Mitochondrial respiration in heart, liver, and kidney of copper-deficient rats

Morphological observations in some tissues indicate that dietary copper deficiency results in structural damage to mitochondria. The purpose of this study was to determine whether mitochondrial function is impaired as well. Male, weanling Sprague-Dawley rats were fed diets deficient or sufficient in copper for 4 weeks. Mitochondria were isolated from heart, liver, kidney cortex, and kidney medulla. P/O ratio, state 3 and state 4 respiration rates (oxygen consumed in the presence and absence of ADP, respectively), and acceptor control index (ratio of state 3:state 4) were determined using succinate or pyruvate/malate as substrate. State 3 respiration rate in mitochondria from copper-deficient hearts and livers was lower than in mitochondria from copper-sufficient hearts. Copper deficiency reduced the state 4 respiration rate only in cardiac mitochondria. Neither respiration rate was affected by copper deficiency in mitochondria from kidney medulla or cortex. P/O ratio was not significantly affected by copper deficiency in any tissue examined. Acceptor control index was reduced only in liver mitochondria. The observed decreases in respiration rates are consistent with decreased cytochrome c oxidase activity, shown by others to occur in mitochondria isolated from hearts and livers of copper-deficient rats.     

Effects of <Emphasis Type="Italic">Ginkgo biloba</Emphasis> extract on heart and liver mitochondrial functions: mechanism(s) of action

Though extracts of Ginkgo biloba leaves (GBE) have a wide pharmacological application, little is known about GBE effects on mitochondria. In this work, effects of ethanolic GBE on the respiration of isolated rat heart and liver mitochondria were investigated. We found that GBE stimulates the pyruvate + malate-dependent State 2 respiration of heart mitochondria and decreases mitochondrial membrane potential. Uncoupling effect of GBE was found to be due to its protonophoric action and is likely to be mediated by the ATP/ADP-translocator and uncoupling proteins. The effect of GBE was less in liver than in heart mitochondria. State 3 respiration of heart mitochondria was slightly stimulated at low and depressed at higher GBE concentrations. Inhibition of State 3 respiration of heart mitochondria was not relieved by uncoupler indicating that GBE may inhibit the respiratory chain complexes or the substrate transport. However, Complex IV of the respiratory chain was not inhibited by GBE. H₂O₂ generation was attenuated by low concentration of GBE probably due to mild uncoupling. The data suggest that mild but not severe uncoupling activity of GBE may be important in providing pharmacological protection of cellular functions in pathological situations.     

Efficient Isolation of Pure and Functional Mitochondria from Mouse Tissues Using Automated Tissue Disruption and Enrichment with Anti-TOM22 Magnetic Beads

To better understand molecular mechanisms regulating changes in metabolism, as observed e.g. in diabetes or neuronal disorders, the function of mitochondria needs to be precisely determined. The usual isolation methods such as differential centrifugation result in isolates of highly variable quality and quantity. To fulfill the need of a reproducible isolation method from solid tissues, which is suitable to handle parallel samples simultaneously, we developed a protocol based on anti-TOM22 (translocase of outer mitochondrial membrane 22 homolog) antibody-coupled magnetic beads. To measure oxygen consumption rate in isolated mitochondria from various mouse tissues, a traditional Clark electrode and the high-throughput XF Extracellular Flux Analyzer were used. Furthermore, Western blots, transmission electron microscopic and proteomic studies were performed to analyze the purity and integrity of the mitochondrial preparations. Mitochondrial fractions isolated from liver, brain and skeletal muscle by anti-TOM22 magnetic beads showed oxygen consumption capacities comparable to previously reported values and little contamination with other organelles. The purity and quality of isolated mitochondria using anti-TOM22 magnetic beads was compared to traditional differential centrifugation protocol in liver and the results indicated an obvious advantage of the magnetic beads method compared to the traditional differential centrifugation technique.     

