Control of glutamate dehydrogenase from Lemna minor by divalent metal ions

The NADH and NAD⁺ dependent reactions catalyzed by glutamate dehydrogenase (GDH) from sterile cultures of Lemna minor are completely inactivated by EDTA. The activities of both reactions can be fully restored by addition of Ca²⁺ and to a lesser extent Mn²⁺, Zn²⁺, Sr²⁺ or La³⁺, whereas Mg²⁺ reactivates only the NAD⁺ dependent reaction. Activation of the NADH reaction by Ca²⁺ has been studied by using partially purified, EDTA pretreated, and Mg²⁺ saturated GDH preparations. Saturation kinetic curves with Ca²⁺ were always sigmoidal, whereas saturation plots for the 3 substrates of the aminating reaction at various fixed Ca²⁺ concentrations showed normal Michaelis kinetics. However, a pronounced substrate inhibition at low Ca²⁺ levels was found, particularly with NH₄⁺ and NADH. Product inhibition studies revealed unchanged enzyme substrate binding characteristics for NADH and 2-oxoglutarate in the Ca²⁺ free enzyme. A drastic alteration was established for the third substrate NH₄⁺. The kinetic data suggest that Ca²⁺ governs an equilibrium between a catalytically inactive (Ca²⁺ free) and an active (Ca²⁺ saturated) enzyme form. Inactivation by removal of Ca²⁺ is related to an alteration in the binding characteristics or binding sequence of the substrate NH₄⁺.     

Regulation of the Na+/Ca2+ Exchanger by Pyridine Nucleotide Redox Potential in Ventricular Myocytes

The cardiac Na⁺/Ca²⁺ exchanger (NCX) is the major Ca²⁺ efflux pathway on the sarcolemma, counterbalancing Ca²⁺ influx via L-type Ca²⁺ current during excitation-contraction coupling. Altered NCX activity modulates the sarcoplastic reticulum Ca²⁺ load and can contribute to abnormal Ca²⁺ handling and arrhythmias. NADH/NAD⁺ is the main redox couple controlling mitochondrial energy production, glycolysis, and other redox reactions. Here, we tested whether cytosolic NADH/NAD⁺ redox potential regulates NCX activity in adult cardiomyocytes. NCX current (I_NCX), measured with whole cell patch clamp, was inhibited in response to cytosolic NADH loaded directly via pipette or increased by extracellular lactate perfusion, whereas an increase of mitochondrial NADH had no effect. Reactive oxygen species (ROS) accumulation was enhanced by increasing cytosolic NADH, and NADH-induced I_NCX inhibition was abolished by the H₂O₂ scavenger catalase. NADH-induced ROS accumulation was independent of mitochondrial respiration (rotenone-insensitive) but was inhibited by the flavoenzyme blocker diphenylene iodonium. NADPH oxidase was ruled out as the effector because I_NCX was insensitive to cytosolic NADPH, and NADH-induced ROS and I_NCX inhibition were not abrogated by the specific NADPH oxidase inhibitor gp91ds-tat. This study reveals a novel mechanism of NCX regulation by cytosolic NADH/NAD⁺ redox potential through a ROS-generating NADH-driven flavoprotein oxidase. The mechanism is likely to play a key role in Ca²⁺ homeostasis and the response to alterations in the cytosolic pyridine nucleotide redox state during ischemia-reperfusion or other cardiovascular diseases.     

Some properties of glutamate dehydrogenase,glutamine synthetase and glutamate synthase from Corynebacterium callunae

