Active site rearrangement of the 2-hydrazinopyridine adduct in Escherichia coli amine oxidase to an azo copper(II) chelate form: a key role for tyrosine 369 in controlling the mobility of the TPQ-2HP adduct

Adduct I (lambda(max) at approximately 430 nm) formed in the reaction of 2-hydrazinopyridine (2HP) and the TPQ cofactor of wild-type Escherichia coli copper amine oxidase (WT-ECAO) is stable at neutral pH, 25 degrees C, but slowly converts to another spectroscopically distinct species with a lambda(max) at approximately 530 nm (adduct II) at pH 9.1. The conversion was accelerated either by incubation of the reaction mixture at 60 degrees C or by increasing the pH (>13). The active site base mutant forms of ECAO (D383N and D383E) showed spectral changes similar to WT when incubated at 60 degrees C. By contrast, in the Y369F mutant adduct I was not stable at pH 7, 25 degrees C, and gradually converted to adduct II, and this rate of conversion was faster at pH 9. To identify the nature of adduct II, we have studied the effects of pH and divalent cations on the UV-vis and resonance Raman spectroscopic properties of the model compound of adduct I (2). Strikingly, it was found that addition of Cu2+ to 2 at pH 7 gave a product (3) that exhibited almost identical spectroscopic signatures to adduct II. The X-ray crystal structure of 3 shows that it is the copper-coordinated form of 2, where the +2 charge of copper is neutralized by a double deprotonation of 2. These results led to the proposal that adduct II in the enzyme is TPQ-2HP that has migrated onto the active site Cu2+. The X-ray crystal structure of Y369F adduct II confirmed this assignment. Resonance Raman and EPR spectroscopy showed that adduct II in WT-ECAO is identical to that seen in Y369F. This study clearly demonstrates that the hydrogen-bonding interaction between O4 of TPQ and the conserved Tyr (Y369) is important in controlling the position and orientation of TPQ in the catalytic cycle, including optimal orientation for reactivity with substrate amines.     

Structural Snapshots from the Oxidative Half-reaction of a Copper Amine Oxidase: IMPLICATIONS FOR O2 ACTIVATION*

The mechanism of molecular oxygen activation is the subject of controversy in the copper amine oxidase family. At their active sites, copper amine oxidases contain both a mononuclear copper ion and a protein-derived quinone cofactor. Proposals have been made for the activation of molecular oxygen via both a Cu(II)-aminoquinol catalytic intermediate and a Cu(I)-semiquinone intermediate. Using protein crystallographic freeze-trapping methods under low oxygen conditions combined with single-crystal microspectrophotometry, we have determined structures corresponding to the iminoquinone and semiquinone forms of the enzyme. Methylamine reduction at acidic or neutral pH has revealed protonated and deprotonated forms of the iminoquinone that are accompanied by a bound oxygen species that is likely hydrogen peroxide. However, methylamine reduction at pH 8.5 has revealed a copper-ligated cofactor proposed to be the semiquinone form. A copper-ligated orientation, be it the sole identity of the semiquinone or not, blocks the oxygen-binding site, suggesting that accessibility of Cu(I) may be the basis of partitioning O₂ activation between the aminoquinol and Cu(I).     

Role of the interactions between the active site base and the substrate Schiff base in amine oxidase catalysis. Evidence from structural and spectroscopic studies of the 2-hydrazinopyridine adduct of Escherichia coli amine oxidase

