Regulation of fatty acid beta-oxidation in rat heart mitochondria

In an attempt to elucidate the mechanism by which the rate of fatty acid oxidation is tuned to the energy demand of the heart, the effects of changing intramitochondrial ratios of [acetyl-CoA]/[CoASH] and [NADH]/[NAD+] on the rate of beta-oxidation were studied. When 10 mM L-carnitine was added to coupled rat heart mitochondria to lower the ratio of [acetyl-CoA]/[CoASH], the rate of palmitoylcarnitine beta-oxidation, as measured by the formation of acid-soluble products, was stimulated more than fourfold at state 4 respiration while beta-oxidation at state 3 respiration was hardly affected. Neither oxaloacetate nor acetoacetate, added to mitochondria to lower the [NADH]/[NAD+] ratio, stimulated beta-oxidation. Rates of respiration at states 3 and 4 were unchanged by additions of L-carnitine, oxaloacetate, or acetoacetate. Determinations of intramitochondrial ratios of [acetyl-CoA]/[CoASH] by high performance liquid chromatography yielded values close to 10 for palmitoylcarnitine-supported respiration at state 4 and 2.5 at state 3 respiration. Addition of 10 mM L-carnitine caused a dramatic decrease of these ratios to less than 0.2 at both respiration states. Studies with purified or partially purified enzymes revealed strong inhibitions of 3-ketoacyl-CoA thiolase by acetyl-CoA and of L-3-hydroxyacyl-CoA dehydrogenase by NADH. Moreover, the activity of 3-ketoacyl-CoA thiolase at concentrations of acetyl-CoA and CoASH prevailing at state 3 respiration was 4 times higher than its activity in the presence of acetyl-CoA and CoASH observed at state 4. Altogether, this study leads to the conclusion that the rate of beta-oxidation in heart can be regulated by the intramitochondrial ratio of [acetyl-CoA]/[CoASH] which reflects the energy demand of the tissue. The thiolytic cleavage catalyzed by 3-ketoacyl-CoA thiolase may be the site at which beta-oxidation is controlled by the [acetyl-CoA]/[CoASH] ratio.     

Control of mitochondrial beta-oxidation flux

The control of mitochondrial beta-oxidation, including the delivery of acyl moieties from the plasma membrane to the mitochondrion, is reviewed. Control of beta-oxidation flux appears to be largely at the level of entry of acyl groups to mitochondria, but is also dependent on substrate supply. CPTI has much of the control of hepatic beta-oxidation flux, and probably exerts high control in intact muscle because of the high concentration of malonyl-CoA in vivo. beta-Oxidation flux can also be controlled by the redox state of NAD/NADH and ETF/ETFH(2). Control by [acetyl-CoA]/[CoASH] may also be significant, but it is probably via export of acyl groups by carnitine acylcarnitine translocase and CPT II rather than via accumulation of 3-ketoacyl-CoA esters. The sharing of control between CPTI and other enzymes allows for flexible regulation of metabolism and the ability to rapidly adapt beta-oxidation flux to differing requirements in different tissues.     

The redox state of free nicotinamide-adenine dinucleotide in the cytoplasm and mitochondria of rat liver

