Comparison of cerebral NADH and cytochrome aa3 redox shifts during anoxia or hemorrhagic hypotension.

The reduction-oxidation reactions of NADH and cytochrome $\text{aa}{}_3$ to incipient oxygen insufficiency caused by nitrogen ventilation or hemorrhagic hypotension were examined in the exposed cerebral cortex of the cat. A comparison of the onset of redox changes with each procedure shows that cytochrome $\text{aa}{}_3$ reduction precedes the reduction of mitochondrial NAD. This constitutes evidence that, in the living brain, NADH maintains its resting oxidation state at lower cellular oxygen tensions than cytochrome $\text{aa}{}_3$ does, consistent with the differences in oxygen affinity these respiratory chain components exhibit during oxygen titration $\text{in vitro}$.     

Bound cytochrome C as proton donor and acceptor during enzymic oxidoreduction

When ferrocytochrome $\text{c}$ reacts with delipidated cytochrome oxidase under conditions which prevent oxidation, one proton is taken up per molecule of ferrocytochrome $\text{c}$ bound to cytochrome oxidase. When ferricytochrome $\text{c}$ reacts with delipidated Complex III, one proton is released per molecule of ferricytochrome $\text{c}$ bound to Complex III. From these data it can be concluded that the oxidation of ferrocytochrome $\text{c}$ by cytochrome oxidase leads to the release of a proton and an electron, whereas the reduction of ferricytochrome $\text{c}$ by Complex III leads to the uptake of a proton and an electron. Thus ferrocytochrome $\text{c}$ like QH₂ and NADH is both an electron and proton donor, and ferricytochrome $\text{c}$ like Q and O₂ is both an electron and proton acceptor. The pattern for the three mitochondrial electron transfer sequences NADH → Q, QH₂ → ferricytochrome $\text{c}$ and ferrocytochrome $\text{c}$ → O₂ involves separation of an electron and proton on the side of the membrane where electron transfer is initiated and recombination of an electron and a proton in the terminal acceptor on the side of the membrane where electron transfer terminates.     

Energy-coupling mechanisms under aerobic and anaerobic conditions in autotrophically grown Pseudomonas saccharophila

The cell-free preparations from autotrophieally grown Pseudomonas saccharophila catalyzed the process of electron transport from H₂ or various other organic electron donors to either O₂ or NO₃^? with concomitant ATP generation. The respective $\text{P}\text{O}$ ratios with H₂ and NADH were 0.63 and 0.73, the respective $\text{P}\text{NO}{}_3{}^{\mathrm{?}}$ ratios were 0.57 and 0.54. In contrast, the $\text{P}\text{O}$ and $\text{P}\text{NO}{}_3{}^{\mathrm{?}}$ ratios with succinate were 0.18 and 0.11, respectively. ATP formation coupled to the oxidation of ascorbate, in the absence or presence of added N,N,N′,N′-tetramethyl-p-phenylenediamine or cytochrome c, could not be detected. Various uncouplers inhibited phosphorylation with either O₂ or NO₃^? as terminal electron acceptors without affecting the oxidation of H₂ or other substrates. The NADH oxidation at the expense of O₂ or NO₃^? reduction as well as the associated phosphorylation were inhibited by rotenone and amytal. The aerobic and anaerobic H₂ oxidation and coupled ATP synthesis, on the other hand, was unaffected by the flavoprotein inhibitors as well as by the NADH trapping system. The NADH, H₂, and succinate-linked electron transport to O₂ or NO₃^? and the associated phosphorylations were sensitive, however, to antimycin A or 2-n-nonyl-4-hydroxyquino-line-N-oxide, and cyanide or azide. The data indicated that although the phosphorylation sites 1 and II were associated with NADH oxidation by O₂ or NO₃^?, the energy conservation coupled to H₂ oxidation under aerobic or anaerobic conditions appeared to involve site II only.     