2-Hydrazinopyridine (2HP) is an irreversible inhibitor of copper amine oxidases (CAOs). 2HP reacts directly at the C5 position of the TPQ cofactor, yielding an intense chromophore with lambda(max) approximately 430 nm (adduct I) in Escherichia coli amine oxidase (ECAO). The adduct I form of wild type (WT-ECAO) was assigned as a hydrazone on the basis of the X-ray crystal structure. The hydrazone adduct appears to be stabilized by two key hydrogen-bonding interactions between the TPQ-2HP moiety and two active site residues: the catalytic base (D383) and the conserved tyrosine residue (Y369). In this work, we have synthesized a model compound (2) for adduct I from the reaction of a TPQ model compound (1) and 2HP. NMR spectroscopy and X-ray crystallography show that 2 exists predominantly as the azo form (lambda(max) at 414 nm). Comparison of the UV-vis and resonance Raman spectra of 2 with adduct I in WT, D383E, D383N, and Y369F forms of ECAO revealed that adduct I in WT and D383N is a tautomeric mixture where the hydrazone form is favored. In D383E adduct I, the equilibrium is further shifted in favor of the hydrazone form. UV-vis spectroscopic pH titrations of adduct I in WT, D383N, D383E, and 2 confirmed that D383 in WT adduct I is protonated at pH 7 and stabilizes the hydrazone tautomer by a short hydrogen-bonding interaction. The deprotonation of D383 (pKa approximately 9.7) in adduct I resulted in conversion of adduct I to the azo tautomer with a blue shift of the lambda(max) to 420 nm, close to that of 2. In contrast, adduct I in D383N and D383E is stable and did not show any pH-dependent spectral changes. In Y369F, adduct I was not stable and gradually converted into a new species with lambda(max) at approximately 530 nm (adduct II). A detailed mechanism for the adduct I formation in WT has been proposed that is consistent with the mechanism proposed for the oxidation of substrate by CAOs but addresses some key differences in the active site chemistry of hydrazine inhibitors and substrate amines.     

Relationship of stopped flow to steady state parameters in the dimeric copper amine oxidase from Hansenula polymorpha and the role of zinc in inhibiting activity at alternate copper-containing subunits

The expression of a copper amine oxidase (CAO) from Hansenula polymorpha in Saccharomyces cerevisiae under differing culture conditions leads to the incorporation of varied levels of CAO-bound zinc. The presence of substantial amount of zinc results in two distinctive enzyme species, designated as the fast and slow enzymes. Both forms are rapidly reduced by substrate methylamine with a rate constant of 199 s(-1) but behave remarkably differently in their oxidation rates; the fast enzyme is oxidized by dioxygen at a rate of 22.1 s(-1), whereas the slow enzyme reacts at a rate of 1.8 x 10(-4) s(-1). The apparent kcat of the enzyme preparation is linearly proportional to the fraction of the fast enzyme, with an extrapolated value of 6.17 s(-1) when the enzyme is 100% in its "fast" form. A comparison of rate constants for cofactor reduction and reoxidation steps, measured in stopped flow experiments, to the extrapolated kcat implicates additional steps in the steady state reaction. Measurement of the proportion of oxidized (ETPQ(ox)) and reduced cofactor (ETPQ(red)) under steady state conditions indicates approximately 50% of each cofactor form at 0.8 or 2 mM methylamine. Kinetic isotope effect measurements using deuterated amine substrate lead to the following steady state values: (D)(k(red)) = 8.5 (0.5), (D)(kcat) = 1.7 (0.1), and (D)(kcat/K(m)) = 4.3 (0.2). The collective data allow the calculation of partially rate-determining constants during the reductive half-reaction (ca. 200 s(-1) for binding of substrate to ETPQ(ox) and 27.9 s(-1) for release of aldehyde product or a protein isomerization from ETPQ(red)); an additional step with a rate constant of 13.2 s(-1) is assigned to the oxidative half-reaction, most likely for the release of product hydrogen peroxide. These results, together with the sole detection of oxidized and reduced cofactor during rapid scanning stopped flow experiments, indicate that four steps contribute to kcat, with the first electron transfer from cofactor to O2 contributing ca. 29%. An investigation of the relationship between the copper content and the extent of the fast enzyme shows that only the copper-containing homodimer is capable of rapid reoxidation and that zinc-copper heterodimers are incapable of rapid turnover at either subunit. This implies communication between the metal sites of the two subunits per dimer that impacts O2 binding and/or electron transfer from reduced cofactor to bound O2.     

