High phosphorylation efficiency and depression of uncoupled respiration in mitochondria under hypoxia

Mitochondria are confronted with low oxygen levels in the microenvironment within tissues; yet, isolated mitochondria are routinely studied under air-saturated conditions that are effectively hyperoxic, increase oxidative stress, and may impair mitochondrial function. Under hypoxia, on the other hand, respiration and ATP supply are restricted. Under these conditions of oxygen limitation, any compromise in the coupling of oxidative phosphorylation to oxygen consumption could accentuate ATP depletion, leading to metabolic failure. To address this issue, we have developed the approach of oxygen-injection microcalorimetry and ADP-injection respirometry for evaluating mitochondrial function at limiting oxygen supply. Whereas phosphorylation efficiency drops during ADP limitation at high oxygen levels, we show here that oxidative phosphorylation is more efficient at low oxygen than at air saturation, as indicated by higher ratios of ADP flux to total oxygen flux at identical submaximal rates of ATP synthesis. At low oxygen, the proton leak and uncoupled respiration are depressed, thus reducing maintenance energy expenditure. This indicates the importance of low intracellular oxygen levels in avoiding oxidative stress and protecting bioenergetic efficiency.     

Nicorandil preserves the function of the mitochondrial phosphorylative and oxidative system in an animal model of global ischemia-reperfusion.

Ischemia followed by reperfusion (IR) negatively affects mitochondrial function. At the level of the oxidative-phosphorylative system, IR inhibits the respiratory complexes and ATP synthase, and increases the passive leak of protons through the inner mitochondrial membrane, uncoupling respiration from phosphorylation, decreasing mitochondrial potential and, consequently, ATP production. Drugs that minimize the mitochondrial damage induced by IR may prove to be clinically effective. In the present work, we analyzed the impact of nicorandil, a mitochondrial ATP-sensitive potassium channel agonist, on mitochondrial dysfunction at the level of the oxidative-phosphorylative system of rat hearts subjected to IR. The decrease in the respiratory control ratio (RCR) induced by IR leads to the conclusion that IR has a negative impact on the activity of the mitochondrial respiratory system, uncoupling oxidation from phosphorylation. This effect is reversed by nicorandil, which increases not only RCR, but also the ADP/O ratio. Regarding respiratory rate, state 3 rate was approximately the same for all the experimental groups, while state 4 rate was lower for the group where IR was induced in the presence of nicorandil. This result is in accordance with the data obtained for the RCR and ADP/O. State 4 rate is most affected by uncoupling, given that it is controlled by proton leak. Mitochondria subjected to IR in the presence of nicorandil have a lower state 4 rate, i.e. they are less uncoupled. From these results we conclude that nicorandil preserves the function of mitochondria subjected to IR in terms of both respiration and phosphorylative capacity.     

PKCepsilon activation augments cardiac mitochondrial respiratory post-anoxic reserve--a putative mechanism in PKCepsilon cardioprotection

Modest cardiac-overexpression of constitutively active PKCepsilon (aPKCepsilon) in transgenic mice evokes cardioprotection against ischemia. As aPKCepsilon interacts with mitochondrial respiratory-chain proteins we hypothesized that aPKCepsilon modulates respiration to induce cardioprotection. Using isolated cardiac mitochondria wild-type and aPKCepsilon mice display similar basal mitochondrial respiration, rate of ATP synthesis and adenosine nucleotide translocase (ANT) functional content. Conversely, the aPKCepsilon mitochondria exhibit modest hyperpolarization of their inner mitochondrial membrane potential (DeltaPsi(m)) compared to wild-type mitochondrial by flow cytometry. To assess whether this hyperpolarization engenders resilience to simulated ischemia, anoxia-reoxygenation experiments were performed. Mitochondria were exposed to 45 min anoxia followed by reoxygenation. At reoxygenation, aPKCepsilon mitochondria recovered ADP-dependent respiration to 44 +/- 3% of baseline compared to 28 +/- 2% in WT controls (P = 0.03) in parallel with enhanced ATP synthesis. This preservation in oxidative phosphorylation is coupled to greater ANT functional content [42% > concentration of atractyloside for inhibition in the aPKCepsilon mitochondria vs. WT control (P < 0.0001)], retention of mitochondrial cytochrome c and conservation of DeltaPsi(m). These data demonstrate that mitochondria from PKCepsilon activated mice are intrinsically resilient to anoxia-reoxygenation compared to WT controls. This resilience is in part due to enhanced recovery of oxidative phosphorylation coupled to maintained ANT activity. As maintenance of ATP is a prerequisite for cellular viability we conclude that PKCepsilon activation augmented mitochondrial respiratory capacity in response to anoxia-reoxygenation may contribute to the PKCepsilon cardioprotective program.     

