A catalytic triad is responsible for acid-base chemistry in the Ascaris suum NAD-malic enzyme

The pH dependence of kinetic parameters of several active site mutants of the Ascaris suum NAD-malic enzyme was investigated to determine the role of amino acid residues likely involved in catalysis on the basis of three-dimensional structures of malic enzyme. Lysine 199 is positioned to act as the general base that accepts a proton from the 2-hydroxyl of malate during the hydride transfer step. The pH dependence of V/K(malate) for the K199R mutant enzyme reveals a pK of 5.3 for an enzymatic group required to be unprotonated for activity and a second pK of 6.3 that leads to a 10-fold loss in activity above the pK of 6.3 to a new constant value up to pH 10. The V profile for K199R is pH independent from pH 5.5 to pH 10 and decreases below a pK of 4.9. Tyrosine 126 is positioned to act as the general acid that donates a proton to the enolpyruvate intermediate to form pyruvate. The pH dependence of V/K(malate) for the Y126F mutant is qualitatively similar to K199R, with a requirement for a group to be unprotonated for activity with a pK of 5.6 and a partial activity loss of about 3-fold above a pK of 6.7 to a new constant value. The Y126F mutant enzyme is about 60000-fold less active than the wild-type enzyme. In contrast to K199R, the V rate profile for Y126F also shows a partial activity loss above pH 6.6. The wild-type pH profiles were reinvestigated in light of the discovery of the partial activity change for the mutant enzymes. The wild-type V/K(malate) pH-rate profile exhibits the requirement for a group to be unprotonated for catalysis with a pK of 5.6 and also shows the partial activity loss above a pK of 6.4. The wild-type V pH-rate profile decreases below a pK of 5.2 and is pH independent from pH 5.5 to pH 10. Aspartate 294 is within hydrogen-bonding distance to K199 in the open and closed forms of malic enzyme. D294A is about 13000-fold less active than the wild-type enzyme, and the pH-rate profile for V/K(malate) indicates the mutant is only active above pH 9. The data suggest that the pK present at about pH 5.6 in all of the pH profiles represents D294, and during catalysis D294 accepts a proton from K199 to allow K199 to act as a general base in the reaction. The pK for the general acid in the reaction is not observed, consistent with rapid tautomerization of enolpyruvate. No other ionizable group in the active site is likely responsible for the partial activity change observed in the pH profiles, and thus the group responsible is probably remote from the active site and the effect on activity is transmitted through the protein by a conformational change.     

Roles of active site residues in Pseudomonas aeruginosa phosphomannomutase/phosphoglucomutase

In Pseudomonas aeruginosa, the dual-specificity enzyme phosphomannomutase/phosphoglucomutase catalyzes the transfer of a phosphoryl group from serine 108 to the hydroxyl group at the 1-position of the substrate, either mannose 6-P or glucose 6-P. The enzyme must then catalyze transfer of the phosphoryl group on the 6-position of the substrate back to the enzyme. Each phosphoryl transfer is expected to require general acid-base catalysis, provided by amino acid residues at the enzyme active site. An extensive survey of the active site residues by site-directed mutagenesis failed to identify a single key residue that mediates the proton transfers. Mutagenesis of active site residues Arg20, Lys118, Arg247, His308, and His329 to residues that do not contain ionizable groups produced proteins for which V(max) was reduced to 4-12% of that of the wild type. The fact that no single residue decreased catalytic activity more significantly, and that several residues had similar effects on V(max), suggested that the ensemble of active site amino acids act by creating positive electrostatic potential, which serves to depress the pK of the substrate hydroxyl group so that it binds in ionized form at the active site. In this way, the necessity of positioning the reactive hydroxyl group near a specific amino acid residue is avoided, which may explain how the enzyme is able to promote catalysis of both phosphoryl transfers, even though the 1- and 6-positions do not occupy precisely the same position when the substrate binds in the two different orientations in the active site. When Ser108 is mutated, the enzyme retains a surprising amount of activity, which has led to the suggestion that an alternative residue becomes phosphorylated in the absence of Ser108. (31)P NMR spectra of the S108A protein confirm that it is phosphorylated. Although the S108A/H329N protein had no detectable catalytic activity, the (31)P NMR spectra were not consistent with a phosphohistidine residue.     