Resonance Raman spectroscopy of methylamine dehydrogenase from bacterium W3A1

Resonance Raman spectroscopy has been used to probe the structure of the covalently bound quinone cofactor in methylamine dehydrogenase from the bacterium W3A1. Spectra were obtained on the phenylhydrazine and 2-pyridylhydrazine derivatives of the native enzyme, on the quinone-containing subunit labeled with phenylhydrazine, and on an active-site peptide also labeled with phenylhydrazine. Comparisons of these spectra to the corresponding spectra of copper-containing amine oxidase derivatives indicate that the quinones in these two classes of quinoproteins are not identical. The resonance Raman spectra of the native enzyme and small subunit have also been measured. 16O/18O exchange permitted the carbonyl modes of the quinone to be identified in the resonance Raman spectrum of oxidized methylamine dehydrogenase: a band at 1614 cm-1, together with a shoulder at 1630 cm-1, are assigned as modes containing substantial C = O stretching character. D2O/H2O exchange has pronounced effects on the resonance Raman spectrum of the oxidized enzyme, suggesting that the quinone may have numerous hydrogen bonds to the protein or that it is unusually sensitive to the local environment. Resonance Raman spectra of the isolated small subunit, and its phenylhydrazine derivative, are considerably different from the corresponding spectra of the intact protein. An attractive explanation for these observations is that the quinone cofactor in methylamine dehydrogenase from W3A1 is located at the interface between the large and small subunits, as found for the enzyme from Thiobacillus versutus [Vellieux, F. M. D., Huitema, F., Groendijk, H., Kalk, K. H., Frank, J. Jzn., Jongejan, J. A., & Duine, J. A. (1989) EMBO J. 8, 2171-2178].(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies of the mechanism of the delta 5-3-ketosteroid isomerase reaction by substrate, solvent, and combined kinetic deuterium isotope effects on wild-type and mutant enzymes

delta 5-3-Ketosteroid isomerase (EC 5.3.3.1) catalyzes the isomerization of delta 5-3-ketosteroids to delta 4-3-ketosteroids by a conservative tautomeric transfer of the 4 beta-proton to the 6 beta-position using Tyr-14 as a general acid and Asp-38 as a general base [Kuliopulos, A., Mildvan, A. S., Shortle, D., & Talalay, P. (1989) Biochemistry 28, 149]. On deuteration of the 4 beta-position (97.0%) of the substrate, kcat(H)/kcat(4 beta-D) is 6.1 in H2O and 6.3 in D2O. The solvent isotope effect, kcat(H2O)/kcat(D2O), is 1.6 for both the 4 beta-H and 4 beta-D substrates. Mutation of Tyr-55 to Phe lowers kcat 4.3-fold; kcat(H)/kcat/4 beta-D) is 5.3 in H2O and 5.9 in D2O, and kcat(H2O)/kcat(D2O) with the 4 beta-H and 4 beta-D substrates is 1.5 and 1.7, respectively, indicating concerted general acid-base catalysis in either the enolization or the ketonization step of both the wild-type and the Tyr-55----Phe (Y55F) mutant enzymes. An additional slow step occurs with the Y55F mutant. Smaller isotope effects on Km are used to estimate individual rate constants in the kinetic schemes of both enzymes. On deuteration of the 4 alpha-position (88.6%) of the substrate, the secondary isotope effect on kcat/Km corrected for composition is 1.11 +/- 0.02 with the wild-type enzyme and 1.12 +/- 0.02 with the Y55F mutant. These effects decrease to 1.06 +/- 0.01 and 1.07 +/- 0.01, respectively, when the 4 beta-position is also deuterated, thereby establishing these to be kinetic (rather than equilibrium) secondary isotope effects and to involve a proton-tunneling contribution. Deuteration of the 6-position of the substrate (92.0%) produces no kinetic isotope effects on kcat/Km with either the wild-type (1.00 +/- 0.01) or the Y55F mutant (1.01 +/- 0.01) enzyme. Since a change in hybridization from sp3 to sp2 occurs at C-4 only during enolization of the substrate and a change in hybridization at C-6 from sp2 to sp3 occurs only during reketonization of the dienol intermediate, enolization of the substrate constitutes the concerted rate-limiting step. Concerted enolization is consistent with the right angle or antarafacial orientations of Tyr-14 and Asp-38 with respect to the enzyme-bound substrate and with the additive effects on kcat of mutation of these catalytic residues [Kuliopulos, A., Talalay, P., & Mildvan, A. S. (1990) Biophys. J. 57, 39a].     

