Reduction of superoxide production by mitochondria oxidizing NADH in the presence of organic acids

Effects of multiple substrates on oxygen uptake and superoxide production by mitochondria isolated from the pericarp tissue of green bell pepper (Capsicum annuum L.) were studied. Mitochondria isolated from peppers stored at 4 °C for 5 and 6 days had higher rates of oxygen uptake and were less sensitive to cyanide than mitochondria isolated from freshly harvested peppers. Succinate enhanced state 2 and state 4 rates of oxygen uptake with exogenous NADH in the absence of cytochrome path inhibitors, but not state 3 rates by mitochondria isolated from either freshly harvested or cold-stored bell peppers. The sensitivity of NADH oxidation to cyanide was reduced by both malate and succinate in mitochondria from cold-stored bell peppers, whereas only succinate was effective in mitochondria from freshly harvested peppers.Mitochondria isolated from both freshly harvested peppers and those stored at 4 °C for 5 and 6 days produced superoxide in the absence of exogenous substrates. Superoxide production by mitochondria from freshly harvested bell peppers increased when the mitochondria were supplied with malate, succinate or NADH, but only NADH enhanced superoxide production by mitochondria from cold-stored peppers. Both succinate and malate reduced the production of superoxide by mitochondria isolated from cold-stored bell peppers. Succinate and malate as second substrates also reduced the production of superoxide with NADH by mitochondria from both freshly harvested and cold-stored bell peppers. Malonate, a competitive inhibitor of succinate dehydrogenase, was inhibitory to oxygen uptake and to superoxide production.Mitochondria isolated from cold-stored bell peppers converted succinate to pyruvate at 25 °C at considerably higher rates than those of mitochondria from freshly harvested bell peppers. Since pyruvate has been shown to activate the alternative oxidase and the presence of pyruvate is essential for continued alternative oxidase activity, we suggest that pyruvate limits superoxide production by enhancing the flow of electrons through the alternative path. A direct scavenging of superoxide by succinate, malate and pyruvate, however, cannot be ruled out.     

Specific inhibition by macrocyclic polyethers of mitochondrial electron transport at site I

The macrocyclic polyethers dibenzo-18-crown-6 (XXVIII) and dicyclohexyl-18-crown-6 (XXXI) inhibit the valinomycin-mediated K⁺ accumulation energized by glutamate, -ketoglutarate, malate plus pyruvate or isocitrate but not that promoted by succinate, ascorbate plus TMPD or ATP. The polyethers inhibit the oxidation of the former group of substrates without preventing either the oxidation of succinate or ascorbate plus TMPD or the hydrolysis of ATP.The substrate oxidation inhibited by the macrocyclic polyethers is relieved in intact mitochondria by increasing the concentration of K⁺ in the medium. It is also completely reverted by supplementing the medium with valinomycin, Cs⁺ and phosphate, or else by the addition of vitamin K₃.In submitochondrial sonic particles the macrocyclic polyethers inhibit the oxidation of NADH as well as the ATP-driven reversal of electron flow at the site I of the electron transport chain. They also block the oxidation of NADH in non-phosphorylating Keilin-Hartree particles as well as in Hatefi's NADH-coenzyme Q reductase. The polyethers do not inhibit electron transport in mitochondria from the yeast which lack the first coupling site.The inhibition of electron transport by the polyethers do not require of the addition of alkali metal cations such as K⁺ in intact mitochondria or other membrane preparations.It is established that the macrocyclic polyethers XXVIII and XXXI, already characterized as mobile carrier molecules for K⁺ in model lipid membranes, inhibit electron transport at site I of the electron transport chain from mitochondrial membranes.It is suggested that the ability of the polyethers to coordinate alkali metal cations in aqueous versus lipid environments, but not K⁺ transportper se, is related to their rotenone-like induced inhibition of electron flow in mitochondrial membranes.Supported in part by a Grant from the Research Corporation.     