Hepatic gluconeogenesis and mitochondrial function during hibernation

1. The aim of these studies was to investigate a mitochondrial basis for changes in gluconeogenesis during hibernation. 2. State 3 respiration rates in liver mitochondria from hibernating ground squirrels were reduced by 62-66%. The limiting reaction appeared to be electron transport, particularly in respiratory complex III. 3. The mitochondrial ATP + ADP + AMP content was reduced by 29% during hibernation; cellular adenine nucleotide content was unchanged. 4. Pyruvate carboxylation in intact mitochondria was decreased 75% during hibernation, although total pyruvate carboxylase activity was not lower. 5. Rates of gluconeogenesis in intact hepatocytes isolated from hibernators were lower than in cells from non-hibernators.     

Rat liver response elicited by long-term cold exposure.

We measured mitochondrial protein mass as well as State 4 and 3 respiratory rates using different substrates in isolated liver mitochondria from 30-day cold-exposed rats. In addition, we measured the respiration under different conditions of stimulation in isolated hepatocytes from long-term cold-exposed rats. The results show that long-term cold exposure elicits a significant increase in hepatic mass and mitochondrial protein mass. No variation was found in oxygen consumption of isolated mitochondria and hepatocytes. On the whole, the results indicate that long-term exposure elicits an increase in hepatic mitochondrial protein mass but not in hepatic oxygen consumption.     

Cytochrome c Effect on Respiration of Heart Mitochondria: Influence of Various Factors

The effect of exogenous cytochrome c on respiration rate of the rat and human heart mitochondria was assessed in situ, using permeabilized fibers. It was (i) much more pronounced in State 2 and 4 than in State 3 with all the respiratory substrates (pyruvate+malate, succinate, palmitoyl-CoA+carnitine and octanoyl-L-carnitine), (ii) different with different substrates, (iii) much higher after ischemia in both metabolic states, particularly in the case of succinate oxidation compared to pyruvate+malate, (iv) the highest in State 4 with succinate as a substrate. Similar results were obtained with the isolated rat and rabbit heart mitochondria. The differences in the degree of stimulation of mitochondrial respiration by cytochrome c and, thus, sensitivity of cytochrome c test in evaluation of the intactness/injury of outer mitochondrial membrane are probably determined by the differences in the cytochrome c role in the control of mitochondrial respiration in the above-described conditions.     

In vitro alteration of the size of the liver mitochondrial adenine nucleotide pool: Correlation with respiratory functions

Mitochondrial respiration was studied as a function of the total adenine nucleotide content of rat liver mitochondria. The adenine nucleotide content was varied by treating isolated mitochondria with pyrophosphate or by incubating pyrophosphate-treated mitochondria with ATP. Mitochondria with at least 4 nmol adenine nucleotides/mg protein maintained at least 80% of the State 3 activity of control mitochondria, which had approximately 10 nmol/mg protein. However, State 3 decreased rapidly once the adenine nucleotide content fell below 4 nmol/mg protein. Between 2 and 4 nmol adenine nucleotides/mg, State 3 was not limited by the maximal capacity of electron flow as measured by the uncoupled respiration. However, at very low adenine nucleotide levels (<2 nmol/mg), the uncoupled rates of respiration were markedly depressed. State 4 was not affected by changes in the mitochondrial adenine nucleotide content. Adenine translocase activity varied in almost direct correlation with changes in the adenine nucleotide content. Therefore, adenine translocase activity was more sensitive than State 3 to changes in total adenine nucleotides over the range of 4 to 10 nmol/mg protein. The results suggest that (i) State 3 is dependent on the level of intramitochondrial adenine nucleotides, particularly in the range below 4 nmol/mg protein, (ii) adenine translocase activity is not rate-limiting for oxidative phosphorylation in mitochondria with the normal complement of adenine nucleotides, however, at low adenine nucleotide levels, depressed State 3 rates may be explained in part by the low rate of ADP translocation, and (iii) a mechanism of net ATP uptake exists in mitochondria with low internal adenine nucleotides.     

