Glucose 6-phosphate dehydrogenase activity in membranes of erythrocytes from normal individuals and subjects with Mediterranean G6PD deficiency

Unsealed, hemoglobin-free erythrocyte ghosts contain low yet significant levels of Glucose 6-phosphate dehydrogenase (G6PD) activity. This activity is comparable in erythrocyte ghosts obtained from normal individuals and from G6PD-deficient subjects (of Mediterranean type), in spite of the marked differences found in the corresponding cytosolic compartments. The membrane preparations can bind purified human G6PD (type B) to their cytoplasmic surface according to patterns of positive cooperativity. 2.4 × 10⁴ and 1.6 × 10⁴ G6PD-binding sites are present on the inner surface of each ghost obtained from normal and from G6PD-deficient erythrocytes, respectively, the relevant association constants being 2.8 × 10⁶ M^?1 and 0.82 × 10⁶ M^?1. The interaction of G6PD with the ghosts is unaffected by different ionic strengths or by metabolites such as glucose 6-phosphate, NADP and NADPH.     

A kinetic study of -acetohydroxy acid isomeroreductase from Salmonella typhimurium

The kinetic mechanism of α-acetohydroxy acid isomeroreductase from Salmonella typhimurium has been investigated by initial velocity kinetic and product inhibition studies. The results of the initial velocity studies are consistent with a sequential reaction. The product inhibition studies suggest an ordered reaction with NADPH and the acetohydroxy acid adding in that order, and dihydroxy acid release before NADP release.NADPH binding has been studied both by fluorimetric techniques and difference spectroscopy. From these investigations it has been calculated that 4 moles of NADPH bind per mole of enzyme; the first molecule of NADPH binds with a dissociation constant of 1.7 × 10^?6m, the subsequent 3 moles of NADPH bind with a constant of 6 × 10^?6m. Biphasic kinetics have been demonstrated at a wide range of NADPH concentrations. The occurrence of biphasic kinetics and two separate binding constants are discussed in terms of negative cooperativity.     

The optical biosensor study of the redox partner interaction with the cytochrome P450 2B4-containing monooxygenase system under hydroxylation conditions

The interactions between cytochrome P450 2B4 (d-2B4), NADPH:cytochrome P450 reductase and cytochrome b5 have been investigated in the monomeric reconstituted P450 2B4-containing monooxygenase system in the presence of a substrate (7-pentoxyresorufin) and an electron donor, NADPH. Each partner was immobilized via its amino groups on the carboxymethyldextran biochip surface of the optical biosensor IAsys+. Such mode immobilization was not accompanied by any loss of activities of the immobilized proteins. The formation of binary d-Fp/d-2B4 complexes was registered. The association/dissociation rate constants (k_on/k_off) were (0.013 ± 0.005) × 10⁶ M^?1 s^?1/0.05 ± 0.02 s^?1, and dissociation constant (K_D) was (0.26 ± 0.13) × 10^?6 M. Comparison of k_on, k_off and K_D values for d-Fp/d-2B4 complexes formed under hydroxylation (O-dealkylation) with corresponding constants obtained for the oxidized proteins of (0.10 ± 0.03) × 10⁶ M^?1 s^?1/(0.14 ± 0.06) s^?1, and (0.71 ± 0.37) × 10^?6 M, respectively shows that the decrease in k_on and an insignificant decrease in K_D are associated with the increase of complex lifetime during transition from the oxidized to hydroxylation conditions. Complex formation between d-Fp and d-b5 was not registered in both hydroxylation conditions and in the case of oxidized forms of these proteins. In both cases formation of the ternary d-Fp/d-2B4/d-b5 complexes occurred.     