Mitochondrial adenosine triphosphatase of Zajdela hepatoma. III. Effect of uncouplers on the hydrolysis of intramitochondrial ATP.

Hydrolysis of extramitochondrial ATP by coupled Zajdela hepatoma mitochondria is not stimulated by uncouplers of oxidative phosphorylation. The results of the present study show that the hydrolysis of intramitochondrial ATP in these mitochondria is stimulated by DNP and CCCP. It is proposed that the uncoupler insensitivity of ATPase in coupled Zajdela hepatoma mitochondria with exogenous ATP as a substrate result from an altered functional relationship between ATPase and ADP, ATP translocase.     

Effect of adrenochrome on adenine nucleotides and mitochondrial oxidative phosphorylation in rat heart

Effects of adrenochrome, an oxidation product of epinephrine, on myocardial energy production were investigated by studying changes in adenine nucleotide content and mitochondrial oxidative phosphorylation activities in the isolated rat heart. Perfusion of the heart with 50 mg/L adrenochrome induced a marked decline in contractile force within 5 min and this was associated with a rapid decline in the myocardial ATP/AMP ratio. A significant decrease in ATP and ATP/ADP ratio as well as a significant increase in ADP and AMP content was observed at 10 min of perfusion with adrenochrome. Furthermore, mitochondrial oxidative phosphorylation activities were unchanged except that an increase in state 4 respiration and a decrease in RCI value were seen in the heart perfused with adrenochrome for 10 min. Autoradiography of the sections from hearts perfused with 14C-adrenochrome revealed the localization of a significant amount of radioactivity on mitochondria. Adrenochrome at concentrations of 20 mg/L or higher was found to inhibit the oxidative phosphorylation activities of heart mitochondria under in vitro conditions. The depressant effects of adrenochrome on mitochondrial oxidative phosphorylation were additive to those seen with calcium. These data suggest that adrenochrome in the presence of excess calcium in the myocardial cell may impair the process of energy production in mitochondria and this may result in contractile failure of hearts exposed to this cardiotoxic metabolite of epinephrine.     

Mechanism of loss of adenine nucleotides from mitochondria during myocardial ischemia.

We tested the hypothesis that loss of mitochondrial adenine nucleotides during myocardial ischemia is induced by the accumulation of inorganic phosphate (Pi) and a decrease in cytosolic ATP. In the isolated perfused rat heart, loss of mitochondrial adenine nucleotides (ATP + ADP + AMP) was preceded by the rise in tissue Pi and the loss of tissue ATP. After 30 min ischemia, the average rate of loss of mitochondrial adenine nucleotides was c. 1.5% of the initial pool/min. In isolated heart mitochondria, there are two pathways for adenine nucleotide release: a 'fast', phosphate-dependent pathway, which is inhibited by atractyloside; and a 'slow', phosphate-independent pathway, which is insensitive to atractyloside. Decreasing the pH from 7.4 to 6.5 significantly decreased the rate of release by the phosphate-dependent pathway (but not the phosphate-independent pathway). Analysis of release rates indicated that HPO4-2 is responsible for the phosphate-induced release; Vmax = 53.8% of the pool/per minute, Km = 7.5 mM. In vitro, extramitochondrial ATP inhibited adenine nucleotide release in the presence of Pi such that the rate of release was inversely proportional to the extramitochondrial [ATP]; extrapolation to zero ATP indicated a release rate of 2 to 3% of the pool/per minute, which is approximately equal to the rate of the 'slow' phosphate-independent pathway. Moreover, increasing the Pi concentration did not increase the rate of adenine nucleotide release in the presence of extramitochondrial ATP. Accumulation of mitochondrial adenine nucleotides was observed when the mitochondria were incubated in the presence of 4 mM or greater ATP. The results suggest that the rise in intracellular Pi during myocardial ischemia does not induce the loss of adenine nucleotides from the mitochondrial compartment, but rather that degradation of cytosolic ATP results in a slowing of ATP influx such that the rate of efflux (phosphate-independent) exceeds the rate of influx.     