Steady-state kinetic analysis for the reaction of ammonium and alkylammonium ions with methylamine dehydrogenase from bacterium W3A1

The steady-state kinetic mechanism for the reaction of n-alkylamines and phenazine ethosulfate (PES) or phenazine methosulfate (PMS) with methylamine dehydrogenase from bacterium W3A1 is found to be of the ping-pong type. This conclusion is based on the observations that 1/v versus 1/[methylamine] or 1/[butylamine] plots, at various constant concentrations of an oxidizing substrate, and 1/v versus 1/[PES] or 1/[PMS] plots, at various constant concentrations of a reducing substrate, are parallel. Additionally, the values of kcat/Km for four n-alkylamines are identical when PES is the oxidizing substrate, as were the kcat/Km values for four reoxidizing substrates when methylamine was the reducing substrate. Last, analysis of steady-state kinetic data obtained when methylamine and propylamine are presented to the enzyme simultaneously and PES and PMS are used simultaneously also supports the involvement of a ping-pong mechanism. The enzymic reaction with either methylamine or PES is dependent on the ionic strength, and the data indicate that each interacts with an anionic site on methylamine dehydrogenase. The presence of ammonium ion at low concentration activates the enzyme, but at high concentration this ion is a competitive inhibitor in the reaction involving methylamine and the enzyme. A complete steady-state mechanism describing these ammonia effects is presented and is discussed in light of the nature of the pyrroloquinoline quinone cofactor covalently bound to the enzyme.     

Rates of oxygen and hydrogen exchange as indicators of TPQ cofactor orientation in amine oxidases.

This study presents the first detailed examination by resonance Raman (RR) spectroscopy of the rates of solvent exchange for the C5 and C3 positions of the TPQ cofactor in several wild-type copper-containing amine oxidases and mutants of the amine oxidase from Hansenula polymorpha (HPAO). On the basis of crystal structure analysis and differing rates of C5 [double bond] O and C3 [bond] H exchange within the enzyme systems, but equally rapid rates of C5 [double bond] O and C3 [bond] H exchange in a TPQ model compound, it is proposed that these data can be used to determine the TPQ cofactor orientation within the active site of the resting enzyme. A rapid rate of C5 [double bond] O exchange (t(1/2) < 30 min) and a slow (t(1/2) = 6 h) to nonexistent rate of C3 [bond] H exchange was observed for wild-type HPAO, the amine oxidase from Arthrobacter globiformis, pea seedling amine oxidase at pH 7.1, and the E406Q mutant of HPAO. This pattern is ascribed to a productive TPQ orientation, with the C5 [double bond] O near the substrate-binding site and the C3 [bond] H near the Cu. In contrast, a slow rate of C5 [double bond] O exchange (t(1/2) = 1.6-3.3 h) coupled with a fast rate of C3 [bond] H exchange (t(1/2) < 30 min) was observed for the D319E and D319N catalytic base mutants of HPAO and for PSAO at pH 4.6 (t(1/2) = 4.5 h for C5 [double bond] O exchange). This pattern identifies a flipped orientation, involving 180 degrees rotation about the C alpha-C beta bond, which locates the C3 [bond] H near the substrate-binding site and the C5 double bond] O near the Cu. Finally, fast rates of both C5 [double bond] O and C3 [bond] H exchange (t(1/2) < 30 min) were observed for the amine oxidase from Escherichia coli and the N404A mutant of HPAO, suggesting a mobile cofactor, with multiple TPQ orientations between productive and flipped. These results demonstrate that opposing sides of the TPQ ring possess different degrees of solvent accessibility and that the rates of C5 [double bond] O and C3 [bond] H exchange can be used to predict the TPQ cofactor orientation in the resting forms of these enzymes.     