Some Reactions of Isolated Corn Mitochondria Influenced by Juglone

The effects of juglone on the uptake of O₂ by excised corn roots (Zea mays L., Wf9 cms- T × M14) and isolated corn mitochondria arc reported. The O₂ uptake by excised corn roots, as measured by an O₂ electrode, was inhibited more than 90% after a one-hour treatment of 500 μM juglone. Lesser inhibitions were observed with 50 μM and 250 μM juglone. In a KC1 reaction medium in the absence of inorganic phosphate (Pi), juglone stimulated the rate of O₂ uptake by isolated mitochondria oxidizing NADH, succinate, or malate + pyruvate. In the presence of Pi, juglone concentrations of 3 μM and greater inhibited the state 3 oxidation rates of succinate and malate + pyruvate, lowered respiratory control and ADP/O ratios obtained from the oxidation of NADH, malate + pyruvate, or succinate, and reduced the coupled deposition of calcium phosphate within isolated mitochondria driven, by the oxidation of malate + pyruvate. The inhibition of state 3 O₂ uptake by isolated mitochondria, an oxidative state in which electron transfer is coupled to ATP production, is seen to correlate with the inhibition affected by juglone when applied to tissues in vivo.     

Oxidations of various substrates and effects of the inhibitors on purified mitochondria isolated from <Emphasis Type="Italic">Kalanchoë pinnata</Emphasis>

Kalanchoë pinnata mitochondria readily oxidized succinate, malate, NADH, and NADPH at high rates and coupling. The highest respiration rates usually were observed in the presence of succinate. The high rate of malate oxidation was observed at pH 6.8 with thiamine pyrophosphate where both malic enzyme (ME) and pyruvate dehydrogenase were activated. In CAM phase III of K. pinnata mitochondria, both ME and malate dehydrogenase (MDH) simultaneously contributed to metabolism of malate. However, ME played a main function: malate was oxidized via ME to produce pyruvate and CO₂ rather than via MDH to produce oxalacetate (OAA). Cooperative oxidation of two or three substrates was accompanied with the dramatic increase in the total respiration rates. Our results showed that the alternative (Alt) pathway was more active in malate oxidation at pH 6.8 with CoA and NAD⁺ where ME operated and was stimulated, indicating that both ME and Alt pathway were related to malate decarboxylation during the light. In K. pinnata mitochondria, NADH and NADPH oxidations were more sensitive with KCN than that with succinate and malate oxidations, suggesting that these oxidations were engaged to cytochrome pathway rather than to Alt pathway and these capacities would be desirable to supply enough energy for cytosol pyruvate orthophosphate dikinase activity.     

Fuscin,an inhibitor of respiration and oxidative phosphorylation in ox-neck muscle mitochondria

1. The effect of fuscin on the mitochondrial oxidation of pyruvate plus malate, of succinate and of ascorbate plus tetramethyl-p-phenylenediamine (TMPD) and on the redox changes of succinate-reducible cytochromes b and c was investigated using tightly-coupled ox-neck muscle mitochondria.     

Impaired substrate utilization in mitochondria from strain 129 dystrophic mice

Mitochondria from skeletal muscle, heart and liver of strain 129/ReJ-dy dystrophic mice and their littermate controls were characterized with respect to their respiratory and phosphorylating activities. Skeletal muscle mitochondria from dystrophic mice showed significantly lower state 3 respiratory rates than controls with both pyruvate + malate and succinate as substrates (P < 0.01). ADP/O and Ca²⁺/O ratios were found to be normal. A decreased rate of NADH oxidation (0.01 <P < 0.05) by sonicated mitochondrial suspensions from dystrophic mice was also seen. High respiratory rates with ascorbate + phenazine methosulfate as substrates indicated that cytochrome oxidase was not rate limiting in the oxidation of either pyruvate + malate or succinate. Skeletal muscle mitochondria from dystrophic mice showed no deficiency in any of the cytochromes or coenzyme Q. Mg²⁺-stimulated ATPase activity was higher in dystrophic muscle mitochondria than in controls, but basal and oligomycin-insensitive activities were virtually identical to those of controls. A significant reduction in the intramitochondrial NAD⁺ content (0.01 <P < 0.02) was seen in dystrophic skeletal muscle as compared to controls. Heart mitochondria from dystrophic mice showed similar, though less extensive abnormalities while liver mitochondria were essentially normal. We concluded from these results that skeletal muscle mitochondria from strain 129 dystrophic mice possess impairments in substrate utilization which may result from (1) an abnormality in the transfer of electrons on the substrate side of coenzyme Q in the case of succinate oxidation; (2) a defect on the path of electron flow from NADH to cytochrome c, and (3) a deficiency of NAD⁺ in the case of NAD⁺-linked substrates.     

