Isotope effects on binding of NAD+ to lactate dehydrogenase

The isotope effect on binding [4-2H]NAD+ and [4-3H]NAD+ to lactate dehydrogenase has been shown to be 1.10 +/- 0.03 by whole molecule isotope ratio mass spectrometry and 1.085 +/- 0.01 by 3H/14C scintillation counting. These values demonstrate that specific interactions of the nicotinamide ring with the enzyme make the C-H bond at C-4 less stiff in the binary complex.     

NADH binding to porcine mitochondrial malate dehydrogenase.

The binding of NADH to porcine mitochondrial malate dehydrogenase in phosphate buffer at pH 7.5 has been studied by equilibrium and kinetic methods. Hyperbolic binding was obtained by fluorimetric titration of enzyme with NADH, in the presence or absence of hydroxymalonate. Identical results were obtained for titrations of NADH with enzyme in the presence or absence of hydroxymalonate, measured either by fluorescence emission intensity or by the product of intensity and anisotropy. The equilibrium constant for NADH dissociation was 3.8 +/- 0.2 micrometers, over a 23-fold range of enzyme concentration, and the value in the presence of saturating hydroxymalonate was 0.33 +/- 0.02 micrometer over a 10-fold range of enzyme concentration. The rate constant for NADH binding to the enzyme in the presence of hydroxymalonate was 3.6 X 10(7) M-1 s-1, while the value for dissociation from the ternary complex was 30 +/- 1 s-1. No limiting binding rate was obtained at pseudo-first order rate constants as high as 200 s-1, and the rate curve for dissociation was a single exponential for at least 98% of the amplitude. In addition to demonstrating that the binding sites are independent and indistinguishable, the absence of effects of enzyme concentration on the KD value indicates that NADH binds with equal affinity to monomeric and dimeric enzyme forms.     

Calorimetric investigation of binding of NADH to pig muscle lactate dehydrogenase

Thermal titrations have been performed to study the enthalpy of binding (Δ H_b) of the reduced coenzyme, NADH, to the pig muscle isoenzyme (M₄) of lactate dehydrogenase (EC 1.1.1.27). It has been shown that at 25°C, pH 7.0, in 0.2 M phosphate buffer Δ H_b is ?32.5 ± 1.5 kcal per mole of enzyme. The calorimetric titration data can be well represented within the limits of experimental error by a theoretical binding curve calculated on the assumption of four independent and identical binding sites.     

Kinetic behaviour of chicken liver mitochondrial malate dehydrogenase and lactate dehydrogenase mixtures

• 1.1. In the mitochondria of chicken liver cells there is lactate dehydrogenase activity that catalyses the reduction of the oxaloacetate by the NADH.
• 2.2. The presence of lactate dehydrogenase in the malate dehydrogenase preparations causes an apparent activation in the double-reciprocal plot at high oxaloacetate concentrations that depends on the lactate dehydrogenase/malate dehydrogenase ratio in the preparation.
• 3.3. The separation of the two molecular forms of chicken liver mitochondrial malate dehydrogenase, free from lactate dehydrogenase, is described.

     

Kinetic behaviour of soluble and mitochondrial bound lactate dehydrogenase

Rabbit liver mitochondrial fraction shows lactate dehydrogenase activity. The kinetic behaviour of mitochondrial bound enzyme fits a bibi sequential type mechanism as well as the cytosolic rabbit liver lactate dehydrogenase. The bound enzyme has greater values of Km(NADH) and Km(pyruvate) than the soluble one, suggesting that binding induces a decrease in the affinity of both substrates. The behaviour of the free and the mitochondrial-bound enzyme is of the Michaelis-Menten type, but the kinetics of a mixture of rabbit liver cytosolic and mitochondrial-bound lactate dehydrogenase is sigmoidal, suggesting that a cooperative phenomenon takes place.     

Ligand binding and protein dynamics in lactate dehydrogenase

Recent experimental studies suggest that lactate dehydrogenase (LDH) binds its substrate via the formation of a LDH/NADH.substrate encounter complex through a select-fit mechanism, whereby only a minority population of LDH/NADH is binding-competent. In this study, we perform molecular dynamics calculations to explore the variations in structure accessible to the binary complex with a focus on identifying structures that seem likely to be binding-competent and which are in accord with the known experimental characterization of forming binding-competent species. We find that LDH/NADH samples quite a range of protein conformations within our 2.148 ns calculations, some of which yield quite facile access of solvent to the active site. The results suggest that the mobile loop of LDH is perhaps just partially open in these conformations and that multiple open conformations, yielding multiple binding pathways, are likely. These open conformations do not require large-scale unfolding/melting of the binary complex. Rather, open versus closed conformations are due to subtle protein and water rearrangements. Nevertheless, the large heat capacity change observed between binding-competent and binding-incompetent can be explained by changes in solvation and an internal rearrangement of hydrogen bonds. We speculate that such a strategy for binding may be necessary to get a ligand efficiently to a binding pocket that is located fairly deep within the protein's interior.     