Characteristics of the three major ammonia assimilatory enzymes, glutamate dehydrogenase (GDH), glutamine synthetase (GS) and glutamate synthase (GOGAT) in Corynebacterium callunae (NCIB 10338) were examined. The GDH of C. callunae specifically required NADPH and NADP⁺ as coenzymes in the amination and deamination reactions, respectively. This enzyme showed a marked specificity for -ketoglutarate and glutamate as substrates. The optimum pH was 7.2 for NADPH-GDH activity (amination) and 9.0 for NADP⁺-GDH activity (deamination). The results showed that NADPH-GDH and NADP⁺-GDH activities were controlled primarily by product inhibition and that the feedback effectors alanine and valine played a minor role in the control of NADPH-GDH activity. The transferase activity of GS was dependent on Mn⁺² while the biosynthetic activity of the enzyme was dependent on Mg²⁺ as essential activators. The pH optima for transferase and biosynthetic activities were 8.0 and 7.0, respectively. In the transfer reaction, the K _m values were 15.2 mM for glutamine, 1.46 mM for hydroxylamine, 3.5×10^-3 mM for ADP and 1.03 mM for arsenate. Feedback inhibition by alanine, glycine and serine was also found to play an important role in controlling GS activity. In addition, the enzyme activity was sensitive to ATP. The transferase activity of the enzyme was responsive to ionic strength as well as the specific monovalent cation present. GOGAT of C. callunae utilized either NADPH or NADH as coenzymes, although the latter was less effective. The enzyme specifically required -ketoglutarate and glutamine as substrates. In cells grown in a medium with glutamate as the nitrogen source, the optimum pH was 7.6 for NADPH-GOGAT activity and 6.8 for NADH-GOGAT activity. Findings showed that NADPH-GOGAT and NADH-GOGAT activities were controlled by product inhibition caused by NADP⁺ and NAD⁺, respectively, and that ATP also had an important role in the control of NADPH-GOGAT activity. Both activities of GOGAT were found to be inhibited by azaserine.Abbreviations GDH glutamate dehydrogenase - GOGAT glutamate synthase - GS glutamine synthetase     

Metabolic regulation of the glucose-6-phosphate dehydrogenase from Paracoccus denitrificans grown on glucose/nitrate

Glucose-6-phosphate dehydrogenase (d-glucose-6-phosphate: NADP⁺ l-oxidoreductase EC 1.1.1.49) isolated from Paracoccus denitrificans grown on glucose/nitrate exhibits both NAD⁺-and NADP⁺-linked activities. Both activities have a pH optimum of pH 9.6 (Glycine/NaOH buffer) and neither demonstrates a Mg²⁺ requirement. Kinetics for both NAD(P)⁺ and glucose-6-phosphate were investigated. Phosphoenolpyruvate inhibits both activities in a competitive manner with respect to glucose-6-phosphate. ATP inhibits the NAD⁺-linked activity competitively with respect to glucose-6-phosphate but has no effect on the NADP⁺-linked activity. Neither of the two activities are inhibited by 100 M NADH but both are inhibited by NADPH. The NAD⁺-linked activity is far more sensitive to inhibition by NADPH than the NADP⁺-linked activity.     

Glutamate Dehydrogenases: The Why and How of Coenzyme Specificity

NAD⁺ and NADP⁺, chemically similar and with almost identical standard oxidation–reduction potentials, nevertheless have distinct roles, NAD⁺ serving catabolism and ATP generation whereas NADPH is the biosynthetic reductant. Separating these roles requires strict specificity for one or the other coenzyme for most dehydrogenases. In many organisms this holds also for glutamate dehydrogenases (GDH), NAD⁺-dependent for glutamate oxidation, NADP⁺-dependent for fixing ammonia. In higher animals, however, GDH has dual specificity. It has been suggested that GDH in mitochondria reacts only with NADP(H), the NAD⁺ reaction being an in vitro artefact. However, contrary evidence suggests mitochondrial GDH not only reacts with NAD⁺ but maintains equilibrium using the same pool as accessed by β-hydroxybutyrate dehydrogenase. Another complication is the presence of an energy-linked dehydrogenase driving NADP⁺ reduction by NADH, maintaining the coenzyme pools at different oxidation–reduction potentials. Its coexistence with GDH makes possible a futile cycle, control of which is not yet properly explained. Structural studies show NAD⁺-dependent, NADP⁺-dependent and dual-specificity GDHs are closely related and a few site-directed mutations can reverse specificity. Specificity for NAD⁺ or for NADP⁺ has probably emerged repeatedly during evolution, using different structural solutions on different occasions. In various GDHs the P7 position in the coenzyme-binding domain plays a key role. However, whereas in other dehydrogenases an acidic P7 residue usually hydrogen bonds to the 2′- and 3′-hydroxyls, dictating NAD⁺ specificity, among GDHs, depending on detailed conformation of surrounding residues, an acidic P7 may permit binding of NAD⁺ only, NADP⁺ only, or in higher animals both.     