Nonenzymatic reduction of nitrosobenzene to phenylhydroxylamine by NAD(P)H

The nonenzymatic reduction of nitrosobenzene by NADPH and NADH in aqueous buffer solution at 25°C is described. Both reactants quantitatively convert nitrosobenzene to phenylhydroxylamine. Rate constants for reduction (k_r) were determined spectrophotometrically and found to be identical at pH 5.7 and 7.4 and independent of buffer concentration. The values of k_NADH (124–149 M^?1 sec^?1) and k_NADPH (131–170 M^?1 sec^?1) are essentially identical. The reaction is not subject to general catalysis or specific salt effects. The oxidation of phenylhydroxylamine by NAD(P) to nitrosobenzene is only stimulated by a factor of 1.2 over oxidation in its absence (when the ratio of NADP: phenylhydroxylamine was 8:1).     

Characterization and Regulatory Properties of Glucose-6-Phosphate Dehydrogenase from Black Gram (Phaseolus mungo)

Glucose-6-phosphate dehydrogenase (E.C. 1.1.1.49) was partially purified by fractionation with ammonium sulfate and phosphocellulose chromatography. The K_m value for glucose-6-phosphate is 1.6 × 10^?4 and 6.3 × 10^?4M at low (1.0–6.0 × 10^?4M) and high (6.0–30.0 × 10^?4M) concentrations of the substrate, respectively. The K_m value for NADP⁺ is 1.4 × 10^?5M. The enzyme is inhibited by NADPH, 5-phosphoribosyl-1-pyrophosphate, and ATP, and it is activated by Mg²⁺, and Mn²⁺. In the presence of NADPH, the plot of activity vs. NADP⁺ concentration gave a sigmoidal curve. Inhibition of 5-phosphoribosyl-1-pyrophosphate and ATP is reversed by Mg²⁺ or a high pH. It is suggested that black gram glucose-6-phosphate dehydrogenase is a regulatory enzyme of the pentose phosphate pathway.     

Purification and characterization of a wound-induced ω-hydroxyfatty acid:NADP oxidoreductase from potato tuber disks (Solanum tuberosum L.)

ω-Hydroxyfatty acid dehydrogenase (ω-hydroxyfatty acid:NADP oxidoreductase) catalyzes the reaction ω-hydroxyfatty acid + NADP ? ω-oxofatty acid + NADPH +H⁺. In wound-healing potato tuber disks, the ω-oxofatty acid generated by this enzyme is further oxidized to the corresponding dicarboxylic acid by a separate enzyme, ω-oxofatty acid dehydrogenase. ω-Hydroxy acid dehydrogenase, but not ω-oxo acid dehydrogenase, was found to be induced by wounding potato tubers. ω-Hydroxy acid dehydrogenase has been purified 600-fold to near homogeneity from wound-healing potato tuber disks by a combination of gel filtration, anion-exchange, and hydroxylapatite chromatography followed by NADP-Sepharose affinity chromatography, in about 1% yield. The molecular weight and Stokes radius of this enzyme as determined by gel exclusion chromatography are 60,000 and 31 Å, respectively. Sodium dodecyl sulfate-gel electrophoresis gave a molecular weight of 31,000, indicating that the deydrogenase is a dimer with subunits of similar molecular weight. The pH optima for the reaction in the forward and reverse directions are 9.5 and 8.5, respectively, and V in the forward and reverse directions are 140 and 3200 nmol/min/mg, respectively. Apparent K_m values for NADP, 16-hydroxyhexadecanoic acid, NADPH, and 16-oxohexadecanoic acid are 100, 20, 5, and 7 μm respectively. The equilibrium constant of the reaction at pH 9.5 and 30 °C is 1.4 × 10^?9m. The enzyme preparation did not show any stereospecificity for hydride transfer from NADPH to 16-oxohexadecanoic acid.     

