On the rate of proton exchange with solvent of the catalytic histidine in flavocytochrome b2 (yeast L-lactate dehydrogenase).

The family of FMN-dependent, alpha-hydroxy acid-oxidizing enzymes catalyzes substrate dehydrogenation by a mechanism the first step of which is abstraction of the substrate alpha-proton (so-called carbanion mechanism). For flavocytochrome b2 and lactate oxidase, it was shown that once on the enzyme this proton is lost only slowly to the solvent (Lederer F, 1984, In: Bray RC, Engel PC, Mayhew SG, eds, Flavins & flavoproteins, Berlin: Walter de Gruyter & Co., pp 513-526; Urban P, Lederer F, 1985, J Biol Chem 260:11115-11122). This suggested the occurrence of a pKa increase of the catalytic histidine upon enzyme reduction by substrate. For flavocytochrome b2, the crystal structure indicated 2 possible origins for the stabilization of the imidazolium form of His 373: either a network of hydrogen bonds involving His 373, Tyr 254, flavin N5 and O4, a heme propionate, and solvent molecules, and/or electrostatic interactions with Asp 282 and with the reduced cofactor N1 anion. In this work, we probe the effect of the hydrogen bond network at the active site by studying proton exchange with solvent for 2 mutants: Y254F and the recombinant flavodehydrogenase domain, in which this network should be disrupted. The rate of proton exchange, as determined by intermolecular hydrogen transfer experiments, appears identical in the flavodehydrogenase domain and the wild-type enzyme, whereas it is about 3-fold faster in the Y254F mutant. It thus appears that specific hydrogen bonds to the solvent do not play a major role in stabilizing the acid form of His 373 in reduced flavocytochrome b2. Removal of the Y254 phenol group induces a pKa drop of about half a pH unit for His 373 in the reduced enzyme. Even then, the rate of exchange of the imidazolium proton with solvent is still lower by several orders of magnitude than that of a normally ionizing histidine. Other factors must then also contribute to the pKa increase, such as the electrostatic interactions with D282 and the anionic reduced cofactor, as suggested by the crystal structure.     

Amino acid sequence of long chain alpha-hydroxy acid oxidase from rat kidney, a member of the family of FMN-dependent alpha-hydroxy acid-oxidizing enzymes

The complete amino acid sequence of rat kidney long chain alpha-hydroxy acid oxidase has been determined by microsequencing, using a number of standard enzymatic and chemical cleavages. Peptides were purified by high pressure liquid chromatography or by gel electrophoresis followed by electrotransfer. The sequence comprises 352 residues and ends with a peroxisomal targeting sequence SRL. The present work definitely establishes that hydroxy acid oxidase is a member of the family of FMN-dependent alpha-hydroxy acid-oxidizing enzymes. The family includes lactate oxidase, short chain alpha-hydroxy acid oxidase (glycolate oxidase), flavocytochrome b2, and mandelate dehydrogenase. There are altogether 45 totally conserved positions among the six sequences known. The sequence similarities are analyzed in light of the known three-dimensional structure of flavocytochrome b2 and glycolate oxidase. It is concluded that long chain hydroxy acid oxidase should be folded as a beta 8 alpha 8 barrel and should dehydrogenate alpha-hydroxy acids according to the same chemical mechanism as other enzymes of the family, in spite of a Tyr----Phe substitution at the active site.     

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.     

pKa's of ionizable groups in proteins: atomic detail from a continuum electrostatic model

A macroscopic electrostatic model is used to calculate the pKa values of the titratable groups in lysozyme. The model makes use of detailed structural information and treats solvation self-energies and interactions arising from permanent partial charges and titratable charges. Both the tetragonal and triclinic crystal structures are analyzed. Half of the experimentally observed pKa shifts (11 out of 21) are well reproduced by calculations for both structures; this includes the unusually high pKa of Glu 35 in the active site. For more than half the pKa's (13 out of 21), there is a large difference (1-3.3 pK units) between the results from the two structures. Many of these correspond to the titrating groups for which the calculations are in error. Since for an ionic strength of 0.1 M the Debye screening between titratable groups leads to a very high effective dielectric constant (the average value for all pairs of titrating groups is approximately 900), near-neighbor interactions dominate the pKa perturbations. Thus, the pKa values are very sensitive to the details of the local protein conformation, and it is likely that side-chain mobility has an important role in determining the observed pKa shifts.     