Studies of the mechanism of glutamine synthetase utilizing pH-dependent behavior in catalysis and binding

The pKa values of enzyme groups of Escherichia coli glutamine synthetase which affect catalysis and/or substrate binding were determined by measuring the pH dependence of Vmax and V/K. Analysis of these data revealed that two enzyme groups are required for catalysis with apparent pKa values of approximately 7.1 and 8.2. The binding of ATP is essentially independent of pH in the range studied while the substrate ammonia must be deprotonated for the catalytic reaction. Using methylamine and hydroxylamine in place of ammonia, the pKa value of the deprotonated amine substrate as expressed in the V/K profiles was shifted to a lower pKa value for hydroxylamine and a higher pKa value for methylamine. These data indicate that the amine substrate must be deprotonated for binding. Hydroxylamine is at least as good a substrate as ammonia judged by the kinetic parameters whereas methylamine is a poor substrate as expressed in both the V and V/K values. Glutamate binding was determined by monitoring fluorescence changes of the enzyme and the data indicate that a protonated residue (pKa = 8.3 +/- 0.2) is required for glutamate binding. Chemical modification by reductive methylation with HCHO indicated that the group involved in glutamate binding most likely is a lysine residue. In addition, the Ki value for the transition state analog, L-3-amino-3-carboxy-propanesulfonamide was measured as a function of pH and the results indicate that an enzyme residue must be protonated (pKa = 8.2 +/- 0.1) to assist in binding. A mechanism for the reaction catalyzed by glutamine synthetase is proposed from the kinetic data acquired herein. A salt bridge is formed between the gamma-phosphate group of ATP and an enzyme group prior to attack by the gamma-carboxyl of glutamate on ATP to form gamma-glutamyl phosphate. The amine substrate subsequently attacks gamma-glutamyl phosphate resulting in formation of the tetrahedral adduct before phosphate release. A base on the enzyme assists in the deprotonation of ammonia during its attack on gamma-glutamyl phosphate or after the protonated carbinol amine is formed. Based on the kinetic data with the three amine substrates, catalysis is not rate-limiting through the pH range 6-9.     

Oxidation in H2O and D2O of 6-ethyl-5H-dibenz(c,e)azepine and 1-methylnicotinamide by aldehyde oxidase from rabbit liver

We report the solvent hydrogen isotope effects associated with the oxidation of 6-ethyl-5H-dibenz(c,e)azepine (6-ED) and 1-methylnicotinamide (1-MN) catalyzed by aldehyde oxidase from rabbit liver using two assay methods. The first uses 2,6-dichlorophenolindophenol (DCI) as electron acceptor in an indirect assay in which the bleaching of DCI is measured as the substrate is oxidized. The second uses molecular oxygen as electron acceptor in a direct assay in which the oxidation of 1-MN to its pyridones is accompanied by an increase in absorbance at 300 nm and the oxidation of 6-ED to its lactam product is accompanied by a decrease in absorbance at 335 nm. We have found a solvent hydrogen isotope effect close to unity in the turnover number for each substrate and for each assay method. The solvent hydrogen isotope effects on kcat/Km ranged from 0.4 to 1.1. We conclude that changes in bonding of hydrogen in solvent water, including hydrolysis of or general base attack on an enzyme-intermediate complex, do not play a rate-contributing role in the maximal velocity of oxidation of 1-MN and 6-ED catalyzed by aldehyde oxidase from rabbit liver.     

Electronegativity of aromatic amines as a basis for the development of ground state inhibitors of lysyl oxidase

Benzylamine derivatives containing para substituents of differing electronegativity as well as isomers of aminomethylpyridine have been assessed for their substrate and inhibitor potentials toward lysyl oxidase. Substituted benzylamines with increasingly electronegative para substituents had the lowest KI values and thus were the most effective inhibitors of the oxidation of elastin by lysyl oxidase. The kcat values for these compounds as substrates of lysyl oxidase were also reduced with increasingly electronegative para substituents. Both the Dkcat and D(kcat/Km) kinetic isotope effects decreased with increasingly electronegative p-substituents in [alpha, alpha'-2H]benzylamines. In contrast, there was no Dkcat solvent isotope effect with [2H] H2O while the D(kcat/Km) solvent isotope effect tended to increase with increasingly electronegative p-substituents. These results are consistent with the stabilization of an enzyme-generated substrate carbanion and thus the retardation of substrate oxidation by electronegative substituents. Such ground state stabilization thus can result in compounds with increased potential for the inhibition of the oxidation of protein substrates of lysyl oxidase.     