Allosteric inhibition of the Ca2+-activated hydrophilic channel of the mitochondrial inner membrane by nucleotides

Summary The control by nucleotides of the Ca²⁺-activated channel which regulates the nonspecific permeability of the mitochondrial inner membrane has been investigated quantitatively. The cooperative binding of two molecules of ADP to the internal (matrix) side of the channel causes a mixed-type inhibition of channel activity. ATP, AMP, cAMP and GDP are all ineffective. NADH shows a pattern of inhibition similar to that of ADP, though the apparentK _I is higher by a factor of 200. NADPH relieves the inhibition by NADH. NAD⁺ also inhibits, but its affinity is a factor of 10 less than that of NADH. When ADP and NADH are added together, they act synergistically to inhibit the Ca²⁺-activated channel. It is concluded that the concept of the modification of enzyme activity by the allosteric binding of nucleotides, which is well established for soluble enzyme systems, also has application to the regulation of channels that control membrane permeability.     

Inhibition of ruthenium red-insensitive mitochondrial Ca2+ release and its pyridine nucleotide specificity

Isolated, intact rat liver mitochondria, without extraneous substrates but loaded with Ca²⁺ (20 nmol/mg), can be observed to release Ca²⁺ when treated with ruthenium red. Such release can be inhibited by 0.33 mM dlisocitrate but not by 10 mM dl-β-hydroxybutyrate. Assays of NADP⁺, NADPH, NAD⁺, and NADH revealed that only the reduction of NADP⁺ can be linked with such inhibition of Ca²⁺ release, not that of NAD⁺. Since ruthenium redinsensitive Ca²⁺ release is a physiological (but normally masked) process, this experimental approach avoids some potential problems ascribed to strong pyridine nucleotide oxidation. It is suggested that specific NADP⁺:NADPH dependent reactions are part of a physiological mechanism regulating Ca²⁺ release/retention.     

Purification and characterization of pyruvate dehydrogenase complex from borccoli floral buds.

The pyruvate dehydrogenase complex (PDC) was purified from Brassica oleracea var. italica floral buds to a specific activity of approximately 6 μmol of NADH formed/min/ mg of protein. The PDC had cofactor requirements for NAD⁺, thiamine pyrophosphate, coenzyme A, and a divalent cation (Mg²⁺, Ca²⁺, or Mn²⁺). The enzyme catalyzed the oxidative decarboxylation of pyruvate at a rate threefold faster than 2-oxobutyrate but was inactive toward 2-oxoglutarate. The PDC was competively inhibited by acetyl-CoA against CoA and NADH against NAD⁺. The enzyme was shown to be more sensitive to regulation by NADH than acetyl-CoA.     

Characteristics of glutamate dehydrogenase in mitochondria prepared from corn shoots

The amination of α-ketoglutarate (α-KG) by NADH-glutamate dehydrogenase (GDH) obtained from Sephadex G-75 treated crude extracts from shoots of 5-day-old seedlings was stimulated by the addition of Ca²⁺. The NADH-GDH purified 161-fold with ammonium sulfate, DEAE-Toyopearl, and Sephadex G-200 was also activated by Ca²⁺ in the presence of 160 micromolar NADH. However, with 10 micromolar NADH, Ca²⁺ had no effect on the NADH-GDH activity. The deamination reaction (NAD-GDH) was not influenced by the addition of Ca²⁺.

About 25% of the NADH-GDH activity was solubilized from purified mitochondria after a simple osmotic shock treatment, whereas the remaining 75% of the activity was associated with the mitochondrial membrane fraction. When the lysed mitochondria, mitochondrial matrix, or mitochondrial membrane fraction was used as the source of NADH-GDH, Ca²⁺ had little effect on its activity. The mitochondrial fraction contained about 155 nanomoles Ca per milligram of mitochondrial protein, suggesting that the NADH-GDH in the mitochondria is already in an activated form with regard Ca²⁺. In a simulated in vitro system using concentrations of 6.4 millimolar NAD, 0.21 millimolar NADH, 5 millimolar α-KG, and 5 millimolar glutamate thought to occur in the mitochondria, together with 1 millimolar Ca²⁺, 10 and 50 millimolar NH₄⁺, and purified enzyme, the equilibrium of GDH was in the direction of glutamate formation.