Solvent and primary deuterium isotope effects show that lactate CH and OH bond cleavages are concerted in Y254F flavocytochrome b2, consistent with a hydride transfer mechanism

Yeast flavocytochrome b(2) catalyzes the oxidation of lactate to pyruvate; because of the wealth of structural and mechanistic information available, this enzyme has served as the model for the family of flavoproteins catalyzing oxidation of alpha-hydroxy acids. Primary deuterium and solvent isotope effects have now been used to analyze the effects of mutating the active site residue Tyr254 to phenylalanine. Both the V(max) and the V/K(lactate) values decrease about 40-fold in the mutant enzyme. The primary deuterium isotope effects on the V(max) and the V/K(lactate) values increase to 5.0, equivalent to the intrinsic isotope effect for the wild-type enzyme. In addition, both the V(max) and the V/K(lactate) values exhibit solvent isotope effects of 1.5. Measurement of the solvent isotope effect with deuterated lactate establishes that the primary and solvent isotope effects arise from the same chemical step, consistent with concerted cleavage of the lactate OH and CH bonds. The pH dependence of the mutant enzyme is not significantly different from that of the wild-type enzyme; this is most consistent with a requirement that the side chain of Tyr254 be uncharged for catalysis. The results support a hydride transfer mechanism for the mutant protein and, by extension, wild-type flavocytochrome b(2) and the other flavoproteins catalyzing oxidation of alpha-hydroxy acids.     

Chloride binding regulates the Schiff base pK in gecko P521 cone-type visual pigment

The binding of chloride is known to shift the absorption spectrum of most long-wavelength-absorbing cone-type visual pigments roughly 30 nm to the red. We determined that the chloride binding constant for this color shift in the gecko P521 visual pigment is 0.4 mM at pH 6.0. We found an additional effect of chloride on the P521 pigment: the apparent pKa of the Schiff base in P521 is greatly increased as the chloride concentration is increased. The apparent Schiff base pKa shifts from 8.4 for the chloride-free form to >10.4 for the chloride-bound form. We show that this shift is due to chloride binding to the pigment, not to the screening of the membrane surface charges by chloride ions. We also found that at high pH, the absorption maximum of the chloride-free pigment shifts from 495 to 475 nm. We suggest that the chloride-dependent shift of the apparent Schiff base pKa is due to the deprotonation of a residue in the chloride binding site with a pKa of ca. 8.5, roughly that of the Schiff base in the absence of chloride. The deprotonation of this site results in the formation of the 475 nm pigment and a 100-fold decrease in the pigment's ability to bind chloride. Increasing the concentration of chloride results in the stabilization of the protonated state of this residue in the chloride binding site and thus increased chloride binding with an accompanying increase in the Schiff base pK.     

Flavocytochrome b2: reactivity of its flavin with molecular oxygen

Flavocytochrome b2, a flavohemoprotein, catalyzes the oxidation of lactate at the expense of the physiological acceptor cytochrome c in the yeast mitochondrial intermembrane space. The mechanism of electron transfer from the substrate to monoelectronic acceptors via FMN and heme b2 has been intensively studied over the years. Each prosthetic group is bound to a separate domain, N-terminal for the heme, C-terminal for the flavin. Each domain belongs to a distinct evolutionary family. In particular, the flavodehydrogenase domain is homologous to a number of well-characterized l-2-hydroxy acid-oxidizing enzymes. Among these, some are oxidases for which the oxidative half-reaction produces hydrogen peroxide at the expense of oxygen. For bacterial mandelate dehydrogenase and flavocytochrome b2, in contrast, the oxidative half-reaction requires monoelectronic acceptors. Several crystal structures indicate an identical fold and a highly conserved active site among family members. All these enzymes form anionic semiquinones and bind sulfite, properties generally associated with oxidases, whereas electron transferases are expected to form neutral semiquinones and to yield superoxide anion. Thus, flavocytochrome b2 is a highly unusual dehydrogenase-electron transferase, and one may wonder how its flavin reacts with oxygen. In this work, we show that the separately engineered flavodehydrogenase domain produces superoxide anion in its slow reaction with oxygen. This reaction apparently also takes place in the holoenzyme when oxygen is the sole electron acceptor, because the heme domain autoxidation is also slow; this is not unexpected, in view of the heme domain mobility relative to the tetrameric flavodehydrogenase core (Xia, Z. X., and Mathews, F. S. (1990) J. Mol. Biol. 212, 837-863). Nevertheless, this reaction is so slow that it cannot compete with the normal electron flow in the presence of monoelectronic acceptors, such as ferricyanide and cytochrome c. An inspection of the available structures of family members does not provide a rationale for the difference between the oxidases and the electron transferases.     