Resonance Raman spectroscopy and enhanced photoreducibility for the 420 nm pulsed form of cytochrome oxidase

Resonance Raman (RR) spectra, with 413.1 nm Kr+ laser excitation, are reported for cytochrome oxidase in resting, reduced, and 428 nm (oxygenated) forms, and for the first time, in the 420 nm (pulsed) forms [(1984) J. Biol. Chem. 259, 2073-2076]. The differences between the resting, 420 nm, and 428 nm forms' RR spectra are small. All these forms contain FeIII only, as indicated by single v4 bands at approximately 1371 cm-1, and the reoxidized forms show partial conversion from high- to intermediate- or low-spin heme a3 (intensity shift from 1575 to 1588 cm-1 for v2). The 420 nm form differs strikingly from both the 428 nm and resting forms, however, in being much more readily photoreduced by the laser illumination. This property is linked to the protein conformational change believed to be responsible for the greater accessibility to exogenous ligands of the heme a3 in the 420 nm form.     

The organic functional group in copper-containing amine oxidases. Resonance Raman spectra are consistent with the presence of topa quinone (6-hydroxydopa quinone) in the active site

Resonance Raman spectroscopy has been used to probe the structure of the organic cofactor in copper-containing amine oxidases from bovine plasma, porcine kidney, pea seedlings, and the bacterium Arthrobacter P1. The enzymes were first derivatized with phenylhydrazine or p-nitrophenylhydrazine; resonance Raman spectra were obtained on the intact derivatized enzymes and on a derivatized active-site peptide isolated from bovine plasma amine oxidase. Spectra of the intact amine oxidase phenylhydrazones are practically identical, consistent with the enzymes examined containing a similar cofactor. Only minor frequency shifts and some intensity variations are detected between the resonance Raman spectra of intact bovine plasma amine oxidase and the isolated peptide. These spectral perturbations are attributable to differences in the micro-environment between the intact, folded protein and the isolated small peptide in aqueous solution. This rules out the possibility that a new structure is formed during the isolation of the derivatized active-site peptide. Importantly, the resonance Raman spectra of the phenylhydrazine and p-nitrophenylhydrazine derivatives of the bovine plasma amine oxidase peptide are identical to the spectra of the corresponding derivatives of topa quinone (6-hydroxydopa quinone). Hence these data provide strong, independent support for the recent identification of topa as the organic functional group in bovine plasma amine oxidase (Janes, S. M., Mu, D., Wemmer, D., Smith, A. J., Kaur, S., Maltby, D., Burlingame, A. L., and Klinman, J.P. (1990) Science 248, 981-987).     

Purification and characterization of methylamine oxidase induced in Aspergillus niger AKU 3302

Crude extract of Aspergillus niger AKU 3302 mycelia incubated with methylamine showed a single amine oxidase activity band in a developed polyacrylamide gel that weakly cross-reacted with the antibody against a copper/topa quinone-containing amine oxidase (AO-II) from the same strain induced by n-butylamine. Since the organism cannot grow on methylamine and the already known quinoprotein amine oxidases of the organism cannot catalyze oxidation of methylamine, the organism was forced to produce another enzyme that could oxidize methylamine when the mycelia were incubated with methylamine. The enzyme was separated and purified from the already known two quinoprotein amine oxidases formed in the same mycelia. The purified enzyme showed a sharp symmetric sedimentation peak in analytical ultracentrifugation showing S20,w0 of 6.5s. The molecular mass of 133 kDa estimated by gel chromatography and 66.6 kDa found by SDS-PAGE confirmed the dimeric structure of the enzyme. The purified enzyme was pink in color with an absorption maximum at 494 nm. The enzyme readily oxidized methylamine, n-hexylamine, and n-butylamine, but not benzylamine, histamine, or tyramine, favorite substrates for the already known two quinoprotein amine oxidases. Inactivation by carbonyl reagents and copper chelators suggested the presence of a copper/topa quinone cofactor. Spectrophotometric titration by p-nitrophenylhydrazine showed one reactive carbonyl group per subunit and redox-cyclic quinone staining confirmed the presence of a quinone cofactor. pH-dependent shift of the absorption spectrum of the enzyme-p-nitrophenylhydrazone (469 nm at neutral to 577 nm at alkaline pH) supported the identity of the cofactor with topaquinone. Nothern blot analysis indicated that the methylamine oxidase encoding gene is largely different from the already known amine oxidase in the organism.     

