The proton-translocating nicotinamide–dinucleotide (phosphate) transhydrogenase of rat liver mitochondria

1. The NAD(P) transhydrogenase activity of the soluble fraction of sonicated rat liver mitochondrial preparations was greater than the NAD-linked isocitrate dehydrogenase activity, and the NAD-linked and NADP-linked isocitrate dehydrogenase activities were not additive. The NAD-linked isocitrate dehydrogenase activity was destroyed by an endogenous autolytic system or by added nucleotide pyrophosphatase, and was restored by a catalytic amount of NADP. 2. We concluded that the isocitrate dehydrogenase of rat liver mitochondria was exclusively NADP-specific, and that the oxoglutarate/isocitrate couple could therefore be used unequivocally as redox reactant for NADP in experiments designed to operate only the NAD(P) transhydrogenase (or loop 0) segment of the respiratory chain in intact mitochondria. 3. During oxidation of isocitrate by acetoacetate in intact, anaerobic, mitochondria via the rhein-sensitive, but rotenone- and arsenite-insensitive, NAD(P) transhydrogenase, measurements of the rates of carbonyl cyanide p-trifluoromethoxyphenylhydrazone-sensitive and carbonyl cyanide p-trifluoromethoxyphenylhydrazone-insensitive pH change in the presence of various oxoglutarate/isocitrate concentration ratios gave an -->H(+)/2e(-) quotient of 1.94+/-0.12 for outward proton translocation by the NAD(P) transhydrogenase. 4. Measurements with a K(+)-sensitive electrode confirmed that the electrogenicity of the NAD(P) transhydrogenase reaction corresponded to the translocation of one positive charge per acid equivalent. 5. Sluggish reversal of the NAD(P) transhydrogenase reaction resulted in a significant inward proton translocation. 6. The possibility that isocitrate might normally be oxidized via loop 0 at a redox potential of -450mV, or even more negative, is discussed, and implies that a P/O quotient of 4 for isocitrate oxidation might be expected.     

On the oxidation of reduced nicotinamide dinucleotide phosphate by submitochondrial particles from beef heart

The oxidation of NADPH catalyzed by submitochondrial particles from beef heart in the absence and presence of NAD⁺ has been investigated. The data confirm earlier findings in this laboratory concerning the occurrence of an NADPH dehydrogenase with 2,6-dichlorophenolindophenol as the electron acceptor. This reaction is highly sensitive to palmityl-CoA, a feature further substantiating its possible relationship to nicotinamide nucleotide transhydrogenase. The particles also catalyzed a very low NADPH oxidase activity which probably proceeds via NADH dehydrogenase and is unrelated to transhydrogenase.     

Further studies on corticosteroidogenesis VI. Pyruvate and malate supported steroid 11β-hydroxylation in rat adrenal gland mitochondria

Pyruvate and pyruvate plus ATP have been shown to support 11β-hydroxylation of 11-deoxycorticosterone into corticosterone in incubated rat adrenal gland mitochondria. Corticosterone production with pyruvate plus ATP was not as great as with malate plus P_i, malate plus ATP or malate plus pyruvate. Respiratory chain inhibitors, trans-aconitate, oxaloacetate, arsenite and the uncoupler 2,4-dinitrophenol, inhibited corticosterone formation. On the other hand, cysteine sulfinate and pyruvate, which led to the removal of excess metabolic oxaloacetate formed from malate oxidation, increased rat adrenal mitochondrial O₂ consumption as well as corticosterone production from 11-deoxycorticosterone. P_i and ATP also appeared to act in the same way in that these agents brought about a greater conversion rate of oxaloacetate into pyruvate. Pyruvate, resulting from the oxidation of malate, accumulated in the incubation system only when arsenite was added. Arsenite additions to malate and isocitrate inhibited the conversion of 11-deoxycorticosterone into corticosterone except when the 11β-hydroxylation of 11-deoxycorticosterone was supported with exogenous NADPH in Ca²⁺-swollen mitochondria. These results as well as the observations that NAD-linked malate dehydrogenase ( -malate: NAD⁺ oxidoreductase (decarboxylating), EC 1.1.1.39) is at least 10 times as active as the NADP-linked enzyme ( -malate: NADP⁺ oxidoreductase (decarboxylating), EC 1.1.1.39) in sonicated rat adrenal gland mitochondria, led to the conclusion that under our incubation conditions malate was mainly oxidized via the NAD-linked malate dehydrogenase. The fact that in malate incubations pyruvate did not accumulate because of its further metabolism in rat adrenal gland mitochondria, does not support the possibility that these mitochondria are the source of pyruvate for a “malate shuttle” originally thought to occur in rat adrenal gland⁷. This shuttle would have depended on the formation of pyruvate from malate in rat adrenal gland mitochondria followed by extrusion of the pyruvate formed intramitochondrially into the cytoplasm of the cell.     