Dynamics of protein ligand binding on multiple time scales: NADH binding to lactate dehydrogenase

Although the importance of atomic motion to how proteins function has been conjectured for several decades, the characterization of protein dynamics on multiple time scales is scant. This is because of severe experimental and theoretical difficulties, particularly characterizing the nanosecond to millisecond time scales. Here, we apply advanced laser-induced temperature-jump relaxation spectroscopic techniques to examine the kinetics of NADH binding to lactate dehydrogenase over this time scale. The bimolecular rate process, at about 290 micros, is easily observed as are multiple faster events (with relaxation times of 200 ns, 3.5 micros, and 24 micros), revealing a rich dynamical nature of the binding step. The results show that there are multiple structures of bound enzyme-ligand complexes, some of which are likely to be far from the catalytically productive structure. The results have important implications for interpretations of the binding thermodynamics of ligands to LDH and, by extension, to other proteins. The observed processes likely play a role in the dynamics of the chemistry that is catalyzed by lactate dehydrogenase.     

Ligand binding and stabilization of malate- and lactate dehydrogenase

Binding of coenzymes, coenzyme fragments and phenolate ligands to malate- and lactate dehydrogenase was studied. From linear competition in titration experiments, the coenzyme binding site was concluded to bind all the ligands employed. The analogy between the phenolate ligands and tetraiodofluorescein which is known to bind at the adenosine binding site suggests binding of phenolates at this site. Coenzymes and coenzyme fragments retard the irreversible thermal inactivation of the enzymes. The retardation effect decreases in the order NADH greater than NAD greater than ADPR greater than or equal to AMP for both enzymes. Phenolate ligands binding to the adenosine pocket do not stabilize the enzymes. The stabilization is concluded to originate from the interaction of coenzyme phosphate and nicotinamide with the enzymes. The interactions with the adenosine moiety and with the second ribose seem to be ineffective in retardation of thermal denaturation.     

The differential binding of lactate dehydrogenase (LDH) isozymes to ribonucleoprotein particles

An attempt was made to explore the possibility that in higher organisms gene expression might be controlled at the cytoplasmic sites of protein synthesis by interfering with the release of certain proteins from their templates. The existence of such mechanisms would be indicated, for instance, by the presence of tissue-foreign proteins in the ribosome fraction, such as tissue-atypical LDH isozymes. Ribosomes and postmicrosomes were prepared from guinea pig liver and kidney in 0.88 M sucrose +10⁻⁴M MgCl₂ solution and analyzed by starch gel electrophoresis for the isozyme patterns of particle-associated LDH. Ribosomes isolated from both organs were found to be associated with LDH. The enzyme could not be removed from the particles by repeated resuspension in sucrose medium, but treatment of the particles with agents, which cause a disintegration of their structure, as well as with salt solutions of high ionic strength released LDH in nonsedimentable form. The isozyme patterns of particle-associated LDH were different from those of the total homogenate. A correlation was found between the electrophoretic mobility of a given isozyme and the amounts of it which were recovered from the ribosome fraction. The results indicated that basic isozymes were preferentially bound to the ribonucleoprotein particles during fractionation in solutions of low ionic strength and did not represent genuine ribosomal enzyme proteins.     

Macro lactate dehydrogenase (LD) due to protein binding of LD isoenzyme 1

Abnormal lactate dehydrogenase (LD) isoenzyme patterns apparently due to protein binding of LD-1 have been observed in a patient with hepatoma. The abnormal patterns were observed within 30 h of death but were preceded by normal LD isoenzyme patterns. Heat treatment of the abnormal specimens followed by addition of control serum reproduced the abnormal pattern. This is consistent with immunoglobulin binding of LD. Results such as those observed in this case could serve to confound the interpretation of LD isoenzyme analyses. The diagnostic significance of these results is not clear.     

Functional anion binding sites in dogfish M4 lactate dehydrogenase

X-ray diffraction data have been collected from dogfish M₄ lactate dehydrogenase crystals in which ammonium sulfate had been exchanged by citrate at pH 6.0 and 7.8. Data were also collected from crystals which had been soaked in 0.1 m oxamate, a lactate dehydrogenase inhibitor. The difference electron density maps obtained have been interpreted in terms of two exchangeable anion binding sites, one at the active center and one between two subunits. The active center site is coincident with the substrate binding site in a ternary complex, while the subunit boundary site, which has been observed in several different forms of the enzyme, may be involved in stabilizing the tetramer.     