Purification and Kinetic Characterization of Glucose-6-phosphate Dehydrogenase from Dictyostelium discoideum

Reimers, J. M., Huang, Q., Albe, K. R., and Wright, B. E. 1993. Purification and kinetic characterization of glucose-6-phosphate dehydrogenase from Dictyostelium discoideum. Experimental Mycology 17, 1-6. Glucose-6-phosphate dehydrogenase from Dictyostelium discoideum was purified 650-fold and kinetically characterized. The enzyme catalyzed the conversion of G6P + NADP to 6PG + NADPH stoichiometrically and irreversibly in vitro . The purified enzyme is specific for NADP. Michaelis constants for G6P and NADP were 0.040 and 0.011 mM, respectively. NADPH was found to be a competitive inhibitor with respect to NADP with a K_i of 0.006 mM and a noncompetitive inhibitor with respect to G6P. The data from initial velocity and product inhibition studies were consistent with a sequential mechanism.     

The effect of NADP on the subunit structure and activity of spinach chloroplast glyceraldehyde-3-phosphate dehydrogenase

Spinach chloroplast glyceraldehyde phosphate dehydrogenase (d-glyceraldehyde-3-phosphate: NADP oxidoreductase, phosphorylating; EC 1.2.1.13) is an equilibrium mixture of aggregates of a basic protomer (M_r about 145,000) and is active with both NADP and NAD. The enzyme is primarily “tetrameric” (M_r about 600,000), although minor amounts of smaller and larger oligomers are also found. Gel chromatography in buffer containing 30 μm NADP results in depolymerization of the enzyme, mainly to protomers. NAD does not dissociate and counteracts this effect of NADP.The apparent K_m values of the protomers are 7 μm (NADP) and 8 μm (NAD). The aggregates with a M_r > 10⁶ have properties similar to the protomers. The tetramer as first isolated has higher M_m values for NADP (380 μm) and NAD (48 μm), but its apparent affinity for NADP is further decreased by repeated gel filtrations in buffer or by a single one in buffer containing NAD. Such preparations display nonlinear kinetics when NADP is the varied substrate and have a K_m (NADP) of about 1.5–3.3 μm. All these effects are reversible.V values are apparently the same in all enzyme forms and the $\text{V (}\text{NADP}\text{)}\text{V (}\text{NAD}\text{)}$ ratio always approaches 2. Since, however, the enzyme is presumably dissociated by the NADP concentrations required for a “saturating” assay, the significance of V (NADP) seems questionable.     

Isolation and characterization of a protease inhibitor from spinach leaves

An acid-stable and heat-labile proteinous protease inhibitor which was found in spinach leaves but not in seeds was isolated by sequential chromatography and preparative isoelectric focusing. The isoelectric point of this inhibitor was 4.5. The inhibitor had a M_r of ca 18 000 and was rich in aspartic acid and glycine; it had 4 half-cystine, 2 tryptophan and no methionine residues. Its extinction coefficient (E|_cm^%) was 13.7 at 280 nm. The inhibition was competitive and the dissociation constant was 3.32 × 10^?13 M. The inhibitor was specific to serine proteases and strongly inhibited trypsin and weakly inhibited α-chymotrypsin and kallikrein.     

The interaction of substrate-related ketals with bacterial and viral neuraminidases

Arthrobacter sialophilus neuraminidase catalyzes the hydration of 5-acetamido-2,6-anhydro-3, 5-dideoxy-d-glycero-d-galacto-non-2-enonic acid (2,3-dehydro-AcNeu) with K_m and k_cat values of 8.9 × 10^?4m and 6.40 × 10^?4 s^?1, respectively. The methyl ester of 2,3-dehydro-AcNeu as well as 2,3-dehydro-4-epi-AcNeu are also hydrated by the enzyme. The product resulting from the enzymatic hydration of 2,3-dehydro-AcNeu is N-acetylneuraminic acid. A series of derivatives of 2,3-dehydro-AcNeu (K_I 1.60 × 10^?6m) including 2,3-dehydro-4-epi-AcNeu (2.10 × 10^?4m) and 2,3-dehydro-4-keto-AcNeu (K_I = 6.10 × 10^?5 m) were each competitive inhibitors of the enzyme. The methyl esters of these ketal derivatives were also competitive enzyme inhibitors. Dissociation constants for these ketals were determined independently by fluorescence enzyme titrations which gave values similar to those found kinetically. These six relatives of 2,3-dehydro-AcNeu were also competitive inhibitors for the influenza viral neuraminidases. For the viral neuraminidases, the dissociation constant for 2,3-dehydro-AcNeu and its methyl ester were 2.40 × 10^?6 and 1.17 × 10^?3m, respectively. The interpretation placed upon the K_I values determined for these ketals against the Arthrobacter versus influenza neuraminidases is that the bacterial enzyme has a more flexible glycone binding site.     

