The pH dependence of the reductive carboxylation of pyruvate by malic enzyme

The maximum velocity of the malic enzyme (L-malate: NADP+ oxidoreductase (oxaloacetate-decarboxylating), EC 1.1.1.40) reductive carboxylation of pyruvate and V/KCO2 are pH-independent from pH 5.5 to pH 8.5. V/K for pyruvate exhibits pK values values of 6.50 +/- 0.25 and 7.25 +/- 0.25. These data suggest that the binding of pyruvate locks the protonation state of enzyme. In addition, the pK values are within experimental error identical for the pH dependence of V/Kmalate and V/Kpyruvate. Thus, the catalytic groups appear to have reverse protonation states in the two reaction directions. The ratio of (V/Kmalate)/(V/Kpyruvate) is 100, suggesting that the protonation state of enzyme is optimum in the malate oxidative decarboxylation direction. Thus, the group with a pK of about 6 is unprotonated and the group with a pK of 7.5 is protonated for malate decarboxylation, and the opposite is true for pyruvate reductive carboxylation.     

pH studies on the chemical mechanism of rabbit muscle pyruvate kinase. 1. Alternate substrates oxalacetate, glycolate, hydroxylamine, and fluoride

The decarboxylation of oxalacetate shows equilibrium-ordered kinetics, with Mg2+ adding before oxalacetate. The Ki for Mg2+ increases below a pK of 6.9, corresponding to a ligand of the metal that is probably glutamate, and decreases above a pK of 9.2, corresponding to water coordinated to enzyme-bound Mg2+. Both V and V/KOAA decrease above the pK of 9.2, suggesting that the carbonyl oxygen of oxalacetate must replace water in the inner coordination sphere of Mg2+ prior to decarboxylation. The enzyme-Mg2+-oxalacetate complex must be largely an outer sphere one, however, since the pK of 9.2 is seen in the V profile. The phosphorylation of glycolate or N-hydroxycarbamate (the actual substrate that results from reaction of hydroxylamine with bicarbonate) occurs only above the pK of 9.2, with V/K profiles decreasing below this pH. The alkoxides of these substrates appear to be the active species, replacing water in the coordination sphere of Mg2+ prior to phosphorylation by MgATP. Glycolate, but not N-hydroxycarbamate, can bind when not an alkoxide, since the V profile for the former decreases below a pK of 8.9, while V for the latter is pH independent. Initial velocity patterns for phosphorylation of fluoride in the presence of bicarbonate show saturation by MgATP but not by fluoride. The V/K profile for fluoride decreases above the pK of 9.0, showing that fluoride must replace water in the coordination sphere of Mg2+ prior to phosphorylation. None of the above reactions is sensitive to the protonation state of the acid-base catalyst that assists the enolization of pyruvate in the physiological reaction.     

pH dependence of kinetic parameters for oxalacetate decarboxylation and pyruvate reduction reactions catalyzed by malic enzyme

Both chicken liver NADP-malic enzyme and Ascaris suum NAD-malic enzyme catalyze the metal-dependent decarboxylation of oxalacetate. Both enzymes catalyze the reaction either in the presence or in the absence of dinucleotide. The presence of dinucleotide increases the affinity of oxalacetate for the chicken liver NADP-malic enzyme, but this information could not be obtained in the case of A. suum NAD-malic enzyme because of the low affinity of free enzyme for NAD. The kinetic mechanism for oxalacetate decarboxylation by the chicken liver NADP-malic enzyme is equilibrium ordered at pH values below 5.0 with NADP adding to enzyme first. The Ki for NADP increases by a factor of 10 per pH unit below pH 5.0. An enzyme residue is required protonated for oxalacetate decarboxylation (by both enzymes) and pyruvate reduction (by the NAD-malic enzyme), but the beta-carboxyl of oxalacetate must be unprotonated for reaction (by both enzymes). The pK of the enzyme residue of the chicken liver NADP-malic enzyme decreases from a value of 6.4 in the absence of NADP to about 5.5 with Mg2+ and 4.8 with Mn2+ in the presence of NADP. The pK value of the enzyme residue required protonated for either oxalacetate decarboxylation or pyruvate reduction for the A. suum NAD-malic enzyme is about 5.5-6.0. Although oxalacetate binds equally well to protonated and unprotonated forms of the NADP-enzyme, the NAD-enzyme requires that oxalacetate or pyruvate selectively bind to the protonated form of the enzyme. Both enzymes prefer Mn2+ over Mg2+ for oxalacetate decarboxylation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on the mechanism of the malate dehydrogenase reaction.