Tissue-specific depression of mitochondrial proton leak and substrate oxidation in hibernating arctic ground squirrels

A significant proportion of standard metabolic rate is devoted to driving mitochondrial proton leak, and this futile cycle may be a site of metabolic control during hibernation. To determine if the proton leak pathway is decreased during metabolic depression related to hibernation, mitochondria were isolated from liver and skeletal muscle of nonhibernating (active) and hibernating arctic ground squirrels (Spermophilus parryii). At an assay temperature of 37 degrees C, state 3 and state 4 respiration rates and state 4 membrane potential were significantly depressed in liver mitochondria isolated from hibernators. In contrast, state 3 and state 4 respiration rates and membrane potentials were unchanged during hibernation in skeletal muscle mitochondria. The decrease in oxygen consumption of liver mitochondria was achieved by reduced activity of the set of reactions generating the proton gradient but not by a lowered proton permeability. These results suggest that mitochondrial proton conductance is unchanged during hibernation and that the reduced metabolism in hibernators is a partial consequence of tissue-specific depression of substrate oxidation.     

Attenuation of doxorubicin-induced contractile and mitochondrial dysfunction in mouse heart by cellular glutathione peroxidase

The cardiac toxicity of doxorubicin (DOX), a potent anticancer anthracycline antibiotic, is believed to be mediated through the generation of reactive oxygen species (ROS) in cardiomyocytes. This study aims to determine the function of cellular glutathione peroxidase (Gpx1), which is located in both mitochondria and cytosol, in defense against DOX-induced cardiomyopathy using a line of transgenic mice with cardiac overexpression of Gpx1. The Gpx1-overexpressing hearts were markedly more resistant than nontransgenic hearts to DOX-induced acute functional derangements, including impaired contractility and diastolic properties, decreased coronary flow rate, and reduced heart rate. In addition, DOX treatment impairs mitochondrial function of nontransgenic hearts as evident in a decreased rate of NAD-linked State 3 respiration, presumably a result of inactivation of complex I activity. This is associated with increases in the rates of NAD- and FAD-linked State 4 respiration and declines in P/O ratio, suggesting that the electron transfer and oxidative phosphorylation are uncoupled in these mitochondrial samples. These functional deficits of mitochondria could be largely prevented by Gpx1 overexpression. Taken together, these studies provide new evidence to further support the role of ROS, particularly H(2)O(2) and/or fatty acid hydroperoxides, in causing contractile and mitochondrial dysfunction in mouse hearts acutely exposed to DOX.     

Effects of gamma-irradiation on isolated rat liver mitochondria

Gamma-irradiation of isolated rat liver mitochondria with doses of up to 475 Gy leading to hydrated electrons (G = 1.9, corrected for reaction with solutes), 30 Gy leading to carbohydrate radicals, (G = 5.6), 100 Gy leading to superoxide radicals (G = 6.2), and 130 Gy leading to formate radicals (G = 6.2) showed, within the error of the measurements, no effects on the rate of oxygen uptake in the various respiratory states, the respiratory control ratio, or the adenosine diphosphate to atomic oxygen ratio. Typical values obtained were 0.020-0.100 nmol O2 s-1 mg protein-1 for State 1 respiration, 0.25-0.33 nmol O2 s-1 mg protein-1 for State 4 respiration and 0.65-1.10 nmol O2 s-1 mg protein-1 for State 3 respiration. Typical respiratory control ratios ranged from 2.0-3.5 for succinate and 4.0-6.5 for a 1:1 glutamate: malate substrate mixture. Adenosine diphosphate to atomic oxygen ratios with succinate as substrate varied from 1.6 to 1.9. Because these results are unexpected, in situ and in vitro irradiated mitochondria were examined in an electron microscope and compared to mitochondria in situ, non-irradiated mitochondria and mitochondria isolated after whole liver irradiation. Irradiation of isolated mitochondria with 375 Gy results in the partial destruction of the mitochondrial outer membrane with no significant changes in respiratory rates.     