Steroid hydroxylations by guinea-pig adrenal tissue fractions

The effect of oxidizable substrates, -ketoglutarate and isocitrate on 11β-hydroxylation in guinea-pig adrenal mitochondria has been studied. These substrates supported the conversion of Compound S (17,21-dihydroxy-pregnene-3,20-dione) into cortisol as well as exogenously added NADPH in Ca²⁺-swollen mitochondria. Progesterone was also hydroxylated at the C-11β position but not at the C-21 position. Microsomes, on the other hand, when NADPH was added, converted pregnenolone, progesterone and 17-hydroxyprogesterone into Compound S, but showed no steroid 11β-hydroxylating activity. Evidence obtained in incubations carried out with -ketoglutarate and isocitrate in the presence of 2,4-dinitrophenol, oligomycin, amytal and antimycin A indicate that -ketoglutarate utilization for steroid 11β-hydroxylation is dependent on activity of the classical electron chain. This activity can be related to high energy intermediates possibly needed for NADPH reduction arising from NADH oxidation via the energy-requiring transhydrogenase reaction. These reactions do not appear necessary for isocitrate utilization and isocitrate oxidation probably gives rise to intramitochondrial NADPH reduction as a result of a NADP⁺-linked isocitrate dehydrogenase. Data obtained in oxygen uptake studies with an antimycin A blocked system supplied with -ketoglutarate, are in accordance with this conclusion. The high-speed supernatant fraction (103000 × g) could partially replace -ketoglutarate, isocitrate or Ca²⁺ + NADPH, indicating that it contains a factor(s) (the physiological substrate?) which brings about intramitochondrial NADPH.     

The control of isocitrate oxidation by rat liver mitochondria

1. The factors capable of affecting the rate of isocitrate oxidation in intact mitochondria include the rate of isocitrate penetration, the activity of the NAD-specific and NADP-specific isocitrate dehydrogenases, the activity of the transhydrogenase acting from NADPH to NAD(+), the rate of NADPH oxidation by the reductive synthesis of glutamate and the activity of the respiratory chain. A quantitative assessment of these factors was made in intact mitochondria. 2. The kinetic properties of the NAD-specific and NADP-specific isocitrate dehydrogenases extracted from rat liver mitochondria were examined. 3. The rate of isocitrate oxidation through the respiratory chain in mitochondria with coupled phosphorylation is approximately equal to the maximal of the NAD-specific isocitrate dehydrogenase but at least ten times as great as the transhydrogenase activity from NADPH to NAD(+). 4. It is concluded that the energy-dependent inhibition of isocitrate oxidation by palmitoylcarnitine oxidation is due to an inhibition of the NAD-specific isocitrate dehydrogenase. 5. Kinetic studies of NAD-specific isocitrate dehydrogenase demonstrated that its activity could be inhibited by one or more of the following: an increased reduction of mitochondrial NAD, an increased phosphorylation of mitochondrial adenine nucleotides or a fall in the mitochondrial isocitrate concentration. 6. Uncoupling agents stimulate isocitrate oxidation by an extent equal to the associated stimulation of transhydrogenation from NADPH to NAD(+). 7. A technique is described for continuously measuring with a carbon dioxide electrode the synthesis of glutamate from isocitrate and ammonia.     