The stereospecificity of the chicken heart mitochondrial malate dehydrogenase as well as the ability of this enzyme to form various abortive complexes has been further investigated. The enzyme was found to be specific for the A-hydrogen of NADH. Complex formation of the enzyme with oxalacetate and oxidized coenzymes is pH-dependent and is promoted at alkaline pH values. The enol form of oxalacetate appears to be the species that participates in the formation of the complexes. The binding of L-malate, D-malate, or hydroxymalonate to the enzyme. NADH complex is also pH-dependent, and involves a group on the enzyme with a pK of 7.5. The binding of L-malate is promoted at alkaline pH values, whereas the binding of D-malate and hydroxymalonate is favored at acidic pH values. These results indicate that L-malate and enol-oxalacetate preferentially or exclusively bind to the nonprotonated form of the enzyme, whereas keto-oxalactate, hydroxymalonate, and D-malate only bind to the protonated form of the enzyme. Based on this conclusion, a detailed chemical mechanism for the malate dehydrogenase reaction has been postulated and a schematic illustration of the transition state of the enzyme is presented.     

Steady-state kinetic studies of the metal ion-dependent decarboxylation of oxalacetate catalyzed by pyruvate kinase

Steady-state kinetic studies with differing divalent metals ions have been carried out on the pyruvate kinase-catalyzed, divalent cation-dependent decarboxylation of oxalacetate to probe the role of the divalent metal ion in this reaction. With either Mn2+ or Co2+, initial velocity patterns show that the divalent metal ion is bound to the enzyme in a rapid equilibrium prior to the addition of oxalacetate. Further, there is no change in the initial velocity patterns or the kinetic parameters in the presence or absence of K+, indicating that K+ is not required for oxalacetate decarboxylation. Dead-end inhibition of the decarboxylation reaction by the physiological substrate phosphoenolpyruvate indicates that phosphoenolpyruvate binds only to the enzyme-metal ion complex and not to free enzyme. The pKi values for both Mn2+ and Co2+ decrease below a pK of 7.0, and increase above a pK of 8.9. Since these pK values are the same for both ions, both of the observed pK values must be attributable to enzymatic residues. The pK of 7.0 is presumably that of a ligand to the metal ion, while the pK of 8.9 is probably that of the lysine involved in enolization of pyruvate in the normal physiological reaction. However, with Co2+ as divalent cation, the V for oxalacetate decreases above a pK of 8.0, the V/K decreases above two pK values averaging 7.8, and the pKi for oxalate decreases above a single pK of 7.3. These data indicate that metal-coordinated water is displaced during the binding of substrates or inhibitors and the other pK value observed in both V and V/K pH profiles (pK of 8.3 with Co2+ and 9.2 with Mg2+) is an enzymatic residue whose deprotonation disrupts the charge distribution in the active site and decreases activity.     

Isotope effect studies of chicken liver NADP malic enzyme: role of the metal ion and viscosity dependence