Identification of essential ionizable groups and evaluation of subsite affinities in the active site of beta-D-glucosidase F1 from a Streptomyces sp

Partial amino acid sequences, the essential ionizable groups directly involved in catalytic reaction, and the subsite structure of beta-D-glucosidase purified from a Streptomyces sp. were investigated in order to analyze the reaction mechanism. On the basis of the partial amino acid sequences, the enzyme seemed to belong to the family 1 of beta-glucosidase in the classification of glycosyl hydrolases by Henrissat (1991). Dependence of the V and Km values on pH, when the substrate concentration was sufficiently lower than Km, gave the values of 4.1 and 7.2 for the ionization constants, pKe1 and pKe2 of essential ionizable groups 1 and 2 of the free enzyme, respectively. When the dielectric constant of the reaction mixture was decreased in the presence of 10% methanol, the pKe1 and pKe2, values shifted to higher, to +0.60 and +0.35 pH unit, respectively. The findings supported the notion that the essential ionizable groups of the enzyme were a carboxylate group (-COO-, the group 1) and a carboxyl group (-COOH, the group 2). The subsite affinities Ai's in the active site were evaluated on the basis of the rate parameters of laminarioligosaccharides. Subsites 1 and 2 having positive Ai values (A1 was 1.10 kcal/mol and A2 was 4.98 kcal/mol) were considered to probably facilitate the binding of the substrate to the active site. However, the subsites 3 and 4 showed negative Ai values (A3 was -0.21 kcal/mol and A4 was -2.8 kcal/mol).     

A probe of the active site acidity of carboxypeptidase A

The substrate analogue 2-(1-carboxy-2-phenylethyl)-4-phenylazophenol is a potent competitive inhibitor of carboxypeptidase A. Upon ligation to the active site, the azophenol moiety undergoes a shift of pKa from a value of 8.76 to a value of 4.9; this provides an index of the Lewis acidity of the active site zinc ion. Examination of the pH dependence of Ki for the inhibitor shows maximum effectiveness in neutral solution (limiting Ki = 7.6 X 10(-7) M), with an increase in Ki in acid (pK1 = 6.16) and in alkaline solution (pK2 = 9.71, pK3 = 8.76). It is concluded that a proton-accepting enzymic functional group with the lower pKa (6.2) controls inhibitor binding, that ionization of this group is also manifested in the hydrolysis of peptide substrates (kcat/Km), and that the identity of this group is the water molecule that binds to the active site metal ion in the uncomplexed enzyme (H2OZn2+L3). Reverse protonation state inhibition is demonstrated, and conventional concepts regarding the mechanism of peptide hydrolysis by the enzyme are brought into question.     

The effect of pH on the transpeptidation and hydrolytic reactions of rat kidney gamma-glutamyltransferase

The effect of pH upon the transpeptidation and hydrolytic reactions of gamma-glutamyltransferase [5-glutamyl)-peptide:amino-acid 5-glutamyltransferase, EC 2.3.2.2) have been investigated. It was found that the enzyme was irreversibly inactivated below pH 7.5 or above pH 9.4. Transpeptidation was markedly pH-dependent, while hydrolysis was pH-independent. The pH optimum for transpeptidation was found to vary for different acceptors. The ascending limb of the pH-optimum curve is attributed to the pK of the alpha-amino group of the acceptor, while the descending limb of the pH-optimum curve is attributed to an ionisable group in the active site of the enzyme. These observations provide much information about the interaction of the enzyme with the acceptor: (1) the true acceptor for gamma-glutamyltransferase is the deprotonated form of the amino acid; (2) glycylglycine has a similar acceptor activity to methionine, its apparent higher activity being due to the low pK of the alpha-amino group; (3) the enzyme is reversibly inactivated at higher pH by the deprotonation of a group in the active site which is involved in both binding of acceptor and catalysis of transpeptidation (this group is not involved in the hydrolysis reaction); (4) at pH 8.5, the normal pH for assay, only 47% of the enzyme is active, while at pH 7.4 gamma-glutamyltransferase is 93% in the active form.     

Kinetic characterization of a T-state of Ascaris suum phosphofructokinase with heterotropic negative cooperativity by ATP eliminated.