The oxidation of tricarboxylic acid cycle intermediates, with particular reference to isocitrate, by intact mitochondria isolated from the liver of the American eel, Anguilla rostrata leSueur.

The oxidation of exogenously added substrates has been studied in intact liver mitochondria isolated from the American eel, Anguilla rostrata. These data, coupled to determinations of the activity and localization of critical tricarboxylic acid (TCA) cycle enzymes, have been used to propose a pathway for the eel liver TCA cycle. (1) Isocitric, α-ketoglutaric, succinic, and malic acids are oxidized at essentially equivalent rates by eel mitochondria, with normal ADP:O and respiratory control ratios. No oxidation of citric, oxaloacetic, or pyruvic acids was detected when added alone or with malate, although oxaloacetic acid + pyruvic acid was oxidized but at a much reduced rate. (2) Radioactively labeled isocitrate was incorporated into at least α-ketoglutaric, succinic, and malic acids, indicating the eel liver TCA cycle is normal between isocitrate and malate. (3) No activity of the NAD-linked isocitrate dehydrogenase (IDH) could be detected, but NADP-IDH activities were higher in the mitochondria than cytosolic fractions. An active NADPH:NAD transhydrogenase was localized to the mitochondrial compartment. (4) These data suggest an important role for the NADP-IDH:transhydrogenase enzyme couple in eel liver TCA cycle function, and a pathway incorporating these ideas is proposed.     

Is there Ca2+(Sr2+)-3-hydroxybutyrate symport in rat-liver mitochondria? A reappraisal

The observation in this laboratory that respiration and Sr2+ import were stimulated by the addition of 3-hydroxybutyrate to suspensions of N-ethylmaleimide-treated mitochondria respiring in state 6, after the addition of Sr2+, in a sucrose medium containing choline as substrate, led to the proposal by Moyle and Mitchell [(1977) FEBS Lett. 84, 135-140] that there is a Ca2+(Sr2+)-3-hydroxybutyrate symporter in rat liver mitochondria. However, experiments described in the present paper support a different interpretation. Under the conditions of the experiments by Moyle and Mitchell, the rate of respiration and the poise of Sr2+ accumulation are mainly limited, not by delta mu H+, but by lack of respiratory substrate. Even though N-ethylmaleimide is a potent inhibitor of 3-hydroxybutyrate dehydrogenase, we have found that, somewhat surprisingly, under the special conditions of these experiments, sufficient 3-hydroxybutyrate dehydrogenase activity remains available to account for the 3-hydroxybutyrate-dependent respiratory stimulation and Sr2+ import.     

Some properties of pyruvate and 2-oxoglutarate oxidation by blowfly flight-muscle mitochondria

1. High rates of state 3 pyruvate oxidation are dependent on high concentrations of inorganic phosphate and a predominance of ADP in the intramitochondrial pool of adenine nucleotides. The latter requirement is most marked at alkaline pH values, where ATP is profoundly inhibitory. 2. Addition of CaCl(2) during state 4, state 3 (Chance & Williams, 1955) or uncoupled pyruvate oxidation causes a marked inhibition in the rate of oxygen uptake when low concentrations of mitochondria are employed, but may lead to an enhancement of state 4 oxygen uptake when very high concentrations of mitochondria are used. 3. These properties are consistent with the kinetics of the NAD-linked isocitrate dehydrogenase (EC 1.1.1.41) from this tissue, which is activated by isocitrate, citrate, ADP, phosphate and H(+) ions, and inhibited by ATP, NADH and Ca(2+). 4. Studies of the redox state of NAD and cytochrome c show that addition of ADP during pyruvate oxidation causes a slight reduction, whereas addition during glycerol phosphate oxidation causes a ;classical' oxidation. Nevertheless, it is concluded that pyruvate oxidation is probably limited by the respiratory chain in state 4 and by the NAD-linked isocitrate dehydrogenase in state 3. 5. The oxidation of 2-oxoglutarate by swollen mitochondria is also stimulated by high concentrations of ADP and phosphate, and is not uncoupled by arsenate.     