The role of the metal ion in the oxidative decarboxylation of malate by chicken liver NADP malic enzyme and details of the reaction mechanism have been investigated by 13C isotope effects. With saturating NADP and the indicated metal ion at a total concentration 10-fold higher than its Km, the following primary 13C kinetic isotope effects at C4 of malate [13(V/Kmal)] were observed at pH 8.0: Mg2+, 1.0336; Mn2+, 1.0365; Cd2+, 1.0366; Zn2+, 1.0337; Co2+, 1.0283; Ni2+, 1.025. Knowing the partitioning of the intermediate oxalacetate between decarboxylation to pyuvate and reduction to malate allows calculation of the intrinsic carbon isotope effect for decarboxylation. For Mg2+ as activator, this was 1.049 with NADP and 1.046 with 3-acetylpyridine adenine dinucleotide phosphate, although the intrinsic primary deuterium isotope effects on dehydrogenation were 5.6 and 4.2, and the partition ratios of the oxalacetate intermediate for decarboxylation as opposed to hydride transfer were 0.11 and 3.96 (the result of the different redox potentials of NADP and the acetylpyridine analogue). The close agreement of the intrinsic 13C isotope effects with each other and with the 13C isotope effect for the Mg2+-catalyzed nonenzymatic decarboxylation of oxalacetate of 1.0489 [Grissom, C. B., & Cleland, W. W. (1986) J. Am. Chem. Soc. 108, 5582] indicates a similarity of transition states for these reactions. It was not possible to calculate reasonable intrinsic carbon isotope effects with the other metal ions by use of the partitioning ratio of oxalacetate because of decarboxylation by another mechanism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of the divalent metal ion in the NAD:malic enzyme reaction: an ESEEM determination of the ground state conformation of malate in the E:Mn:malate complex.

The conformation of L-malate bound at the active site of Ascaris suum malic enzyme has been investigated by electron spin echo envelope modulation spectroscopy. Dipolar interactions between Mn2+ bound to the enzyme active site and deuterium specifically placed at the 2-position, the 3R-position, and the 3S-position of L-malate were observed. The intensities of these interactions are related to the distance between each deuterium and Mn2+. Several models of possible Mn-malate complexes were constructed using molecular graphics techniques, and conformational searches were conducted to identify conformers of malate that meet the distance criteria defined by the spectroscopic measurements. These searches suggest that L-malate binds to the enzyme active site in the trans conformation, which would be expected to be the most stable conformer in solution, not in the gauche conformer, which would be more similar to the conformation required for oxidative decarboxylation of oxalacetate formed from L-malate at the active site of the enzyme.     

High activity of NADP-dependent malic enzyme in mitochondria from abdomen muscle of the crayfish Orconectes limosus.

1. Mitochondria isolated from abdomen muscle of crayfish Orconectes limosus exhibit malic enzyme activity in the presence of L-malate, NADP and Mn2+ ions after addition of Triton X-100. Under optimal conditions about 230 nmole of reduced NADP and an equivalent amount of pyruvate are produced per min per mg of mitochondrial protein. 2. The pH optimum for decarboxylation of L-malate is about 7.5. 3. The apparent Km for L-malate, NADP and Mn2+ ions was found to be 0.66, 0.012, and 0.0025 mM, respectively. 4. The requirement for Mn2+ can be replaced by Mg2+, Co2+ and Ni2+ ions; however, higher concentrations of these ions than Mn2+ are required for a full stimulation of malic enzyme activity. 5. Oxaloacetate and pyruvate inhibited the enzyme activity in a competitive manner with apparent Ki values of 0.05 mM and 5.4 mM, respectively.     

Chemical mechanism of the adenosine cyclic 3',5'-monophosphate dependent protein kinase from pH studies

The pH dependence of kinetic parameters and inhibitor dissociation constants for the adenosine cyclic 3',5'-monophosphate dependent protein kinase reaction has been determined. Data are consistent with a mechanism in which reactants selectively bind to enzyme with the catalytic base unprotonated and an enzyme group required protonated for peptide (Leu-Arg-Arg-Ala-Ser-Leu-Gly) binding. Binding of the peptide apparently locks both of the above enzyme residues in their correct protonation state. MgATP preferentially binds fully ionized and requires an enzyme residue (probably lysine) to be protonated. The maximum velocity and V/KMgATP are pH independent. The V/K for Ser-peptide is bell-shaped with pK values of 6.2 and 8.5 estimated. The pH dependence of 1/Ki for Leu-Arg-Arg-Ala-Ala-Leu-Gly is also bell-shaped, giving pK values identical with those obtained for V/KSer-peptide, while the Ki for MgAMP-PCP increases from a constant value of 650 microM above pH 8 to a constant value of 4 mM below pH 5.5. The Ki for uncomplexed Mg2+ obtained from the Mg2+ dependence of V and V/KMgATP is apparently pH independent.     

