Interaction of bovine skeletal muscle lactate dehydrogenase with liposomes. Comparison with the data for the heart enzyme

The effects of pH, salt concentration and the presence of oxidized and reduced forms of coenzyme on the interaction of skeletal muscle lactate dehydrogenase with the liposomes derived from the total fraction of bovine erythrocyte lipids were investigated by ultracentrifugation and were compared with those results obtained using the heart-rate isoenzyme which we have previously studied. Liposomes are good adsorptive systems for both types of isoenzyme. In the presence of erythrocyte lipid liposomes, bovine muscle and heart lactate dehydrogenases form two kinds of complex: lactate dehydrogenase adsorbed to liposomes and soluble lactate dehydrogenase-phospholipid complexes. Soluble protein-phospholipid complexes reveal different dependences of their stabilities on pH values and it seems that the nature of the binding site in either isozyme is different. In addition, absorption of the isoenzymes on the liposomes also reveals in difference in the effects of NAD and NADH. While the presence of NAD dissociates LDH-H4 from the liposomes and NADH does not influence its adsorption, NAD promotes the binding of LDH-M4, and NADH favors the dissociation.     

Interaction of bovine heart lactate dehydrogenase with erythrocyte lipids

The interaction between bovine heart lactate dehydrogenase and erythrocyte lipid suspension as a function of pH, NAD, NADH, lipid and salt concentration was studied by ultracentrifugation. In the presence of erythrocyte lipid liposomes the enzyme forms two kinds of complex: lactate dehydrogenase adsorbed to liposomes and soluble lactate dehydrogenase-phospholipid complexes. The two complexes reveal different dependence of their stability on pH values. Lactate dehydrogenase decreases its specific activity when it binds to the phospholipid molecules. Efficient adsorption of lactate dehydrogenase to liposomes occurs in their pH range 6.0-8.0 and at low ionic strength. The adsorption is diminished in the presence of NAD+ but it is not influenced by NADH. Possible mechanisms of the interaction and implications for the function in vivo are discussed.     

Ultracentrifugation studies of the location of the site involved in the interaction of pig heart lactate dehydrogenase with acidic phospholipids at low pH. A comparison with the muscle form of the enzyme

Lactate dehydrogenase (LDH) from the pig heart interacts with liposomes made of acidic phospholipids most effectively at low pH, close to the isoelectric point of the protein (pH = 5.5). This binding is not observed at neutral pH or high ionic strength. LDH-liposome complex formation requires an absence of nicotinamide adenine dinucleotides and adenine nucleotides in the interaction environment. Their presence limits the interaction of LDH with liposomes in a concentration-dependent manner. This phenomenon is not observed for pig skeletal muscle LDH. The heart LDH-liposome complexes formed in the absence of nicotinamide adenine dinucleotides and adenine nucleotides are stable after the addition of these substances even in millimolar concentrations. The LDH substrates and studied nucleotides that inhibit the interaction of pig heart LDH with acidic liposomes can be ordered according to their effectiveness as follows: NADH > NAD > ATP = ADP > AMP > pyruvate. The phosphorylated form of NAD (NADP), nonadenine nucleotides (GTP, CTP, UTP) and lactate are ineffective. Chemically cross-linked pig heart LDH, with a tetrameric structure stable at low pH, behaves analogously to the unmodified enzyme, which excludes the participation of the interfacing parts of subunits in the interaction with acidic phospholipids. The presented results indicate that in lowered pH conditions, the NADH-cofactor binding site of pig heart LDH is strongly involved in the interaction of the enzyme with acidic phospholipids. The contribution of the ATP/ADP binding site to this process can also be considered. In the case of pig skeletal muscle LDH, neither the cofactor binding site nor the subunit interfacing areas seem to be involved in the interaction.     

