in nearly every type of cancer investigated to date. However, the mechanism underlying the interrelation is unknown. We used human cell lines depleted of mitochondrial DNA as models and analyzed the outcome of mitochondrial dysfunction on major cellular repair activities. We show that the deoxyribonucleoside triphosphate (dNTP) pools are affected, most prominently we detect a 3-fold reduction of the dTTP pool when normalized to the number of cells in S-phase. It is known that imbalanced dNTP pools are mutagenic and in accordance, we show that mitochondrial dysfunction results in chromosomal instability, which can explain its role in tumor development. We did not find any straightforward correlation between ATP levels and dNTP pools in cells with defective mitochondrial activity. Our results suggest that mitochondria are central players in maintaining genomic stability and in controlling essential nuclear processes such as upholding a balanced supply of nucleotides.     

细胞核基因组和线粒体基因组的相互作用

线粒体DNA是细胞内唯一的核外遗传物质,线粒体的主要功能是合成ATP,为细胞生命活动提供直接能量。线粒体基因组与核基因组在基因、蛋白以及细胞水平上相互作用,共同保证细胞能量代谢有关的活动,维持着线粒体的正常功能和细胞的正常状态。