Engineering of the iron site in ribonucleotide reductase to a self-hydroxylating monooxygenase.

Protein R2 of ribonucleotide reductase contains a dinuclear ferric iron center adjacent to a tyrosyl radical in the interior of the protein matrix. A patch of hydrophobic residues surrounds the iron-radical cofactor. Its importance during the oxidative generation of the iron-radical cofactor was investigated by site-directed mutagenesis of Phe-208 to tyrosine. The mutant protein R2 F208Y has prominent absorption bands at 460 and 720 nm reminiscent of those in ferric-catecholate complexes. Resonance Raman spectroscopy shows that the iron center of R2 F208Y contains a bidentate catechol ligand. The mechanism for generation of this protein-derived dihydroxyphenylalanine may be similar to the catalytic cycle of methane monooxygenase.     

On the contribution of the positively charged headgroup of choline to substrate binding and catalysis in the reaction catalyzed by choline oxidase

Recent kinetic studies established that the positive charge on the trimethylammonium group of choline plays an important role in substrate binding and specificity in the reaction catalyzed by choline oxidase. In the present study, pH and solvent viscosity effects with the isosteric analogue of choline 3,3-dimethyl-butan-1-ol have been used to further dissect the contribution of the substrate positive charge to substrate binding and catalysis in the reaction catalyzed by choline oxidase. Both the kcat and kcat/Km values with 3,3-dimethyl-butan-1-ol increased to limiting values that were approximately 3- and approximately 400-times lower than those observed with choline, defining pKa values that were similar to the thermodynamic pKa value of approximately 7.5 previously determined. No effects of increased solvent viscosity were observed on the kcat and kcat/Km values with the substrate analogue at pH 8, suggesting that the chemical step of substrate oxidation is fully rate-limiting for the overall turnover and the reductive half-reaction in which the alcohol substrate is oxidized to the aldehyde. The kcat/Km value for oxygen determined with the substrate analogue was pH-independent in the pH range from 6 to 10, with an average value that was approximately 75-times lower than that previously determined with choline as substrate. These data are consistent with the positive charge headgroup of choline playing important roles for substrate binding and flavin oxidation, with minimal contribution to substrate oxidation.     

The organic cofactor in plasma amine oxidase: evidence for pyrroloquinoline quinone and against pyridoxal phosphate.

Plasma amine oxidases (EC 1.4.3.6) are classified as containing the organic cofactor pyridoxal phosphate. Biochemical and bioassays on the pig plasma amine oxidase fail to reveal the presence of pyridoxal phosphate and 31P n.m.r. evidence is also inconsistent with pyridoxal phosphate in the enzyme. Resonance Raman spectral studies on phenylhydrazone derivatives of the pig and bovine plasma enzymes have been carried out and comparisons made with the corresponding derivatives of pyridoxal phosphate and pyrroloquinoline quinone (PQQ). The resonance Raman evidence indicates that the cofactor in both plasma amine oxidases is PQQ or a closely related species and not pyridoxal phosphate. The results substantiate earlier reports concerning the identity of the organic cofactor.     