The effects of adenine nucleotides on NADH binding to mitochondrial malate dehydrogenase

The effects of adenine nucleotides on initial velocity and NADH binding have been studied with the malate dehydrogenase reaction. ATP, ADP, and AMP were inhibitors competitive with NADH and uncompetitive with oxaloacetate but caused only 50–60% inhibition at saturating concentrations. Direct fluorescence titrations indicated that saturating concentrations of the adenine nucleotides displaced 50–60% of the bound NADH from enzyme-NADH complex. Adenine and adenosine had no inhibitory effect but ADP-ribose caused complete inhibition and NADH dissociation. The possible mechanistic basis for these results and their physiological implications are discussed.     

The approach to the Michaelis complex in lactate dehydrogenase: the substrate binding pathway

We examine here the dynamics of forming the Michaelis complex of the enzyme lactate dehydrogenase by characterizing the binding kinetics and thermodynamics of oxamate (a substrate mimic) to the binary lactate dehydrogenase/NADH complex over multiple timescales, from nanoseconds to tens of milliseconds. To access such a wide time range, we employ standard stopped-flow kinetic approaches (slower than 1 ms) and laser-induced temperature-jump relaxation spectroscopy (10 ns-10 ms). The emission from the nicotinamide ring of NADH is used as a marker of structural transformations. The results are well explained by a kinetic model that has binding taking place via a sequence of steps: the formation of an encounter complex in a bimolecular step followed by two unimolecular transformations on the microsecond/millisecond timescales. All steps are well described by single exponential kinetics. It appears that the various key components of the catalytically competent architecture are brought together as separate events, with the formation of strong hydrogen bonding between active site His(195) and substrate early in binding and the closure of the catalytically necessary protein surface loop over the bound substrate as the final event of the binding process. This loop remains closed during the entire period that chemistry takes place for native substrates; however, motions of other key molecular groups bringing the complex in and out of catalytic competence appear to occur on faster timescales. The on-enzyme K(d) values (the ratios of the microscopic rate constants for each unimolecular step) are not far from one. Either substantial, approximately 10-15%, transient melting of the protein or rearrangements of hydrogen bonding and solvent interactions of a number of water molecules or both appear to take place to permit substrate access to the protein binding site. The nature of activating the various steps in the binding process seems to be one overall involving substantial entropic changes.     

The use of auramine O to study ligand binding and subunit cooperativity of lactate dehydrogenase

The tetrameric molecule of pig skeletal muscle lactate dehydrogenase binds a cationic fluorescent probe, auramine O, at four equal non-interacting sites with a dissociation constant of (1.25 +/- 0.2) X 10(-4) M. Fluorescence of the dye/enzyme mixture is strongly pH-dependent, with a maximum at pH 6.3-6.8. Auramine O-binding sites are located outside the active center of the enzyme. The microenvironment of the bound dye changes upon interaction of lactate dehydrogenase with NAD+, NADH, ADP and pyruvate. The binding of specific ligands induces an increase in fluorescence of auramine O-enzyme complex. This effect was used to determine the dissociation constants of the complexes of lactate dehydrogenase with specific ligands. Pyruvate was demonstrated to bind to the apoenzyme-auramine O complex with a dissociation constant of 5.2 X 10(-4) M. With the use of auramine O, it became possible to reveal subunit interactions within the tetrameric molecule of lactate dehydrogenase. They are manifested in the changes of the microenvironment of a dye-binding site located on one of the subunits induced by the binding of ligands in the active center of a neighboring subunit.     

Semiempirical calculations of the oxygen equilibrium isotope effect on binding of oxamate to lactate dehydrogenase

Semiempirical methods have been used in an attempt to predict theoretically the experimentally observed value of 0.9840 for the oxygen isotope effect on binding of oxamate to lactate dehydrogenase. The overall strategy involved vibrational analysis of oxamate in two different environments; that of the active site residues and in aqueous solution. The comparison of calculated values with the experimentally determined isotope effect proved the AM1 Hamiltonian to be superior to the PM3 Hamiltonian in this modelling. While most tested methods of accounting for solvent effects on the vibrational frequencies of the solute yielded similar results it turned out that what was crucial for the purpose of determination of the isotope effect was the model of oxamate in the active site of the enzyme. In particular, the major factor responsible for the inverse value of this isotope effect can be ascribed to the formation of an ordered, bifurcated hydrogen bond between the oxamate carboxylate and the guanidinium group of the active site histidine. Correspondence to: P. Paneth