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.     

Effects of two ionizing groups on the active site of human carbonic anhydrase B.

Investigation of some pH-dependent properties of human erythrocyte carbonic anhydrase B indicate that the active site is influenced by at least two charged groups. The properties studied include the pH dependence of inhibition of native, monocarboxamidomethyl, and monocarboxymethyl enzymes by iodide ion and the pH dependence of the visible spectra of the cobalt derivatives of these enzymes. One ionizing group has a pKa of about 7.3 in the native enzyme, 8.2 in the carboxyamidomethyl enzyme, and 9.0 in the carboxymethyl enzyme. It has a major influence on activity and anion inhibition, and on the visible spectra of the cobalt enzymes. A second group has a pKa of about 6.1 in native and modified enzymes. When zinc is at the active site, the secondary group in its acidic form decreases the Ki for I-. With the carboxyamidomethyl and carboxymethyl enzymes, the Ki decreases by about an order of magnitude. However, if cobalt is substituted for zinc in the modified enzymes, this group does not influence the Ki for I- and the binding of I- does not influence the pKa of the spectral transitions caused by ionization of this secondary group. In the case of nonalkylated Co2+-enzyme, another ionizing group with a pK of about 6.2 prevents the binging of I- at low pH. These results show that the active site is altered when cobalt is substituted for zinc in carbonic anhydrase B.     

Proton-transfer effects in the active-site region of Escherichia coli thioredoxin using two-dimensional 1H NMR.

A series of two-dimensional (2D) correlated 1H NMR spectra of reduced and oxidized Escherichia coli thioredoxin have been used to probe the effects of pH in the vicinity of the active site, -Cys32-Gly-Pro-Cys35-, using the complete proton resonance assignments available for thioredoxin. In either oxidation state, the majority of residues of the thioredoxin molecule remain unchanged between pH 5.7 and pH 10, as indicated by the identical chemical shifts of the C alpha H, C beta H, and other protons. In reduced thioredoxin, a fairly widespread region around the active-site dithiol is affected by the titration of a group or groups with pKa approximately 7.1-7.4 in 2H2O. Another titration, with pKa approximately 8.4, affects a smaller region of the protein. Oxidized thioredoxin contains a disulfide and no free thiol groups; nevertheless, the proton resonances of many groups in the active-site region were observed to titrate with a pKa of 7.5, probably as a result of an abnormally high pKa value for the carboxyl group of the buried Asp-26 residue. For reduced thioredoxin, the results indicate that Asp-26 is titrating in this pH range, as well as both thiol groups. The new results are strongly suggestive that the mechanism of thioredoxin-catalyzed protein disulfide reduction may be critically dependent on proton transfer as well as electron transfer within the active site.     

Hydroxamates as substrates and inhibitors for FMN-dependent 2-hydroxy acid dehydrogenases

Long-chain hydroxy acid oxydase (HAO) is a member of a flavoenzyme family with significant amino acid sequence similarity and strongly conserved three-dimensional structure; in particular, active-site amino acids involved in catalysis are invariant, with one exception, and numerous enzymatic studies suggest an identical chemical mechanism involving an intermediate carbanion for all family members. Known physiological substrates are a variety of L-2-hydroxy acids. Peroxisomal HAO differs from the other family members in that its actual physiological substrate is not known; it was first described as an L-amino acid oxidase, and recently was identified as an enzyme that converts creatol (hydroxycreatinine) to methylguanidine (a metabolite involved in a variety of uremic syndromes). Creatol (2-amino-5-hydroxy-1-methyl-4(5H)imidazolone) is not a 2-hydroxy acid. We show in this work that 2-hydroxyphenyl acetohydroxamate (HYPAH, the hydroxamate of mandelic acid), a compound that bears similarity both to mandelate (one of the best substrates known) and to creatol, is turned over by HAO, but between 10- and 100-fold less efficiently than mandelate itself. The compound also binds to the active site of homologous flavocytochrome b(2) (L-lactate dehydrogenase). Comparative pH-rate studies for mandelate and its hydroxamate suggest that HYPAH may bind in its ionized form. Both pH-rate profiles are bell-shaped curves, as are those determined for two other family members, flavocytochrome b(2) and mandelate dehydrogenase; while the group with an acid pK(a) between 5 and 6 is most likely the active-site histidine (the residue which abstracts the substrate C2 proton), the identity of the basic group is less clear. It has been proposed to be one of the active site arginines (Lehoux, I., and Mitra, B. (1999) Biochemistry38, 5836-5848); we suggest as an alternative that it could be the lysine residue that interacts with the flavin N1 and O2 positions and stabilizes the negative charge of reduced flavin. In addition to these studies, we have found that HAO is competitively inhibited by benzohydroxamate, which is one atom shorter than HYPAH; its affinity is nearly 100-fold lower than that of the substrate, in contrast to the strong inhibition it exerts on mandelate racemase (Maurice, St. M., and Bearne, S. L. (2000) Biochemistry39, 13324-13335). In the latter case, the 100-fold higher affinity compared to mandelate was proposed to arise from the fact that the hydroxamate can mimic the enolic intermediate which lies on the reaction pathway after C2 proton abstraction. Thus our results do not support the existence of a similar enolic intermediate for HAO (and probably its homologues), although they do not disprove it.     