1. The concentrations of the oxidized and reduced substrates of the lactate-, beta-hydroxybutyrate- and glutamate-dehydrogenase systems were measured in rat livers freeze-clamped as soon as possible after death. The substrates of these dehydrogenases are likely to be in equilibrium with free NAD(+) and NADH, and the ratio of the free dinucleotides can be calculated from the measured concentrations of the substrates and the equilibrium constants (Holzer, Schultz & Lynen, 1956; Bücher & Klingenberg, 1958). The lactate-dehydrogenase system reflects the [NAD(+)]/[NADH] ratio in the cytoplasm, the beta-hydroxybutyrate dehydrogenase that in the mitochondrial cristae and the glutamate dehydrogenase that in the mitochondrial matrix. 2. The equilibrium constants of lactate dehydrogenase (EC 1.1.1.27), beta-hydroxybutyrate dehydrogenase (EC 1.1.1.30) and malate dehydrogenase (EC 1.1.1.37) were redetermined for near-physiological conditions (38 degrees ; I0.25). 3. The mean [NAD(+)]/[NADH] ratio of rat-liver cytoplasm was calculated as 725 (pH7.0) in well-fed rats, 528 in starved rats and 208 in alloxan-diabetic rats. 4. The [NAD(+)]/[NADH] ratio for the mitochondrial matrix and cristae gave virtually identical values in the same metabolic state. This indicates that beta-hydroxybutyrate dehydrogenase and glutamate dehydrogenase share a common pool of dinucleotide. 5. The mean [NAD(+)]/[NADH] ratio within the liver mitochondria of well-fed rats was about 8. It fell to about 5 in starvation and rose to about 10 in alloxan-diabetes. 6. The [NAD(+)]/[NADH] ratios of cytoplasm and mitochondria are thus greatly different and do not necessarily move in parallel when the metabolic state of the liver changes. 7. The ratios found for the free dinucleotides differ greatly from those recorded for the total dinucleotides because much more NADH than NAD(+) is protein-bound. 8. The bearing of these findings on various problems, including the following, is discussed: the number of NAD(+)-NADH pools in liver cells; the applicability of the method to tissues other than liver; the transhydrogenase activity of glutamate dehydrogenase; the physiological significance of the difference of the redox states of mitochondria and cytoplasm; aspects of the regulation of the redox state of cell compartments; the steady-state concentration of mitochondrial oxaloacetate; the relations between the redox state of cell compartments and ketosis.     

Intermediates of peroxisomal beta-oxidation of [U-14C]hexadecanedionoate. A study of the acyl-CoA esters which accumulate during peroxisomal beta-oxidation of [U-14C]hexadecanedionate and [U-14C]hexadecanedionoyl-mono-CoA.

1. The oxidation of [U-14C]hexadecanedionoyl-mono-CoA was stimulated by CoA, by carnitine in the absence of CoA and by the presence of an NAD(+)-regenerating system. 2. Substrate inhibition was observed with respect to [U-14C]hexadecanedionoyl-mono-CoA at concentrations greater than 35 microM. 3. Acetyl-CoA and the dicarboxyl-CoA esters of chain length C6-16 were detected by HPLC under standard incubation conditions. 4. In the absence of the NAD(+)-regenerating system, 2-enoyl-CoA and 3-hydroxacyl-CoA esters were detected. 5. In general, the peroxisomal beta-oxidation of dicarboxylates is very similar to that of monocarboxylates [Bartlett, K., Hovik, R., Eaton, S., Watmough, N. J. & Osmundsen, H. (1990) Biochem. J. 270, 175-180] except that chain shortening does not proceed beyond C6. 6. We conclude that the peroxisomal beta-oxidation of dicarboxylates is regulated by the redox state of the peroxisomal matrix and CoA availability.     

Imaging cytosolic NADH-NAD(+) redox state with a genetically encoded fluorescent biosensor

NADH is a key metabolic cofactor whose sensitive and specific detection in the cytosol of live cells has been difficult. We constructed a fluorescent biosensor of the cytosolic NADH-NAD(+) redox state by combining a circularly permuted GFP T-Sapphire with a bacterial NADH-binding protein, Rex. Although the initial construct reported [NADH] × [H(+)] / [NAD(+)], its pH sensitivity was eliminated by mutagenesis. The engineered biosensor Peredox reports cytosolic NADH:NAD(+) ratios and can be calibrated with exogenous lactate and pyruvate. We demonstrated its utility in several cultured and primary cell types. We found that glycolysis opposed the lactate dehydrogenase equilibrium to produce a reduced cytosolic NADH-NAD(+) redox state. We also observed different redox states in primary mouse astrocytes and neurons, consistent with hypothesized metabolic differences. Furthermore, using high-content image analysis, we monitored NADH responses to PI3K pathway inhibition in hundreds of live cells. As an NADH reporter, Peredox should enable better understanding of bioenergetics.     