Preparation and Respirometric Assessment of Mitochondria Isolated from Skeletal Muscle Tissue Obtained by Percutaneous Needle Biopsy

Respirometric profiling of isolated mitochondria is commonly used to investigate electron transport chain function. We describe a method for obtaining samples of human Vastus lateralis, isolating mitochondria from minimal amounts of skeletal muscle tissue, and plate based respirometric profiling using an extracellular flux (XF) analyzer. Comparison of respirometric profiles obtained using 1.0, 2.5 and 5.0 μg of mitochondria indicate that 1.0 μg is sufficient to measure respiration and that 5.0 μg provides most consistent results based on comparison of standard errors. Western blot analysis of isolated mitochondria for mitochondrial marker COX IV and non-mitochondrial tissue marker GAPDH indicate that there is limited non-mitochondrial contamination using this protocol. The ability to study mitochondrial respirometry in as little as 20 mg of muscle tissue allows users to utilize individual biopsies for multiple study endpoints in clinical research projects.     

A method for isolating lung mitochondria from rabbits, rats, and mice with improved respiratory characteristics.

Previous methods for isolating lung mitochondria, particularly from rabbits, have yielded preparations which exhibit low respiratory control ratios (RCRs). We now report a method for the isolation of lung mitochondria from rabbit, rat, and mouse with RCRs, ADP/O ratios, and rates of substrate oxidation comparable to those for liver mitochondria. These mitochondrial preparations fail to oxidize exogenously added NADH and exhibit RCRs, during succinate oxidation, which closely approximate those obtained with NADH-linked substrates. However, an otherwise latent Mg²⁺-stimulated ATPase activity can still be elicited when Mg²⁺ is added to the mitochondrial incubation medium. This ATPase activity is insensitive to oligomycin and atractyloside, indicating that the source is from contaminating endoplasmic reticulum. The pH and EDTA concentration for maximum substrate oxidation and RCR were found to be 7.2 and 0.1 mm, respectively. State 4 respiration was affected by pH and EDTA concentration while state 3 respiration appeared to be independent of these two factors over the ranges studied.     

Acutely administered melatonin restores hepatic mitochondrial physiology in old mice

Damage to mitochondria as a result of the intrinsic generation of free radicals is theoretically involved in the processes of cellular aging. Herein, we investigated whether acutely administered melatonin, due to its free radical scavenging activity, would influence mitochondrial metabolism. Mitochondrial respiratory activity and respiratory chain complex I and IV activities in liver mitochondria from a strain of senescence-accelerated-prone mice (SAMP8) and a strain of senescence-accelerated-resistant mice (SAMR1) were measured when the animals were 12 months of age. Respiratory control index (RCI), ADP/O ratio, State 3 respiration and dinitrophenol (DNP)-dependent uncoupled respiration were significantly lower in SAMP8 than in SAMR1. In contrast, State 4 respiration was significantly higher in SAMP8 than in SAMR1. Activities of complexes I and IV in SAMP8 were significantly lower than in SAMR1. Melatonin administration (10mg/kg body weight, intraperitoneally) 1h prior to sacrifice significantly increased RCI, ADP/O ratio, State 3 respiration and DNP-induced uncoupled respiration in SAMP8 while also significantly reducing State 4 respiration in SAMP8. The injection of melatonin also significantly increased complex I activity in both mouse strains and complex IV activity in the liver of SAMP8 mice. These results document an age-related decrease in hepatic mitochondrial function in SAM which can be modified by an acute pharmacological injection of melatonin; the indole stimulated mitochondrial respiratory chain activity which would likely reduce deteriorative oxidative changes in mitochondria that normally occur in advanced age.     

The role of long-chain acyl-CoA in the damage of oxidative phosphorylation in heart mitochondria

The aim of this investigation was to study the effect of intramitochondrial acyl-CoA on the respiration of rabbit heart mitochondria over the whole range of stationary respiratory rates between States 4 and 3. The creatine phosphokinase system was used for stabilization of extramitochondrial adenine nucleotide concentration. It was shown that acyl-CoA depressed respiration more effectively in the intermediate range of respiration between States 4 and 3. The effect of acyl-CoA was negligible near State 4 and in State 3. These data are in line with our previous results concerning the dependence of the adenine nucleotide translocator control coefficient on the rate of mitochondrial respiration. Thus, our data suggest that long-chain acyl-CoA may regulate oxidative phosphorylation in heart mitochondria in vivo.     