Properties of the oxidation of exogenous NADH and NADPH by plant mitochondria. Evidence against a phosphatase or a nicotinamide nucleotide transhydrogenase being responsible for NADPH oxidation

(1) The optimum pH for the oxidation of exogenous NADH by mitochondria from both Jerusalem artichoke (Helianthus tuberosus) tubers and Arum maculatum spadices was 7.0–7.1. NADPH oxidation had a lower optimum pH of 6.6 in Arum and 6.0 in Jerusalem artichoke mitochondria. In both types of mitochondria the rates of NADH and NADPH oxidation were identical below pH 6.0–5.5. (2) It is shown conclusively that neither a phosphatase converting NADPH to NADH nor a nicotinamide nucleotide transhydrogenase was involved in the oxidation of NADPH by these mitochondria. (3) Palmitoyl-CoA, an inhibitor of transhydrogenase activity in mammalian mitochondria, inhibits both NADH and NADPH oxidation by plant mitochondria with a K_i of about 10 μM. (4) It is concluded that the known properties of NAD(P)H oxidation are best explained by assuming the presence of a second dehydrogenase specific for NADPH. At low pH, electron flow from the two dehydrogenases to oxygen shares a common rate-limiting step.     

The nicotinamide nucleotide specificity of glutamate dehydrogenase in intact RAT-liver mitochondria

1. The kinetics of oxidation of intramitochondrial reduced nicotinamide nucleotides by -oxoglutarate plus ammonia in intact rat-liver mitochondria have been reinvestigated. It is demonstrated that the preferential oxidation of NADPH observed on addition of ammonia to mitochondria, preincubated under energized conditions in the presence of -oxoglutarate, is due to a transhydrogenation catalysed by glutamate dehydrogenase rather than to an energy-dependent modification of the nicotinamide nucleotide specificity of the enzyme in intact mitochondria.

2. When mitochondria are preincubated at 25 °C under energized conditions in the presence of respiratory inhibitors with the substrates of glutamate dehydrogenase, an oxidation of NADPH, but not of NADH, is brought about by decreasing the reaction temperature. Both the rate of NADPH oxidation and the final steady-state mass-action ratio of nicotinamide nucleotides are dependent on the concentration of ammonia and on the final reaction temperature. A similar effect is observed when rhein is added to the reaction medium at 25 °C in order to inhibit the energy-linked transhydrogenase reaction.

3. In the presence of the substrates of glutamate dehydrogenase, intact ratliver mitochondria catalyse an ATPase reaction due to the simultaneous activity of the energy-linked transhydrogenase and the non-energy-linked transhydrogenation catalysed by glutamate dehydrogenase.

4. These findings are discussed in relation to the nicotinamide nucleotide specificity of glutamate dehydrogenase and to a possible compartmentation of nicotinamide nucleotides in intact rat-liver mitochondria.     

Mitochondrial isocitrate dehydrogenase and isocitrate oxidation of rat ventral prostate.

Mitochondrial preparations isolated from rat ventral prostate were capable of oxidizing isocitrate by way of NADP isocitrate dehydrogenase (NADP-IDH) and NAD-IDH. NAD-IDH activity required ADP for activation. The pH responses for NAD-IDH and NADP-IDH were quite different. The results indicated that two different enzymes were involved in the NAD- and NADP-IDH activities. Indirect evidence indicated that NADPH-NAD transhydrogenase activity might also be involved in the mitochondrial pathway for isocitrate oxidation. NADP-IDH activity was significantly greater than NAD-IDH activity. The oxidation of isocitrate through IDH activity was coupled to the cytochrome system by NADPH- and NADH-cytochrome c reductase activities. Citrate, via isocitrate, oxidation proceeded at a much slower rate suggesting that aconitase activity could be limiting in the oxidation of citrate. In comparison to other tissues, the prostate oxidative enzyme activities are considerably lower. The results suggest that the accumulation of high prostate citrate levels is not due to a limitation imposed by a lack of IDH activity in prostate mitochondria.     

Competition for energy between phosphoenolpyruvate and citrulline synthesis in guinea-pig liver mitochondria

1. The interrelationship between citrulline synthesis and phosphoenolpyruvate formation has been studied in guinea-pig liver mitochondria incubated with glutamate in State 3 and in the presence of uncoupler and oligomycin.