The pH variation of steady-state kinetic parameters of site-specific Co(2+)-reconstituted liver alcohol dehydrogenase. A mechanistic probe for the assignment of metal-linked ionizations

To identify ionizations of the active site metal-bound water in horse liver alcohol dehydrogenase (alcohol:NAD+ oxidoreductase; EC 1.1.1.1), the pH, solvent isotope, temperature, and anion dependences of the steady-state kinetic parameters kcat and kcat/KM have been evaluated under initial velocity conditions for the native and the active site-specific Co(2+)-reconstituted enzyme. In the oxidation of benzyl alcohol, a bell-shaped pattern of four prototropic equilibria was observed under conditions of saturating concentrations of NAD+. It is shown that the ionizations governing kcat (pK1 congruent to 6.7, pK2 congruent to 10.6) belong to the ternary enzyme-NAD(+)-alcohol complex, whereas the ionizations governing kcat/KM (pK1' congruent to 7.5, pK2' congruent to 8.9) belong to the binary enzyme-NAD+ complex. The ionizations pK1 and pK1' are not influenced by metal substitution and are ascribed to His-51 on the basis of experimental estimates of their associated enthalpies of ionization. On the other hand, pK2 and pK2' are significantly decreased (delta pKa congruent to 1.0) in the Co(2+)-enzyme and are attributed to the active site metal-bound water molecule. The shape of the pH profiles requires that the metal ion coordinates a neutral water molecule in the ternary enzyme-NAD(+)-alcohol complex under physiological conditions. The possible catalytic role of the water molecule within a pentacoordinate metal ion complex in the active site is discussed.     

NMR determination of lysine pKa values in the Pol lambda lyase domain: mechanistic implications

The base excision repair (BER) process requires removal of an abasic deoxyribose-5-phosphate group, a catalytic activity that has been demonstrated for the N-terminal 8 kDa domain of DNA polymerase beta (Pol beta), and for the homologous domain of DNA polymerase lambda (Pol lambda). Previous studies have demonstrated that this activity results from formation of a Schiff base adduct of the abasic deoxyribose C-1' with a lysine residue (K312 in the case of Pol lambda), followed by a beta-elimination reaction. To better understand the underlying chemistry, we have determined pKa values for the lysine residues in the Pol lambda lyase domain labeled with [epsilon-13C]lysine. At neutral pH, the H(epsilon) protons on 3 of the 10 lysine residues in this domain, K287, K291, and K312, exhibit chemical shift inequivalence that results from immobilization of the lysyl side chains. For K287 and K291, this results from the K287-E261 and K291-E298 salt bridge interactions, while for K312, immobilization apparently results from steric and hydrogen-bonding interactions that constrain the position of the lysine side chain. The pKa value of K312 is depressed to 9.58, a value indicating that at physiological pH K312 will exist predominantly in the protonated form. Titration of the domain with hairpin DNA containing a 5'-tetrahydrofuran terminus to model the abasic site produced shifts of the labeled lysine resonances that were in fast exchange but appeared to be complete at a stoichiometry of approximately 1:1.3, consistent with a dissociation constant of approximately 1 microM. The epsilon-proton shifts of K273 were the most sensitive to the addition of the DNA, apparently due to changes in the relative orientation between K273 and W274 in the DNA complex. The average pKa values increased by 0.55, consistent with the formation of some DNA-lysine salt bridges and with the general pH increase expected to result from a reduction in the net positive charge of the complex. A general increase in the Hill coefficients observed in the complex is consistent with the screening of the interacting lysine residues by the DNA. The pKa of K312 residue increased to 10.58 in the complex, probably due to salt bridge formation with the 5'-phosphate group of the DNA. The pKa values obtained for the lyase domain of Pol lambda in the present study are consistent with recent crystallographic studies of Pol beta complexed with 5-phosphorylated abasic sugar analogues in nicked DNA which reveal an open site with no obvious interactions that would significantly depress the pK value for the active site lysine residue. It is suggested that due to the heterogeneity of the damaged DNA substrates with which Pol lambda as well as other related polymerases may be required to bind, the unexpectedly poor optimization of the lyase catalytic site may reflect a compromise of flexibility with catalytic efficiency.     