Studies on Mitochondrial Proteins. II. Localization of Components in the inner membrane labelling with diazobenzenesulfonate,a non-penetrating probe

The topography of the inner membrane of rat liver mitochondria was studied using a probe, diazobenzenesulfonate, which interacts preferentially with surface components. Inner membranes were examined both in a native orientation as found in the intact mitochondrion or in an inverted state as found in isolated inner membranes prepared by sonication.Enzyme inactivation as a consequence of diazobenzenesulfonate labeling was employed to determine the localization of a number of inner membrane activities. In inner membranes labeled on the outer surface, NADH and succinate oxidation were strongly inhibited while ATPase and $\text{ascorbate}\text{-N,N,N′,N′-}\text{tetramethyl}\text{-p-}\text{phenylene-diamine}$ (TMPD) oxidase activities were unaffected. In inner membranes labeled on the inner surface. ATPase and succinate oxidation were inactivated while NADH oxidation and ascorbate-TMPD oxidase were unaffected. Succinate dehydrogenase was inhibited only by labeling the inner surface while NADH dehydrogenase was inhibited to a similar extent by treatment of either surface.Sodium dodecylsulfate-polypeptides (66 000 and 26 000) on the outer surface of the inner membrane and five polypeptides (80 000, 66 000, 51 000-48 000, and 26 000) on the inner surface. These results indicate a highly asymmetric localization of inner membrane components.     

The regulation of pyruvate dehydrogenase by fatty acids in isolated rabbit heart mitochondria.

The rate of pyruvate oxidation by isolated rabbit heart mitochondria was inhibited by fatty acylcarnitine derivatives. The extent of inhibition by pyruvate oxidation in State 3 was greatest with palmitylcarnitine and only a minimal inhibition was observed with acetylcarnitine, while octanoylcarnitine or octanoate caused an intermediate extent of inhibition. Analyses of the intramitochondrial $\text{ATP}\text{ADP}$ and $\text{NADH}\text{NAD}{}^{\mathrm{+}}$ ratios under the different conditions of incubation indicated that it is unlikely that changes in either or both of these parameters were the primary negative effectors of the rate of pyruvate oxidation. A positive correlation between the decrease in the rate of pyruvate oxidation and the decrease in the level of free CoASH in the mitochondria was observed. Extraction and assay of the pyruvate dehydrogenase from rabbit heart mitochondria during the time course of the fatty acid-mediated inhibition of pyruvate oxidation indicated that pyruvate dehydrogenase was strongly inactivated when palmitylcarnitine was the fatty acid, while incubation with octanoate and acetylcarnitine resulted in less extensive inactivation of pyruvate dehydrogenase. Measurement of the effects of NADH, NAD⁺, acetyl-CoA, and CoASH on the inactivation of pyruvate dehydrogenase extracted from rabbit heart mitochondria indicated that NADH and acetyl-CoA activated the pyruvate dehydrogenasee kinase while CoASH strongly inhibited the kinase and NAD⁺ was without effect. In addition, palmityl-CoA and octanoyl-CoA had little, if any, effect on the pyruvate dehydrogenase kinase activity. It was observed that palmityl-CoA but not octanoyl-CoA strongly inhibited the activity of the extracted pyruvate dehydrogenase. Hence, it is concluded that (a) decreased mitochondrial CoASH levels, which essentially remove a potent inhibitor of the pyruvate dehydrogenase kinase, (b) possibly a diminished free CoASH supply, which may be utilized as a substrate for the active complex, and (c) direct inhibitory effects of palmityl-CoA on the active form of the pyruvate dehydrogenase complex combine to make palmitylcarnitine a much more potent inhibitor of mitochondrial pyruvate oxidation than shorter chain length acylcarnitine derivatives.     

The connection between ionophore-mediated Ca2+-movements and intermediary metabolism in human red cells. II. Site and mode of glycolytic activation during Ca2+-loading

Human red cells (RBC) respond to moderate Ca²⁺-loading with increased ATP consumption and stimulation of glycolytic flux. 1. Ca²⁺-induced metabolite transitions at different pH-values showed a clearcut crossover at the glyceraldehyde-3-phosphate dehydrogenase/3-phosphoglycerate kinase ($\text{GAPDH}\text{PGK}\text{)-steps}$. 2. The behavior of glycolytic metabolites in iodoacetate-treated, GAPDH-inhibited, and in phosphoenolpyruvate-loaded RBC ruled out activation of hexokinase, phosphofructokinase and pyruvate kinase. 3. Glycolytic stimulation is linked to Ca²⁺-extrusion rate and not to the loaded Ca²⁺. 4. Adenine nucleotides and inorganic phosphate could be ruled out as the connecting link between glycolytic activation and Ca²⁺-extrusion. 5. NADH oxidation was observed at all pH-values studied when the RBC were incubated either at low or high extracellular potassium. NADH is product-inhibitor of GAPDH. The concentration (34 μM) of thermodynamically free NADH calculated from the $\text{GAPDH}\text{PGK}$ equilibrium reactants was in the inhibitory range: any decrease in NADH is therefore followed by activation of GAPDH. $\text{NAD}\text{NADH}$ ratio seems to be the connecting link between ATP consuming ion transport and ATP generation by glycolysis.     