Conformation of coenzyme fragments when bound to lactate dehydrogenase

The conformations of adenosine, 5′-AMP and 5′-ADP when bound to dogfish M₄ lactate dehydrogenase at pH 7.8 or greater have been determined at 2.8 Å resolution to investigate the events on coenzyme binding. The coenzyme fragments AMP and ADP induce a conformational change in lactate dehydrogenase at pH values less than 6.0 in the same way as do NAD⁺, NADH or ADPR at any pH value. The structure of NAD⁺ when bound to lactate dehydrogenase had previously been determined at 5.0 Å resolution. The structures of the bound adenosine, AMP, ADP and NAD⁺ are compared with the preliminary structure of NAD in a 3.0 Å resolution map of the ternary complex LDH-NAD—pyruvate. Small but significant changes in the binding of the phosphates could be important in the folding of the protein loop over the substrate binding pocket.     

Lactate dehydrogenase isoenzymes of sperm cells and testes

1. The kinetic and metabolic properties of lactate dehydrogenase isoenzyme LDH_x from human sperm cells and rat testes were studied. 2. LDH_x shows a sensitivity to inhibition by stilboestrol diphosphate, urea and guanidinium chloride different from that of the LDH-H₄ and LDH-M₄ isoenzymes. 3. About 10 and 20% of the total lactate dehydrogenase activity of testes and sperm cells respectively were associated with particulate fractions. In sperm cells 11% was localized in the middle piece and 18·8% in the head fraction. LDH_x was found in all particulate fractions of sperm cells. The middle piece contained 41·0% of total LDH_x activity and showed high succinate dehydrogenase activity. 5. The pH-dependence of lactate/pyruvate and NAD⁺/NADH concentration ratios were estimated. Lactate dehydrogenase in sperm cells has maximal activity with NADH as coenzyme at pH7·5 and with NADPH as coenzyme at pH6·0. At pH6·0 a 10% greater oxidation of NADPH than of NADH was found. At acid pH lactate hydrogenase may function as an enzyme bringing about transhydrogenation from NADPH to NAD⁺. 6. In agreement with the stoicheiometry of the lactate de- hydrogenase reaction, the lactate/pyruvate concentration ratio decreased with increasing pH. 7. The lactate/pyruvate and NAD⁺/NADH concentration ratios were estimated with glucose, fructose and sorbitol as substrates and as a function of time after addition of these substrates. During a 20min. period after the addition of the substrates, changes in lactate/pyruvate and NAD⁺/NADH concentration ratios were noticed. Increasing concentration of the substrates mentioned gave rise to asymptotic increases in lactate and pyruvate. 8. Sorbitol did not act as a substrate for LDH_x. 9. The findings described are consistent with the idea that LDH_x is different from other known lactate dehydrogenase isoenzymes, but that it has a metabolic function similar to that of the isoenzymes of other tissues.     

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.     

Properties and synthesis regulation of NAD(P)H dehydrogenases from Rhodobacter capsulatus

Three NAD(P)H dehydrogenases were found and purified from a soluble fraction of cells of the purple non-sulfur bacterium Rhodobacter capsulatus, strain B10. Molecular mass of NAD(P)H, NADPH and NADH dehydrogenases are 67 000 (4 · 18 000), 35 000 and 39 000, and the isoelectric points are 4.6, 4.3 and 4.5, respectively. NAD(P)H dehydrogenase is characterized by a higher sensitivity to quinacrine, NADPH dehydrogenase by its sensitivity to p-chloromercuribenzoate and NADH dehydrogenase by its sensitivity to sodium arsenite. In contrast to the other two enzymes, NAD(P)H dehydrogenase is capable of oxidizing NADPH as well as NADH, but the ratio of their oxidation rates depends on the pH. All NAD(P)H dehydrogenases reacted with ferricyanide, 2,6-dichlorophenolindophenol, benzoquinone and naphthoquinone, but did not exhibit transhydrogenase, reductase or oxidase activity. Moreover, NADH dehydrogenase was also capable of reducing FAD and FMN. NAD(P)H and NADH dehydrogenases possessed cytochrome-c reductase activity, which was stimulated by menadione and ubiquinone Q₁. The activity of NAD(P)H and NADH dehydrogenases depended on culture-growth conditions. The activity of NAD(P)H dehydrogenase from cells grown under chemoheterotrophic aerobic conditions was the lowest and it increased notably under photoheterotrophic anaerobic conditions upon lactate or malate growth limitation. The activity of NADH dehydrogenase was higher from the cells grown under photoheterotrophic anaerobic conditions upon nitrate growth limitation and under chemoheterotrophic aerobic conditions. NADPH dehydrogenase synthesis dependence on R. capsulatus growth conditions was insignificant.     