2. In coupled mitochondria the rate of phosphoenolpyruvate production was limited by a higher capacity of aspartate aminotransferase than that of phosphopyruvate carboxylase for the intramitochondrial oxalacetate. Citrulline formation was low due to the small production of NH₃ since glutamate oxidation in State 3 proceeds via the transamination pathway.

3. Inhibition of aspartate aminotransferase by aminooxyacetate in State 3 resulted in increases in both phosphoenolpyruvate and citrulline synthesis. Under uncoupled conditions, however, an increase of phosphoenolpyruvate formation was accompanied by a decrease of both citrulline production and the ATP content of the incubation medium. Restoration of the citrulline production was observed on the addition of exogenous ATP.

4. The results indicate that when energy is generated via substrate-level phosphorylation, the inhibition of citrulline production is probably due to a higher availability of GTP to the phosphopyruvate carboxylase than to the nucleoside diphosphate kinase.     

Mitochondrial and cytosolic NADPH systems and isocitrate dehydrogenase indicator metabolites during ureogensis from ammonia in isolated rat hepatocytes.

1. Citrate isocitrate and 2-oxoglutarate levels were determined in isolated rat hepatocytes and in particulate and soluble fractions, thereof, obtained by the digitonin and silicone oil fractionation technique. 2. Caculated from isocitrate/2-oxoglutarate ratios ("indicator metabolite method"), the redox potential of mitochondrial free NADPH is -402 mV, whereas that of the extramitochondrial (cytosolic) space is about 10 mV more positive, -392 mV. 3; Addition of ammonia (either as ammonium chloride or from urea plus urease) to isolated hepatocytes causes preferential oxidation of mitochondrial NADPH, is demonstrated by spectrophotometry of the dihydro band and by the changes in the isocitrate/2-oxoglutarate ratios. The redox potential difference of free NADPH between mitochondria and cytosol is abolished or even reserved. 4. It is concluded that during urogenesis from ammonia mitochondrial isocitrate oxidation is shifted largely in favor of the NADP-linked as opposed to the NAD-linked enzyme; isocitrate concentration under these conditions is less than 10 muM, below the Km (isocitrate) of the NAD-linked enzyme but in the range of that for the NADP-linked enzyme. 5. Both in the absence and in the presence of ammonia there is a concentration gradient across the mitochondrial inner membrane (from mitochondria to cytosol) for citrate, isocitrate, and also, to a smaller extent, for 2-oxoglutarate. 6. These results and data in the literature on enzyme activity are in agreement with the assumption of near-equilibrium of NADP-dependent isocitrate dehydrogenases in the mitochondrial matrix and cytosolic spaces in the absence of ammonia; accordingly, during urea formation from added ammonia the redox potential of mitochondrial free NADPH is increased to -391 mV or possibly even higher if there exists an indicator error under this condition.     

Properties of substantially chlorophyll-free pea leaf mitochondria prepared by sucrose density gradient separation

Mitochondria isolated from pea leaves (Pisum sativum L. var Massey Gem) and purified on a linear sucrose density gradient were substantially free of contamination by Chl and peroxisomes. They showed high respiratory rates and good respiratory control and ADP/O ratios. Malate, glutamate, succinate, glycine, pyruvate, α-ketoglutarate, NADH, and NADPH were oxidized but little or no oxidation of citrate, isocitrate, or proline was detected. The oxidation of NADPH by the purified mitochondria did not occur via a transhydrogenase or phosphatase converting it to NADH. NADPH oxidation had an absolute requirement for added Ca²⁺, whereas NADH oxidation proceeded in its absence. In addition, oxidation of the two substrates showed different sensitivities to chelators and sulfhydryl reagents, and faster rates of O₂ uptake were observed with both substrates than with either alone. This indicates that the NADPH dehydrogenase is distinct from the exogenous NADH dehydrogenase.     

