Conserved tyrosine-369 in the active site of Escherichia coli copper amine oxidase is not essential.

Copper amine oxidases are homodimeric enzymes that catalyze two reactions: first, a self-processing reaction to generate the 2,4,5-trihydroxyphenylalanine (TPQ) cofactor from an active site tyrosine by a single turnover mechanism; second, the oxidative deamination of primary amine substrates with the production of aldehyde, hydrogen peroxide, and ammonia catalyzed by the mature enzyme. The importance of active site residues in both of these processes has been investigated by structural studies and site-directed mutagenesis in enzymes from various organisms. One conserved residue is a tyrosine, Tyr369 in the Escherichia coli enzyme, whose hydroxyl is hydrogen bonded to the O4 of TPQ. To explore the importance of this site, we have studied a mutant enzyme in which Tyr369 has been mutated to a phenylalanine. We have determined the X-ray crystal structure of this variant enzyme to 2.1 A resolution, which reveals that TPQ adopts a predominant nonproductive conformation in the resting enzyme. Reaction of the enzyme with the irreversible inhibitor 2-hydrazinopyridine (2-HP) reveals differences in the reactivity of Y369F compared with wild type with more efficient formation of an adduct (lambda(max) = 525 nm) perhaps reflecting increased mobility of the TPQ adduct within the active site of Y369F. Titration with 2-HP also reveals that both wild type and Y369F contain one TPQ per monomer, indicating that Tyr369 is not essential for TPQ formation, although we have not measured the rate of TPQ biogenesis. The UV-vis spectrum of the Y369F protein shows a broader peak and red-shifted lambda(max) at 496 nm compared with wild type (480 nm), consistent with an altered electronic structure of TPQ. Steady-state kinetic measurements reveal that Y369F has decreased catalytic activity particularly below pH 6.5 while the K(M) for substrate beta-phenethylamine increases significantly, apparently due to an elevated pK(a) (5.75-6.5) for the catalytic base, Asp383, that should be deprotonated for efficient binding of protonated substrate. At pH 7.0, the K(M) for wild type and Y369F are similar at 1.2 and 1.5 microM, respectively, while k(cat) is decreased from 15 s(-1) in wild type to 0.38 s(-1), resulting in a 50-fold decrease in k(cat)/K(M) for Y369F. Transient kinetics experiments indicate that while the initial stages of enzyme reduction are slower in the variant, these do not represent the rate-limiting step. Previous structural and solution studies have implicated Tyr369 as a component of a proton shuttle from TPQ to dioxygen. The moderate changes in kinetic parameters observed for the Y369F variant indicate that if this is the case, then the absence of the Tyr369 hydroxyl can be compensated for efficiently within the active site.     

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.     

Role of a strictly conserved active site tyrosine in cofactor genesis in the copper amine oxidase from Hansenula polymorpha

The copper amine oxidases catalyze the O(2)-dependent, two-electron oxidation of amines to aldehydes at an active site that contains Cu(II) and topaquinone (TPQ) cofactor. TPQ arises from the autocatalytic, post-translational oxidation of a tyrosine side chain within the same active site. The contributions of individual active site amino acids to each of these chemical processes are being delineated. Previously, using the amine oxidase from the yeast Hansenula polymorpha (HPAO), mutations of a strictly conserved and structurally pivotal active site tyrosine (Y305) were studied and their effects on the catalytic cycle demonstrated [Hevel, J. M., Mills, S. A., and Klinman, J. P. (1999) Biochemistry 38, 3683-3693]. This study examines mutations at the same position for their effects on cofactor generation. While the Y305A mutation had moderate effects on the kinetics of catalysis (2.5- and 8-fold effects on k(cat) using ethylamine and benzylamine as substrates), the same mutation slows cofactor formation by approximately 45-fold relative to that of the wild-type (WT). Additionally, the Y305A mutant forms at least two species: primarily TPQ at lower pH and a species with a blue-shifted absorbance at high pH (lambda(max) = 400 nm). The 400 nm species does not react with phenylhydrazine or ethylamine and is stable toward pH buffer exchange, long-term storage (>3 weeks), incubation at high temperatures, or incubation with reductants and colorimetric peroxide quenching reagents. A similar species accumulates appreciably even at approximately neutral pH in the Y305F mutant, despite the fact that the rate of TPQ formation is reduced only 3-fold relative to that of WT HPAO. This small impact of Y305F on the rate of biogenesis contracts with a decrease in k(cat) (using ethylamine as the substrate) of 125-fold. The opposing effects of mutations at position 305 in biogenesis versus catalysis indicate that a single residue can be recruited for different roles during these processes.     