Uncoupling to survive? The role of mitochondrial inefficiency in ageing

Mitochondria are incompletely coupled, and during oxidative phosphorylation some of the redox energy in substrates is lost as heat. Incomplete coupling is mostly due to a natural leak of protons across the mitochondrial inner membrane. In rat hepatocytes the futile cycle of proton pumping and proton leak is responsible for 20-25% of respiration; in perfused rat muscle the value is 35-50%. Mitochondrial proton cycling is estimated to cause 20-25% of basal metabolic rate in rats. Proton cycling is equally prominent in hepatocytes from several different mammalian and ectotherm species, so it may be a general pathway of ecologically significant energy loss in all aerobes. Because it occurs in ectotherms, thermogenesis cannot be its primary function. Instead, an attractive candidate for the function of the universal and expensive energy-dissipating proton cycle is to decrease the production of superoxide and other reactive oxygen species (ROS). This could be important in helping to minimise oxidative damage to DNA and in slowing ageing. Mitochondria are the major source of cellular ROS, and increased mitochondrial proton conductance leads to oxidation of ubiquinone and decreased ROS production in isolated mitochondria. However, to date there is no direct evidence in cells or organisms that mitochondrial proton cycling lowers ROS production or oxidative damage or that it increases lifespan.     

A significant portion of mitochondrial proton leak in intact thymocytes depends on expression of UCP2

The uncoupling protein homologue UCP2 is expressed in a variety of mammalian cells. It is thought to be an uncoupler of oxidative phosphorylation. Uncoupling proteins previously have been shown to be capable of translocating protons across phospholipid bilayers in proteoliposome systems. Furthermore, studies in mitochondria from yeast overexpressing the proteins have led to suggestions that they may act as uncouplers in cells. However, this issue is controversial, and to date, definitive experimental evidence is lacking as to whether UCP2 mediates part or all of the basal mitochondrial proton leak in mammalian cells in situ. In the present study, by using thymocytes isolated from UCP2-deficient and wild-type (WT) mice, we addressed the question whether UCP2 is directly involved in catalyzing proton leak in intact cells. Over a range of mitochondrial membrane potentials (DeltaPsi(m)), proton leak activity was lower in thymocytes from UCP2-deficient mice compared with WT mice. At physiological levels of DeltaPsi(m), a significant portion (50%) of basal proton leak in resting cells depended on UCP2. Of note, proton leak in whole cells from WT mice, but not UCP2-deficient mice, responded to stimulation by 4-[(E)-2-(5,6,7,8-tetrahydro-5,5,8,8-tetramethyl-2-napthalenyl)-1-propenyl]benzoic acid (TTNPB), a known activator of UCP2 activity. Consistent with the observed changes in proton leak, DeltaPsi(m) and ATP levels were increased in untreated thymocytes from UCP2-deficient mice. Interestingly, resting respiration was unaltered, suggesting that UCP2 function in resting cells may be concerned with the control of ATP production rather than substrate oxidation. This study establishes that UCP2, expressed at endogenous levels, mediates proton leak in intact cells.     