Evidence for two sites of superoxide production by mitochondrial NADH-ubiquinone oxidoreductase (complex I)

Complex I (NADH-ubiquinone oxidoreductase) can form superoxide during forward electron flow (NADH-oxidizing) or, at sufficiently high protonmotive force, during reverse electron transport from the ubiquinone (Q) pool (NAD(+)-reducing). We designed an assay system to allow titration of the redox state of the superoxide-generating site during reverse electron transport in rat skeletal muscle mitochondria: a protonmotive force generated by ATP hydrolysis, succinate:malonate to alter electron supply and modulate the redox state of the Q pool, and inhibition of complex III to prevent QH(2) oxidation via the Q cycle. Stepwise oxidation of the QH(2)/Q pool by increasing malonate concentration slowed the rates of both reverse electron transport and rotenone-sensitive superoxide production by complex I. However, the superoxide production rate was not uniquely related to the resultant potential of the NADH/NAD(+) redox couple. Thus, there is a superoxide producer during reverse electron transport at complex I that responds to Q pool redox state and is not in equilibrium with the NAD reduction state. In contrast, superoxide production during forward electron transport in the presence of rotenone was uniquely related to NAD redox state. These results support a two-site model of complex I superoxide production; one site in equilibrium with the NAD pool, presumably the flavin of the FMN moiety (site I(F)) and the other dependent not only on NAD redox state, but also on protonmotive force and the reduction state of the Q pool, presumably a semiquinone in the Q-binding site (site I(Q)).     

Thiol redox and phosphate transport in renal brush-border membrane. Effect of nicotinamide

In the present study, the effect of thiol redox and its possible role in the inhibitory effect of nicotinamide on renal brush-border membrane (BBM) phosphate uptake was examined. Addition of thiol reducing agent, dithiothreitol (DTT, 5 mM), caused an increase, while addition of thiol oxidant, diamide (DM, 5 mM) caused a reversible decrease in sodium-dependent BBM phosphate uptake. Kinetic analyses revealed an increase in both Vmax and Km by DTT, and a decrease in Vmax by DM. These results suggest that thiol redox influences BBM phosphate uptake with sulfhydryl (SH) groups relate to its capacity and disulfide (SS) groups to its affinity for phosphate. Since changes in cytosolic NAD levels may affect BBM thiol redox through changes in redox states of NADP and glutathione systems, we have examined such possibility by studying the effect of nicotinamide (NM). Incubation of proximal tubules with NM (10 mM) induced an oxidative effect on redox states of cytosolic NAD, NADP systems as inferred from decreased cellular lactate/pyruvate, malate/pyruvate, respectively. Measurements of cytosolic glutathiones and BBM thiols also revealed that NM pretreatment shifted the cytosolic glutathione redox (GSH/GSSG) and BBM thiol redox (SH/SS) toward more oxidized state. On the other hand, incubation of proximal tubules with NM suppressed phosphate uptake by the subsequently isolated BBM vesicles. The lower phosphate uptake by NM-pretreated BBM vesicles was reversed by DTT and was resistant to the inhibitory effect of DM. These results thus suggest that BBM thiol oxidation may be involved in the inhibitory effect of NM on BBM phosphate uptake.     

Studies on the peroxisomal oxidation of palmitate and lignocerate in rat liver

We have investigated the pathways involved in the peroxisomal oxidation of palmitate and lignocerate, measured as the cyanide-insensitive formation of acetyl units, in rat-liver homogenates. The peroxisomal beta-oxidation of both fatty acids is dependent on the presence of ATP, coenzyme A, NAD+ and Mg2+. However, there is a striking difference in the dependence of the rate of oxidation of the two substrates on the concentration of the individual cofactors, especially ATP. The peroxisomal beta-oxidation of lignocerate was inhibited to a progressively greater extent by increasing concentrations of palmitate and vice versa. Activation of lignoceric acid to lignoceroyl-CoA, however, was not inhibited by increasing concentrations of palmitate, and vice versa. It can be concluded that the peroxisomal palmitate and lignocerate beta-oxidation pathways differ in at least one enzymic reaction (the synthetase), but that the two pathways share at least one common step.     