Characterization of an Escherichia coli sulfite oxidase homologue reveals the role of a conserved active site cysteine in assembly and function

We report the biochemical and biophysical characterization of YedYZ, a sulfite oxidase homologue from Escherichia coli. YedY is a soluble catalytic subunit with a twin arginine leader sequence for export to the periplasm by the Tat translocation system. YedY is the only molybdoenzyme so far isolated from E. coli with the Mo-MPT form of the molybdenum cofactor. The electron paramagnetic resonance (EPR) signal of the YedY molybdenum is similar to that of known Mo-MPT containing enzymes, with the exception that only the Mo(IV) --> Mo(V) transition is observed, with a midpoint potential of 132 mV. YedZ is a membrane-intrinsic cytochrome b with six putative transmembrane helices. The single heme b of YedZ has a midpoint potential of -8 mV, determined by EPR spectroscopy of YedZ-enriched membrane preparations. YedY does not associate strongly with YedZ on the cytoplasmic membrane. However, mutation of the YedY active site Cys102 to Ser results in very efficient targeting of YedY to YedZ in the membrane, demonstrating a clear role for YedZ as the membrane anchor for YedY. Together, YedYZ comprise a well-conserved bacterial heme-molybdoenzyme found in a variety of bacteria that can be assigned to the sulfite oxidase class of enzyme.     

An unexpected role for the active site base in cofactor orientation and flexibility in the copper amine oxidase from Hansenula polymorpha.

The role of the active site aspartate base in the aminotransferase mechanism of the copper amine oxidase from the yeast Hansenula polymorpha has been probed by site-directed mutagenesis. The D319E mutant catalyzes the oxidation of methylamine and phenethylamine, but not that of benzylamine. kcat/Km for methylamine is found to be 80-fold reduced compared to that of the wild type. Viscosogen and substrate and solvent deuteration have no effect on this parameter for D319E, which is suggestive of limitation of kcat/Km by a conformational change. This conformational change is proposed to be the movement of the cofactor into a productive orientation upon the binding of substrate. In the absence of substrate, a flipped cofactor orientation is likely, on the basis of resonance Raman evidence that the C5 carbonyl of the cofactor is less solvent accessible than the C3 hydrogen. kcat for D319E methylamine oxidase is reduced 200-fold compared to that of the wild type and is unaffected by substrate deuteration, but displays a substantial solvent isotope effect. A 428 nm absorbance is evident under conditions of saturating methylamine and oxygen with D319E. The D319N mutant is observed to produce a similar absorbance at 430 nm when treated with ammonia despite the fact that this mutant has no amine oxidase activity. Resonance Raman spectroscopy indicates the formation of a covalent ammonia adduct and identifies it as the deprotonated iminoquinone. In contrast, when the D319E mutant is reacted with ammonia, it gives predominantly a 340-350 nm species. This absorbance is ascribed to a localization of the cofactor oxyanion induced by binding of the cation at the active site and not to covalent adduct formation. Resonance Raman spectroscopic examination of the steady state species of D319E methylamine oxidation, in combination with the kinetic data, indicates that the 428 nm species is the deprotonated iminoquinone produced upon reoxidation of the reduced cofactor. A model is proposed in which a central role of the active site base is to position the free cofactor and several enzyme intermediates for optimal activity.     

The role of specific amino acid residues in the active site of Escherichia coli DNA polymerase I on translesion DNA synthesis across from and past an N-2-aminofluorene adduct

