Equilibrium binding of coenzymes and substrates to nicotinamide-adenine dinucleotide phosphate-linked isocitrate dehydrogenase from bovine heart mitochondria.

1. The stoicheiometries and affinities of ligand binding to isocitrate dehydrogenase were studied at pH 7.0, mainly by measuring changes in NADPH and protein fluorescence. 2. The affinity of the enzyme for NADPH is about 100-fold greater than it is for NADP+ in various buffer/salt solutions, and the affinities for both coenzymes are decreased by Mg2+, phosphate and increase in ionic strength. 3. The maximum binding capacity of the dimeric enzyme for NADPH, from coenzyme fluorescence and protein-fluorescence measurements, and also for NADP+, by ultrafiltration, is 2 mol/mol of enzyme. Protein-fluorescence titrations of the enzyme with NADP+ are apparently inconsistent with this conclusion, indicating that the increase in protein fluorescence caused by NADP+ binding is not proportional to fractional saturation of the binding sites. 4. Changes in protein fluorescence caused by changes in ionic strength and by the binding of substrates, Mg2+ or NADP+ (but not NADPH) are relatively slow, suggesting conformation changes. 5. In the presence of Mg2+, the enzyme binds isocitrate very strongly, and 2-oxoglutarate rather weakly. 6. Evidence is presented for the formation of an abortive complex of enzyme-Mg2+-isocitrate-NADPH in which isocitrate and NADPH are bound much more weakly than in their complexes with enzyme and Mg2+ alone. 7. The results are discussed in relation to the interpretation of the kinetic properties of the enzyme and its behaviour in the mitochondrion.     

The mechanisms of reductive carboxylation reactions. Carbon dioxide or bicarbonate as substrate of nicotinamide-adenine dinucleotide phosphate-linked isocitrate dehydrogenase and `malic'' enzyme

1. A simple kinetic method was devised to show whether dissolved CO(2) or HCO(3)- ion is the substrate in enzyme-catalysed carboxylation reactions. 2. The time-course of the reductive carboxylation of 2-oxoglutarate by NADPH, catalysed by isocitrate dehydrogenase, was studied by a sensitive fluorimetric method at pH7.3 and pH6.4, with large concentrations of substrate and coenzyme and small carbon dioxide concentrations. 3. Reaction was initiated by the addition of carbon dioxide in one of three forms: (i) as the dissolved gas in equilibrium with bicarbonate; (ii) as unbuffered bicarbonate solution; (iii) as the gas or as an unbuffered solution of the gas in water. Different progress curves were obtained in the three cases. 4. The results show that dissolved CO(2) is the primary substrate of the enzyme, and that HCO(3)- ion is at best a very poor substrate. The progress curves are in quantitative agreement with this conclusion and with the known rates of the reversible hydration of CO(2) under the conditions of the experiments. The effects of carbonic anhydrase confirm the conclusions. 5. Similar experiments on the reductive carboxylation of pyruvate catalysed by the ;malic' enzyme show that dissolved CO(2) is the primary substrate of this enzyme also. 6. The results are discussed in relation to the mechanisms of these enzymes, and the effects of pH on the reactions. 7. The advantages of the method and its possible applications to other enzymes involved in carbon dioxide metabolism are discussed.     

On the mechanism of NADP+-linked isocitrate dehydrogenase from heart mitochondria. II. The transient-state kinetics of the oxidative decarboxylation of isocitrate

The kinetics of a single turnover of enzyme-catalysed oxidative decarboxylation have been studied by mixing a stoichiometric complex of enzyme, isocitrate and Mg2+ with large concentrations of NADP+ in a stopped-flow apparatus, and monitoring the formation of NADPH by fluorescence measurements. A transient is revealed that exhibits enhanced nucleotide fluorescence and is not detectable by light absorption measurements. The results obtained with the largest NADP+ concentrations, such that the product NADPH is largely displaced from its enzyme complex, show that a step that precedes the release of free NADPH is rate-limiting in the oxidative decarboxylation reaction under conditions of catalytic cycling. The rate constants for this step, tentatively identified as the formation of the complex of enzyme, Mg2+ and NADPH from a precursor NADPH-containing complex, and for the dissociation of NADPH from this complex have been estimated from the integrated rate equation for a simple model for the product phase of the reaction, by methods of nonlinear regression analysis. In line with the conclusions from the preceding paper, it is suggested that formation of an abortive complex of enzyme, Mg2+, isocitrate and NADPH under catalytic cycling conditions serves to by-pass the potentially rate-limiting dissociation of NADPH from the enzyme-Mg2+-NADPH complex.     

The ultraviolet fluorescence spectra of DPN-linked isocitrate dehydrogenase from bovine heart.

