Effect of pH on the transient reduction of pig-plasma benzylamine oxidase by benzylamine derivatives.

1. The transient kinetics of reduction of the 470-nm absorption band in benzylamine oxidase by substrate at different pH values between 6 and 10 have been studied by stopped-flow techniques, and substituent effects on kinetic parameters for the reduction process have been examined using a series of ring-substituted benzylamine derivatives as the substrates. 2. Reduction of the enzyme by substrate takes place in two kinetically distinguishable steps, with the intermediate formation of an enzyme-substrate complex in which the substrate appears to be covalently bound through its amino group to the prosthetic group of the enzyme, possibly in the form of an amine-pyridoxal Schiff-base. 3. The apparent stability of the enzyme-substrate complex shows no obvious dependence on the electronic properties of the amine substrates, but is strongly pH-dependent in a way suggesting that substrate-binding involves the non-protonated amines, exclusively, and requires the presence of the acid form of an ionizing group in the enzyme with apparent pKa of 8.8. 4. Reduction of the enzymatic 470-nm chromophore and release of the aldehyde product of the catalytic process are rate-limited by the same monomolecular reaction step involving the enzyme-substrate complex. Rate constants for the rate-limiting reaction exhibit no significant dependence on pH between 6 and 10, but correlate with Hammett sigma-values for the ring-substituted benzylamine derivatives tested, yielding a phi-value of + 0.3.     

Kinetic isotope effects on the catalytic activity of pig-plasma benzylamine oxidase.

1. Isotope effects on the catalytic activity of benzylamine oxidase at pH 7 and 9 have been studied by steady-state and transient-state kinetics methods, using [alpha,alpha-2H]benzylamine as the substrate. 2. Replacement of the alpha-hydrogen atoms in benzylamine by deuterium has no significant effect on substrate-binding to benzylamine oxidase, neither does it affect the rate of reoxidation of the reduced form of the enzyme. Conversion of the primarily formed enzyme-substrate complex into the reduced enzyme species, however, exhibits an isotope effect of about 3. 3. The data obtained are consistent with a mechanism in which reduction of benzylamine oxidase takes place by a rapid pre-equilibration between enzyme and substrate to form an amine-pyridoxal Schiff-base, which is then tautomerized by a comparatively slow prototropic shift to an amino aldehyde-pyridoxamine Schiff-base from which there is a rapid hydrolytic release of the aldehyde product corresponding to the amine substrate. Proton abstraction from the alpha-carbon of the amine moiety in the primary Schiff-base appears to be at least partially rate-limiting for the tautomerization step, and hence for the entire process of enzyme reduction.     

Stopped-flow spectrophotometric characterization of enzymic reaction intermediates in the anaerobic reduction of pig-plasma benzylamine oxidase by amine substrates.

Reduction of benzylamine oxidase by p-methoxybenzylamine under anaerobic conditions leads to biphasic absorbance changes at 470 nm. These reflect the intermediate formation of an enzyme substrate complex with spectral properties different from those of native enzyme and fully reduced enzyme. The spectrally modified enzyme-substrate complex exhibits a broad difference absorption band centered around 360 nm. The transient accumulation of this intermediate during reaction can be conveniently followed by stopped-flow techniques at wavelengths between 320 and 360 nm, where contributions from the subsequent reduction of the enzymic 470-nm chromophore are of minor significance. 2. Analogous intermediates exhibiting similar absorption spectra seem to be formed on reduction of the enzyme by benzylamine and other amine substrates which were tested. Substitution of benzylamine as the reducing substrate by [alpha, alpha-2H]benzylamine results in a decreased accumulation of the spectrally modified intermediate. This indicates that its formation is preceded by deprotonation of the alpha-carbon of the amine substrate. 3. Circular dichroism spectra of benzylamine oxidase exhibit a positive band at 360 nm, lending support to the previous conclusion that benzylamine oxidase is a pyridoxal enzyme. Formation of the spectrally modified enzyme-substrate complex then most likely reflects the prototropic shift converting an amine-pyridoxal Schiff-base obtained by rapid pre-equilibration between enzyme and substrate into an aldehyde-pyridoxamine Schiff-base.     