Effects of equisetin on rat liver mitochondria: Evidence for inhibition of substrate anion carriers of the inner membrane

The effect of equisetin, an antibiotic produced byFusarium equiseti, has been studied on mitochondrial functions (respiration, ATPase, ion transport). Equisetin inhibits the DNP-stimulated ATPase activity of rat liver mitochondria and mitoplasts in a concentration-dependent manner; 50% inhibition is caused by about 8 nmol equisetin/mg protein. The antibiotic is without effect either on the ATPase activity of submitochondrial particles or on the purified F₁-ATPase. It inhibits both the ADP- or DNP-activated oxygen uptake by mitochondria in the presence of glutamate + malate or succinate as substrates, but only the ADP-stimulated respiration is inhibited if the electron donors are TMPD + ascorbate. It does not affect the NADH or succinate oxidation of submitochondrial particles. Equisetin inhibits in a concentration-dependent manner the active Ca²⁺-uptake of mitochondria energized both by ATP or succinate without affecting the Ca²⁺-uniporter itself. The antibiotic inhibits the ATP-uptake by mitochondria (50% inhibition at about 8 nmol equisetin/mg protein) and the P_i and dicarboxylate carrier. It does not lower the membrane potential at least up to 200 nmol/mg protein concentration. The data presented in this paper indicate that equisetin specifically inhibits the substrate anion carriers of the mitochondrial inner membrane.Abbreviations EGTA ethyleneglycol bis/-aminoethylether/-N, N-tetraacetic acid - DNP 2, 4-dinitrophenol - TMPD N,N,N,N,tetramethyl-p-phenylenediamine - CCP carbonylcyanide-m-chlorophenyl hydrazone - TPP tetraphenyl-phosphonium - Hepes /4,(2-hydroxyethyl)-1-piperazine-ethanesulfonic acid/     

Isolation and properties of flight muscle mitochondria of the bumblebee Bombus terrestris (L.)

This report describes the isolation procedure and properties of tightly coupled flight muscle mitochondria of the bumblebee Bombus terrestris (L.). The highest respiratory control index was observed upon oxidation of pyruvate, whereas the highest respiration rates were registered upon oxidation of a combination of the following substrates: pyruvate + malate, pyruvate + proline, or pyruvate + glutamate. The respiration rates upon oxidation of malate, glutamate, glutamate + malate, or succinate were very low. At variance with flight muscle mitochondria of a number of other insects reported earlier, B. terrestris mitochondria did not show high rates of respiration supported by oxidation of proline. The maximal respiration rates were observed upon oxidation of α-glycerophosphate. Bumblebee mitochondria are capable of maintaining high membrane potential in the absence of added respiratory substrates, which was completely dissipated by the addition of rotenone, suggesting high amount of intramitochondrial NAD-linked oxidative substrates. Pyruvate and α-glycerophosphate appear to be the optimal oxidative substrates for maintaining the high rates of oxidative metabolism of the bumblebee mitochondria.     

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.     

Uncoupled oxidation in rat heart mitochondria

Isolated heart mitochondria possessing a high phosphorylation efficiency with pyruvate and malate as substrates oxidize NADH and ascorbate unassociated with ADP phosphorylation. This uncoupled pathway is expressed partially when succinate or NAD-linked substrates are oxidized. The uncoupled oxidation is likely to be the result of the presence of a mitochondrial population with the high-permeable inner membrane in intact tissues. The nature and origin of a uncoupled respiratory system and its role in the thermoproduction of endotherms are discussed.     

Properties of Wheat Mitochondria. Study of Substrates, Cofactors and Inhibitors

Isolated mitochondria of wheat shoots oxidize α- ketoglutarate, DL-malate succinate and NADH with good relative respiration control and ADP: O ratio. They have high affinity for α-ketoglutarate and NADH as substrates and utilize malate and succinate with a respiration ratio of about one-half of α-ketoglutarate. The average ADP : O ratios approach the expected theoretical values, i.e., 3.6 ± 0.2 for α-ketoglutarate, 1.8 ± 0.2 for succinate, and 2.8 ± 0.2 for malate. The ADP: O ratio with NADH is 1.8 ± 0.2. The maximum coupling of oxidation and phosphorylation is obtained at concentrations of 10 mM, 2 mM, 10 mM and 8 mM for α-ketoglutarate, NADH, malate and succinate, respectively. — Wheat mitochondria have little or no dependence on added cofactors. Mitochondria prepared by our procedure apparently retain sufficient amounts of endogenous cofactors required for NAD-linked systems. FAD⁺ is found to improve succinate oxidation. Cytochrome c does not have any significant effect on respiratory parameters of wheat mitochondria. — Wheat mitochondria are some -what resistant to DNP at 1.7 × 10^-5M. Malonate seems to improve coupling of α-ketoglutarate oxidation. Other Krebs cycle intermediates have been tested on three major substrates of TCA cycle, i.e., α-ketoglutarate, malate and succinate.     