Enzyme activities in mitochondria isolated from ripening tomato fruit

Mitochondria were isolated from tomato (Lycopersicon esculentum L.) fruit at the mature green, orange-green and red stages and from fruit artificially suspended in their ripening stage. The specific activities of citrate synthase (EC 4.1.3.7), malate dehydrogenase (EC 1.1.1.37), NAD-linked isocitrate dehydrogenase (EC 1.1.1.41) and NAD-linked malic enzyme (EC 1.1.1.38) were determined. The specific activities of all these enzymes fell during ipening, although the mitochondria were fully functional as demonstrated by the uptake of oxygen. The fall in activity of mitochondrial malate dehydrogenase was accompanied by a similar fall in the activity of the cytosolic isoenzyme. Percoll-purified mitochondria isolated from mature green fruit remained intact for more than one week and at least one enzyme, citrate synthase, did not exhibit the fall in specific activity found in normal ripening fruit.     

The Activities of Some Energy-Metabolising Enzymes in Nonsynaptic (Free) and Synaptic Mitochondria Derived from Selected Brain Regions

Abstract: The enzyme complement of two different mitochondrial preparations from adult rat brain has been studied. One population of mitochondria (synaptic) is prepared by the lysis of synaptosomes, the other (nonsynaptic or free) by separation from homogenates. These populations have been prepared from distinct regions of the brain: cortex, striatum, and pons and medulla oblongata. The following enzymes have been measured: pyruvate dehydrogenase (EC 1.2.4.1), citrate synthase (EC 4.1.3.7), NAD-linked isocitrate dehydrogenase (EC 1.1.1.41), NADP-linked isocitrate dehydrogenase (EC 1.1.1.42), fumarase (EC 4.2.1.2), NAD-linked malate dehydrogenase (EC 1.1.1.37), D-3-hydroxybutyrate dehydrogenase (EC 1.1.1.30), and mitochondrially bound hexokinase (EC 2.7.1.1) and creatine kinase (EC 2.7.3.2). The nonsynaptic (free) mitochondria show higher enzyme specific activities in the regions studied than the corresponding values recorded for the synaptic mitochondria. The significance of these observations is discussed in the light of the different metabolic activities of the two populations of mitochondria and the compartmentation of the metabolic activities of the brain.     

Effect of phthalonic acid on respiration and metabolite transport in higher plant mitochondria

Phthalonate was found to inhibit the following parameters in higher plant mitochondria; glutamate and isocitrate oxidation, swelling in ammonium citrate and glutamate (but not malate), citrate-isocitrate exchange, oxalacetate entry and efflux, and NAD-linked malic enzyme. Phthalonate had little effect on malate, NADH, or oxoglutarate oxidation, nor on malate, isocitrate, or glutamate dehydrogenases. The results indicate that phthalonate is an inhibitor of oxalacetate, glutamate, and citrate transport in plant mitochondria, but not of oxoglutarate or dicarboxylate transport.     

The oxidation of exogenous cytochrome c by mitochondria. Resolution of a long-standing controversy

Several reports in the past have dealt with the oxidation of cytochrome c added to suspensions of rat liver mitochondria. Yet, it is generally believed that the cytochrome cannot penetrate the outer membrane. Probably it has been assumed that the permeability of the outer membrane to cytochrome c is very low but finite, and that fast oxidation may be observed if time is allowed for sufficient penetration before initiation of electron flow. Here we show that this view is false. The main fraction of rat liver mitochondria, as isolated by conventional procedures, does not catalyse any significant oxidation of added cytochrome c, even after prolonged incubation. The observed appreciable oxidation of added cytochrome c is catalysed by a very small fraction (5-12%) of the mitochondria that apparently has a damaged outer membrane. Consequently, the turnover of cytochrome oxidase is very high in this fraction during oxidation of added cytochrome c. This finding readily explains why Moyle and Mitchell (e.g., FEBS Lett. 88 (1978) 268-272; 90 (1978) 361-365) have failed to observe proton translocation by cytochrome oxidase during oxidation of ferrocytochrome c added to rat liver mitochondria, which has been their main reason for rejecting the proton-pumping function of cytochrome oxidase.     

Activities of NAD-specific and NADP-specific isocitrate dehydrogenases in rat-liver mitochondria. Studies with D-threo-alpha-methylisocitrate.