Mitochondrial oxidative phosphorylation in heart from stressed cardiomyopathic hamsters

Stress alone is generally not sufficient to produce serious disease, but stress imposed upon pre-existing disease can contribute to disease progression. To explore this phenomenon, cold-immobilization stress was imposed on young 12.5 month, necrotic phase with small vessel coronary spasm) and older (5 month, quiescent phase, between necrosis and heart failure) cardiomyopathic hamsters. Our hypothesis was that changes in mitochondrial energy processes are involved in stress induced pathology. Polarographic and high performance liquid chromatography (HPLC) techniques were used to measure mitochondrial respiration and oxidative phosphorylation and concentrations of phosphocreatine and adenylates, respectively, in hearts from young and old cardiomyopathic hamsters (stressed and unstressed). No significant differences were found between the young (2.5 month) and old (5 month) age groups in unstressed and stressed healthy hamsters and between young (2.5 month) and old (5 month) unstressed cardiomyopathic hamsters with respect to different parameters of mitochondrial oxidative phosphorylation and with respect to concentration of bioenergetic metabolites, except that ADP concentration was higher in older cardiomyopathic hamsters. Application of stress uncovered differences between young and old cardiomyopathic hamsters: respiration control index was lower and State 4 respiration was higher in young compared to old cardiomyopathic hamsters; whereas the total concentration of ATP was decreased to the same level in both cardiomyopathic groups when compared to control. Mitochondrial oxidative phosphorylation in young cardiomyopathic hamsters was more sensitive to Ca2+, as evidenced by partial uncoupling of respiration and oxidative phosphorylation, than in older cardiomyopathic hamsters and controls. In conclusion, young cardiomyopathic hamsters, i.e. in the necrotic phase of disease, were more susceptible to stress induced changes in mitochondrial oxidative phosphorylation than older cardiomyopathic hamsters and controls.     

Decreased ATP-synthesis ability of liver mitochondria in spontaneously hypertensive rats (SHR): role of calcium overload of the mitochondria

It has been shown previously, that a decrease of ATP amount and changed balance of the other macroergic phosphates are observed in different tissues of spontaneously hypertensive rats (SHR) compared with the normotensive controls (WKY). The aim of the present study was to assess the ability of SHR liver isolated mitochondria to synthesize ATP and to clarify its dependence on extramitochondrial calcium concentration. Macroergic phosphate concentrations were measured by high performance liquid chromatography (HPLC). The present work shows for the first time, that SHR liver mitochondria initially differ from WKY ones by decreased (by 30%) ATP synthesis rate. Respiratory control coefficient and phosphorylation rate in SHR and WKY mitochondria change in different manner when extramitochondrial calcium concentration increases from 0 to 50 microM. When calcium concentration is increased up to 50 microM both parameters in WKY mitochondria are about one half compared with the condition when the medium does not contain calcium. In the conditions, when the medium contains 50 microM of calcium, complete uncoupling of oxidation and phosphorylation in SHR mitochondria is observed. Thus the decrease of ATP synthesis rate in SHR mitochondria in conjunction with reduced tolerance to calcium overload (by respiratory control coefficient and phosphorylation rate) in comparison with WKY may be considered as the main cause of cell energy deficiency, observed in experimental variant of primary arterial hypertension.     

Mitochondria in eosinophils: functional role in apoptosis but not respiration

In most eukaryotic cells, mitochondria use the respiratory chain to produce a proton gradient, which is then harnessed for the synthesis of ATP. Recently, mitochondrial roles in regulation of apoptosis have been discovered in many cell types. Eosinophils (Eos) die by apoptosis, but the presence and function of mitochondria in Eos are unknown. This study found that Eos contain mitochondria in small numbers, as shown by labeling with membrane potential-sensitive dyes and in situ PCR for a mitochondrial gene. Eos generate mitochondrial membrane potential from hydrolysis of ATP rather than from respiration, as shown by mitochondrial respiratory inhibitors and mitochondrial uncouplers. The mitochondria provide insignificant respiration but can induce apoptosis, as shown by using the mitochondrial F(1)F(0)-ATPase inhibitor oligomycin and translocation of cytochrome c. Thus during differentiation of Eos, although respiration is lost, the other central role of mitochondria, the induction of apoptosis, is retained.     