Lysyloxidase and benzylamine oxidase in pig aorta

Three enzymes were isolated from pig aorta: a benzylamine oxidase differing from the plasma type, and two different types of lysyloxidase. Some properties of the two types of lysyloxidase are described. The three enzymes were inhibited by cupric copper chelating agents and by carbonyl reagents. They did not cross-react with the antibodies to pure pig plasma benzylamine oxidase.     

Evidence for alternative binding modes in the interaction of benzylamine analogues with bovine liver monoamine oxidase B

The interaction of purified bovine liver MAO B with the benzylamine analogues N,N-dimethylbenzylamine and alpha-methylbenzylamine has been investigated. Both classes of analogues are competitive inhibitors of benzylamine oxidase activity. The K(i) values were determined for nine different para-substituted N, N-dimethylbenzylamine analogues. Analysis of the binding affinities demonstrate the deprotonated forms of the tertiary amines are preferentially bound to MAO B and the affinity decreases with increasing van der Waals volume of the para-substituent. The correlation for this relation is:Log K(i)=-0.97+/-(0.28)sigma+(0. 75+/-0.11)(0.1xV(w))-4.24+/-(0.16)alpha-Methyl benzylamine analogues are also found to be competitive inhibitors of MAO B-catalyzed benzylamine oxidation. Similar K(i) values were determined using either the S or R stereoisomers. Analysis of the binding affinities of five para-substituted alpha-methylbenzylamine analogues to MAO B shows the deprotonated form also to be preferentially bound and the affinity is marginally increased with increasing van der Waals volume of the para-substituent:Log K(i)=-0.71sigma-(0.32)(0. 1xV(w))-3.50Comparison of these data with that previously published for para-substituted benzylamine binding to MAO B (Walker and Edmondson, Biochemistry 33 (1994) 7088-7098) demonstrates that these benzylamine analogues exhibit differing modes of binding to the active site of MAO B. The presence of an electronic substituent effect in the binding of these two classes of analogues compared with the lack of an observable electronic effect in the binding of benzylamine to MAO B is consistent with the proposal that orientation of the benzyl ring of the bound substrate is responsible for the absence of an electronic substituent effect on the rate of the reductive half reaction (Miller and Edmondson, Biochemistry 38 (1999) 13670-13683).     

On the interaction between xanthine oxidase and actin

Xanthine oxidase increases the rate of actin polymerization. This occurs at oxidase concentrations as low as 40 nM provided the concentration of the polymerizing agent is low (0.5 mM MgCl2). In the presence of 0.1 M KCl plus 1 mM MgCl2 as the polymerizing agents, xanthine oxidase does not affect the rate of the polymerization but increases significantly the rate of the conversion of F(ATP)actin into F(ADP.Pi)actin and probably also the rate of the orthophosphate release.     

Unprecedented lysyloxidase activity of Pichia pastoris benzylamine oxidase

Benzylamine oxidase (EC 1.4.3.6) from the yeast Pichia pastoris is a 106 kDa quinoprotein containing one copper atom per molecule. It has a broad substrate specificity ranging from butylamine to peptidyl lysine in collagen and elastin. The kinetic data obtained using lysine-containing model peptides as substrates indicate an astonishing similarity to mammalian lysyloxidase. This similarity is further supported by the inhibition of both enzymes with beta-aminopropionitrile.     

The kinetics of reoxidation of reduced benzylamine oxidase.

1. The mechanism of reoxidation of reduced benzylamine oxidase has been investigated at different pH between 6 and 10 by steady-state and transient-state kinetic methods. 2. The reoxidation process involves minimally a second-order interaction between reduced enzyme and oxygen leading to the formation of a spectrally modified enzyme intermediate, and a subsequent first-order step converting this intermediate into free enzyme. The variation with pH of rate constants according to such a reaction scheme is reported. 3. Under aerobic conditions the oxygen-independent reaction represents the main rate-limiting step in the catalytic process at alkaline pH. At neutral or acid pH the interaction between reduced enzyme and oxygen becomes mainly rate-limiting, indicating that the concentration of oxygen may be a critical factor controlling enzyme activity under physiological conditions. 4. The spectrally modified intermediate formed during the reoxidation process exhibits a difference-absorption band centered around 290 nm in comparison to free enzyme, and an additional difference-absorption band at 470 nm in comparison to reduced enzyme. These data indicate that formation of the intermediate, besides leading to a reappearance of the 470-nm absorption band disappearing on reduction of the enzyme, results in a spectral perturbation of one or several aromatic amino-acid residues in the protein. This perturbation could possibly reflect a conformational change of the enzymes.     