Diethylpyrocarbonate inactivation of NAD-malic enzyme from Ascaris suum

Treatment with diethylpyrocarbonate results in a first-order loss of the malate oxidative decarboxylase activity of NAD-malic enzyme. First-order plots are biphasic, with about 40-50% activity loss in the first phase. The inactivation process is not saturable, and the second-order rate constant is 4.7 M-1 S-1. Malate (250 mM) provides complete protection against inactivation (as measured by a decrease in the inactivation rate), and less malate is required with Mg2+ present. Partial protection (50%) is afforded by either NAD+ (1 mM) or Mg2+ (50 mM). Treatment of modified (inactive) enzyme with hydroxylamine restores activity to 100% of the control when corrected for the effect of hydroxylamine on unmodified enzyme. A total of 10-13 histidine residues/subunit are acylated concomitant with loss of activity while 1-2 tyrosines are modified prior to any activity loss. The presence of Mg2+ and malate at saturating concentrations protect 1-2 histidine residues/subunit. The intrinsic fluorescence of the enzyme decreases with time after addition of diethylpyrocarbonate, but the rate constant for this process is at least 10-fold too low to account for the biphasicity observed in the first order plots. The histidine modified which is responsible for loss of activity has a pK of 8.3 as determined from the pH dependence of the rate of inactivation. The histidine titrated is still modified under conditions where the residue is completely protonated but at a rate 1/100 the rate of the unprotonated histidine. The results suggest that 1-2 histidines are in or near the malate binding site and are required for malate oxidative decarboxylation.     

Tartrate dehydrogenase catalyzes the stepwise oxidative decarboxylation of D-malate with both NAD and thio-NAD

Tartrate dehydrogenase catalyzes the divalent metal ion- and NAD-dependent oxidative decarboxylation of D-malate to yield CO(2), pyruvate, and NADH. The enzyme also catalyzes the metal ion-dependent oxidation of (+)-tartrate to yield oxaloglycolate and NADH. pH-rate profiles and isotope effects were measured to probe the mechanism of this unique enzyme. Data suggest a general base mechanism with likely general acid catalysis in the oxidative decarboxylation of D-malate. Of interest, the mechanism of oxidative decarboxylation of D-malate is stepwise with NAD(+) or the more oxidizing thio-NAD(+). The mechanism does not become concerted with the latter as observed for the malic enzyme, which catalyzes the oxidative decarboxylation of L-malate [Karsten, W. E., and Cook, P. F. (1994) Biochemistry 33, 2096-2103]. It appears the change in mechanism observed with malic enzyme is specific to its transition state structure and not a generalized trait of metal ion- and NAD(P)-dependent beta-hydroxy acid oxidative decarboxylases. The V/K(malate) pH-rate profile decreases at low and high pH and exhibits pK(a) values of about 6.3 and 8.3, while that for V/K(tartrate) (measured from pH 7.5 to pH 9) exhibits a pK(a) of 8.6 on the basic side. A single pK(a) of 6.3 is observed on the acid side of the V(max) pH profile, but the pK(a) seen on the basic side of the V/K pH profiles is not observed in the V(max) pH profiles. Data suggest the requirement for a general base that accepts a proton from the 2-hydroxyl group of either substrate to facilitate hydride transfer. A second enzymatic group is also required protonated for optimum binding of substrates and may also function as a general acid to donate a proton to the enolpyruvate intermediate to form pyruvate. The (13)C isotope effect, measured on the decarboxylation of D-malate using NAD(+) as the dinucleotide substrate, decreases from a value of 1.0096 +/- 0.0006 with D-malate to 1.00787 +/- 0.00006 with D-malate-2-d, suggesting a stepwise mechanism for the oxidative decarboxylation of D-malate. Using thio-NAD(+) as the dinucleotide substrate the (13)C isotope effects are 1.0034 +/- 0.0007 and 1.0027 +/- 0.0002 with D-malate and D-malate-2-d, respectively.     