Evidence for dimer/tetramer equilibrium in Trypanosoma brucei 6-phosphogluconate dehydrogenase

6-Phosphogluconate dehydrogenase (6PGDH), the third enzyme of the pentose phosphate pathway (PPP), is essential for biosyntheses and oxidative stress defence. It also has the function of depleting 6PG, whose accumulation induces cell senescence. 6PGDH is a proposed drug target for African trypanosomiasis caused by Trypanosoma brucei and for other microbial infections and cancer. Gel filtration, density gradient sedimentation, cross-linking and dynamic light scattering were used to assay the oligomerization state of T. brucei 6PGDH in the absence and presence of several ligands. The enzyme displays a dimer–tetramer equilibrium and NADPH (but not NADP) reduces the rate of approach to equilibrium, while 6PG is able to antagonize the NADPH effect. The different behaviour of the two forms of coenzyme appears to be related to the differences in ΔC_p, with NADP binding ΔC_p closer to what is expected of crystallographic structures, while NADPH ΔC_p is three times larger. The estimated dimer–tetramer association constant is 1.5 · 10⁶ M^? 1, and the specific activity of the tetramer is about 3 fold higher than the specific activity of the dimer. Thus, cellular conditions promoting tetramer formation could allow an efficient clearing of 6PG. Experiments carried out on sheep liver 6PGDH indicate that tetramerization is a specificity of the parasite enzyme.     

Uptake and binding of β-ecdysone in imaginal discs of Drosophila melanogaster

The kinetics of uptake and retention of β-ecdysone by imaginal discs from late third instar larvae of Drosophila melanogaster correspond well with those of the first synthetic response of discs to hormone, an increase in RNA synthesis.Competition studies indicate the presence of two types of hormone binding sites, specific and non-specific. The specific sites are saturated at hormone concentrations which fully induce morphogenesis. Results are consistent with the hypothesis that analogs which induce morphogenesis at differing concentrations bind to the same sites. Experiments with the inhibitors N-ethylmaleimide, actinomycin d, and cycloheximide suggest that the binding sites are pre-existing in the cell and require functional sulfhydryl groups for binding.Specific binding, binding that is competed by excess unlabeled β-ecdysone, is saturable (70–80 nM). Kinetic rate constants for this specific binding were estimated to be k_a = 1.5 × 10⁵M^?1 min^?1, k_d = 3 × 10^?2 min^?1. The equilibrium dissociation constant calculated from the kinetic rate constants was K_eq = 2 × 10^?7M compared to 1.7 × 10^?7M β-ecdysone required to induce morphogenesis in vitro and 2.5 × 10^?7M determined to be the in vivo concentration at the time of induction of morphogenesis.     

Bull semen nicotinamide adenine dinucleotide nucleosidase. VI. Fluorescence studies of the enzyme with reduced nicotinamide adenine dinucleotide

The binding of NADH to bull semen NAD nucleosidase was observed to be accompanied by a considerable enhancement of the fluorescence of NADH. The fluorescence enhancement observed in the binding of NADH to the enzyme was utilized to study the stoichiometry of binding of this compound to the enzyme. Results obtained from the fluorescence titration of the enzyme with NADH indicated the binding of one mole of NADH per mole of enzyme (36,000 g). The dissociation constant for the enzyme-NADH complex was determined to be 2.52 × 10^?6m. NADH was also found to be a very effective competitive inhibitor of the NADase-catalyzed hydrolysis of NAD, and the inhibitor dissociation constant (K_I) for the enzyme-NADH complex was determined to be 2.99 × 10^?6m which was in good agreement with the value obtained from the fluorescence titration experiments.     