On the role of superoxide in reactions catalyzed by rubredoxin of Pseudomonas oleovorans

In the presence of NADH, and the reductase and rubredoxin components of the ω-hydroxylation system of $\text{Pseudomonas oleovorans}$, epinephrine is oxidized to adrenochrome at pH 7.8, and the reaction is strongly inhibited by the addition of superoxide dismutase (SDM). Boiled SDM has no effect on the reaction rate. The oxidation reaction is oxygen-dependent, and approximately 1 mole of H₂O₂ is produced per mole of O₂ consumed. The stoichiometry between NADH oxidation and adrenochrome formation is approximately 2:1. Epoxidation and epinephrine oxidation are mutually competitive reactions, despite the fact that the epoxidation reaction is not stimulated by a superoxide generating system nor inhibited by SDM.     

pH profiles of proline transport with membrane vesicles from Mycobacterium phlei with artificial and natural electron donors

Proline transport and rates of oxidation with artifical and natural electron donors were examined with membrane vesicles from $\text{M.}$$\text{phlei}$ as a function of pH. The levels of transport and rates of oxidation were parallel with generated NADH as substrate. With ascorbate-TPD, both the rate and level of transport increased from pH 7.5 to 9.0. The rate of total oxygen consumption with ascorbate-TPD correlated with the transport studies. However, when oxygen consumption was corrected for the auto-oxidation of ascorbate-TPD, the corrected oxygen consumption did not correlate with transport. Rates of cytochrome reduction were examined with ascorbate-TPD as electron donors to determine respiratory chain oxidation. For cytochromes c and a + a₃, the rates of reduction decreased as a function of pH, while active transport of proline increased.     

Immunochemical study on the participation of cytochrome b5 in drug oxidation reactions of mouse liver microsomes.

Highly purified divalent and monovalent antibodies against cytochrome $\text{b}{}_5$, anti-$\text{b}{}_5$ immunoglobulin G (IG) and anti-$\text{b}{}_5$ Fab', were used in elucidating the role of this cytochrome in the drug-oxidizing enzyme system of mouse liver microsomes. Anti-$\text{b}{}_5$ IG strongly inhibited not only NADH-supported but also NADPH-supported oxidation of 7-ethoxycoumarin and benzo(a)pyrene, but had no inhibitory action on the oxidation of aniline. Anti-$\text{b}{}_5$ Fab' also inhibited NADH-supported and NADPH-supported benzo(a)pyrene hydroxylation. These observations indicate an essential role of cytochrome $\text{b}{}_5$ in the transfer of electrons not only from NADH but also from NADPH to cytochrome P-450 in the microsomal oxidation of some drugs, but not of aniline.     

Effects of ethanol-derived acetaldehyde on the phosphorylation potential and on the intramitochondrial redox state in intact rat liver

The role of acetaldehyde (AcH) in the ethanol-induced shift toward reduction of the cytosolic and mitochondrial free NAD⁺/free NADH ratios and its effect on the phosphorylation potential was investigated in livers of fed, intact rats given ethanol (1 g/kg ip). Calcium cyanamide, an inhibitor of mitochondrial aldehyde dehydrogenase, was administered to block predominantly intramitochondrial NADH production from AcH oxidation. Compared with ethanol alone, cyanamide almost totally reversed the elevation of the β-OH-butyrate/acetoacetate ratio but only slightly reduced the lactate/ pyruvate ratio, which was calculated to be in near equilibrium with the hepatic ethanol/ AcH ratio after cyanamide. Ethanol or cyanamide alone had no effect on ATP, ADP, or P_i, but together they significantly decreased the $\text{ATP}\text{ADP}\text{· P}{}_{\mathrm{<mtext>i</mtext>}}$ ratio by increasing both ADP and P_i levels. No association between changes in the phosphorylation potential and the redox states was, however, observed. An ethanol-induced increase in AMP was abolished by cyanamide. The results demonstrate that the effect of ethanol on the mitochondrial redox state requires active AcH oxidation and suggest that moderate AcH accumulation likely to occur during alcohol-aversive drug treatment significantly lowers the cellular phosphorylation potential.     

The effects of mefloquine on Escherichia coli.

Mefloquine, a quinoline-4-methanol antimalarial drug, also possesses bactericidal activity. Mefloquine causes rapid loss of bacterial viability, cell and spheroplast lysis, cessation of macromolecular synthesis, release of macromolecular constituents, and inhibition of the oxidation of NADH by isolated $\text{E. coli}$ membranes. Results are consistent with the hypothesis that mefloquine is a membrane-active drug.     