Structure-function relationships in the regulation of energy transfer between mitochondria and ATPases in cardiac cells

The present study discusses the role of structural organization of cardiac cells in determining the mechanisms of regulation of oxidative phosphorylation and interaction between mitochondria and ATPases. In permeabilized adult cardiomyocytes, the apparent K_m (Michaelis-Menten constant) for ADP in the regulation of respiration is far higher than in mitochondria isolated from the myocardium. Respiration of mitochondria in permeabilized cardiomyocytes is effectively activated by endogenous ADP produced by ATPases from exogenous ATP, and the activation of respiration is associated with a decrease in the apparent K_m for ATP in the regulation of ATPase activity compared with this parameter in the absence of oxidative phosphorylation. It has also been shown that a large fraction of the endogenous ADP stimulating respiration remains inaccessible for the exogenous ADP trapping system, consisting of pyruvate kinase and phosphoenolpyruvate, unless the mitochondrial structures are modified by controlled proteolysis. These data point to the endogenous cycling of adenine nucleotides between mitochondria and ATPases. Accordingly, the current hypothesis is that in cardiac cells, mitochondria and ATPases are compartmentalized into functional complexes (ie, intracellular energetic units [ICEUs]), which appear to represent a basic pattern of organization of energy metabolism in these cells. Within the ICEUs, the mitochondria and ATPases interact via different routes: creatine kinase-mediated phosphoryltransfer; adenylate kinase-mediated phosphoryltransfer; and direct ATP and ADP channelling. The function of ICEUs changes not only after selective proteolysis, but also during contraction of cardiomyocytes caused by an increase in cytosolic Ca²⁺ concentration up to micromolar levels. In these conditions, the apparent K_m for exogenous ADP and ATP in the regulation of respiration markedly decreases, and more ADP becomes available for the exogenous pyruvate kinase-phosphoenolpyruvate system, which indicates altered barrier functions of the ICEUs. Thus, structural changes transmitted from the contractile apparatus to mitochondria clearly participate in the regulation of mitochondrial function due to alterations in localized restriction of the diffusion of adenine nucleotides. The importance of strict structural organization in cardiac cells emerged drastically from experiments in which the regulation of mitochondrial respiration was assessed in a novel cardiac cell line, that is, beating and nonbeating HL-1 cells. In these cells, the mitochondrial arrangement is irregular and dynamic, whereas the sarcomeric structures are either absent (in nonbeating HL-1 cells) or only rarely present (in beating HL-1 cells). In parallel, the apparent K_m for exogenous ADP in the regulation of respiration was much lower than that in permeabilized primary cardiomyocytes, and trypsin treatment exerted no impact on the low K_m value for ADP, in contrast to adult cardiomyocytes where it caused a marked decrease in this parameter. The HL-1 cells were also characterized by the absence of direct exchange of adenine nucleotides. The results further support the concept that the ICEUs in adult cardiomyocytes are products of complex structural organization developed to create the most optimal conditions for effective energy transfer and feedback between mitochondria and ATPases.     

Methods to detect mitochondrial function

The bioenergetic function of mitochondria can be investigated in intact cells by a variety of methods. A simple biochemical method to compare mitochondrial oxidative phosphorylation with glycolytic ATP synthesis takes advantage of the Pasteur effect, since the amount of lactate produced under basal conditions is an indication of glycolytic ATP, while the Delta-lactate (the difference between excess lactate produced after inhibition of respiration and basal lactate) represents ATP produced anaerobically in order to compensate for decreased oxidative phosphorylation after respiratory chain inhibition. The system has been validated in a series of cells, including human platelets and lymphocytes and lines cultured in vitro. Measurement of KCN-sensitive oxygen consumption by the cells and its sensitivity to uncouplers can be good supplementary indication of mitochondrial phosphorylative capacity.     