Immunological Difference between Glucose-6-P Dehydrogenase and Hexose-6-P Dehydrogenase from Human Liver

SHAW and Barto¹ have demonstrated the presence of an autosomally inherited glucose-6-P dehydrogenase (G6PD) in the deer mouse. Subsequently, Ohno et al.² found a similar enzyme in trout and showed that this enzyme and the autosomally inherited mouse enzyme differed from the sex-linked G6PD in possessing marked catalytic activity with galactose-6-P. This autosomally inherited G6PD was therefore named hexose-6-P dehydrogenase (H6PD)^2,3. It was shown to oxidize glucose-6-P, galactose-6-P, mannose-6-P and 2-deoxy glucose-6-P with a K_m of the order of 10^?5 M. It also oxidizes glucose with a K_m of 0.7 M³. It appears to be identical to the so-called “glucose dehydrogenase”. The enzyme utilizes both NAD and NADP and is microsome-bound. G6PD is localized in the soluble fraction of the cells of various tissues. Although it has been shown that two dehydrogenases from liver have different substrate specificity, molecular weight and elec-trophoretic mobility^3,4, it has been suggested that the two enzymes are merely isozymes and they might be interconvertible^5–7. We have now partially purified the two enzymes from human liver and show that they have different immunological properties.     

Can uranium follow the iron-acquisition pathway? Interaction of uranyl-loaded transferrin with receptor 1

Transferrin receptor 1 (R_D) binds iron-loaded transferrin and allows its internalization in the cytoplasm. Human serum transferrin also forms complexes with metals other than iron, including uranium in the uranyl form (UO₂ ²⁺). Can the uranyl-saturated transferrin (TUr₂) follow the receptor-mediated iron-acquisition pathway? In cell-free assays, TUr₂ interacts with R_D in two different steps. The first is fast, direct rate constant, k ₁ = (5.2 ± 0.8) × 10⁶ M^?1 s^?1; reverse rate constant, k _?1 = 95 ± 5 s^?1; and dissociation constant K ₁ = 18 ± 6 μM. The second occurs in the 100-s range and leads to an increase in the stability of the protein–protein adduct, with an average overall dissociation constant K _d = 6 ± 2 μM. This kinetic analysis implies in the proposed in vitro model possible but weak competition between TUr₂ and the C-lobe of iron-loaded transferrin toward the interaction with R _D.     

Inhibition of AChE by malathion and some structurally similar compounds

Inhibition of bovine erythrocyte acetylcholinesterase (free and immobilized on controlled pore glass) by separate and simultaneous exposure to malathion and malathion transformation products which are generally formed during storage or through natural or photochemical degradation was investigated. Increasing concentrations of malathion, its oxidation product malaoxon, and its isomerisation product isomalathion inhibited free and immobilized AChE in a concentration-dependent manner. K_I, the dissociation constant for the initial reversible enzyme inhibitor-complex, and k₃, the first order rate constant for the conversion of the reversible complex into the irreversibly inhibited enzyme, were determined from the progressive development of inhibition produced by reaction of native AChE with malathion, malaoxon and isomalathion. K_I values of 1.3 × 10^{? 4} M^{? 1}, 5.6 × 10^{? 6} M^{? 1} and 7.2 × 10^{? 6} M^{? 1} were obtained for malathion, malaoxon and isomalathion, respectively. The IC₅₀ values for free/immobilized AChE, (3.7 ± 0.2) × 10^{? 4} M/(1.6 ± 0.1) × 10^{? 4}, (2.4 ± 0.3) × 10^{? 6}/(3.4 ± 0.1) × 10^{? 6} M and (3.2 ± 0.3) × 10^{? 6} M/(2.7 ± 0.2) × 10^{? 6} M, were obtained from the inhibition curves induced by malathion, malaoxon and isomalathion, respectively. However, the products formed due to photoinduced degradation, phosphorodithioic O,O,S-trimethyl ester and O,O-dimethyl thiophosphate, did not noticeably affect enzymatic activity, while diethyl maleate inhibited AChE activity at concentrations > 10 mM. Inhibition of acetylcholinesterase increased with the time of exposure to malathion and its inhibiting by-products within the interval from 0 to 5 minutes. Through simultaneous exposure of the enzyme to malaoxon and isomalathion, an additive effect was achieved for lower concentrations of the inhibitors (in the presence of malaoxon/isomalathion at concentrations 2 × 10^{? 7} M/2 × 10^{? 7} M, 2 × 10^{? 7} M/3 × 10^{? 7} M and 2 × 10^{? 7} M/4.5 × 10^{? 7} M), while an antagonistic effect was obtained for all higher concentrations of inhibitors. The presence of a non-inhibitory degradation product (phosphorodithioic O,O,S-trimethyl ester) did not affect the inhibition efficiencies of the malathion by-products, malaoxon and isomalathion.     