Enzyme-catalyzed free radical reactions with nicotinamide-adenine nucleotides: I. Lactate dehydrogenase-catalyzed chain oxidation of bound NADH by superoxide radicals

The radiation-induced oxidation of NADH by Superoxide radicals proceeds in the presence of lactate dehydrogenase by a chain mechanism. The reaction is initiated by O₂^? radicals, and propagated by O₂. The chain length is a function of [NADH]/[lactate dehydrogenase], the concentration of O₂, the dose rate, and pH. The chain reaction can be inhibited by addition of ascorbic acid.     

Substrate-induced conformational changes in lactate dehydrogenase. Proteolysis of the immobilized enzyme in the presence of specific substrates.

We report here a new approach to the study of the conformation of enzymes in the presence of specific substrates. Rabbit muscle lactate dehydrogenase was attached to CL-Sepharose via a cleavable spacer arm (-NH-(CH2)6NHCO(CH2)2SS(CH2)2CO-). The bound lactate dehydrogenase was digested with subtilisin BPN' in the presence of substrates of lactate dehydrogenase. The use of a flow system permits the maintenance of saturating levels of substrates. Proteolysis was followed by loss of activity of the enzyme column. The time course of proteolysis in the presence of either NADH, NAD+, or pyruvate alone did not differ from the control. However, when NADH and pyruvate were present simultaneously, the enzyme became more susceptible to proteolysis. The initial rate of proteolysis was increased by 40%. The abortive ternary complex (lactate dehydrogenase - NAD+ - pyruvate) also showed an increase in susceptibility to proteolysis. These findings clearly show that the productive ternary complex (lactate dehydrogenase - NADH - pyruvate) is conformationally different from the apoenzyme and binary complexes under optimal catalytic conditions.     

The interaction of pyridine-adenine-dinucleotides containing a hydrazide group with swine muscle lactate dehydrogenase]

Hydrazide group of 4-substituted NAD analogues is shown to interact with functional groups of substrate-binding site in double complexes with pig muscle lactate dehydrogenase (isoenzyme M4). The lactic acid residue, which is structurally incorporated into NAD analogue, improves slightly the binding of dinucleotide, while 2,2,6,6-tetramethylpiperidine-1-oxyl residue considerably decreases the firmless of binding. The comparison of the inhibitory ability of oxamate, incotinic acid hydraxide and their spin-labelled derivatives indicates the restricted and stiff sizes of a substrate-binding site.     

Relationship between hydroxypyruvate and the production of oxalate in vitro

Chicken liver lactate dehydrogenase (l-lactate: NAD⁺ oxidoreductase, EC 1.1.1.27) catalyses the reversible reduction reaction of hydroxypyruvate to l-glycerate. It also catalyses the oxidation reaction of the hydrated form of glyoxylate to oxalate and the reduction of the non-hydrated form to glycolate. At pH 8, these latter two reactions are coupled. The coupled system equilibrium is attained when the NAD⁺/NADH ratio is greater than unity.Hydroxypyruvate binds to the enzyme at the same site as the pyruvate. When there are substances with greater affinity to this site in the reaction medium and their concentration is very high, hydroxypyruvate binds to the enzyme at the l-lactate site. In vitro and with purified preparation of lactate dehydrogenase, hydroxypyruvate stimulates the production of oxalate from glyoxylate-hydrated form and from NAD; the effect is due to the fact that hydroxypyruvate prevents the binding of non-hydrated form of glyoxylate to the lactate dehydrogenase in the pyruvate binding site. At pH 8, the l-glycerate stimulates the production of glycolate from glyoxylate-non-hydrated form and NADH since hydroxypyruvate prevents the binding of glyoxylate-hydrated form to the enzyme.     