Kinetics of primary interaction of D-amino acid oxidase with its substrate

The formation of an initial enzyme-substrate complex of D-amino acid oxidase (D-amino acid: O2 oxidoreductase (deaminating), EC 1.4.3.3) and its substrate, D-alpha-aminobutyric acid, was studied kinetically at lower temperature and pH than their optima. The time course of the absorbance change at 516 nm in an anaerobic reaction was not exponential, but biphasic. The ratio of the rapidly reacting component to the slowly reacting one was decreased upon lowering of the temperature. The reaction rate of the rapidly reacting component depended on substrate concentration and gave a linear Arrhenius plot in the temperature range from -10 to +15 degrees C. The reaction rate of the slowly reacting component also depended on both substrate concentration and temperature. The rapidly reacting and slowly reacting components could be assigned to the substrate binding of the dimer and monomer, respectively, of this enzyme.     

Oxidation of benzylamine Br-derivatives by lentil seedling copper-amine oxidase

ABSTRACT

Copper amine oxidase was shown to be able to catalyse the oxidative deamination of 2-, 3- and 4-Br-derivatives of benzylamine to the corresponding aldehydes, that all absorb at 250 nm. This change in the absorption spectrum made it possible to follow the enzyme reaction. 2-Br-benzylamine, 3-Br-benzylamine, and 4-Br-benzylamine showed K_m values similar to benzylamine, but 3-Br-benzylamine showed a slower k_c, which allows it to be a catalytically more efficient substrate. Under anaerobic conditions the native enzyme oxidised 1 equivalent of all Br-derivatives and released 1 equivalent of aldehyde per enzyme subunit. These findings demonstrate that, in anaerobic conditions, the enzyme can oxidise substrates with a single incomplete turnover. The possible involvement of the cofactor 6-hydroxydopa quinone and of a negatively charged residue in the oxidation of Br-benzylamines is discussed.     

Kinetics of the interaction between aspartic aminotransferase and anions.

The kinetics of the interaction between deionized supernatant aspartic aminotransferase and various anions (cacodylate, phosphate and chloride) were studied by the temperature-jump technique. The anion concentration in the range covered by our experiments does not affect the transamination rate. On the other hand the conformational transition, recently observed at the active site of the enzyme, is hindered by an excess of anions. A single relaxation effect was observed at the enzyme chromophore wavelength in systems containing the aldimine form of the enzyme and the above anions. It is shown that this effect corresponds to the protonation of the chromophore. The relaxation times were of about 10 mus with phosphate, 20-100 mus with cacodylate and 1-2 ms with chloride. The pH and concentration dependence of this effect were studied. The fits of experimental data to a rate equations for various models were tested by a chi2 analysis. The best fit was obtained with models where anions bind rapidly to a site close to the chromophore, so that the pK of the chromophore is affected by anions binding. The rate of the observed relaxation considerably increased when the anion has buffering capacities; this indicates, in the case of cacodylate and phosphate, that the acidic component of the buffer directly exchanges a proton with the enzyme chromophore.     

A catalytic mechanism for the enzyme benzylamine oxidase from pig plasma

Initial-velocity and product-inhibition studies on the enzyme benzylamine oxidase from pig plasma indicate that the order of substrate addition and product release is benzylamine on, ammonia off, oxygen on, hydrogen peroxide off, benzaldehyde off. Ammonia, but not benzaldehyde, is released under strictly anaerobic conditions which provides independent evidence for this order. Benzyl alcohol is a substrate for the enzyme. A chemical mechanism consistent with all the data is proposed.