The phosphorylation potentials generated by respiring Ehrlich ascites tumor mitochondria

The extra- and intramitochondrial phosphorylation potentials (ΔG_p(out) and ΔG_p(in), respectively) generated by respiring Ehrlich ascites tumor mitochondria were determined, using succinate, pyruvate + malate, ascorbate + N,N,N′,N′-tetramethyl-p-phenylenediamine, and ascorbate + ferrocyanide as substrate systems. Values of ΔG_p(out) exceeding 15 kcal mol^?1 (62.8 kJ mol^?1) in post-ADP state 4 respiration were found with succinate as substrate, in agreement with data on normal rat liver mitochondria. ΔG_p(out) values exceeding 15 kcal mol^?1 (62.8 kJ mol^?1) were also observed with ascorbate + TMPD or ascorbate + ferrocyanide as substrates. Slightly lower values of ΔG_p(out) were found with the NAD-linked substrates pyruvate + malate. The intramitochondrial ΔG_p(in) developed by respiring Ehrlich ascites tumor mitochondria respiring on succinate approached 12 kcal mol^?1 (50.2 kJ mol^?1), in agreement with reported values on rat liver mitochondria. The prior accumulation of Ca²⁺ and phosphate by the Ehrlich cell mitochondria did not lower the extramitochondrial ΔG_p(out) developed after a subsequent addition of ADP. Although the rate of oxidative phosphorylation of Ehrlich ascites tumor cells is reduced by intramitochondrial Ca²⁺ and phosphate (Villalobo and Lehninger (1980) J. Biol. Chem., 255, 2457–2464) they are still capable of generating ATP in the suspending medium against a high thermodynamic gradient, as expressed by the [ATP]/[ADP][P_i]mass action ratio.     

Endogenous elemental sulfur (S°) in dormant and aging α-spores of Phomopsis viticola

Endogenous elemental sulfur (S°) was measured in dormant α-spores of Phomopsis viticola Sacc. (ATCC 44940) from young (25-day-old) and aging (105-day-old) cultures grown on malt extract agar medium enriched with [³⁵S]-MgSO₄. Endogenous S° from the mitochondrial fraction, and the lipid and aqueous cytoplasmic fractions of young and aging α-spores were purified by column chromatography followed by thin-layer chromatography. The purity of mitochondrial pellets were checked by the catalase (EC 1.11.1.6) and acid phosphatase (EC 3.1.3.1) activities. Activities of the mitochondrial enzymes NAD⁺-isocitrate dehydrogenase (EC 1.1.1.41) and cytochrome c oxidase (EC 1.9.3.1) were also measured to determine the distribution of the endogenous S° between mitochondria and cytoplasm. In young dormant α-spores, endogenous S° was mostly found in the cytoplasmic lipid reserves, which were mainly phospholipids. The mitochondrial fraction of these young α-spores contained ca 10% of the total endogenous S°, whereas in aging α-spores stored for 105 days the endogenous S° was mainly (ca 90%) localized in the mitochondrial fraction. This accumulation of S° in mitochondria of aging α-spores was correlated with a sharp decrease in phospholipid reserves, endogenous and exogenous respiratory activities, ATP concentration, uptake of sulfate, and NAD⁺-isocitrate dehydrogenase and cytochrome c oxidase activities. These metabolic changes were correlated with an irreversible loss of germination capacity which leads to the natural death of P. viticolaα-spores. During the first min of the breaking of dormancy, the young α-spores possess a 7.3-fold capacity to reduce exogenous S° with production of hydrogen sulfide, as compared to the aging α-spores. In young α-spores the production of hydrogen sulfide was almost totally inhibited by 40 μM antimycin A (92%), and strongly inhibited by 2mM azide (75%) and by 15 μM 2,4-dinitrophenol (63%). Our work suggests that endogenous S° plays a key role in the regulation of the dormancy and aging processes of α-spores of P. viticola.     