The affinity analogue, 2',3'-dialdehyde ATP has been used to chemically modify the ATP-inhibitory site of Ascaris suum phosphofructokinase, thereby locking the enzyme into a less active T-state. This enzyme form has a maximum velocity that is 10% that of the native enzyme in the direction of fructose 6-phosphate (F6P) phosphorylation. The enzyme displays sigmoid saturation for the substrate fructose 6-phosphate (S0.5 (F6P) = 19 mM and nH = 2.2) at pH 6.8 and a hyperbolic saturation curve for MgATP with a Km identical to that for the native enzyme. The allosteric effectors, fructose 2,6-bisphosphate and AMP, do not affect the S0.5 for F6P but produce a slight (1.5- and 2-fold, respectively) V-type activation with Ka values (effector concentration required for half-maximal activation) of 0.40 and 0.24 mM, respectively. Their activating effects are additive and not synergistic. The kinetic mechanism for the modified enzyme is steady-state-ordered with MgATP as the first substrate and MgADP as the last product to be released from the enzyme surface. The decrease in V and V/K values for the reactants likely results from a decrease in the equilibrium constant for the isomerization of the E:MgATP binary complex, thus favoring an unisomerized form. The V and V/KF6P are pH dependent with similar pK values of about 7 on the acid side and 9.8 on the basic side. The microenvironment of the active site appears to be affected minimally as evidenced by the similarity of the pK values for the groups involved in the binding site for F6P in the modified and native enzymes.     

pH dependency of the reactions catalyzed by chorismate mutase-prephenate dehydrogenase from Escherichia coli

The variation with pH of the kinetic parameters associated with the mutase and dehydrogenase reactions catalyzed by chorismate mutase-prephenate dehydrogenase has been determined with the aim of elucidating the role that ionizing amino acid residues play in binding and catalysis. The pH dependency of log V for the dehydrogenase reaction shows that the enzyme possesses a single ionizing group with a pK value of 6.5 that must be unprotonated for catalysis. This same group is observed in the V/Kprephenate, as well as in the V/KNAD, profile. The V/Kprephenate profile exhibits a second ionizing residue with a pK value of 8.4 that must be protonated for the binding of prephenate to the enzyme. For the mutase reaction, the V/Kchorismate profile indicates the presence of three ionizing residues at the active site. Two of these residues, with similar pK values of about 7, must be protonated, while the third, with a pK value of 6.3, must be unprotonated. It can be concluded that all three groups are concerned with the binding of chorismate to the enzyme since the maximum velocity of the mutase reaction is essentially independent of pH. This conclusion is confirmed by the finding that the Ki profile for the competitive inhibitor, (3-endo,8-exo)-8-hydroxy-2-oxabicyclo[3.3]non-6-ene-3,5-dicarboxylic acid, shows the same three ionizing groups as observed in the V/Kchorismate profile. By contrast, the Ki profile for carboxyethyldihydrobenzoate shows only one residue, with a pK value of 7.3, that must be protonated for binding of the inhibitor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Aspartokinase-homoserine dehydrogenase I from Escherichia coli: pH and chemical modification studies of the kinase activity

The pH variation of the kinetic parameters was examined for the kinase activity of the bifunctional enzyme aspartokinase--homoserine dehydrogenase I isolated from Escherichia coli. The V/K profile for L-aspartic acid indicates the loss of activity upon protonation of a cationic acid type group with a pK value near neutrality. Incubation of the enzyme with diethyl pyrocarbonate at pH 6.0 results in a loss of enzymic activity. The reversal of this reaction by neutral hydroxylamine, the appearance of a peak at 242 nm for the inactivated enzyme, and the observation of a pK value of 7.0 obtained from variation of the inactivation rate with pH all suggest that enzyme inactivation occurs by modification of histidine residues. The substrate L-aspartic acid protects one residue against inactivation, which implies that this histidine may participate in substrate binding or catalysis. Activity loss was also observed at high pH due to the ionization of a neutral acid group with a pK value of 9.8. The reactions of AK-HSD I with N-acetylimidazole and tetranitromethane have been investigated to obtain information about the functional role of tyrosyl residues in the enzyme. The acylation of tyrosines leads to inactivation of the enzyme, which can then be fully reversed by treatment with hydroxylamine. Incubation of the enzyme with tetranitromethane at pH 9.5 also leads to rapid inactivation, and the substrates of the kinase reaction provide substantial protection against inactivation. However, three tyrosines are protected by substrates, implying a structural role for these amino acids.     