Studies on the aminopeptidase activity of rat cathepsin H.

Three synthetic substrates H-Arg-NH-Mec, Bz-Arg-NH-Mec and H-Cit-NH-Mec (Bz, Benzoyl; NH-Mec, 4-methylcoumaryl-7-amide; Cit, citrulline) were used to characterize specificity requirements for the P1-S1 interaction of cathepsin H from rat liver. From rapid equilibrium kinetic studies it was shown that Km, kcat and the specificity constants kcat/Km are quite similar for substrates with a free alpha-amino group. In contrast, a 25-fold decrease of kcat/Km was observed for the N-terminal-blocked substrate Bz-Arg-NH-Mec. The activation energies for H-Arg-NH-Mec and Bz-Arg-NH-Mec were determined to be 37 kJ/mol and 55 kJ/mol, respectively, and the incremental binding energy delta delta Gb of the charged alpha-amino group was estimated to -8.1 kJ/mol at pH 6.8. The shown preference of cathepsin H for the unblocked substrates H-Arg-NH-Mec and H-Cit-NH-Mec was further investigated by inspection of the pH dependence of kcat/Km. The curves of the two substrates with a charged alpha-amino group showed identical bell-shaped profiles which both exhibit pKa1 and pKa2 values of 5.5 and 7.4, respectively, at 30 degrees C. The residue with a pKa1 of 5.5 in the acid limb of the activity profile of H-Arg-NH-Mec was identified by its ionization enthalpy delta Hion = 21 kJ/mol as a beta-carboxylate or gamma-carboxylate of the enzyme, whereas the residue with a pKa2 of 7.4 was assigned to the free alpha-amino group of the substrate with a delta Hion of 59 kJ/mol. Bz-Arg-NH-Mec showed a different pH-activity profile with a pKa1 of 5.4 and a pKa2 of 6.6 at 30 degrees C. Cathepsin H exhibits no preference for a basic P1 side chain as has been shown by the similar kinetics of H-Arg-NH-Mec and the uncharged, isosteric substrate H-Cit-NH-Mec. In summary, specific interactions of an anionic cathepsin H active site residue with the charged alpha-amino group of substrates caused transition state stabilization which proves the enzyme to act preferentially as an aminopeptidase.     

Bromopyruvate as an affinity label for baker's yeast flavocytochrome b2. Kinetic study of the inactivation reaction.

Bromopyruvate was shown to completely inactivate cytochrome b2 in a reaction that obeyed the kinetic criteria required for affinity labels: it inactivated flavocytochrome b2 according to saturation kinetics, and the inactivation reaction was competitively inhibited by the substrate or competitive inhibitors. Inactivation was irreversible. The behaviour of both forms of flavocytochrome b2 (lintact and proteolytically cleaved) was examined. It was found that the reduced cleaved enzyme was not inactivated by bromopyruvate; this phenomenon can probably be ascribed to a structural change undergone upon reduction. The value of the lactate dissociation constant of intact cytochrome b2 cytochrome b2 was determined in competition experiments with bromopyruvate. By comparison with the divergent published values for the Ks of the cleaved from, it appears that only those that differ from the Km by a factor of two or three are reasonable. This study opens the way for the identification of an active site residue and localization in the peptide chain of the bifunctional enzyme.     