The redox switch/redox coupling hypothesis

We provide an integrative interpretation of neuroglial metabolic coupling including the presence of subcellular compartmentation of pyruvate and monocarboxylate recycling through the plasma membrane of both neurons and glial cells. The subcellular compartmentation of pyruvate allows neurons and astrocytes to select between glucose and lactate as alternative substrates, depending on their relative extracellular concentration and the operation of a redox switch. This mechanism is based on the inhibition of glycolysis at the level of glyceraldehyde 3-phosphate dehydrogenase by NAD(+) limitation, under sufficiently reduced cytosolic NAD(+)/NADH redox conditions. Lactate and pyruvate recycling through the plasma membrane allows the return to the extracellular medium of cytosolic monocarboxylates enabling their transcellular, reversible, exchange between neurons and astrocytes. Together, intracellular pyruvate compartmentation and monocarboxylate recycling result in an effective transcellular coupling between the cytosolic NAD(+)/NADH redox states of both neurons and glial cells. Following glutamatergic neurotransmission, increased glutamate uptake by the astrocytes is proposed to augment glycolysis and tricarboxylic acid cycle activity, balancing to a reduced cytosolic NAD(+)/NADH in the glia. Reducing equivalents are transferred then to the neuron resulting in a reduced neuronal NAD(+)/NADH redox state. This may eventually switch off neuronal glycolysis, favoring the oxidation of extracellular lactate in the lactate dehydrogenase (LDH) equilibrium and in the neuronal tricarboxylic acid cycles. Finally, pyruvate derived from neuronal lactate oxidation, may return to the extracellular space and to the astrocyte, restoring the basal redox state and beginning a new loop of the lactate/pyruvate transcellular coupling cycle. Transcellular redox coupling operates through the plasma membrane transporters of monocarboxylates, similarly to the intracellular redox shuttles coupling the cytosolic and mitochondrial redox states through the transporters of the inner mitochondrial membrane. Finally, transcellular redox coupling mechanisms may couple glycolytic and oxidative zones in other heterogeneous tissues including muscle and tumors.     

Regulation of cyclic photophosphorylation in Rhodospirillum rubrum by the redox state of nicotinamide-adenine dinucleotide.

We have investigated the effect of the redox state of added NAD on the rates of anaerobic cyclic photophosphorylation which are supported by membrane vesicles isolated from Rhodospirillum rubrum. As the redox potential of NAD was lowered, the activity decreased according to a typical potentiometric titration. The Nernst plot showed an apparent midpoint potential (E'o) of -350 mV and had a slope which corresponded to a two-electron transition. Besides, an almost identical potentiometric relationship was found to exist between the extent of light-elicited ATP formation in anaerobic suspensions of intact R. rubrum cells and the redox potential of intracellular NAD. These results suggest that physiological photophosphorylation in R. rubrum requires the oxidized form of a membrane-bound constituent (E'o = -350 mV) whose redox state is controlled by the redox state of cytoplasmic NAD.     

A plate reader method for the measurement of NAD, NADP, glutathione, and ascorbate in tissue extracts: Application to redox profiling during Arabidopsis rosette development

Glutathione, NAD, and NADP are key nonprotein redox couples in the aqueous phase of virtually all cells, whereas in plant cells ascorbate also plays an important role in redox homeostasis. This work presents the development and validation of plate reader assays that allow rapid analysis of these four redox couples in extracts of Arabidopsis leaves. Analytical methods were adapted and validated for specific measurement of oxidized and reduced forms. Oxidized and reduced forms of glutathione and ascorbate, as well as NAD(+) and NADP(+), were measured in HCl extracts, NADH, and NADPH in parallel alkaline extracts. Both standards and extracts gave linear assay responses, and recovery quotients of added metabolites through the extraction procedure were generally high. The plate reader method was validated against more conventional spectrophotometric assays and also, for glutathione, by HPLC analysis. The method was shown to yield quantitative data for six independent extracts with a total sample preparation and analysis time of 4h. Analysis of the four redox couples throughout Arabidopsis rosette development showed that redox states were relatively constant but that total pools of NAD, glutathione, and ascorbate were significantly modified by day length and developmental stage.     