     

Malate: A Possible Source of Error in the NAD Glutamate Dehydrogenase Assay

The effects of externally induced metabolic perturbations areoften studied through changes of the enzyme activity patternsin crude plant extracts. From glutamate dehydrogenase (GDH)it is reported that environmental changes not only influencethe amount of the enzymatic activity, but also the ratio ofthe aminating to the deaminating activities (NADH/NAD⁺ ratio).Using crude cell extracts of suspension cultures of wheat (Triticumaestivum L. cv. Heines Koga II) we find evidence that the pretreatmentof the homogenate directly influences this ratio. Dialysis ofthese crude cell extracts resulted in a 70% loss of the NAD⁺activity, while the NADH activity remained unchanged. The deaminatingactivity in the dialysed extract could be completely restoredupon addition of a dialysable factor which was identified tobe malate. The interference of malate with the glutamate dehydrogenasereaction is caused through the action of malate dehydrogenaseand glutamate oxaloacetate transaminase which are both presentin high activities in the extracts. Only in exhaustively dialysedcell extracts can the proper deaminating GDH activity be determined.The results are discussed in the light of the controversialreports on the variable ratio of the NADH/NAD⁺ activity of GDH. Key words: Glutamate dehydrogenase, malate, NADH/NAD⁺, activity, Triticum aestivum     

The effect of calcium on the oxidation of acetaldehyde by rat liver mitochondria.

Isolated liver mitochondria oxidized acetaldehyde in the following order: State 4< state 3< valinomycin. Ca²⁺, in concentrations greater than 0.10 mM, inhibited the oxidation of acetaldehyde by isolated liver mitochondria under all conditions. Valinomycin-stimulated oxidation of acetaldehyde was more sensitive to inhibition by Ca²⁺ than were the state 3 or 4 rates of acetaldehyde oxidation. Acetaldehyde could support an energy-dependent uptake of Ca²⁺ at rates about 20 percent that found with succinate. Ruthenium red, an inhibitor of Ca²⁺ translocation, almost completely prevented the inhibition by Ca²⁺, under all conditions. The addition of externally added NAD⁺ or NADH provided complete relief against the inhibitions by Ca²⁺ of the state 4 and 3 rates of acetaldehyde oxidation. Although some relief was also observed with the valinomycin-stimulated system, significant inhibition persisted. Cations such as Zn²⁺, Cu²⁺, or Hg²⁺ also inhibited acetaldehyde oxidation, whereas Mg²⁺ and Mn²⁺ were without effect. These cations also blocked glutamate oxidation and presumably inhibit acetaldehyde oxidation by preventing reoxidation of NADH. The greater sensitivity of the ionophore-stimulated oxidation of acetaldehyde to inhibition by Ca²⁺ may reflect release of intramitochondria K⁺, which is known to occur in the presence of Ca²⁺, suggesting that acetaldehyde oxidation is influenced by the cation environment within the mitochondria.     

Differential role of glutamate dehydrogenase in nitrogen metabolism of maize tissues

Both calli and plantlets of maize (Zea mays L. var Tuxpeño 1) were exposed to specific nitrogen sources, and the aminative (NADH) and deaminative (NAD⁺) glutamate dehydrogenase activities were measured at various periods of time in homogenates of calli, roots, and leaves. A differential effect of the nitrogen sources on the tissues tested was observed. In callus tissue, glutamate, ammonium, and urea inhibited glutamate dehydrogenase (GDH) activity. The amination and deamination reactions also showed different ratios of activity under different nitrogen sources. In roots, ammonium and glutamine produced an increase in GDH-NADH activity whereas the same metabolites were inhibitory of this activity in leaves. These data suggest the presence of isoenzymes or conformers of GDH, specific for each tissue, whose activities vary depending on the nutritional requirements of the tissue and the state of differentiation.     