Spinach glycolate oxidase and yeast flavocytochrome b2 are structurally homologous and evolutionarily related enzymes with distinctly different function and flavin mononucleotide binding

A comparison of the three-dimensional structures of the flavin mononucleotide (FMN)-dependent enzymes glycolate oxidase, flavocytochrome b2, and trimethylamine dehydrogenase is presented. Their flavin-binding domains all have the same structural motif, the 8-fold beta/alpha-barrel domain, which is also present in a large number of other enzymes. FMN is bound in a similar fashion in all three enzymes. The binding site is at the carboxyl-terminal end of the eight beta-strands of the barrel where the active site is invariably found in this type of domain structure. The similarity of the structures of glycolate oxidase and flavocytochrome b2 extends to the loop regions and even outside the beta/alpha-barrels with a root mean square deviation of 0.93 A for 311 superimposed C alpha-atoms and with a sequence identity of 37%. A detailed analysis of their active sites shows, however, that the orientation of FMN is significantly different in the two structures due to different conformations of residues in the end of strand one. Thus, in flavocytochrome b2 a hydrogen bond is formed between the FMN N-5 position and the main chain amide of Ala-198, while in glycolate oxidase, the ring system is tilted away from the strand, creating a pocket on the re-side of the FMN ring where a water molecule is bound. Model building shows that this site could accommodate the hydroperoxide moiety of a FMN-4a-hydroperoxide intermediate. Thus, in the course of evolution, a few mutations in, and close to, the active sites have fine tuned these enzymes to exert their specific functions as an oxidase or transferase, respectively.     

Study of penicillin amidase from E. coli. pH-dependence of kinetic parameters of enzymatic hydrolysis of benzylpenicillin]

The authors studies pH-dependencies of the kinetic parameters (Vm, KM, Vm/KM) and constants of competitive inhibition by phenylacetic acid of penicillinamidase-catalyzed hydrolysis of benzylpenicillin. The experimental data are in agreement with the assumption according to which there are 3 equilibrium ionogenic forms of the enzyme and enzyme-substrate (or enzyme-inhibitor) complexes, i.e. acidic, neutral and alkaline, the neutral form being the only active form of the Michaelis complex. Values of pK in the ionogenic groups controlling interconversions of both the free enzyme (pK1 6.1 and pK2 7.6) and of the enzyme-substrate complex (pKa 6.1 and pK2 10.2 or the enzyzme-inhibitor complex (pK'1 6.1 and pK'2 9.5) were determined. From this and the previously published results it was concluded that the group with pK 6.1 was involved in the catalysis and the group with pK 10.2 in the maintenance of the active conformation of the active centre of penicillinamidase. The ionogenic group with pK 7.6 was apparently involved in the enzyme-substrate binding.     

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.     

Study of the Hansenula anomala yeast flavocytochrome-b2-cytochrome-c complex 2. Localization of the main association area

The reversible association of the Zn2+-substituted Hansenula anomala cytochrome c dimer (Thomas et al., preceding paper in this issue) to flavocytochrome b2 in oxidized or lactate-reduced state has been investigated by fluorimetry. The same method has been used for the determination of Zn-cytochrome c complexing to defined proteolytic fragments of flavocytochrome b2, either heme-b2-containing monomers or a flavin-linked tetramer. All these fragments but the isolated cytochrome b2 core showed binding stoichiometries, Kd values and ionic strength dependences quite similar to those found for native flavocytochrome b2. These data allowed localization of the single high-affinity binding site of cytochrome c on a particular globule in the dehydrogenase domain of the flavocytochrome b2 protomers. Quenching of the Zn-porphyrin c fluorescence in the various complexes occurred with only minor changes of the fluorescence lifetime and did not show any direct relationship to the presence or the redox state of the heme b2 group.     

Combined Density Functional Theory (DFT) and Continuum Calculations of pK(a) in Carbonic Anhydrase

Deprotonation of zinc-bound water in carbonic anhydrase II is the rate-limiting step in the catalysis of carbon dioxide between gas- and water-soluble forms. To understand the factors determining the extent of dissociation, or pK(a), of the zinc-bound water, we apply quantum chemistry calculations to the active site coupled with a continuum model of the surrounding environment. Experimentally determined changes in pK(a) associated with mutations of the active site are well reproduced by this approach. Analysis of the active site structure and charge/dipole values provides evidence that mutations cause changes in both conformation of the active site structure and local polarization, which accounts for the shifts in pK(a). More specifically, the shifts in pK(a) correlate with the dipole moments of the zinc-bound water upon deprotonation. The data further support the conclusion that the distinct pK(a) values found in mutations of the same type, but applied to different sites, result from asymmetric ligation and different electronic environments around the zinc ion.