The contributions of NAD-specific and NADP-specific isocitrate dehydrogenases to isocitrate oxidation in isolated intact rat liver mitochondria were examined using DL-threo-alpha-methylisocitrate (3-hydroxy-1,2,3-butanetricarboxylate) to specifically inhibit flux through NADP-specific isocitrate dehydrogenase. Under a range of conditions tested with respiring mitochondria, the rate of isocitrate oxidation was decreased by about 20--40% by inhibition of NADP-isocitrate dehydrogenase, and matrix NADP became more oxidized. (a) For mitochondria incubated with externally added DL-isocitrate and citrate, the rate of isocitrate oxidation obtained by extrapolation to infinite alpha-methylisocitrate concentration was approximately 70% of the uninhibited rate in both state 3 and state 4. (b) With pyruvate plus malate added as substrates of citric acid cycle oxidation and isocitrate generated intramitochondrially, a concentration of alpha-methylisocitrate (400 microM) sufficient for 99.99% inhibition of NADP-isocitrate dehydrogenase inhibited isocitrate oxidation in states 4 and 3 by 21 +/- 6% and 19 +/- 11% (mean +/- SEM), respectively. (c) With externally added isocitrate and citrate, the addition of NH4Cl increased isocitrate oxidation by 3--4-fold, decreased NADPH levels by 30--40% and 2-oxoglutarate accumulation by about 40%. The further addition of 600 microM alpha-methylisocitrate decreased the NH4Cl-stimulated isocitrate oxidation by about 40% and decreased NADPH to about 30% of the level prevailing in the absence of NH4Cl; nevertheless, the rate of isocitrate oxidation was still twice as large in the presence of NH4Cl and alpha-methylisocitrate as in their absence. Experiments were also performed with intact mitochondria incubated with respiratory inhibitors to determine additional factors which might affect the flux through the two isocitrate dehydrogenases. (a) In the coupled reduction of acetoacetate by isocitrate, where the rate of reoxidation of reduced pyridine nucleotides is limited by NAD-specific 3-hydroxybutyrate dehydrogenase, 85--100% of the rate of 3-hydroxybutyrate formation was retained in the presence of 400--900 microM alpha-methylisocitrate. (b) In a system where the rate of isocitrate oxidation is limited by the rate of NADPH reoxidation by glutathione reductase, the rate of glutathione reduction extrapolated to infinite alpha-methylisocitrate concentration was from 20--40% of the uninhibited rate. (c) In the coupled synthesis of glutamate from isocitrate and NH4Cl, where the reoxidation of NADPH and NADH can occur via glutamate dehydrogenase, the rate of glutamate production extrapolated to infinite alpha-methylisocitrate concentration was about 60% of the uninhibited rate.     

Membrane-Associated NAD-Dependent Isocitrate Dehydrogenase in Potato Mitochondria

The oxidation isotherms for citrate and isocitrate by potato (Solanum tuberosum var. Russet Burbank) mitochondria in the presence of NAD differ markedly. Citrate oxidation shows positively cooperative kinetics with a sigmoid isotherm, whereas isocitrate oxidation shows Michaelis-Menten kinetics at concentrations up to 3 millimolar, and cooperative kinetics thereafter up to 30 millimolar. In the absence of exogenous NAD, the isocitrate isotherm is sigmoid throughout. The dual isotherm for isocitrate oxidation in the presence of exogenous NAD reflects the operation of two forms of isocitrate dehydrogenase, one in the matrix and one associated with the inner mitochondrial membrane. Whereas in intact mitochondria the activity of the membrane-bound enzyme is insensitive to rotenone, and to butylmalonate, an inhibitor of organic acid transport, isocitrate oxidation by the soluble matrix enzyme is inhibited by both. The membrane-bound isocitrate dehydrogenase does not operate through the NADH dehydrogenase on the outer face of the inner mitochondrial membrane, and is thus considered to face inward. The regulatory potential of isocitrate dehydrogenase in potato mitochondria may be realized by the apportionment of the enzyme between its soluble and bound forms.