Oxalacetate decarboxylase and pyruvate carboxylase activities, and effect of sulfhydryl reagents in malic enzyme from Sulfolobus solfataricus

Malic enzyme (S)-malate: NADP+ oxidoreductase (oxaloacetate-decarboxylating, EC 1.1.1.40) purified from the thermoacidophilic archaebacterium Sulfolobus solfataricus, strain MT-4, catalyzed the metal-dependent decarboxylation of oxaloacetate at optimum pH 7.6 at a rate comparable to the decarboxylation of L-malate. The oxaloacetate decarboxylase activity was stimulated about 50% by NADP but only in the presence of MgCl2, and was strongly inhibited by L-malate and NADPH which abolished the NADP activation. In the presence of MnCl2 and in the absence of NADP, the Michaelis constant and Vm for oxaloacetate were 1.7 mM and 2.3 mumol.min-1.mg-1, respectively. When MgCl2 replaced MnCl2, the kinetic parameters for oxaloacetate remained substantially unvaried, whereas the Km and Vm values for L-malate have been found to vary depending on the metal ion. The enzyme carried out the reverse reaction (malate synthesis) at about 70% of the forward reaction, at pH 7.2 and in the presence of relatively high concentrations of bicarbonate and pyruvate. Sulfhydryl residues (three cysteine residues per subunit) have been shown to be essential for the enzymatic activity of the Sulfolobus solfataricus malic enzyme. 5,5'-Dithiobis(2-nitrobenzoic acid), p-hydroxymercuribenzoate and N-ethylmaleimide caused the inactivation of the oxidative decarboxylase activity, but at different rates. The inactivation of the overall activity by p-hydroxymercuribenzoate was partially prevented by NADP singly or in combination with both L-malate and MnCl2, and strongly enhanced by the carboxylic acid substrates; NADP + malate + MnCl2 afforded total protection. The inactivation of the oxaloacetate decarboxylase activity by p-hydroxymercuribenzoate treatment was found to occur at a slower rate than that of the oxidative decarboxylase activity.     

Alternative substrates for malic enzyme: oxidative decarboxylation of L-aspartate

The NAD-malic enzyme from Ascaris suum will utilize L-aspartate, (2S,3R)-tartrate, and meso-tartrate as substrates with V/K values 10(-4)-10(-5) with respect to malate. There is a strict requirement for the 2S stereochemistry for all of these reactants. Since aspartate is unique as an amino acid reactant for malic enzyme, it was informative to determine the details of its mechanism of oxidative decarboxylation. The initial rate of NADH appearance is directly proportional to the concentration of aspartate, and saturation is difficult to achieve. The pH dependence of V/K(aspartate)E(t) shows a decrease at low pH, giving a pK of 5.7. The pH-independent value of V/K(aspartate)E(t) is 3 M(-1) s(-1), 12500-fold lower than that obtained with L-malate. The dissociation constant for aspartate as a competitive inhibitor of malate is 60 mM at neutral pH, allowing an estimate of about 0.18 s(-1) for V/E(t) with L-aspartate compared to a value of 39 s(-1) obtained with L-malate. The deuterium isotope effect on V/K(aspartate) is pH independent over the range 5.1-6.9 with an average value of 3.3. Data suggest that the monoanion of L-aspartate binds to enzyme and that the same general base, general acid mechanism that is responsible for the oxidative decarboxylation of malate to pyruvate applies to the oxidative decarboxylation of aspartate to iminopyruvate. In addition, the oxidation step appears to be largely rate determining with aspartate as the substrate.     

pH studies on the chemical mechanism of rabbit muscle pyruvate kinase. 2. Physiological substrates and phosphoenol-alpha-ketobutyrate

pH profiles have been determined for the reactions catalyzed by pyruvate kinase between pyruvate and MgATP and between phosphoenolpyruvate and MgADP. V, V/KMgATP, and V/Kpyruvate all decrease below a pK of 8.3 and above one of 9.2. The group with pK = 8.3 is probably a lysine that removes the proton from pyruvate during enolization, while the pK of 9.2 is that of water coordinated to enzyme-bound Mg2+. The fact that this pK shows in all three pH profiles shows that pyruvate forms a predominantly second sphere complex and cannot replace hydroxide to form the inner sphere complex that results in enolization and subsequent phosphorylation. On the basis of the displacement of the pK of the acid-base catalytic group in its V/K profile, phosphoenolpyruvate is a sticky substrate, reacting to give pyruvate approximately 5 times faster than it dissociates. The V/K profile for the slow substrate phosphoenol-alpha-ketobutyrate shows the pK of 8.3 for the acid-base catalytic group in its correct position, but this group must be protonated so that it can donate a proton to the intermediate enolate following phosphoryl transfer. The secondary phosphate pK of the substrate is seen in this V/K profile as well as in the pKi profile for phosphoglycolate (but not in those for glycolate O-sulfate or oxalate), showing a preference for the trianion for binding. The chemical mechanism with the natural substrates thus appears to involve phosphoryl transfer between MgADP and a Mg2+-bound enolate with metal coordination of the enolate serving to make it a good leaving group.     