Understanding how carcinogenic DNA adducts compromise accurate DNA replication is an important goal in cancer research. A central part of these studies is to determine the molecular mechanism that allows a DNA polymerase to incorporate a nucleotide across from and past a bulky adduct in a DNA template. To address the importance of polymerase architecture on replication across from this type of bulky DNA adduct, three active-site mutants of Escherichia coli DNA polymerase I (Klenow fragment) were used to study DNA synthesis on DNA modified with the carcinogen N-2-aminofluorene (AF). Running-start synthesis studies showed that full-length synthesis past the AF adduct was inhibited for all of the mutants, but that this inhibition was substantially less for the F762A mutant. Single nucleotide extension and steady-state kinetic experiments showed that the Y766S mutant displayed higher rates of insertion of each incorrect nucleotide relative to WT across from the dG-AF adduct. This effect was not observed for F762A or E710A mutants. Similar experiments that measured synthesis one nucleotide past the dG-AF adduct revealed an enhanced preference by the F762A mutant for dG opposite the T at this position. Finally, synthesis at the +1 and +2 positions was inhibited to a greater extent for the Y766S and E710A mutants compared with both the WT and F762A mutants. Taken together, this work is consistent with the model that polymerase geometry plays a crucial role in both the insertion and extension steps during replication across from bulky DNA lesions.     

Probing the roles of key residues in the unique regulatory NADH binding site of type II citrate synthase of Escherichia coli

The citrate synthase of Escherichia coli is an example of a Type II citrate synthase, a hexamer that is subject to allosteric inhibition by NADH. In previous crystallographic work, we defined the NADH binding sites, identifying nine amino acids whose side chains were proposed to make hydrogen bonds with the NADH molecule. Here, we describe the functional properties of nine sequence variants, in which these have been replaced by nonbonding residues. All of the variants show some changes in NADH binding and inhibition and small but significant changes in kinetic parameters for catalysis. In three cases, Y145A, R163L, and K167A, NADH inhibition has become extremely weak. We have used nanospray/time-of-flight mass spectrometry, under non-denaturing conditions, to show that two of these, R163L and K167A, do not form hexamers in response to NADH binding, unlike the wild type enzyme. One variant, R109L, shows tighter NADH binding. We have crystallized this variant and determined its structure, with and without bound NADH. Unexpectedly, the greatest structural changes in the R109L variant are in two regions outside the NADH binding site, both of which, in wild type citrate synthase, have unusually high mobilities as measured by crystallographic thermal factors. In the R109L variant, both regions (residues 260 -311 and 316-342) are much less mobile and have rearranged significantly. We argue that these two regions are elements in the path of communication between the NADH binding sites and the active sites and are centrally involved in the regulatory conformational change in E. coli citrate synthase.     

The 650 and chromophore in Escherichia coli is an 'oxy-' or oxygenated compound, not the oxidized form of cytochrome oxidase d: an hypothesis

The form of cytochrome d in Escherichia coli and Azotobacter vinelandii that shows an absorption maximum at 648 to 652 nm ('cytochrome d650') is generally regarded as the oxidized form of this terminal oxidase. Membranes from E. coli grown under oxygen-limited conditions, when treated with ferricyanide, do not reveal cytochrome d650, whereas a sharp symmetrical band at 652 nm results from the reaction of the reduced enzyme with O2 at either room temperature or after flash photolysis of the CO-liganded form at -130 degrees C. Electron paramagnetic resonance spectroscopy of cytochrome d650 trapped at -130 degrees C shows that its spectrum is indistinguishable from the CO-liganded form and does not reveal resonances of high spin ferric haem previously attributed to cytochrome d. An hypothesis is proposed in which cytochrome d650 is an early intermediate in the reaction of reduced cytochrome d650 and oxyhaemoglobin is presented and the hypothesis discussed in relation to earlier work, in which the indirect interconversions of reduced cytochrome d and d650 have been explained by proposing the existence of an 'invisible' form. It is suggested that this form could be the oxidized enzyme.     

Cu(II)-mediated phenol oxygenation: Chemical evidence implicates a unique role of the enzyme active site in promoting the chemically difficult tyrosine monooxygenation in TPQ cofactor biogenesis of copper amine oxidases

Cu(II)-mediated autoxidations of 4-tert-butylphenol under various conditions was studied, the data confirmed imidazole is the best ligand to promote phenol oxygenation. The same reaction of 2,4-di-tert-butylphenol proceeded much more quickly to lead nearly exclusively to oxidative coupling rather than oxygenation under high pressure O₂. These results suggested that Cu(II)-catalyzed phenol autoxidation by activating O₂ and phenol in terms of a phenoxy radical (ArO)–Cu(II)–superoxide ternary complex, whereas selectivity between oxygenation and coupling depends mainly on the electronic structure of ArO. It is appeared that CuAOs could achieve stoichiometric tyrosine monooxygenation by modulating the redox potential of Cu(II) and stabilizing the ternary complex through protein conformational adjustment.     