Zinc and cadmium 5-aminolevulinate dehydratase. Metal-dependent pH profiles

Native 5-aminolevulinic acid dehydratase contains zinc ions, which are essential for the enzymatic activity. Replacement of zinc by cadmium yielded an active enzyme whose kinetic parameters (kkat and Km) are similar to those of the zinc enzyme in the neutral pH range. However, the pH profiles of kcat and Km were different due to different pKa values. Two groups both with pKa values of 6.5 in the free zinc enzyme, but with pKa values of 7.0 in the cadmium enzyme were calculated from plots of log (kcat/Km) versus pH. On the other hand, the enzyme-substrate complex is controlled by one acidic group (zinc pKa = 6.0, cadmium pKa = 6.4) and one basis group (zinc pKa = 8.2, cadmium pKa = 7.7) as calculated from plots of log kcat versus pH. The Arrhenius plots for kcat of the two enzymes show no significant difference, the free energies of activation are 77.1 kJ/mol for the zinc and 76.8 kJ/mol for the cadmium enzyme. From this and from previous work it is concluded that the metal ions are located near the active site and influence the ionisations of essential amino acid residues. From the pH profiles of the modifying reaction and inhibition by diethylpyrocarbonate a histidinyl residue is inferred as one of the ionisable groups of the active site.     

pH variation of the kinetic parameters and the catalytic mechanism of malic enzyme.

The pH variation of the kinetic parameters for the oxidative decarboxylation of L-malate and decarboxylation of oxalacetate catalyzed by malic enzyme has been used to gain information on the catalytic mechanism of this enzyme. With Mn2+ as the activator, an active-site residue with a pK of 5.4 must be protonated for oxalacetate decarboxylation and ionized for the oxidative decarboxylation of L-malate. With Mg2+ as the metal, this pK is 6, and, at high pH, V/K for L-malate decreases when groups with pKs of 7.8 and 9 are deprotonated. The group at 7.8 is a neutral acid (thought to be water coordinated to Mg2+), while the group at 9 is a cationic acid such as lysine. The V profile for reaction of malate shows these pKs displaced outward by 1.4 pH units, since the rate-limiting step is normally TPNH release, and the chemical reaction, which is pH sensitive, is 25 times faster. TPN binding is decreased by ionization of a group with pK 9.3 or protonation of a group with pK 5.3. The pH variation of the Km for Mg shows that protonation of a group with pK 8.7 (possibly SH) decreases metal binding in the presence of malate by a factor of 1400, and in the absence of malate by a factor of 20. A catalytic mechanism is proposed in which hydride transfer is accompanied by transfer of a proton to the group with pK 5.4-6, and enolpyruvate is protonated by water coordinated to the Mg2+ (pK 7.8) after decarboxylation and release of CO2.     

Human dihydrofolate reductase: reduction of alternative substrates, pH effects, and inhibition by deazafolates.

The kinetics of the NADPH-dependent reduction of 7,8-dihydrofolate, folate, and 7,8-dihydrobiopterin by human dihydrofolate reductase have been examined over the pH range from 4.0 to 9.5. The V and V/K profiles obtained with the three substrates indicate that a single ionizing residue at the active site of the enzyme must be protonated for catalysis. Both the maximum velocity of the reactions and the rate of interaction of the substrates with the enzyme-NADPH complex decrease in the order dihydrofolate greater than dihydrobiopterin much greater than folate. From the pK values of the V/K profiles, it can be concluded that, while dihydrofolate behaves as a sticky substrate and dihydrobiopterin exhibits slight stickiness, folate is not a sticky substrate. Further support for this conclusion comes from the results of deuterium isotope effects. The pK values obtained from both the V and V/Kfolate profiles are similar to the intrinsic pK value of 5.6 for both the free enzyme and the enzyme-NADPH complex. The folate analogue, 5-deazafolate, is not a substrate, but it undergoes strong interaction with the enzyme. This interaction, which is enhanced by the presence of NADPH, is due to protonation of the bound ligand that does not involve the single ionizing group at the active center of the enzyme. Difference spectra yield evidence for the protonation of bound 5-deazafolate and show that, on binding to the enzyme-NADPH complex, the pK of the N-8 atom is raised to about 10 from a value of about 4 in solution. The results are in accord with those of a recent paper on the three-dimensional structure of the enzyme-5-deazafolate complex [Davies, J.F., Delcamp, T.J., Prendergast, N.J., Ashfors, V.A., Freisheim, J.H., & Kraut, J. (1990) Biochemistry 29, 9467-9479] which indicate that there is hydrogen bond formation between N-8 of the ligand and the carbonyl group of Ile-7. However, the present findings do not support the idea that bound 5-deazafolate resembles the transition-state complex for folate reduction. Quinazolines also interact strongly with the enzyme but in a pH-independent manner. The dissociation constants for the binary complexes are an order of magnitude lower than that for the binding to the enzyme of unprotonated 5-deazafolate. This difference reflects the hydrophobic nature of the amino acid residues at the active site that are near the N-5 and N-8 nitrogens of bound pterins.     