NADH/NAD redox state of cytoplasmic glycolytic compartments in vascular smooth muscle

The cytoplasmic NADH/NAD redox potential affects energy metabolism and contractile reactivity of vascular smooth muscle. NADH/NAD redox state in the cytosol is predominately determined by glycolysis, which in smooth muscle is separated into two functionally independent cytoplasmic compartments, one of which fuels the activity of Na(+)-K(+)-ATPase. We examined the effect of varying the glycolytic compartments on cystosolic NADH/NAD redox state. Inhibition of Na(+)-K(+)-ATPase by 10 microM ouabain resulted in decreased glycolysis and lactate production. Despite this, intracellular concentrations of the glycolytic metabolite redox couples of lactate/pyruvate and glycerol-3-phosphate/dihydroxyacetone phosphate (thus NADH/NAD) and the cytoplasmic redox state were unchanged. The constant concentration of the metabolite redox couples and redox potential was attributed to 1) decreased efflux of lactate and pyruvate due to decreased activity of monocarboxylate B-H(+) transporter secondary to decreased availability of H(+) for cotransport and 2) increased uptake of lactate (and perhaps pyruvate) from the extracellular space, probably mediated by the monocarboxylate-H(+) transporter, which was specifically linked to reduced activity of Na(+)-K(+)-ATPase. We concluded that redox potentials of the two glycolytic compartments of the cytosol maintain equilibrium and that the cytoplasmic NADH/NAD redox potential remains constant in the steady state despite varying glycolytic flux in the cytosolic compartment for Na(+)-K(+)-ATPase.     

Role of NADH/NAD+ transport activity and glycogen store on skeletal muscle energy metabolism during exercise: in silico studies

Skeletal muscle can maintain ATP concentration constant during the transition from rest to exercise, whereas metabolic reaction rates may increase substantially. Among the key regulatory factors of skeletal muscle energy metabolism during exercise, the dynamics of cytosolic and mitochondrial NADH and NAD+ have not been characterized. To quantify these regulatory factors, we have developed a physiologically based computational model of skeletal muscle energy metabolism. This model integrates transport and reaction fluxes in distinct capillary, cytosolic, and mitochondrial domains and investigates the roles of mitochondrial NADH/NAD+ transport (shuttling) activity and muscle glycogen concentration (stores) during moderate intensity exercise (60% maximal O2 consumption). The underlying hypothesis is that the cytosolic redox state (NADH/NAD+) is much more sensitive to a metabolic disturbance in contracting skeletal muscle than the mitochondrial redox state. This hypothesis was tested by simulating the dynamic metabolic responses of skeletal muscle to exercise while altering the transport rate of reducing equivalents (NADH and NAD+) between cytosol and mitochondria and muscle glycogen stores. Simulations with optimal parameter estimates showed good agreement with the available experimental data from muscle biopsies in human subjects. Compared with these simulations, a 20% increase (or approximately 20% decrease) in mitochondrial NADH/NAD+ shuttling activity led to an approximately 70% decrease (or approximately 3-fold increase) in cytosolic redox state and an approximately 35% decrease (or approximately 25% increase) in muscle lactate level. Doubling (or halving) muscle glycogen concentration resulted in an approximately 50% increase (or approximately 35% decrease) in cytosolic redox state and an approximately 30% increase (or approximately 25% decrease) in muscle lactate concentration. In both cases, changes in mitochondrial redox state were minimal. In conclusion, the model simulations of exercise response are consistent with the hypothesis that mitochondrial NADH/NAD+ shuttling activity and muscle glycogen stores affect primarily the cytosolic redox state. Furthermore, muscle lactate production is regulated primarily by the cytosolic redox state.     

Peroxisomal membrane monocarboxylate transporters: evidence for a redox shuttle system?

One of the many functions of liver peroxisomes is the beta-oxidation of long-chain fatty acids. It is essential for the continuation of peroxisomal beta-oxidation that a redox shuttle system exist across the peroxisomal membrane to reoxidize NADH. We propose that this redox shuttle system consists of a substrate cycle between lactate and pyruvate. Here we present evidence that purified peroxisomal membranes contain both monocarboxylate transporter 1 (MCT 1) and MCT 2 and that along with peroxisomal lactate dehydrogenase (pLDH) form a Peroxisomal Lactate Shuttle. Peroxisomal beta-oxidation was greatly stimulated by the addition of pyruvate and this increase was partially inhibited by the addition of the MCT blocker alpha-cyano-4-hydroxycinnamate (CINN). We also found that peroxisomes generated lactate in the presence of pyruvate. Together these data provide compelling that the Peroxisome Lactate Shuttle helps maintain organelle redox and the proper functioning of peroxisomal beta-oxidation.     