On the mechanism of the glucagon-induced inhibition of hepatic protein synthesis.

The intraperitoneal administration of glucagon (200 μg) to rats produced a transient increase of the hepatic polypeptide chain completion time, the increase being maximum at 5 min returning to control values at 20 min. This inhibitory effect was sustained when glucagon was constantly supplied by continuous infusion. Postmitochondrial supernatants from livers of the control group or rats treated with glucagon for 5 min showed no difference in their protein synthetic activity. After 20 min of intraperitoneal administration of the hormone, that is, when the effect on protein synthesis had vanished, the levels of cAMP were still 40% above those of the control group, and the ribosomal proteins were 110% more phosphorylated. These results suggest that the observed effect of glucagon is not due to its direct action on the protein synthesis machinery. On the other hand, the variations in the hepatic amino acid content brought about by glucagon do not appear to be quantitatively significant to account for the observed inhibition of protein synthesis. The effect of glucagon was always paralleled by a decrease in the $\text{[ATP]}\text{[ADP]}$ ratio which may be responsible for the observed decrease in the rates of elongation and/or termination steps of protein synthesis. Glucagon also produced a rise in the $\text{[NADH]}\text{[NAD}{}^{\mathrm{+}}\text{]}$ ratio in both cellular compartments, cytosol and mitochondria, as reflected by the rise in the lactate to pyruvate and the β-hydroxybutyrate to acetoacetate ratios. This shift of the NAD⁺ couple to a more reduced state seems to be the result of an increased mobilization and oxidation of fatty acids brought about by the hormone. It is postulated then that the primary effect of glucagon leading to a decrease in protein synthesis is probably to increase the state of reduction of the hepatic nicotinamide nucleotide system. This point of view is supported by the fact that the nicotinamide and adenine nucleotide systems in rat liver are in equilibrium through cytosolic equilibrium reactions, so that a decrease in the $\text{[ATP]}\text{[ADP]}$ ratio brought about by glucagon may be secondary to the increase in the $\text{[NADH]}\text{[NAD}{}^{\mathrm{+}}\text{]}$ ratio. This hypothesis is supported by the fact that glucagon was not effective in inhibiting hepatic protein synthesis in rats pretreated with a drug, 2-benzene-sulfonamido-5-(β-methoxy-ethoxy)pyrimidine, that prevents fatty acid mobilization and the subsequent changes in the $\text{[NADH]}\text{[NAD}{}^{\mathrm{+}}\text{]}$ and $\text{[ATP]}\text{[ADP]}$ ratios. Furthermore, the administration of exogenous fatty acid brings about an inhibition of the rate of hepatic protein synthesis accompanied by a decrease in the ATP levels and an increase in the state of reduction of the NAD⁺ system.     

A shuttle system for the transfer of reducing equivalents in mouse sperm mitochondria.

Studies have been carried out on an $\text{in vitro}$ reconstituted system composed of mouse lactate dehydrogenase isozyme X or C4, branched chain amino acid aminotransferase, NAD, alpha-hydroxy isocaproate, glutamate and mouse sperm mitochondria. This system demonstrated capacity for the oxidation of extramitochondrial NADH. It is proposed that a branched chain alpha-hydroxyacid / amino acid shuttle for the transfer of reducing equivalents from cytosol to mitochondria may be functional in mouse spermatozoa.     

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.     

A proline shuttle in insect flight muscle.

A proline shuttle for oxidation of extramitochondrial NADH was reconstituted from soluble and mitochondrial fractions of blowfly ($\text{Phormia}$$\text{regina}$) flight muscle. The soluble fraction catalyzed reduction of Δ′-pyrroline-5-carboxylate to proline via the action of Δ′-pyrroline-5-carboxylate reductase (EC 1.5.1.2). The reaction required NADH as hydrogen donor, NAD (P) H being ineffective in this regard. Mitochondria catalyzed regeneration of Δ′-pyrroline-5-carboxylate from proline via action of proline oxidase. The capacity of the shuttle to operate under conditions of possible competition for Δ′-pyrroline-5-carboxylate between Δ′-pyrroline-5-carboxylate reductase and Δ′-pyrroline-5-carboxylate dehydrogenase (EC 1.5.1.12) was incestigated. Results of these investigations indicate that dehydrogenase activity does not significantly interfere with shuttle activity.     