Structure of lactate dehydrogenase inhibitor generated from coenzyme.

Two inhibitors of lactate dehydrogenase generated during NADH storage have been isolated by chromatography. One is a dimer of the dinucleotide where the AMP moiety is unmodified. The other is also generated from NAD+ in the presence of a high concentration of phosphate ions at alkaline pH. This inhibitor was proved to be the addition compound of one phosphate group to position C-4 of the nicotinamide ring of NAD+ by NMR spectroscopy, enzymatic cleavage, and dissociation to NAD+ at neutral pH. This compound is a competitive inhibitor with respect to NAD+ in the presence of the lactate dehydrogenase with a Ki of 2 X 10(-7) M. The interaction of this inhibitor with lactate dehydrogenase is discussed relative to the structure of this enzyme.     

Schistosoma mansoni: Purification and characterization of malate dehydrogenases

Isoelectric focusing of a homogenate of Schistosoma mansoni, followed by malate dehydrogenase-specific staining, showed the presence of two major and five minor malate dehydrogenase isoenzymes (EC 1.1.1.37), with isoelectric points ranging from 7.3 to 9.5. The malate dehydrogenase isoenzymes were purified by gel filtration, followed by ion-exchange chromatography on DEAE- and CM-cellulose. The isoenzymes could be differentiated by their susceptibility to substrate inhibition. No differences in the Michaelis-Menten constants for substrate were found. One of the isoenzymes is inhibited by 5′-AMP. Further purification of this particular isoenzyme was achieved by affinity chromatography on 5′-AMP-Sepharose 4B. Analysis after subcellular fractionation indicated a mitochondrial origin for this isoenzyme. The mitochondrial isoenzyme (at a recovery of 80%) was purified 218-fold compared to the crude soluble extract, and contained about 40% of the total malate dehydrogenase activity. The enzyme has a molecular weight of 65,500 and showed absolute specificity for l-malic acid, NAD, and NADH. The final preparation has a specific activity of 451 U/mg protein. Physicochemical studies, including binding constants, substrate inhibition, thermostability, and pH optima, demonstrated differences between the mitochondrial and cytoplasmic enzymes. A role for malate dehydrogenase in Schistosoma mansoni metabolism is discussed.     

Relationship between hydroxypyruvate and the production of oxalate in vitro.

Chicken liver lactate dehydrogenase (L-lactate:NAD+ oxidoreductase, EC1.1.1.27) catalyses the reversible reduction reaction of hydroxypyruvate to L-glycerate. It also catalyses the oxidation reaction of the hydrated form of glyoxylate to oxalate and the reduction of the non-hydrated form of glyoxylate to oxalate and the reduction of the non-hydrated form to glycolate. At pH 8, these latter two reactions are coupled. The coupled system equilibrium is attained when the NAD+/NADH ratio is greater than unity. Hydroxypyruvate binds to the enzyme at the same site as the pyruvate. When there are substances with greater affinity to this site in the reaction medium and their concentration is very high, hydroxypyruvate binds to the enzyme at the L-lactate site. In vitro and with purified preparation of lactate dehydrogenase, hydroxypyruvate stimulates the production of oxalate from glyoxylate-hydrated form and from NAD; the effect is due to the fact that hydroxypyruvate prevents the binding of non-hydrated form of glyoxylate to the lactate dehydrogenase in the pyruvate binding site. At pH 8, THE L-glycerate stimulates the production of glycolate from glyoxylate-non-hydrated form and NADH since hydroxypyruvate prevents the binding of glyoxylate-hydrated form to the enzyme     