Construction of Engineered Water-soluble PQQ Glucose Dehydrogenase with Improved Substrate Specificity

This was the first study that achieved a narrowing of the substrate specificity of water soluble glucose dehydrogenase harboring pyrroloquinoline quinone as their prosthetic group, PQQGDH-B. We conducted the introduction of amino acid substitutions into the loop 6BC region of the enzyme, which made up the active site cleft without directly interacting with the substrate, and constructed a series of site directed mutants. Among these mutants, Asn452Thr showed the least narrowed substrate specificity while retaining a similar catalytic efficiency, thermal stability and EDTA tolerance as the wild-type enzyme. The relative activities of mutant enzyme with lactose were lower than that of the wild-type enzyme. The altered substrate specificity profile of the mutant enzyme was found to be mainly due to increase in Km value for substrate than glucose. The predicted 3D structures of Asn452Thr and the wild-type enzyme indicated that the most significant impact of the amino acid substitution was observed in the interaction between the 6BC loop region with lactose.     

Construction of Engineered Water-soluble PQQ Glucose Dehydrogenase with Improved Substrate Specificity

This was the first study that achieved a narrowing of the substrate specificity of water soluble glucose dehydrogenase harboring pyrroloquinoline quinone as their prosthetic group, PQQGDH-B. We conducted the introduction of amino acid substitutions into the loop 6BC region of the enzyme, which made up the active site cleft without directly interacting with the substrate, and constructed a series of site directed mutants. Among these mutants, Asn452Thr showed the least narrowed substrate specificity while retaining a similar catalytic efficiency, thermal stability and EDTA tolerance as the wild-type enzyme. The relative activities of mutant enzyme with lactose were lower than that of the wild-type enzyme. The altered substrate specificity profile of the mutant enzyme was found to be mainly due to increase in Km value for substrate than glucose. The predicted 3D structures of Asn452Thr and the wild-type enzyme indicated that the most significant impact of the amino acid substitution was observed in the interaction between the 6BC loop region with lactose.     

Yeast hexokinase A. Succinylation and properties of the active subunit.

Yeast hexokinase A (ATP:D-hexose 6-phosphotransferase, EC2.7.1.1) dissociates into its subunits upon reaction with succinic anhydride. The chemically modified subunits could be isolated in a catalytically active form. The Km values found for ATP and for glucose were of the some order as those found for the native enzyme. Of the 37 amino groups present per enzyme subunit, 2-3 of these groups might be located in the proximity of the region of subunit interactions. The 50% loss of the initial activity, which follows the succinylation of these more reactive amino groups, does not seem to be due to the modification of a residue on the enzyme active site or to a change of the tertiary structure of the protein. This 50%loss of the enzyme activity may be related to the dissociation of the dimer into monomers. Both native enzyme and the succinylated subunits have the same H-dependent denaturation rate profiles in response to 2 M urea. Moreover, the apparent pK of the group involved in the transition from a more stable conformation of the protein in the acid range to a less stable one at alkaline pH seems to be similar to the pK of the group implicated in the transition between the protonated inactive form of the enzyme and an active deprotonated form. The succinylated subunit presents 'negative co-operativity' with respect to ATP at slightly acid pH; however, the burst-type slow transient in the reaction progress curve and the activation effect induced by physiological polyanions, effects observed for the native enzyme, were not detected in the standard experimental conditions with the succinylated subunit.     