Compartmentation of cytosolic dehydrogenases studied by transfer of tritium from labelled substrates into lactate in rat hepatocytes

This paper describes the transfer of tritium from [2-³H]xylitol or (1R)-[1-³H]ethanol into lactate in cells from fed rats either untreated or triiodothyronine-treated. The labelling pattern of lactate during the metabolism of [2-³H]xylitol or (1R)-[1-³H]ethanol follows the equation $\text{L = K(1?e}{}^{\mathrm{<mtext>?</mtext><mtext>t</mtext><mtext>\tau </mtext>}}\text{)}$ (μmol tritium/μmol lactate). The yield in lactate together with the minimum value of the total flux of reducing equivalents are used to estimate the specific radioactivity of NADH. We have calculated the lactate dehydrogenase-catalysed oxidation rate of NADH from the experimental values of lactate labelling and the specific radioactivity of NADH. We found the calculated flux of reducing equivalents from NADH to pyruvate to be of the same order of magnitude whether labelled ethanol or labelled xylitol was metabolized. We found the flux to be only a few percent of the maximal activity of lactate dehydrogenase. The results obtained suggest that the cytoplasm can be regarded as one compartment, containing a single pool of NAD(H).     

Cobalt cytochrome c: enzymic assays.

An improved synthesis for cobalt-cytochrome $\text{c}$ has been developed; its half reduction potential is ?140 ± 20mV. Reduced ^Cocyt-$\text{c}$³ is oxidized by bovine heart cytochrome $\text{c}$ oxidase at a rate ～45% that of the native cytochrome $\text{c}$. It is not reduced by mitochondrial NADH or succinate cytochrome $\text{c}$ reductase nor by microsomal NADH or NADPH cytochrome $\text{c}$ reductase.     

H2 metabolism in photosynthetic organisms. II. Light-dependent H2 evolution by preparations from Chlamydomonas, Scenedesmus and spinach.

Light-dependent H₂ evolution from dithiothreitol as electron donor was observed with cell-free preparations of anaerobically adapted $\text{Chlamydomonas reinhardii, Scenedesmus obliquus}$ and from spinach chloroplasts mixed with $\text{Chlamydomonas}$ hydrogenase. NADH substituted for dithiothreitol as electron donor only in the $\text{Chlarmydomonas}$ preparation. Dibromothymoquinone, an antagonist of plastoquinone, selectively inhibited H₂ photoevolution from NADH. These results are interpreted as indicating that 3-(3,4-dichlorophenyl)-1,1-dimethyl urea insensitive H₂ photoevolution by algae containing hydrogenase is due to the capability of NADH to reduce plastoquinone in the electron transport chain, and to evolve H₂ by a low redox potential carrier of photosystem I.     

The involvement of cytochrome P-450 in the NADH-dependent O-demethylation of p-nitroanisole in phenobarbital-treated rabbit liver microsomes.

Addition of $\text{p}$-nitroanisole to a reaction mixture containing phenobarbital-pretreated rabbit liver microsomes brings about an increase the reoxidation rate of NADH-reduced cytochrome b₅. Addition of partially purified cytochrome b₅ to a solution containing microsomes results in a marked increase in both NADH- and NADPH-dependent O-demethylation of $\text{p}$-nitroanisole. $\text{p}$-Nitroanisole also increases the rate of NADH mediated cytochrome P-450 reduction. From these and other results described in the Discussion section, we confirm that electrons required for NADH-dependent O-demethylation of $\text{p}$-nitroanisole is transfered from NADH to cytochrome P-450 via cytochrome b₅ and that cytochrome P-450 is the enzyme which catalyzes $\text{p}$-nitroanisole O-demethylation.     

Reactivity of an FAD-dependent oxygenase with free flavins: a new mode of uncoupling in flavoprotein oxygenases.

Conversion of 2-methyl-3-hydroxypyridine-5-carboxylic acid (Cpd I) to α-(N-acetylaminomethylene)succinic acid (Cpd A) is catalyzed by an FAD protein, Cpd I oxygenase (Sparrow, et al., J. Biol. Chem. [1969] $\text{244}$, 2590–2600) according to the equation: Cpd I + O₂ + NADH + H⁺ → Cpd A + NAD⁺. When free FAD, FMN or riboflavin is added to reaction mixtures, oxidation of NADH remains dependent on presence of oxygenase and Cpd I, but is partially uncoupled from the oxygenation of Cpd I. Under these conditions, free reduced flavins appear in solution, as shown by their ability to reduce cytochrome c. These effects are not due to an increased rate of NADH oxidation. Such uncoupling may lead to appearance of artifactual species of activated oxygen or flavin that play no intermediate role in the oxygenase reaction.