Cofactor Engineering: a Novel Approach to Metabolic Engineering in Lactococcus lactis by Controlled Expression of NADH Oxidase

NADH oxidase-overproducing Lactococcus lactis strains were constructed by cloning the Streptococcus mutans nox-2 gene, which encodes the H₂O-forming NADH oxidase, on the plasmid vector pNZ8020 under the control of the L. lactis nisA promoter. This engineered system allowed a nisin-controlled 150-fold overproduction of NADH oxidase at pH 7.0, resulting in decreased NADH/NAD ratios under aerobic conditions. Deliberate variations on NADH oxidase activity provoked a shift from homolactic to mixed-acid fermentation during aerobic glucose catabolism. The magnitude of this shift was directly dependent on the level of NADH oxidase overproduced. At an initial growth pH of 6.0, smaller amounts of nisin were required to optimize NADH oxidase overproduction, but maximum NADH oxidase activity was twofold lower than that found at pH 7.0. Nonetheless at the highest induction levels, levels of pyruvate flux redistribution were almost identical at both initial pH values. Pyruvate was mostly converted to acetoin or diacetyl via α-acetolactate synthase instead of lactate and was not converted to acetate due to flux limitation through pyruvate dehydrogenase. The activity of the overproduced NADH oxidase could be increased with exogenously added flavin adenine dinucleotide. Under these conditions, lactate production was completely absent. Lactate dehydrogenase remained active under all conditions, indicating that the observed metabolic effects were only due to removal of the reduced cofactor. These results indicate that the observed shift from homolactic to mixed-acid fermentation under aerobic conditions is mainly modulated by the level of NADH oxidation resulting in low NADH/NAD⁺ ratios in the cells.     

Molecular orientation and position of the pig M4 and H4 isoenzymes of lactate dehydrogenase in their crystal cells

Ternary complexes of M₄ and H₄ isoenzymes of porcine lactate dehydrogenase have been crystallized, the M₄ isoenzyme in space group P22₁2₁ with one half molecule per asymmetric unit, and the H₄ isoenzyme in space group C₂ with one whole molecule per asymmetric unit. The orientation and position of the tetramers in their unit cells have been determined by X-ray analysis. Rotation function results comparing the ternary complexes of the pig M₄ isoenzyme with the known structure of the dogfish M₄ enzyme not only defined the direction but also permitted recognition of the individual P, Q and R molecular 2-fold axes. The position of the molecular center was determined by placing a properly oriented dogfish M₄ lactate dehydrogenase electron density into the pig muscle cell. Structure factors were calculated as the molecular center was varied along the common crystallographic and molecular 2-fold axis and compared with observed amplitudes. Precession photographs of the three major zones of the monoclinic pig H₄ isoenzyme exhibited striking similarities to the corresponding zones of the orthorhombio pig M₄ isoenzyme, in spite of the differences in space groups. These similarities permit the determination of approximate phases from the implied orientation and position of the pig H₄ lactate dehydrogenase molecule in its monoclinic cell.     

Thermodynamic studies of the activation of rabbit muscle lactate dehydrogenase by phosphate.