Detailed reaction mechanism of macrophomate synthase. Extraordinary enzyme catalyzing five-step transformation from 2-pyrones to benzoates

Macrophomate synthase from the fungus Macrophoma commelinae IFO 9570 is a Mg(II)-dependent dimeric enzyme that catalyzes an extraordinary, complex five-step chemical transformation from 2-pyrone and oxalacetate to benzoate involving decarboxylation, C-C bond formation, and dehydration. The catalytic mechanism of the whole pathway was investigated in three separate chemical steps. In the first decarboxylation step, the enzyme loses oxalacetate decarboxylation activity upon incubation with EDTA. Activity is fully restored by addition of Mg(II) and is not restored with other divalent metal cations. The dissociation constant of 0.93 x 10(-)(7) for Mg(II) and atomic absorption analysis established a 1:1 stoichiometric complex. Inhibition of pyruvate formation with 2-pyrone revealed that the actual product in the first step is a pyruvate enolate, which undergoes C-C bond formation in the presence of 2-pyrone. Incubation of substrate analogs provided aberrant adducts that were produced via C-C bond formation and rearrangement. This strongly indicates that the second step is two C-C bond formations, affording a bicyclic intermediate. Based on the stereospecificity, involvement of a Diels-Alder reaction at the second step is proposed. Incubation of the stereospecifically deuterium-labeled malate with 2-pyrones in the presence of malate dehydrogenase provided information for the stereochemical course of the reaction catalyzed by macrophomate synthase, indicating that the first decarboxylation provides pyruvate (Z)-[3-(2)H]enolate and that dehydration at the final step occurs with anti-elimination accompanied by concomitant decarboxylation. Examination of kinetic parameters in the individual steps suggests that the third step is the rate-determining step of the overall transformation.     

Glycine metabolism and oxalacetate transport by pea leaf mitochondria

Isolated pea leaf mitochondria oxidatively decarboxylate added glycine. This decarboxylation could be linked to the respiratory chain (in which case it was coupled to three phosphorylations) or to mitochondrial malate dehydrogenase when oxalacetate was supplied. Decarboxylation rates measured as O₂ uptake, or CO₂ and NH₃ release were adequate to account for whole leaf photorespiration. Oxalacetate-supported glycine decarboxylation, measured by linking malate efflux to added malic enzyme, yielded rates considerably less than the electron transport rates. Butylmalonate inhibited malate efflux but not oxalacetate entry; phthalonate inhibited oxalacetate entry but had little effect on malate or α-ketoglutarate oxidation. It is suggested that oxalacetate and malate transport are catalyzed by separate carrier systems of the mitochondrial membrane.     

Carbon-13 and deuterium isotope effects on oxalacetate decarboxylation by pyruvate carboxylase

Deuterium and 13C isotope effects for the enzymic decarboxylation of oxalacetate showed that both deuterium- and 13C-sensitive steps in the reaction are partially rate limiting. A normal alpha-secondary effect of 1.2 per deuterium was calculated for the reaction in which pyruvate-d3 was the substrate, suggesting that the enolate of pyruvate was an intermediate in the reaction. The large normal alpha-secondary deuterium isotope effect of 1.7 when oxalacetate-d2 was the substrate suggests that the motions of the secondary hydrogens are coupled to that of the primary hydrogen during the protonation of the enolate of pyruvate. The reduction in the magnitude of the 13C isotope effect for the oxamate-dependent decarboxylation of oxalacetate from 1.0238 to 1.0155 when the reaction was performed in D2O (primary deuterum isotope effect = 2.1) clearly indicates that the transfer of the proton and carboxyl group between biotin and pyruvate does not occur via a single concerted reaction. Mechanisms in which biotin is activated to react with CO2 (prior to transfer of the proton on N-1) by bond formation between the sulfur and the ureido carbon, or in which the sequence of events is decarboxylation of oxalacetate, proton transfer from biotin to enolpyruvate, and carboxylation of enolbiotin, predict that the 13C isotope effect in D2O should be substantially lower than the observed value. A stepwise mechanism that does fit the data is one in which a proton is removed from biotin by a sulfhydryl group on the enzyme prior to carboxyl transfer, as long as the sulfhydryl group has an abnormally low pK.(ABSTRACT TRUNCATED AT 250 WORDS)     