人参皂甙Rg1对快速老化小鼠肝脏线粒体的保护作用

目的 探讨人参皂苷Rg1防治阿尔茨海默病的作用机制.方法 将8.5月龄快速老化小鼠(SAMP8)随机分为SAMP8对照组、SAMP8给Rg1 10 mg/kg组、SAMP8给Rg1 30 mg/kg组,每组10只.同月龄SAMR1 10只作为对照组.给药65 d后提取肝脏线粒体,测定线粒体呼吸功能、线粒体肿胀度和线粒体膜电位.线粒体于-20℃/20℃反复冻融3次破坏线粒体膜,测定线粒体内MDA含量、SOD活性和LDH含量.结果 与SAMR1相比,SAMP8肝脏线粒体呼吸功能显著降低,表现为线粒体3态呼吸显著降低,4态呼吸改变不明显,呼吸控制指数和磷氧比值显著降低;SAMP8小鼠线粒体膜肿胀度显著增高,线粒体膜电位显著降低.此外,SAMP8线粒体MDA含量显著增多、SOD活性显著升高、LDH显著增高.与SAMP8对照组相比,Rg1 10 和30 mg/kg均可显著改善这些线粒体结构和呼吸功能障碍,改善线粒体内生化功能的改变.结论 人参皂苷Rg1可改善快速老化小鼠线粒体结构和功能障碍.     

Brain cellular and mitochondrial respiration in media of altered pH

This study was designed to investigate the effects of altered pH on cellular aerobic energy metabolism in the immature and adult rat cerebral cortex. Cerebral cortical slice respiration was measured polarographically in acid and alkaline media. In separate experiments, the extracellular pH was changed by altering the HCO ₃ ^– concentration or the intracellular pH and extracellular pH were changed by altering the CO₂. Respiratory rates and oxidative phosphorylation in adult rat cerebral mitochindria also were measured in media with an altered pH. Increased intracellular pH inhibited respiratory rates in cortical slices from immature rats more than in tissue from adults. Decreasing the pH to 6.7 produced no changes in respiration in mature cortical slices and moderate inhibition of immature tissue respiration. In cerebral mitochondria, altered pH caused inhibition of State 3 respiration, respiratory control ratios, and ADP/O ratios. These changes were greater and occurred with smaller pH changes in the alkaline compared to the acid direction. From the results of these studies, we conclude that brain cellular respiration is not affected by moderate decreases in intracellular pH. With increased pH, there is inhibition of cellular and mitochondrial respiration, which may be the mechanism for the rise in lactic acid previously observed to result from hypocarbiain vivo.Abbreviations used BSA bovine serum albumin - DNP dinitrophenol - RCR respiratory control ratio     

Studies on the Energy Metabolism of Human Leukocytes: I. Oxidative Phosphorylation by Human Leukocyte Mitochondria

1. Oxidative phosphorylation has been studied in mitochondrial preparationsfrom human leukocytes, using recently developed methods for homogenization,measuring respiration, and assaying for ATP.

2. Appreciable stimulation of both respiration and phosphorylation waslimited to 3 substrates: succinate, malate, and -glycerophosphate. The effectsof other substrates were minimal.

3. The stimulating effects of these 3 substrates responded to inhibitors in amanner typical of mitochondrial oxidative phosphorylation. There was alsoconsiderable endogenous activity which, however, was insensitive to inhibitors.It is concluded the endogenous respiration and phosphorylation are not associated with electron transport. Subtracting their values from the data, P/Oratios consistent with good phosphorylation with the 3 substrates are obtained.

4. Studies with oligomycin and dinitrophenol suggest the presence ofrespiratory control. This indicates the mitochondria are intact. It is concludedthat in the intact leukocyte the mitochondria are a major source of ATP.

Submitted on December 16, 1966 Accepted on March 19, 1967     

Increased mitochondrial oxidative stress in the Sod2 (+/-) mouse results in the age-related decline of mitochondrial function culminating in increased apoptosis