Investigation of the active site of the extracellular beta-D-xylosidase from Aspergillus carbonarius

The catalytic amino acid residues of the extracellular beta-D-xylosidase (beta-D-xyloside xylohydrolase, EC 3.2.1.37) from Aspergillus carbonarius was investigated by the pH dependence of reaction kinetic parameters and chemical modifications of the enzyme. The pH dependence curves gave apparent pK values of 2.7 and 6.4 for the free enzyme, while pK value of 4.0 was obtained for the enzyme-substrate complex using p-nitrophenyl beta-D-xyloside as a substrate. These results suggested that a carboxylate group and a protonated group--presumably a histidine residue--took part in the binding of the substrate but only a carboxylate group was essential in the substrate cleavage. Carbodiimide- and Woodward's reagent K-mediated chemical modifications of the enzyme also supported that a carboxylate residue, located in the active center, was fundamental in the catalysis. The pH dependence of inactivation revealed the involvement of a group with pK value of 4.4, proving that a carboxylate residue relevant for hydrolysis was modified. During modification V(max) decreased to 10% of that of the unmodified enzyme and K(m) remained unchanged, supporting that the modified carboxylate group participated in the cleavage and not in the binding of the substrate. We synthesized and tested a new, potential affinity label, N-bromoacetyl-beta-d-xylopyranosylamine for beta-D-xylosidase. The A. carbonarius beta-D-xylosidase was irreversible inactivated by N-bromoacetyl-beta-D-xylopyranosylamine. The competitive inhibitor beta-D-xylopyranosyl azide protected the enzyme from inactivation proving that the inactivation took place in the active center. Kinetic analysis indicated that one molecule of reagent was necessary for inactivation of one molecule of the enzyme.     

Two-hydronic-reactive states of acetylcholinesterase, mechanistically relevant acid-base catalyst of pKa 6.5 and a modulatory group of pKa 5.5

Variation of experimentally observed pKa values in pH-dependent kinetic studies using acetylcholinesterase (AcChE) is rationalized by proposal of two-hydronic-reactive states, EH and EH2, of the free AcChE molecule. Two kinetically influential ionizations with pKa 6.5 for the general acid-base catalyst, possibly the imidazole group of histidine, and a modulatory group with pKa 5.5 residing at the juxtaposal modulatory site, provided fundamental bases for the observed variation in pK(app) values. Appropriate equations applicable to the proposed kinetic model in conjunction with pKa values (pKI 5.5, pKII 6.5) and relative varied values of the pH-independent rate constants, k'cat/K'm and kcat/Km, of the reactive states were used to generate computer simulation error-free pH-rate profiles. A series of theoretical apparently simple sigmoidal pH-rate profiles with characterizing parameters pK(app) varying between 5.5-6.5 were obtained. Ionization of a modulatory group with pKa 5.5 alone modifies the reaction mechanism of AcChE, and binding of substrates and inhibitors at this site provides modulation of catalysis/binding at the active center. Analysis of the relative magnitudes of pH-independent rate constants for the two reactive states revealed that in terms of the overall catalysis, the EH state shows favorable reactivity towards the cationic reagents with reactivity 1.0, as compared to the EH2 state with reactivities 0.25-0.55. Neutral reagents, in general, make use of the EH2 state more than cationic reagents, with reactivities 1.0 for the EH state and 0.3-1.0 for the EH2 state. Further analysis showed that this discrimination between the two reactive states, by both types of reagents, occurs predominantly through the difference in binding constants K'm and Km. Relative binding of a given cationic reagent to the respective reactive states ranges from K'm = 1.8 X Km to 4.0 X Km, and from K'm = 1.0 X Km to 2.0 X Km for the neutral reagents.     

Comparison of the kinetic specificity of subtilisin and thiolsubtilisin toward n-alkyl p-nitrophenyl esters.

The p-nitrophenyl esters of straight-chain fatty acids were used as substrates of the enzyme subtilisin Novo (EC 3.4.4.16) and its chemically produced artificial enzyme thiolsubtilisin. Subtilisin and thiolsubtilisin pH--activity profiles were determined, and kinetic effects of the active site O-S substitution were observed. Among the substrates tested, both enzymes show highest specificity with p-nitrophenyl butyrate. It was also found that subtilisin is more sensitive to changes in substrate chain length than is thiolsubtilisin. Second-order acylation rate constants (k2/Ks) are remarkably similar for both enzymes. However, thiolsubtilisin deacylation rate constants and Km values are lower than analogous subtilisin constants. While thiolsubtilisin deacylation rate constants give a pH profile identical with that of subtilisin, the pH profile of thiolsubtilisin acylation rate constants shows an active site pK value lowered from the subtilisin pK of 7.15 and exhibits an inflection point at pH 8.45, which is absent in subtilisin.     