pH Effects on the Activity and Regulation of the NAD Malic Enzyme

The NAD malic enzyme shows a pH optimum of 6.7 when complexed to Mg²⁺ and NAD⁺ but shifts to 7.0 when the catalytically competent enzyme-substrate (E-S) complex forms upon binding malate⁻². This is characteristic of an induced conformational change. The slope of the V_max or V_max/K_m profiles is steeper on the alkaline side of the pH optimum. The K_m for malate increases markedly under alkaline conditions but is not greatly affected by pH values below the optimum. The loss of catalysis on the acidic side is due to protonation of a single residue, pK 5.9, most likely histidine. Photooxidation inactivation with methylene blue showed that a histidine is required for catalytic activity. The location of this residue at or near the active site is revealed by the protection against inactivation offered by malate. Three residues, excluding basic residues such as lysine (which have also been shown to be vital for catalytic activity, must be appropriately ionized for malate decarboxylation to proceed optimally. Two of these residues directly participate in the binding of substrates and are essential for the decarboxylation of malate. A pK of 7.6 was determined for the two residues required by the E-S complex to achieve an active state, this composite value representing both histidine and cysteine suggests that both have decisive roles in the operation of the enzyme. A major change in the enzyme takes place as protonation nears the pH optimum, this is recorded as a change in the enzyme's intrinsic affinity for malate (K_{m pH6.7} = 9.2 millimolar, K_{m pH7.7} = 28.3 millimolar). Similar changes in K_m have been observed for the NAD malic enzyme as it shifts from dimer to tetramer. It is most likely that the third ionizable group (probably a cysteine) revealed by the V_max/K_m profile is needed for optimal activity and is involved in the association-dissociation behavior of the enzyme.     

Chemical mechanism of beta-xylosidase from Trichoderma reesei QM 9414: pH-dependence of kinetic parameters.

The variation of kinetic parameters of beta-xylosidase from Trichoderma reesei QM 9414 with pH was used to elucidate the chemical mechanism of the p-nitrophenyl beta-D-xylopyranoside hydrolysis. The pH-dependence of V and V/K(m) showed that a group on the enzyme with a pK value of 3.20 must be unprotonated and a group with a pK value of 5.20 must be protonated for activity and both are involved in catalysis. Solvent-perturbation studies indicated that these groups are neutral acid type. Temperature dependence of kinetic parameters suggested the stickiness of the substrate at lower temperatures than the optimum and the calculated ionization enthalpies pointed to carboxyl groups as responsible for both pKs. Chemical modification with triethyloxonium tetrafluoroborate and protection with the substrate studies demonstrated essential carboxyl groups on the enzyme. Profiles of pK(i) for D-gluconic acid lactone indicated that a group with a pK value of 3.45 must be protonated for binding and it has been assigned to the carboxyl group of D-gluconic acid formed by lactone ring breakdown in solution.     

The pH dependence of the oxidation-reduction midpoint potential of cytochromes c2 in vivo.

A recent report by Pettigrew et al. [Biochim, Biophys. Acta 430, (1976), 197-208] has examined the pH dependence of the oxidation-reduction midpoint potential of cytochromes c2 in vitro. In media of low ionic strength, these workers identified several pKs on the oxidized forms of the cytochromes, and in some cases there were also pKs on the reduced species. In this work we examine the pH dependence of the midpoint potentials of the cytochromes in situ, attached to the chromatophore membrane. Under these conditions no pK values are detected, and we conclude that in vivo there is no net change in the protonation of cytochrome c2 during oxidation or reduction.