Do mitochondria make nitric oxide? no?

Several papers have claimed that mitochondria contain nitric oxide synthase (NOS) and make nitric oxide (NO*) in amounts sufficient to affect mitochondrial respiration. However, we found that the addition of L-arginine or the NOS inhibitor L-NMMA to intact rat liver mitochondria did not have any effect on the respiratory rate in both State 3 and State 4. We did not detect mitochondrial NO* production by the oxymyoglobin oxidation assay, or electrochemically using an NO* electrode. An apparent NO* production detected by the Griess assay was identified as an artifact. NO* generated by eNOS added to the mitochondria could easily be detected, although succinate-supplemented mitochondria appeared to consume NO*. Our data show that NO* production by normal rat liver mitochondria cannot be detected in our laboratory, even though the levels of production claimed in the literature should easily have been measured by the techniques used. The implications for the putative mitochondrial NOS are discussed.     

2,3-butanedione monoxime unmasks Ca(2+)-induced NADH formation and inhibits electron transport in rat hearts

We used 2,3-butanedione monoxime (BDM) to suppress work by the perfused rat heart and to investigate the effects of calcium on NADH production and tissue energetics. Hearts were perfused with buffer containing BDM and elevated perfusate calcium to maintain the rates of cardiac work and oxygen consumption at levels similar to those of control perfused hearts. BDM plus calcium hearts displayed higher levels of NADH surface fluorescence, indicating calcium activation of mitochondrial dehydrogenases. These hearts, however, displayed 20% lower phosphocreatine levels. BDM suppressed the rates of state 3 respiration of isolated mitochondria. Uncoupled respiration was suppressed to a lesser degree, and the state 4 respiration rates were not affected. Double-inhibitor experiments with liver mitochondria using BDM and carboxyatractyloside (CAT) were used to identify the site of inhibition. BDM at low levels (0-5 mM) suppressed respiration. In the presence of CAT at levels that inhibit respiration by 60%, low levels of BDM were without effect. Because these effects were not additive, BDM does not inhibit adenine nucleotide transport. This was supported by an assay of adenine nucleotide transport in liver mitochondria. BDM did not inhibit ATP hydrolysis by submitochondrial particles but strongly suppressed reversed electron transport from succinate to NAD(+). Oxidation of NADH by submitochondrial particles was inhibited by BDM but oxidation of succinate was not. We conclude that BDM inhibits electron transport at site 1.     

Toxicity of emestrin,a new macrocyclic dithiodioxopiperazine mycotoxin,to mitochondrial function

The effect of emestrin, a new macrocyclic epidithiodioxopiperazine mycotoxin from severalEmericella species, on mitochondrial reactions was studied using isolated rat liver mitochondria to gain insight into the molecular mechanism for itsin vivo toxicity to rat and mouse. Emestrin was found to inhibit ATP synthesis in mitochondria causing an uncoupling of oxidative phosphorylation and a depression of respiration in isolated mitochondria. In addition to these effects on mitochondrial respiration, emestrin elicited a dratsic structural alteration (swelling) of mitochondria as observed in thein vivo system. The mitochondrial swelling was significantly enhanced by the subsequent addition of calcium ion. Emestrin B, in which dithio group is replaced by trithio group, exerted an uncoupling effect on oxidative phosphorylation without accompanying such depressive effect on state 3 respiration as observed for emestrin.     

Effect of brief vascular perfusion on the ultrastructure and activity of mitochondria isolated from the rat heart

Summary Mitochondria isolated from heart tissue after a 1-min perfusion with Hanks medium were found to have significantly lower rates of State-3 respiration and respiratory control ratios compared to mitochondria isolated from non-perfused hearts. Examination of the mitochondrial preparations by electron microscopy revealed that a large proportion of the mitochondria isolated from perfused heart tissue were swollen and broken compared to mitochondria from non-perfused hearts.     

Aspects of energy-linked calcium accumulation by rat heart mitochondria.