Regulation of brain mitochondrial H2O2 production by membrane potential and NAD(P)H redox state

Mitochondrial production of reactive oxygen species (ROS) at Complex I of the electron transport chain is implicated in the etiology of neural cell death in acute and chronic neurodegenerative disorders. However, little is known regarding the regulation of mitochondrial ROS production by NADH-linked respiratory substrates under physiologically realistic conditions in the absence of respiratory chain inhibitors. This study used Amplex Red fluorescence measurements of H2O2 to test the hypothesis that ROS production by isolated brain mitochondria is regulated by membrane potential (DeltaPsi) and NAD(P)H redox state. DeltaPsi was monitored by following the medium concentration of the lipophilic cation tetraphenylphosphonium with a selective electrode. NAD(P)H autofluorescence was used to monitor NAD(P)H redox state. While the rate of H2O2 production was closely related to DeltaPsi and the level of NAD(P)H reduction at high values of DeltaPsi, 30% of the maximal rate of H2O2 formation was still observed in the presence of uncoupler (p-trifluoromethoxycarbonylcyanide phenylhydrazone) concentrations that provided for maximum depolarization of DeltaPsi and oxidation of NAD(P)H. Our findings indicate that ROS production by mitochondria oxidizing physiological NADH-dependent substrates is regulated by DeltaPsi and by the NAD(P)H redox state over ranges consistent with those that exist at different levels of cellular energy demand.     

Association and redox properties of the putidaredoxin reductase-nicotinamide adenine dinucleotide complex

Putidaredoxin reductase (PdR) is the flavin protein that carries out the first electron transfer involved in the cytochrome P450cam catalytic cycle. In PdR, the flavin adenine dinucleotide (FAD/FADH2) redox center acts as a transformer by accepting two electrons from soluble nicotinamide adenine dinucleotide (NAD+/NADH) and donating them in two separate, one-electron-transfer steps to the iron-sulfur protein putidaredoxin (Pdx). PdR, like the two more intensively studied monoflavin reductases, adrenodoxin reductase (AdR) and ferredoxin-NADP+ reductase (FNR), has no other active redox moieties (e.g., sulfhydryl groups) and can exist in three different oxidation states: (i) oxidized quinone, (ii) one-electron reduced semiquinone (stable neutral species (blue) or unstable radical anion (red)), and (iii) two-electron fully reduced hydroquinone. Here, we present reduction potential measurements for PdR in support of a thermodynamic model for the modulation of equilibria among the redox components in this initial electron-transfer step of the P450 cycle. A spectroelectrochemical technique was used to measure the midpoint oxidation-reduction potential of PdR that had been carefully purified of all residual NAD+, E0' = -369 +/- 10 mV at pH 7.6, which is more negative than previously reported and more negative than the pyridine nucleotide NADH/NAD+ (-330 mV). After addition of NAD+, the formation of the oxidized reductase-oxidized pyridine nucleotide complex was followed by the two-electron-transfer redox reaction, PdRox:NAD+ + 2e- --> PdRrd:NAD+, when the electrode potential was lowered. The midpoint potential was a hyperbolic function of increasing NAD+ concentration, such that at concentrations of pyridine nucleotide typically found in an intracellular environment, the midpoint potential would be E0' = -230 +/- 10 mV, thereby providing the thermodynamically favorable redox equilibria that enables electron transfer from NADH. This thermodynamic control of electron transfer is a shared mechanistic feature with the adrenodoxin P450 and photosynthetic electron-transfer systems but is different from the kinetic control mechanisms in the microsomal P450 systems where multiple reaction pathways draw on reducing power held by NADPH-cytochrome P450 reductase. The redox measurements were combined with protein fluorescence quenching of NAD+ binding to oxidized PdR to establish that the PdRox:NAD+ complex (KD = 230 microM) is about 5 orders of magnitude weaker than PdRrd:NAD+ binding. These results are integrated with known structural and kinetic information for PdR, as well as for AdR and FNR, in support of a compulsory ordered pathway to describe the electron-transfer processes catalyzed by all three reductases.     