The N-terminal metal-binding site 2 of the Wilson's Disease Protein plays a key role in the transfer of copper from Atox1

The Wilson's disease protein (WNDP) is a copper-transporting ATPase regulating distribution of copper in the liver. Mutations in WNDP lead to a severe metabolic disorder, Wilson's disease. The function of WNDP depends on Atox1, a cytosolic metallochaperone that delivers copper to WNDP. We demonstrate that the metal-binding site 2 (MBS2) in the N-terminal domain of WNDP (N-WNDP) plays an important role in this process. The transfer of one copper from Atox1 to N-WNDP results in selective protection of the metal-coordinating cysteines in MBS2 against labeling with a cysteine-directed probe. Such selectivity is not observed when free copper is added to N-WNDP. Similarly, site-directed mutagenesis of MBS2 eliminates stimulation of the catalytic activity of WNDP by the copper-Atox1 complex but not by free copper. The Atox1 preference toward MBS2 is likely due to specific protein-protein interactions and is not due to unique surface exposure of the metal-coordinating residues or higher copper binding affinity of MBS2 compared with other sites. Competition experiments using a copper chelator revealed that MBS2 retained copper much better than Atox1, and this may facilitate the metal transfer process. X-ray absorption spectroscopy of the isolated recombinant MBS2 demonstrated that this sub-domain coordinates copper with a linear biscysteinate geometry, very similar to that of Atox1. Therefore, non-coordinating residues in the vicinity of the metal-binding sites are responsible for the difference in the copper binding properties of MBS2 and Atox1. The intramolecular changes that accompany transfer of a single copper to N-WNDP are discussed.     

Identification of arginine 331 as an important active site residue in the class II fructose-1,6-bisphosphate aldolase of Escherichia coli.

Treatment of the Class II fructose-1,6-bisphosphate aldolase of Escherichia coli with the arginine-specific alpha-dicarbonyl reagents, butanedione or phenylglyoxal, results in inactivation of the enzyme. The enzyme is protected from inactivation by the substrate, fructose 1,6-bisphosphate, or by inorganic phosphate. Modification with [7-14C] phenylglyoxal in the absence of substrate demonstrates that enzyme activity is abolished by the incorporation of approximately 2 moles of reagent per mole of enzyme. Sequence alignment of the eight known Class II FBP-aldolases shows that only one arginine residue is conserved in all the known sequences. This residue, Arg-331, was mutated to either alanine or glutamic acid. The mutant enzymes were much less susceptible to inactivation by phenylglyoxal. Measurement of the steady-state kinetic parameters revealed that mutation of Arg-331 dramatically increased the K(m) for fructose 1,6-bisphosphate. Comparatively small differences in the inhibitor constant Ki for dihydroxyacetone phosphate or its analogue, 2-phosphoglycolate, were found between the wild-type and mutant enzymes. In contrast, the mutation caused large changes in the kinetic parameters when glyceraldehyde 3-phosphate was used as an inhibitor. Kinetic analysis of the oxidation of the carbanionic aldolase-substrate intermediate of the reaction by hexacyanoferrate (III) revealed that the K(m) for dihydroxyacetone phosphate was again unaffected, whereas that for fructose 1,6-bisphosphate was dramatically increased. Taken together, these results show that Arg-331 is critically involved in the binding of fructose bisphosphate by the enzyme and demonstrate that it interacts with the C-6 phosphate group of the substrate.     

The structural gene for the ribosomal protein S18 in Escherichia coli. II. Chemical studies on the protein S18 having an altered electrophoretic mobility