When intact rat heart mitochondria were pulsed with 150 nmol of CaCl2/mg of mitochondrial protein, only a marginal stimulation of the rate of oxygen consumption was observed. This result was obtained with mitochondria isolated in either the presence or absence of nagarse. In contrast, rat liver mitochondria under similar conditions demonstrated a rapid, reversible burst of respiration associated with energy-linked calcium accumulation. Direct analysis of calcium retention using 45Ca and Millipore filtration indicated that calcium was accumulated by heart mitochondria under the above conditions via a unique energy-dependent process. The rate of translocation by heart mitochondria was less than that of liver mitochondria; likewise the release of bound calcium back into the medium was also retarded. These results suggest that the slower accumulation and release of calcium is characteristic of heart mitochondria. The amound of calcium bound was independent of penetrant anions at low calcium concentrations. Above 100 nmol/mg of mitochondrial protein, the total calcium bound was increased by the presence of inorganic phosphate. Under nonrespiring conditions, a biphasic Scatchard plot indicative of binding sites with different affinities for Ca2+ was observed. The extrapolated constants are 7.5 nmol/mg bound with an apparent half-saturation value of 75 muM and 42.5 nmol/mg bound with half-saturation at 1.15 mM. The response of the reduced State 4 cytochrome b to pulsed additions of Ca2+ was used to calculate an energy-dependent half-saturation constant of 40 muM. When the concentration of free calcium was stabilized at low levels with Ca2+-EGTA buffers, the spectrophotometrically determined binding constant decreased two orders of magnitude to an apparent affinity of 4.16 X 10(-7) M. Primary of calcium transport over oxidative phosphorylation was not observed with heart mitochondria. The phosphorylation of ADP competed with Ca2+ accumulation, depressed the rates of cation transport, and altered the profile of respiration-linked H+ movements. Consistent with these result was the observation that with liver mitochondrial the magnitude of the cytochrome b oxidation-reduction shift was greater for Ca2+ than for ADP, whereas calcium responses never surpassed the ADP response in heart mitochondria. Furthermore, Mg2+ ingibited calcium accumulation by heart mitochondria while having only a slight effect upon calcium transport in liver mitochondria. The unique energetics of heart mitochondrial calcium transport are discussed relative to the regulated flux of cations during the cardiac excitation-relaxation cycle.     

The effect of glucagon on hepatic respiratory capacity

Data from numerous laboratories show that mitochondria isolated from livers treated acutely with glucagon have higher rates of state 3 respiration than control mitochondria. The purpose of the present study was to learn whether this phenomenon is an isolation artifact resulting from a stabilization of the mitochondrial membrane or whether it represents a real increase in the maximal respiratory capacity of liver cells due to glucagon treatment. Electron transport was measured through different spans of the electron transport chain by using ferricyanide as an alternate electron acceptor to O2. With isolated intact liver mitochondria, pretreatment with glucagon was found to cause an increase in electron flow, through both Complex I and Complex III, suggesting that the effect of glucagon was not specific for a single site in the electron transport chain. Using intact isolated hepatocytes, different results are obtained. Respiration was measured in isolated hepatocytes after quantitation of the hepatocyte mitochondrial content by assay of citrate synthase. Hepatocyte respiration could therefore be reported per mg of mitochondrial protein. By providing durohydroquinone to the cells, it was possible to measure electron flow from coenzyme Q to O2 in the absence of the physiological regulation of substrate supply. Likewise, the addition of carbonyl cyanide p-trifluoromethoxyphenylhydrazone released the in situ mitochondria from control by the cytosolic ATP/ADP ratio and it was possible to measure maximal electron flow rates through Complex III. In the presence of carbonyl cyanide p-trifluoromethoxyphenylhydrazone, electron flow was higher in mitochondria in the cell than in isolated mitochondria. Glucagon caused no increase in mitochondrial respiration in situ either in the presence of the physiological substrates or in the presence of durohydroquinone. The data obtained do not support a role for the electron transport chain as a target of glucagon action in hepatocytes.