Intracellular flux analysis applied to the effect of dissolved oxygen on hybridomas

Quantitative estimates of intracellular fluxes and measurements of intracellular concentrations were used to evaluate the effect of dissolved oxygen (DO) concentration on CRL 1606 hybridoma cells in batch culture. The estimates of intracellular fluxes were generated by combining material balances with measurements of extracellular metabolite rates of change. Experiments were performed at DO levels of 60% and 1% air saturation, as well as under oxygen-limited conditions. Cell extracts were analyzed to evaluate the effect of DO on the intracellular concentrations of the glutamate dehydrogenase reactants, as well as the redox state of the pyridine nucleotides in the cytosol and mitochondria. The relationship between cell density and pyridine nucleotide redox state was also investigated. Dissolved oxygen concentration had a significant effect on nitrogen metabolism and the flux through glutamate dehydrogenase was found to reverse at low DO, favoring glutamate formation. The NAD in the cytosol and mitochondria was more reduced under low DO conditions while the cytosolic NAD was more oxidized at low DO. Cytosolic NAD was reduced at higher cell densities while the redox states of cytosolic NADP and mitochondrial NAD did not exhibit significant variation with cell density. These results point to the fundamental role of the intracellular oxidation/reduction state in cell physiology and the possibility of controlling physiological processes through modulation of the dissolved oxygen level or the oxidation/reduction potential of the culture.     

Scanning microfluorometric measurement of cell constituents. Principles of the method and its application to the determination of NAD content and redox state of XTH-2 cells in culture

The scanning of fluorescence of a cell culture along a path several milimeters long, gives a series of signals, which allow calculation of the fluorescence emitted per cell. The emission at 450 +/- 10 nm, excited at 360 nm, provides a measure of NADH (and NADPH) per cell. Combination of this method with modifications in energy metabolism, allows determination in the same sample of total NAD content, of NAD redox state, content of NAD in the mitochondria and content of NAD plus NADP in the cytoplasm. The method can be extended to measure other cellular constituents by labelling with fluorescent markers, e.g. antibodies.     

Succinate Dehydrogenase and Other Respiratory Pathways in Thylakoid Membranes of Synechocystis sp. Strain PCC 6803: Capacity Comparisons and Physiological Function

Respiration in cyanobacterial thylakoid membranes is interwoven with photosynthetic processes. We have constructed a range of mutants that are impaired in several combinations of respiratory and photosynthetic electron transport complexes and have examined the relative effects on the redox state of the plastoquinone (PQ) pool by using a quinone electrode. Succinate dehydrogenase has a major effect on the PQ redox poise, as mutants lacking this enzyme showed a much more oxidized PQ pool. Mutants lacking type I and II NAD(P)H dehydrogenases also had more oxidized PQ pools. However, in the mutant lacking type I NADPH dehydrogenase, succinate was essentially absent and effective respiratory electron donation to the PQ pool could be established after addition of 1 mM succinate. Therefore, lack of the type I NADPH dehydrogenase had an indirect effect on the PQ pool redox state. The electron donation capacity of succinate dehydrogenase was found to be an order of magnitude larger than that of type I and II NAD(P)H dehydrogenases. The reason for the oxidized PQ pool upon inactivation of type II NADH dehydrogenase may be related to the facts that the NAD pool in the cell is much smaller than that of NADP and that the NAD pool is fully reduced in the mutant without type II NADH dehydrogenase, thus causing regulatory inhibition. The results indicate that succinate dehydrogenase is the main respiratory electron transfer pathway into the PQ pool and that type I and II NAD(P)H dehydrogenases regulate the reduction level of NADP and NAD, which, in turn, affects respiratory electron flow through succinate dehydrogenase.     

Regulation of cyclic photophosphorylation in Rhodospirillum rubrum by the redox state of nicotinamide-adenine dinucleotide

We have investigated the effect of the redox state of added NAD on the rates of anaerobic cyclic photophosphorylation which are supported by membrane vesicles isolated from Rhodospirillum rubrum. As the redox potential of NAD was lowered, the activity decreased according to a typical potentiometric titration. The Nernst plot showed an apparent midpoint potential (E′_o) of ?350 mV and had a slope which corresponded to a two-electron transition. Besides, an almost identical potentiometric relationship was found to exist between the extent of light-elicited ATP formation in anaerobic suspensions of intact R. rubrum cells and the redox potential of intracellular NAD. These results suggest that physiological photophosphorylation in R. rubrum requires the oxidized form of a membrane-bound constituent (E′_o = ?350 mV) whose redox state is controlled by the redox state of cytoplasmic NAD.