The kinetics of enzyme changes in yeast under conditions that cause the loss of mitochondria

1. Aerobically grown yeast having a high activity of glyoxylate-cycle, citric acid-cycle and electron-transport enzymes was transferred to a medium containing 10% glucose. After a lag phase of 30min. the yeast grew exponentially with a mean generation time of 94min. 2. The enzymes malate dehydrogenase, isocitrate lyase, succinate–cytochrome c oxidoreductase and NADH–cytochrome c oxidoreductase lost 45%, 17%, 27% and 46% of their activity respectively during the lag phase. 3. When growth commenced pyruvate kinase, pyruvate decarboxylase, alcohol dehydrogenase, glutamate dehydrogenase (NADP⁺-linked) and NADPH–cytochrome c oxidoreductase increased in activity, whereas aconitase, isocitrate dehydrogenase (NAD⁺- and NADP⁺-linked), α-oxoglutarate dehydrogenase, fumarase, malate dehydrogenase, succinate–cytochrome c oxidoreductase, NADH–cytochrome c oxidoreductase, NADH oxidase, NADPH oxidase, cytochrome c oxidase, glutamate dehydrogenase (NAD⁺-linked), glutamate–oxaloacetate transaminase, isocitrate lyase and glucose 6-phosphate dehydrogenase decreased. 4. During the early stages of growth the loss of activity of aconitase, α-oxoglutarate dehydrogenase, fumarase and glucose 6-phosphate dehydrogenase could be accounted for by dilution by cell division. The lower rate of loss of activity of isocitrate dehydrogenase (NAD⁺- and NADP⁺-linked), glutamate dehydrogenase (NAD⁺-linked), glutamate–oxaloacetate transaminase, NADPH oxidase and cytochrome c oxidase implies their continued synthesis, whereas the higher rate of loss of activity of malate dehydrogenase, isocitrate lyase, succinate–cytochrome c oxidoreductase, NADH–cytochrome c oxidoreductase and NADH oxidase means that these enzymes were actively removed. 5. The mechanisms of selective removal of enzyme activity and the control of the residual metabolic pathways are discussed.     

Glutamine synthetase and glutamate synthase from Sclerotinia sclerotiorum

Glutamine synthetase (GS, EC 6.3.1.2) and glutamate synthase (GOGAT, EC 1.4.1.13) were purified from Sclerotinia sclerotiorum and some of their properties studied. The GS transferase and biosynthetic activities, as well as GOGAT activity, were sensitive to feedback inhibition by amino acids and other metabolites. GS showed a marked dependence on ADP in the transferase reaction and on ATP in the Mg²⁺-dependent biosynthetic reaction. Regulation of GS activity by adenylylation/deadenylylation was demonstrated by snake venom phosphodiesterase treatment of the purified enzyme. GOGAT required NADPH as an electron donor; NADH was inactive. GOGAT was strongly inhibited by p-chloromercuribenzoate and the inhibition was reversed by cysteine. The enzyme was also markedly inhibited by o-phenanthroline, 2,2′-bipyridyl and azaserine. l-Methionine-dl-sulphoximine (MSX) and azaserine inhibited the incorporation of ¹⁵N-labelled ammonium sulphate into washed cells of S. sclerotiorum. MSX and azaserine respectively also inhibited purified GS and GOGAT activities. GDH activity was not detected in cell-extracts. Thus the GS/GOGAT pathway is the main route for the assimilation of ammonium compounds in this fungus.     

Glutamate dehydrogenase of lupin nodules: Purification and properties

Glutamate dehydrogenase, GDH (l-glutamate: NAD⁺ oxidoreductase (deaminating) EC 1.4.1.2) was purified from the plant fraction of lupin nodules and the purity of the preparation established by gel electrophoresis and electrofocusing. The purified enzyme existed as 4 charge isozymes with a MW of 270000. The subunit MW, as determined by dodecyl sulphate electrophoresis, was 45 000. On the basis of the results of the MW determinations a hexameric structure is proposed for lupin-nodule GDH. The pH optima for the enzyme were pH 8.2 for the amination reaction and pH 8.8 for the deamination reaction. GDH from lupin nodules showed a marked preference for NADH over NADPH in the amination reaction and used only NAD⁺ for the deamination reaction. Pyridoxal-5′-P and EDTA inhibited activity. The enzyme displayed Michaelis-Menten kinetics with respect to all substrates except NAD⁺. When NAD⁺ was the varied substrate, there was a deviation from Michaelis-Menten behaviour towards higher activity at high concentrations of NAD⁺.     

A re-examination of the reaction between ox liver glutamate dehydrogenase and 1-fluoro-2,4-dinitrobenzene.