The emission maximum of DPN-linked isocitrate dehydrogenase from bovine heart shifted from 316 nm to 324 nm as the excitation wavelength was varied from 265 nm to 300 nm. This shift was accompanied by a nonproportional change in fluorescence intensity. Comparisons of the emission spectra of model compounds in aqueous buffer at pH 7.07 and n-butanol showed that lowered solvent polarity led to a blue shift of the peak of free tryptophan without significant change of fluorescence intensity, whereas the fluorescence intensity of tyrosine amide increased markedly without change in emission maximum. The emission peak of mixtures of tryptophan and tyrosine amide shifted to shorter wavelengths as the proportion of tyrosine amide increased. The results suggest a major contribution of tyrosine to the overall fluorescence of the dehydrogenase. DPNH caused quenching and a blue shift of the protein fluorescence maximum when excited between 270 nm and 290 nm, indicating that the two tryptophan residues per subunit of enzyme are located in different microenvironments of the protein and that DPNH may interact preferentially with the residue emitting at the longer wavelength.     

NAD-specific isocitrate dehydrogenase from bovine heart. Interaction with Ca2+ chelators.

The activity of NAD-specific isocitrate dehydrogenase was inhibited by EDTA, EGTA and other nitrogen-containing polycarboxylate Ca2+ chelators in the absence and in the presence of ADP by a mechanism that could not be attributed solely to the removal of free Ca2+. Carboxymethyltartronate (2-oxapropane-1,1,3-tricarboxylate), an oxygen ether polycarboxylate chelator, did not inhibit when ADP was absent. The activation by ADP, a positive effector of the enzyme, decreased with increasing concentration of carboxymethyltartronate, paralleling the removal of free Ca2+ by this chelator. The following were found when free Ca2+ was decreased to negligible concentrations (5-50 nM) with carboxymethyltartronate. (1) Free Ca2+ enhanced, but was not absolutely required for, activation by ADP. (2) Activation of enzyme activity by magnesium citrate neither required nor was increased by Ca2+ when ADP was absent. However, the potentiation of citrate activation by ADP was facilitated by free Ca2+. (3) The reversal of NADPH inhibition of enzyme activity by ADP did not absolutely require Ca2+, but it was enhanced by free Ca2+. (4) The inhibition of enzyme activity by NADH was not reversed by ADP either with or without Ca2+.     

Nicotinamide adenine dinucleotide dependent isocitrate dehydrogenase from beef heart: subunit heterogeneity and enzyme dissociation.

Heterogeneity in the subunits of nicotinamide adenine dinucleotide dependent isocitrate dehydrogenase from beef heart mitochondria was investigated using one- and two-dimensional electrophoretic analyses in polyacrylamide gels. Electrophoresis under nondenaturing conditions, at several values of pH and gel concentration, followed by second-dimension electrophoresis in the presence of sodium dodecyl sulfate showed that the active enzyme contains four different subunits. The details of these two-dimensional patterns, reelectrophoresis of the active enzyme band under nondenaturing conditions, together with additional evidence indicate that under certain nondenaturing conditions the enzyme exists partially dissociated into its subunits. The molecular weights of the four subunits, determined from electrophoretic mobilities obtained in the presence of sodium dodecyl sulfate, were different, varying between 39 000 and 41 300. Tryptic peptide maps of the subunits are substantially different.     

Studies of a reactive histidine of dyphosphopyridine nucleotide-linked isocitrate dehydrogenase from bovine heart.

Diphosphopyridine nucleotide-linked isocitrate dehydrogenase from bovine heart was inactivated at neutral pH by bromoacetate and diethyl pyrocarbonate and by photooxidation in the presence of methylene blue or rose bengal. Inactivation by diethyl pyrocarbonate was reversed by hydroxylamine. Loss of activity by photooxidation at pH 7.07 was accompanied by progressive destruction of histidine with time; loss of 83% of the enzyme activity was accompanied by modification of 1.1 histidyl residues per enzyme subunit. The pH-rate profiles of inactivation by photooxidation and by diethyl pyrocarbonate modification showed an inflection point around pH 6.6, in accord with the pK_a for a histidyl residue of a protein. Partial protection against inactivation by photooxidation or diethyl pyrocarbonate was obtained with substrate (manganous isocitrate or magnesium isocitrate) or ADP; the combination of substrate and ADP was more effective than the components singly. As demonstrated by differential enzyme activity assays between pH 6.4 and pH 7.5 with and without 0.67 mm ADP, modification of the reactive histidyl residue of the enzyme caused a preferential loss of the positive modulation of activity by ADP. The latter was particularly apparent when substrate partially protected the enzyme against inactivation by rose bengal-induced photooxidation.