Neutron scattering studies of escherichia coli tyrosyl-trna synthetase and of its interaction with trna tyr

Small-angle neutron scattering studies of Escherichia coli tyrosyl-tRNA synthetase indicate that in solution this enzyme is a dimer of M_r, 91 (±6) × 10³ with a radius of gyration R_G of 37.8 ± 1.1 Å.The increase in the scattering mass of the enzyme upon binding tRNA^Tyr has been followed in 20 mm-imidazole · HCl (pH 7.6), 10 mm-MgCl₂, 0.1 mm-EDTA, 10 mm-2-mercaptoethanol, 150 mm-KCl. A stoichiometry of one bound tRNA per dimeric enzyme molecule was found. The R_G of the complex is equal to 41 ± 1 Å. Titration experiments in 74% ²H₂O, close to the matching point of tRNA, show an R_G of 38.5 ± 1 Å for the enzyme moiety in the complex. From these values, a minimum distance of 49 Å between the centre of mass of the bound tRNA and that of the enzyme was calculated.In low ionic strength conditions (20 mm-imidazole-HCl (pH 7.6), 10 mm-MgCl₂, 0.1 mm-EDTA, 10 mm-2-mercaptoethanol) and at limiting tRNA concentrations with respect to the enzyme, titrations of the enzyme by tRNA^Tyr are characterized by the appearance of aggregates, with a maximum scattered intensity at a stoichiometry of one tRNA per two enzyme molecules. At this point, the measured M_r and R_G values are compatible with a compact 1:2, tRNA: enzyme complex. This complex forms with a remarkably high stability constant: (enzyme:tRNA:enzyme)/(enzyme:tRNA)(enzyme) of 0.1 to 0.3(× 10⁶) m^?1 (at 20 °C). Upon addition of more tRNA, the complex dissociates in favour of the 1:1, enzyme:tRNA complex, which has a higher stability constant (1 to 3 (× 10⁶) m^?1).     

Structural polypeptides and products of late genes of bacteriophage Mu: Characterization and functional aspects