Electron Transport and Oxidative Phosphorylation in Arum Spadix Mitochondria

Arum spadix mitochondria exhibited a rapid cyanide-resistantoxygen uptake when oxidizing malate, NADH₂ or succinate, anda slower, cyanide-sensitive oxygen uptake when oxidizing ascorbate+tetramethylphenylenediamine(TMPD). Cytochrome oxidase does not therefore appear to functionas the terminal oxidase in the presence of cyanide, and therather low cytochrome c oxidase activity obtained using ascorbate+TMPDmay exclude it from possessing a major role even in the absenceof cyanide. ATP synthesis has been shown to accompany substrateoxidation. In the presence of antimycin A the P: O ratio accompanyingmalate oxidation was reduced by half, while phosphorylationaccompanying NADH₂ or succinate oxidation was almost completelyabolished. It is proposed that electrons from exogenous NADH₂enter the electron transport chain at a site after that whereendogenous NADH2 donates electrons and that electrons from exogenousNADH₂ are not coupled to ATP synthesis at site 1. The cyanide-resistant,non-phosphorylating electron-transport pathway may functionin the absence of cyanide and account for the low efficiencyof energy conservation observed in this tissue.     

Post-mortem changes in structure and function of ox muscle mitochondria. 1. Electron microscopic and polarographic investigations

Electron microscopy shows that intact mitochondria can be isolated from neck-muscle stored at 144h post-mortem at 4°. Isolated mitochondria, all in the condensed configuration, have clearly defined outer and inner membranes, outer compartments and intracristal spaces; a larger proportion of swollen ones was isolated from the 144h than from the 120 h post-mortem tissue.Mitochondria from 96 h tissue still retained the following % of the initial values for the ADP/O ratio, respiratory control index (RCI) and state 3 respiratory rate observed for 0–5h tissue: malate+pyruvate, 100, 72 and 53; succinate, 80, 30 and 74; ascorbate+ tetramethyl-p-phenylencdiamine (TMPD), 92, 88 and 72.Both the succinate and ascorbate-TMPD oxidase systems appear to have a critical storage time of about 70 h, whereas the malate+pyruvate system has one of about 96 h. Asharp decline of the ADP/O ratio, RCI and the state 3 respiratory rate occurred after this time, but these three parameters were better preserved in the ascorbate-TMPD oxidase system.The oxidation of the citric acid cycle intermediates in the neck-muscle mitochondria thus shows a higher sensitivity to post-mortem ageing with respect to cytochrome oxidase activity. This is probably due to post-mortem muscle acidification.     

Rapid Communication Muscle Mitochondrial ATP Production in Progressive Supranuclear Palsy

Abstract: Six patients with progressive supranuclear palsy (PSP) and 12 age-matched disease-free subjects participated in this study designed to compare rates of ATP production by intact mitochondria from biopsied skeletal muscle. When pyruvate and malate were used as metabolic substrates, rates of ATP production were 0.184 ± 0.025 μmol/min/U of citrate synthase (CS) activity (a mitochondrial marker) in control subjects and 0.131 ± 0.051 μmol/min/U of CS in PSP patients. In the presence of succinate, rates of ATP formation were 0.137 + 0.02 μmol/min/U of CS in controls and 0.109 ± 0.04 /4mUmol/min/U of CS in patients. With N,N,N',N' -tetramethyl- p -phenylenediamine (TMPD) and ascorbate, rates were 0.034 ± 0.008 μm Umol/min/U of CS in controls and 0.022 ± 0.01 μmol/min/U of CS in PSP subjects. Differences between the control and PSP populations reached statistical significance with pyruvate/malate and TMPD/ascorbate. No differences in either muscle histopathology or histochemistry were found between patient and control subjects. Results of this study suggest that oxidative phosphorylation defects occur in muscle mitochondria from patients with PSP.     

Properties of rat liver mitochondria with intermembrane Cytochrome c.