A mutant of Escherichia coli strain CR341 has an altered 30 S ribosomal protein S18. The alteration involves a change in the electrophoretic mobility of S18. S18 proteins were purified from the mutant and the parent strain, respectively, and their amino acid composition and tryptic peptides were compared. The results have shown that the mutational alteration involves substitution of cysteine for arginine. In addition, we determined the electrophoretic mobility of S18 proteins modified by ethyleneimine. The modification, which involves conversion of cysteine residues to S-(2-aminoethyl)cysteine, causes a greater electrophoretic mobility increase in the mutant protein than in the wild type protein, resulting in identical mobilities for the aminoethylated proteins. This experiment gives further support to the conclusion that the original mobility difference between mutant and wild type proteins is due to the mutational substitution of cysteine for arginine. The S18 obtained from a recombinant was also studied. The recombinant protein was found to have the mobility of the wild type protein and the wild type primary structure, as judged by amino acid composition and tryptic peptide analysis. This recombinant was obtained from the mutant by introducing Hfr strain G10 chromosome segments in the region between 70 and 10 minutes, and not in the str-spc region at 64 minutes, as described in the preceding paper. These results, together with those in the preceding paper, show that the mutation studied here is in the structural gene for S18, and that it maps outside the str-spc region.     

The Cu(II)-reductase NADH dehydrogenase-2 of Escherichia coli improves the bacterial growth in extreme copper concentrations and increases the resistance to the damage caused by copper and hydroperoxide

NADH dehydrogenase-2 (NDH-2) from Escherichia coli respiratory chain is a membrane-bound cupric-reductase encoded by ndh gene. Here, we report that the respiratory system of a ndh deficient strain suffered a faster inactivation than that of the parental strain in the presence of tert-butyl hydroperoxide due to endogenous copper. The inactivation was similar for both strains when copper concentration increased in the culture media. Furthermore, several ndh deficient mutants grew less well than the corresponding parental strains in media containing either high or low copper concentrations. A mutant strain complemented with ndh gene almost recovered the parental phenotype for growing in copper limitation or excess. Then, NDH-2 gives the bacteria advantages to diminish the susceptibility of the respiratory chain to damaging effects produced by copper and hydroperoxides and to survive in extreme copper conditions. These results suggest that NDH-2 contributes in the bacterial oxidative protection and in the copper homeostasis.     

The role of enzyme I in the unmasking of an essential thiol of the membrane-bound enzyme II of the phosphoenolpyruvate-glucose phosphotransferase system of Escherichia coli

The membrane-bound component of the phosphotransferase system of Escherichia coli, responsible for the phosphorylative uptake of methyl-α-d-glucoside has an essential thiol group which becomes available to inactivation by thiol reagents in the presents of the phosphate-accepting sugar or when phosphoenolpyruvate synthesis is inhibited. The form resistant to the thiol reagent requires not only the absence of sugar and an intact phosphoenol-pyruvate generating system, but also an intact system generating phosphorylated Hpr which is impaired by heating of a thermosensitive enzyme I mutant.     

Evidence for an essential arginine residue in the active site of Escherichia coli 2-keto-4-hydroxyglutarate aldolase. Modification with 1,2-cyclohexanedione

Treatment of homogeneous preparations of Escherichia coli 2-keto-4-hydroxyglutarate aldolase with 1,2-cyclohexanedione, 2,3-butanedione, phenylglyoxal, or 2,4-pentanedione results in a time- and concentration-dependent loss of enzymatic activity; the kinetics of inactivation are pseudo-first order. Cyclohexanedione is the most effective modifier; a plot of log (1000/t 1/2) versus log [cyclohexanedione] gives a straight line with slope = 1.1, indicating that one molecule of modifier reacts with each active unit of enzyme. The kinetics of inactivation are first order with respect to cyclohexanedione, suggesting that the loss of activity is due to modification of 1 arginine residue/subunit. Controls establish that this inactivation is not due to modifier-induced dissociation or photoinduced structural alteration of the aldolase. The same Km but decreased Vmax values are obtained when partially inactivated enzyme is compared with native. Amino acid analyses of 95% inactivated aldolase show the loss of 1 arginine/subunit with no significant change in other amino acid residues. Considerable protection against inactivation is provided by the substrates 2-keto-4-hydroxyglutarate and pyruvate (75 and 50%, respectively) and to a lesser extent (40 and 35%, respectively) by analogs like 2-keto-4-hydroxybutyrate and 2-keto-3-deoxyarabonate. In contrast, formaldehyde or glycolaldehyde (analogs of glyoxylate) under similar conditions show no protective effect. These results indicate that an arginine residue is required for E. coli 2-keto-4-hydroxyglutarate aldolase activity; it most likely participates in the active site of the enzyme by interacting with the carboxylate anion of the pyruvate-forming moiety of 2-keto-4-hydroxyglutarate.