This paper describes the identification and functional role of late gene products of bacteriophage Mu, including an analysis of the structural proteins of the Mu virion.In vitro reconstitution of infectious phage particles has shown that four genes (E, D, I, J) control the formation of phage heads and that a cluster of eight genes (K, L, M, N, P, Q, R, S) controls the formation of phage tails.Sodium dodecyl sulphate/polyacrylamide gel electrophoresis of Mu polypeptides synthesized in Escherichia coli minicells infected by Mu phages carrying amber mutations in various late genes has resulted in the identification of the products of gene C (15.5 × 10³M_r); H (64 × 10³M_r); F (54 × 10³M_r); G (16 × 10³M_r); L (55 × 10³M_r); N (60 × 10³M_r); P (43 × 10³M_r) and S (56 × 10³M_r). Minicells infected with λpMu hybrid phages and deletion mutants of Mu were used to identify polypeptides encoded by the V-β region of the Mu genome. These are the products of genes V, W or R (41.5 × 10³M_r, and 45 × 10³M_r); U (20.5 × 10³M_r) and of genes located in the β region (24 × 10³M_r (gpgin) and 37 × 10³M_r (possibly gpmom)).Analytical separation of the proteins of the Mu virion revealed that it consists of a major head polypeptide with a molecular weight of 33 × 10³, a second head polypeptide of 54 × 10³ (gpF) and two major tail polypeptides with molecular weights of 55 × 10³ and 12.5 × 10³ (gpL and gpY, respectively). In addition, there are five minor components of the tail (including gpN, gpS and gpU) and approximately seven minor components of the head structure of the virion (including gpH).     

Regulation of C4 photosynthesis: Physical and kinetic properties of active (dithiol) and inactive (disulfide) NADP-malate dehydrogenase from Zea mays

NADP-malate dehydrogenase was purified from leaves of Zea mays in the absence of thiol-reducing agents by (NH₄)₂SO₄, polyethylene glycol, and pH fractionation followed by dye-ligand affinity chromatography and gel filtration. The purified enzyme is completely inactive (no activity detected between pH 6 and 9) but can be reactivated by thiol-reducing agents including dithiothreitol and thioredoxin. The active enzyme shows distinctly alkaline pH optima when assayed in either direction; K_m values at pH 8.5 are oxaloacetate, 18 μm; malate, 24 mm; NADPH, 50 μm; and NADP, 45 μm. The reduction of oxaloacetate is inhibited by NADP (competitive with respect to NADPH, K_i = 50 μm). The molecular weight of the native inactive or active enzyme is 150,000 with subunits of M_r 38,000. Active enzyme is much more sensitive (>50-fold) to heat denaturation than is the inactive enzyme and is irreversibly inactivated by N-ethylmaleimide whereas the inactive enzyme is insensitive to this reagent. The active and inactive forms of NADP-malate dehydrogenase are assumed to correspond to dithiol and disulfide forms of the enzyme, respectively. The relative coenzyme-binding affinities of inactive NADP-malate dehydrogenase differ by a factor of 10² from the binding affinities for active NADP-malate dehydrogenase and 10⁴ for non-thiol-regulated NAD-specific malate dehydrogenase. It is proposed that the 100-fold change in differential binding of NADP and NADPH upon conversion of NADP-malate dehydrogenase to the disulfide form may sufficiently alter the equilibrium of the central enzyme-substrate complexes, and hence the catalytic efficiency of the enzyme, to explain the associated loss of activity.     

Glucose-6-phosphate Dehydrogenase and 6-Phosphogluconate Dehydrogenase of Candida tropicalis Partial Purification and Some Properties

Glucose-6-phosphate (G6P) dehydrogenase and 6-phosphogluconate (6PG) dehydrogenase were partially purified about 53-fold and 47-fold, respectively, from the cell-free extract of glucose-grown Candida tropicalis by means of ammonium sulfate fractionation and DEAE-cellulose column chromatography. AMP acted as the competitive inhibitor against G6P and NADP in the G6P dehydrogenase reaction. This inhibition was remarkable at low concentrations of NADP, increasing the sigmoidicity of the NADP-saturation curve. On the other hand, 6PG dehydrogenase was not affected by AMP. Fructose-1,6-bisphosphate (FDP) and phosphoenolpyruvate (PEP) inhibited slightly G6P dehydrogenase. 6PG dehydrogenase was also weakly inhibited by FDP. Apparent Km values of G6P dehydrogenase were calculated as 1.8 × 10^?4 m for G6P and 3.1 × 10^?5 m for NADP. Those of 6PG dehydrogenase were 9.4 × 10^?5 m for 6PG and 2.8 × 10^?5 m for NADP.