To determine the importance of mitochondrial reactive oxygen species toxicity in aging and senescence, we analyzed changes in mitochondrial function with age in mice with partial or complete deficiencies in the mitochondrial antioxidant enzyme manganese superoxide dismutase (MnSOD). Liver mitochondria from homozygous mutant mice, with a complete deficiency in MnSOD, exhibited substantial respiration inhibition and marked sensitization of the mitochondrial permeability transition pore. Mitochondria from heterozygous mice, with a partial deficiency in MnSOD, showed evidence of increased proton leak, inhibition of respiration, and early and rapid accumulation of mitochondrial oxidative damage. Furthermore, chronic oxidative stress in the heterozygous mice resulted in an increased sensitization of the mitochondrial permeability transition pore and the premature induction of apoptosis, which presumably eliminates the cells with damaged mitochondria. Mice with normal MnSOD levels show the same age-related mitochondrial decline as the heterozygotes but occurring later in life. The premature decline in mitochondrial function in the heterozygote was associated with the compensatory up-regulation of oxidative phosphorylation enzyme activity. Thus mitochondrial reactive oxygen species production, oxidative stress, functional decline, and the initiation of apoptosis appear to be central components of the aging process.     

Uncoupling of oxidative phosphorylation in rat liver mitochondria by general anesthetics.

The general anesthetics chloroform and halothane inhibit ATP synthesis in rat liver mitochondria, in the millimolar concentration range (1-12 mM), in parallel with a reduction of respiratory control and the ratio of ATP produced to oxygen consumed. In these effects, halothane and chloroform are similar to classical, protonophoric, uncouplers. The rate of ADP-stimulated respiration or the rate of uncoupler-stimulated respiration is not affected. Like classical uncouplers, halothane and chloroform also stimulate mitochondrial ATPase activity. However, the extent of stimulation by these agents is larger than by protonophoric uncouplers and, more significantly, ATPase activity stimulated by carbonylcyanide m-chlorophenylhydrazone is further stimulated by these agents. In the presence of the Ca2+ chelator EGTA, halothane and chloroform have no measurable effect on the magnitude of the proton electrochemical potential, delta mu H. In the absence of EGTA these anesthetics have a small effect on delta mu H, apparently due to stimulation of Ca2+ cycling. Under these conditions the membrane potential is decreased while delta pH is increased, but the total value of delta mu H is only slightly decreased. The uncoupling activity of the anesthetics is the same in the presence of absence of EGTA. Thus, in contrast to protonophoric uncouplers, the uncoupling effect of general anesthetics does not depend on the collapse of delta mu H. In the same concentration range in which anesthetics uncouple oxidative phosphorylation both halothane and chloroform increase membrane fluidity, as measured by the partitioning of the hydrophobic spin probe 5-doxyldecane. These findings suggest a role for intramembrane processes in energy conversion that is not dependent on the bulk delta mu H.     

Mitochondrial biogenesis by NO yields functionally active mitochondria in mammals

We recently found that long-term exposure to nitric oxide (NO) triggers mitochondrial biogenesis in mammalian cells and tissues by activation of guanylate cyclase and generation of cGMP. Here, we report that the NO/cGMP-dependent mitochondrial biogenesis is associated with enhanced coupled respiration and content of ATP in U937, L6, and PC12 cells. The observed increase in ATP content depended entirely on oxidative phosphorylation, because ATP formation by glycolysis was unchanged. Brain, kidney, liver, heart, and gastrocnemius muscle from endothelial NO synthase null mutant mice displayed markedly reduced mitochondrial content associated with significantly lower oxygen consumption and ATP content. In these tissues, ultrastructural analyses revealed significantly smaller mitochondria. Furthermore, a significant reduction in the number of mitochondria was observed in the subsarcolemmal region of the gastrocnemius muscle. We conclude that NO/cGMP stimulates mitochondrial biogenesis, both in vitro and in vivo, and that this stimulation is associated with increased mitochondrial function, resulting in enhanced formation of ATP.     

解偶联蛋白2与酒精性肝病

解偶联蛋白2(UCP2)是线粒体内膜上可以调节质子跨膜转运的载体蛋白,可以驱散质子电化学梯度,使氧化呼吸与ATP合成解偶联。UCP2与能量消耗和脂质代谢密切相关,可能参与酒精性肝病(ALD)发病过程中的氧化应激和脂质过氧化。进一步探讨UCP2在ALD中的作用对于ALD的防治具有重要意义。