4-vinyl and 2,4-divinyl deuteration effects on the low frequency resonance Raman bands of myoglobin: correlation with the structure of vinyl group

Resonance Raman spectra of myoglobin (Mb) reconstituted with 4-vinyl and 2,4-divinyl deuterated protoheme IX were studied in several oxidation, spin, and ligation states (deoxyMb, MbO2, MbCO, metMbH2O, and metMbCN-) with special attention to the low frequency vibrations. Frequency shifts observed on deuteration enabled us to assign some Raman bands to vibrations specifically involving the 2- or 4-vinyl group. The most significant deuteration effect was found for a band around 410 cm-1 in the ferrous state, which loses intensity on 4-vinyl deuteration and is ascribed to a porphyrin in-plane vibration strongly coupled with the skeletal bend of the vinyl group at position 4. Such strong coupling implies that the vinyl group lies in the same plane as the pyrrole II ring, as in the crystalline state. Thus, frequency shifts on vinyl deuteration may be useful as a probe of the orientation of the vinyl group. Resonance Raman spectra of Mb coordinated with various sizes of isocyanides are interpreted in terms of vinyl orientational changes induced by ligation.     

Binding and activation of thiamin diphosphate in acetohydroxyacid synthase

Acetohydroxyacid synthases (AHASs) are biosynthetic thiamin diphosphate- (ThDP) and FAD-dependent enzymes. They are homologous to pyruvate oxidase and other members of a family of ThDP-dependent enzymes which catalyze reactions in which the first step is decarboxylation of a 2-ketoacid. AHAS catalyzes the condensation of the 2-carbon moiety, derived from the decarboxylation of pyruvate, with a second 2-ketoacid, to form acetolactate or acetohydroxybutyrate. A structural model for AHAS isozyme II (AHAS II) from Escherichia coli has been constructed on the basis of its homology with pyruvate oxidase from Lactobacillus plantarum (LpPOX). We describe here experiments which further test the model, and test whether the binding and activation of ThDP in AHAS involve the same structural elements and mechanism identified for homologous enzymes. Interaction of a conserved glutamate with the N1' of the ThDP aminopyrimidine moiety is involved in activation of the cofactor for proton exchange in several ThDP-dependent enzymes. In accord with this, the analogue N3'-pyridyl thiamin diphosphate does not support AHAS activity. Mutagenesis of Glu47, the putative conserved glutamate, decreases the rate of proton exchange at C-2 of bound ThDP by nearly 2 orders of magnitude and decreases the turnover rate for the mutants by about 10-fold. Mutant E47A also has altered substrate specificity, pH dependence, and other changes in properties. Mutagenesis of Asp428, presumed on the basis of the model to be the crucial carboxylate ligand to Mg(2+) in the "ThDP motif", leads to a decrease in the affinity of AHAS II for Mg(2+). While mutant D428N shows ThDP affinity close to that of the wild-type on saturation with Mg(2+), D428E has a decreased affinity for ThDP. These mutations also lead to dependence of the enzyme on K(+). These experiments demonstrate that AHAS binds and activates ThDP in the same way as do pyruvate decarboxylase, transketolase, and other ThDP-dependent enzymes. The biosynthetic activity of AHAS also involves many other factors beyond the binding and deprotonation of ThDP; changes in the ligands to ThDP can have interesting and unexpected effects on the reaction.     

Resonance Raman study of the pink membrane photochemically prepared from the deionized blue membrane of H. halobium.

We report here the Resonance Raman spectrum of a 'pink' membrane (lambda max approximately 495 nm) photochemically generated from the deionized 'blue' membrane (Chang et al., 1985). Comparison of the Raman spectrum of the pink membrane with that of the model compounds, as well as the chromophore extraction data, indicate that the chromophore in the pink membrane is in the 9-cis configuration. The Schiff base peak at approximately 1,652 cm-1 shifts to approximately 1,622 cm-1 upon deuteration of the pink membrane, showing that the chromophore is bound to the bacterio-opsin by a protonated Schiff base linkage. The location of the Schiff base peak, as well as the 30 cm-1 shift that it undergoes upon deuteration, are quite different from the corresponding values for the native bacteriorhodopsin, suggesting differences in the local environment for the Schiff base in these pigments.