In an attempt to trace the source of phosphate activation of the enzyme-catalysed pyruvate-lactate interconversion by rabbit muscle lactate dehydrogenase, equilibrium constants were measured to examine the effects of phosphate on interactions pertinent to the enzymic process. Frontal gel-chromatographic studies of the binding of NADH to the enzyme established that the intrinsic association constant is doubled in the presence of 50 mM-phosphate in the buffer (pH 7.4, I0.15). From kinetic studies of the competition between NAD+ and NADH for the coenzyme-binding sites of the enzyme it is concluded that the binding of oxidized nicotinamide nucleotide is also doubled in the presence of 50 mM-phosphate. Competitive-inhibition studies and fluorescence-quenching measurements indicated the lack of a phosphate effect on ternary-complex formation between enzyme-NADH complex and oxamate, a substrate analogue of pyruvate. The equilibrium constant for the interaction between enzyme-NAD+ complex and oxalate, an analogue of lactate, was also shown, by difference spectroscopy, to be insensitive to phosphate concentration. Provided that the effects observed with the substrate analogues mimic those operative in the kinetic situation, the equilibrium constant governing the isomerization of ternary complex is also independent of phosphate concentration. It is concluded that enhanced coenzyme binding is the source of phosphate activation of the rabbit muscle lactate dehydrogenase system.     

Purification and molecular and enzymic properties of mitochondrial NADH dehydrogenase.

Mitochondrial NADH dehydrogenase has been purified to homogeneity by resolution of Complex I from beef heart mitochondria with the chaotrope NaClO₄ and precipitation of the enzyme with ammonium sulfate. The enzyme is water-soluble, has a molecular weight of 69,000 ± 1000 as determined by gel filtration on Sephadex G-100 and agarose 1.5 M. It is an iron-sulfur flavoprotein, with the ratio of flavin (FMN) to nonheme iron to labile sulfide being 1:5–6:5–6. The FMN content suggests a minimum molecular weight of 74,000 ± 3000 for the enzyme. NADH dehydrogenase is composed of three subunits with apparent M_r values, as determined by acrylamide gel electrophoresis as well as by gel filtration on agarose 5 M both in the presence of sodium dodecyl sulfate, of about 51,000, 24,000, and 9–10,000. Coomassie blue stain intensities of the subunits on acrylamide gels suggest that they are present in NADH dehydrogenase in equimolar amounts. However, summation of the apparent M_r values of the dodecyl sulfate-treated subunits appears to overestimate the molecular weight of the native enzyme. The amino acid compositions of NADH dehydrogenase and of each of the isolated and purified subunits have been determined. NADH dehydrogenase catalyzes the oxidation of NADH and NADPH by quinones, ferric compounds, and NAD (3-acetylpyridine adenine dinucleotide was used). All the activities of NADH dehydrogenase are greatly stimulated by addition of guanidine (up to 150 mm), alkylguanidines, arginine, and arginine methyl ester to the assay medium. Phosphoarginine had no effect. These results pointed to the importance of the positively charged guanido group, which appears to interact with and neutralize the negative charges on NAD(P)H and thereby allow for better enzyme-substrate interaction. In the absence of guanidine, NADPH is essentially unoxidized by the enzyme at pH values above 6.0. However, both NADPH dehydrogenase and NADPH → NAD transhydrogenase activities increase dramatically as the assay pH is lowered below pH = 6. Since the pK of the 2′-phosphate of NADPH is 6.1, it appears that the above pH effect is related to protonation of the 2′-phosphate, thus rendering NADPH a closer electronic analog of NADH, which is the primary substrate of the enzyme.     

Binding of nicotinamide nucleotides to dihydrolipoamide dehydrogenase measured with spin-labeled analogs

Binding of NAD and NADH to dihydrolipoamide dehydrogenase fromEscherichia coli and from pig heart was measured using the spin-labeled analogsN ⁶-(2,2,6,6-tetramethylpiperidine-4-yl-1-oxyl)-NAD and -NADH. A decrease in the peak amplitudes of the respective EPR spectra results after adding enzyme to the cofactor analogs. With the bacterial enzyme normal hyperbolic saturation behavior with the NAD analog and one binding site per subunit (K _s =0.51 mM) are observed, while the NADH analog reveals a sigmoidal binding characteristic. A high-affinity and a low-affinity site (K _s =0.087 and 0.33 mM) are found for binding of the NAD analog to the pig heart enzyme and only one type of binding site is observed for the NADH analog (K _s =22 µM).