When rat liver mitochondria were suspended in 0.15 m KCl, the cytochrome c appeared to be solubilized from the binding site on the outside of the inner membrane and trapped in the intermembrane space. When the outer membrane of these mitochondria was disrupted with digitonin at a digitonin concentration of 0.15 mg/mg of protein, the solubilized cytochrome c could be released from mitochondria along with adenylate kinase. When mitochondria were suspended in 0.15 m KCl instead of 0.33 m sucrose, the $\text{ADP}\text{O}$ ratio observed with succinate, β-hydroxybutyrate, malate + pyruvate or glutamate as substrates was little affected. A number of cycles of State 4-State 3-State 4 with ADP was observed. The respiratory control ratios, however, were decreased, particularly when glutamate was used as the substrate. Cytochrome c oxidase activity was also decreased to 55% when assayed using ascorbate + N,N,N′,N′-tetramethyl-p-phenylene-diamine (TMPD) as substrates. Suspension of mitochondria in 0.15 m KCl resulted in an enhancement of the very low NADH oxidation by intact mitochondria and a twofold enhancement of sulfite oxidation. Trapped cytochrome c in outer membrane vesicles prepared from untreated and trypsin-treated intact mitochondria was found to be readily reduced by NADH and suggests that some cytochrome b₅ is located on the inner surface of the outer membrane. The enhanced NADH oxidase could therefore reflect the ability of cytochrome c to mediate intermembrane electron transport. The enhanced sulfite oxidase activity was sensitive to cyanide inhibition and coupled to oxidative phosphorylation ($\text{ADP}\text{O}\text{< 1}$) unlike the activity of mitochondria in sucrose medium. These results suggest that free cytochrome c in the intermembrane space can mediate electron transfer between the sulfite oxidase and the inner membrane.     

Ziram, a sulfhydryl reagent and specific inhibitor of yeast mitochondrial dehydrogenases.

The fungicide zinc dimethyldithiocarbamate (ziram) is a sulfhydryl reagent which inhibits specifically the growth of the yeast Saccharomyces cerevisiae on nonfermentable substrates. In isolated mitochondria, the uncoupled as well as the state 3 oxidations of succinate, α-ketoglutarate, ethanol, and malate plus pyruvate are sensitive to ziram concentrations of 10 to 30 μm. The oxidations of isocitrate, of external NADH, of α-glycerophosphate, and of ascorbate plus tetramethylphenylenediamine exhibit a lower sensitivity to ziram. Succinate, α-ketoglutarate, and pyruvate dehydrogenases activities are 50% inhibited by concentration of ziram lower than 10 μm. At the same concentrations, neither the mitochondrial transports of succinate, ADP, or phosphate nor oxidative phosphorylation and adenosine triphosphatase activities are modified. The kinetic study of the inhibition by ziram of succinate dehydrogenase activity shows that ziram is noncompetitive with succinate and produces sigmoidal inhibitions of state 3 and of uncoupled oxidation of succinate by intact mitochondria. Inhibition of succinate:phenazine methosulfate oxidoreductase activity yields exponential kinetics. However sigmoidal-type inhibition is observed when succinate dehydrogenase activity is stimulated by ATP.     

The use of calcium uptake by small amounts of mitochondria from pancreatic islets to study mitochondrial respiration: the effects of diazoxide and sodium

The net uptake of 45Ca into mitochondria from pancreatic islets is stimulated by substrates that transfer reducing equivalents to various sites of the respiratory chain, such as succinate or glycerol 3-phosphate (site II), malate plus pyruvate (site I) or ascorbate plus TMPD (site III). Diazoxide, a known inhibitor of insulin release in vivo and in vitro, strongly inhibited net 45Ca uptake supported by glycerol phosphate and succinate and weakly inhibited 45Ca uptake supported by the other substrates. These results suggest that diazoxide, although not completely specific, is predominately an inhibitor at site II of the respiratory chain. This result is consistent with previous work that showed diazoxide inhibits the enzyme activity of the mitochondrial glycerol phosphate dehydrogenase in islets. Sodium ion inhibited the net accumulation of 45Ca by islet mitochondria suggesting a similarity between islet mitochondria and those of heart and some other endocrine tissues.     

Oxidative phosphorylation analysis: assessing the integrated functional activity of human skeletal muscle mitochondria—case studies

Oxidative phosphorylation analysis, performed on freshly-isolated mitochondria, assesses the integrated function of the electron transport chain (ETC) coupled to ATP synthesis, membrane transport, dehydrogenase activities, and the structural integrity of the mitochondria. In this review, a case study approach is employed to highlight detection of defects in the adenine nucleotide translocator, the pyruvate dehydrogenase complex, fumarase, coenzyme Q function, fatty acid metabolism, and mitochondrial membrane integrity. Our approach uses the substrates glutamate, pyruvate, 2-ketoglutarate (coupled with malonate), malate, and fatty acid substrates (palmitoylcarnitine, octanoylcarnitine, palmitoyl-CoA (with carnitine), octanoyl-CoA (with carnitine), octanoate and acetylcarnitine) in addition to succinate, durohydroquinone and TMPD/ascorbate to uncover metabolic defects that would not be apparent from ETC assays performed on detergent-solubilized mitochondria.