Reaction of ox liver glutamate dehydrogenase with 1-fluoro-2,4-dinitrobenzene for 4 h at pH 8 caused 86% inactivation, almost complete desensitization to allosteric inhibition by GTP, but only partial desensitization to ADP activation. The enzyme remained hexameric after such treatment. NAD⁺, but not NADH or NADPH, partially protected activity. Protection was enhanced by GTP and decreased by ADP. GTP and NADH together protected effectively, although separately neither protected. GTP and NADPH gave partial protection of activity. Glutarate and succinate, inhibitors competitive with glutamate, gave substantial protection, slightly enhanced in the presence of NAD⁺. With glutarate, but not succinate, an initial activation was seen during chemical modification. The allosteric response to GTP was protected by GTP itself only when NAD⁺ or NAD(P)H was also present; other ligands failed to protect. Similarly ADP alone did not protect ADP sensitivity. NADH partially protected ADP sensitivity, although NADPH did not. ADP itself counteracted the protection given by NADH. GTP with NADH completely protected ADP sensitivity. This combination of ligands thus protects all the assayed properties. GTP with NADPH gave less complete protection of the ADP response. Observed protection patterns varied with the pH and coenzyme concentration of the assay mixture under constant conditions of chemical modification. Overall, the results are inconsistent with the view that dinitrophenylation directly blocks nucleotide binding sites, and suggest rather that it interferes with communication between sites.     

Pyridine nucleotide transhydrogenases of parasitic helminths.

Mitochondria from the parasitic helminth, Hymenolepis diminuta, catalyzed both NADPH:NAD⁺ and NADH:NADP⁺ transhydrogenase reactions which were demonstrable employing the appropriate acetylpyridine nucleotide derivative as the hydride ion acceptor. Thionicotinamide NAD⁺ would not serve as the oxidant in the former reaction. Under the assay conditions employed, neither reaction was energy linked, and the NADPH:NAD⁺ system was approximately five times more active than the NADH:NADP⁺ system. The NADH:NADP⁺ reaction was inhibited by phosphate and imidazole buffers, EDTA, and adenyl nucleotides, while the NADPH:NAD⁺ reaction was inhibited only slightly by imidazole and unaffected by EDTA and adenyl nucleotides. Enzyme coupling techniques revealed that both transhydrogenase systems functioned when the appropriate physiological pyridine nucleotide was the hydride ion acceptor. An NADH:NAD⁺ transhydrogenase system, which was unaffected by EDTA, or adenyl nucleotides, also was demonstrable in the mitochondria of H. diminuta. Saturation kinetics indicated that the NADH:NAD⁺ reaction was the product of an independent enzyme system. Mitochondria derived from another parasitic helminth, Ascaris lumbricoides, catalyzed only a single transhydrogenase reaction, i.e., the NADH:NAD⁺ activity. Transhydrogenase systems from both parasites were essentially membrane bound and localized on the inner mitochondrial membrane. Physiologically, the NADPH:NAD⁺ transhydrogenase of H. diminuta may serve to couple the intramitochondrial metabolism of malate (via an NADP linked “malic” enzyme) to the anaerobic NADH-dependent ATP-generating fumarate reductase system. In A. lumbricoides, where the intramitochondrial metabolism of malate depends on an NAD-linked “malic” enzyme which is localized primarily in the intermembrane space, the NADH:NAD⁺ transhydrogenase activity may serve physiologically in the translocation of hydride ions across the inner membrane to the anaerobic energy-generating fumarate reductase system.     

Pentosan polysulfate,a potent anti HIV and anti tumor agent,inhibits protein serine/threonine and tyrosine kinases