Kinetics of the hydrolysis of monodispersed dihexanoyllecithin catalyzed by a cobra (Naja naja atra) venom phospholipase A2

The hydrolysis of 1,2-dihexanoyl-sn-glycero-3-phosphorylcholine (diC6PC), catalyzed by a cobra (Naja naja atra) venom phospholipase A2, was studied at 25 degrees C ionic strength 0.1 in the presence of 3-10 mM Ca2+, which can saturate the Ca2+-binding site of the enzyme. The initial velocity data, obtained at various concentrations of the substrate below the critical micellar concentration (cmc), were analyzed according to the Michaelis-Menten equation. The Km value was practically independent of pH (between pH 6.75 and 10.30). This finding was consistent with the result of a direct binding study on monodispersed n-alkylphosphorylcholines (Teshima et al. (1981) J. Biochem. 89, 1163-1174). The hydrolysis of the substrate was competitively inhibited by the presence of monodispersed n-dodecylphosphorylcholine (n-C12PC). These results indicated that the substrate and n-C12PC compete for the same site on the enzyme molecule. The pH dependence curve of the kinetic parameter, kcat/Km, exhibited three transitions, below pH 8, between pH 8 and 9.5, and above pH 10. The analysis indicated the participation of three ionizable groups with pK values of 7.25, 8.50, and 10.4. The deprotonation of the first group and the protonation of the third group were found to be essential for the catalysis. The first group was assigned as His 48 in the active site on the basis of its pK value, which had been determined from the pH dependence of the binding constant of Ca2+ (Teshima et al. (1981) J. Biochem. 89, 13-20).(ABSTRACT TRUNCATED AT 250 WORDS)     

Preparation and kinetic properties of gel entrapped urate oxidase.

Urate oxidase from hog liver (urate: oxygen oxidoreductase, EC 1.7.33) has been entrapped in a crosslinked 2-hydroxyethyl methacrylate gel with a 47% retention of activity. The kinetic behavior of the gel entrapped enzyme has been studied in a slurried tank reactor using uric acid as substrate. Internal diffusion effects were found to be negligible for particle sizes below 128 mum. A threefold increase in Km (app) was observed for the 128 mum particles and attributed to diffusional effects. The pH activity profile of the gel entrapped enzyme was bell-shaped at high substrate concentration and could be fitted to a titration curve of two ionizable groups, a basic group having a pK of 7.9 and an acidic group with a pK of 11.0. The gel entrapped enzyme showed excellent stability between pH 6.5 and 10.5.     

Interconversion of E and S isoenzymes of horse liver alcohol dehydrogenase. Several residues contribute indirectly to catalysis.

The E and S isoenzymes of horse liver alcohol dehydrogenase differ by 10 amino acid residues, but only the S isoenzyme is active on 3 beta-hydroxysteroids. This functional difference was correlated to the differences in structures of the isoenzymes by characterizing a series of chimeric enzymes, which could represent intermediates in the evolution of catalytic activity. Deletion of Asp-115 from the E isoenzyme created the E/D115 delta enzyme that is active on steroids. The deletion alters the substrate binding pocket by moving Leu-116, which sterically hinders binding of steroids in the E isoenzyme. A chimeric enzyme (ESE) that has four changes in or near the substrate binding pocket (T94I/R101S/F110L/D115 delta) was 15-30-fold more catalytically efficient (V/Km) on uncharged steroids than was the E/D115 delta enzyme. Molecular modeling suggests that the substitutions at residues 94 and 110 indirectly affect the activity on steroids. ESE enzyme was 6-fold more active than the S isoenzyme on neutral steroids, due to substitutions not in the substrate binding pocket. The K366E and the Q17E/A43T/A59T substitutions in the S isoenzyme gave 2-fold increases in V/Km on steroids, which together can account for the changes observed with the ESE enzyme. The enzymes that are active on steroids did not bind 2,2,2-trifluoroethanol as tightly and were catalytically less efficient than the E isoenzyme with small alcohols. However, these enzymes were two to three and four to five orders of magnitude more efficient with 1-hexanol and 5 beta-androstane-3 beta,17 beta-diol, respectively, than with ethanol. These results demonstrate that several residues not directly participating in substrate binding or chemical catalysis contribute to catalytic efficiency.