The effect of nicotinamide-adenine dinucleotides (NAD⁺ and NADP⁺) on Ca²⁺ transport in rat liver nuclei was investigated. Ca²⁺ uptake and release were determined with a Ca²⁺ electrode. Ca²⁺ uptake was dependent on adenosine triphosphate (ATP; 2mM). The presence of NAD⁺ (2mM) or NADP⁺ (1 and 2mM) caused a significant inhibition of Ca²⁺ uptake following addition of 2mM ATP. Ca²⁺, which accumulated in the nuclei during 6 min after ATP addition, was significantly released by the addition of NAD⁺ (0.5–2mM) or NADP⁺ (0.1–2mM). However, the effect of NADH (2mM) or NADPH (2mM) on Ca²⁺ uptake and release clearly weakened in comparison with the effects of NAD⁺ and NADP⁺. Meanwhile, ryanodine (10M), thapsigargin (10M) or oxalate (0.5mM) had no effect on Ca²⁺ uptake and release in rat liver nuclei. These reagents did not significantly alter the effects of 2mM NAD⁺ on Ca²⁺ uptake and release. Thus, NAD⁺ and NADP⁺ had a potent effect on Ca²⁺ transport in rat liver nuclei. The present findings suggest that the liver cytosolic NAD⁺ (NADP⁺) is a factor in the regulation of the nuclear Ca²⁺ concentration. (Mol Cell Biochem121: 127–133, 1993)     

The internal rotenone‐insensitivae NADPH dehydrogenase contributes to malate oxidation by potato tuber and pea leaf mitochondria

Inside-out submitochondrial particles from both potato (Solanum tuberosum L. cv. Bintje) tubers and pea (Pisum sativum L. cv. Oregon) leaves possess three distinct dehydrogenase activities: Complex I catalyzes the rotenone-sensitive oxidation of deamino-NADH, ND_in(NADPH) catalyzes the rotenone-insensitive and Ca²⁺-dependent oxidation of NADPH and ND_in(NADH) catalyzes the rotenone-insensitive and Ca²⁺-independent oxidation of NADH. Diphenylene iodonium (DPI) inhibits complex I, ND_in(NADPH) and ND_in (NADH) activity with a K_i of 3.7, 0.17 and 63 µM, respectively, and the 400-fold difference in K_i between the two ND_in made possible the use of DPI inhibition to estimate ND_in (NADPH) contribution to malate oxidation by intact mitochondria. The oxidation of malate in the presence of rotenone by intact mitochondria from both species was inhibited by 5 µM DPI. The maximum decrease in rate was 10–20 nmol O₂ mg^?1 min^?1. The reduction level of NAD(P) was manipulated by measuring malate oxidation in state 3 at pH 7.2 and 6.8 and in the presence and absence of an oxaloacetate-removing system. The inhibition by DPI was largest under conditions of high NAD(P) reduction. Control experiments showed that 125 µM DPI had no effect on the activities of malate dehydrogenase (with NADH or NADPH) or malic enzyme (with NAD⁺ or NADP⁺) in a matrix extract from either species. Malate dehydrogenase was unable to use NADP⁺ in the forward reaction. DPI at 125 µM did not have any effect on succinate oxidation by intact mitochondria of either species. We conclude that the inhibition caused by DPI in the presence of rotenone in plant mitochondria oxidizing malate is due to inhibition of ND_in(NADPH) oxidizing NADPH. Thus, NADP turnover contributes to malate oxidation by plant mitochondria.     

Plant pyruvate dehydrogenase complex: analysis of the kinetic properties and metabolite regulation

The pyruvate dehydrogenase complex was isolated from the mitochondria of broccoli florets and shown to be similar in its reaction mechanism to the complexes from other sources. Three families of parallel lines were obtained for the initial velocity patterns, indicating a multisite ping-pong mechanism. The apparent K_m values obtained were 321 ± 18, 148 ± 13, and 7.2 ± 0.51 μm for pyruvate, NAD⁺, and CoA, respectively. Product inhibition studies using acetyl-CoA and NADH yielded results which were in agreement with those predicted by the multisite ping-pong mechanism. Acetyl-CoA and NADH were found to be competitive inhibitors versus CoA and NAD⁺, respectively. All other substrate-product combinations showed uncompetitive inhibition patterns, except for acetyl-CoA versus NAD⁺. Among various metabolites tested, only hydroxypyruvate (K_i = 0.11 mM) and glyoxylate (K_i = 3.27 mM) were found to be capable of inhibiting the broccoli enzyme to a significant degree. Initial velocity patterns using Mg²⁺? or Ca²⁺-thiamine pyrophosphate and pyruvate as the variable substrate were found to be consistent with an equilibrium ordered mechanism where Mg? or Ca-thiamine pyrophosphate bind first, with dissociation constants of 33.8 and 3 μm, respectively. The Mg- or Ca-thiamine pyrophosphate complexes also dissociated rapidly from the enzyme complex.