Polymorphism of horse liver alcohol dehydrogenase

The properties of the most cathodal component of horse liver alcohol dehydrogenase (isozyme SS) have been found to vary. The variability is dependent on the livers from which the enzyme is isolated rather than on the purification procedure. Two distinct preparations, differing in catalytic properties, have been obtained and named S-type and A-type preparations. The preparations can be distinguished from each other by the ratio of activity with acetaldehyde to activity with the steroidal ketone 5_β-dihydrotestosterone. This ratio is about one for the S-type and twenty for the A-type preparations.     

Triplet-singlet energy transfer in the complex of auramine O with horse liver alcohol dehydrogenase

Triplet-singlet energy transfer has been studied in the complex formed between auramine O (AO) and horse liver alcohol dehydrogenase with optically detected magnetic resonance (ODMR) spectroscopy. The results show that Trp-15 and Tyr residues transfer triplet energy mainly by a trivial process, whereas Trp-314 transfers triplet energy by a F?rster process with two observed lifetimes at 77 K of 170 and 50 ms. The different F?rster energy-transfer lifetimes are ascribed either to quenching of the two Trp-314 residues of the dimer by a single asymmetrically bound AO or to two distinct conformations of the enzyme-dye complex with differing separations and/or orientations of donor and acceptor. Individual spin sublevel transfer rate constants are reported for the major decay component with the 170-ms Trp triplet-state lifetime; these are found to be highly selective with kxtr much greater than kytr and kztr.     

Reactivity of horse liver alcohol dehydrogenase with 3-methylcyclohexanols

The specificity of horse liver alcohol dehydrogenase for cyclohexanol and its 3-methyl derivatives was investigated by stopped-flow and initial velocity kinetic studies. The (1S,3S)-3-methylcyclohexanol was 7 times more reactive (V/Km) than cyclohexanol, whereas the (1R,3R)-3-methylcyclohexanol was at least 1000 times less reactive than its enantiomer. Computer simulation of the transient reaction of NAD+ and the cyclohexanols catalyzed by the enzyme suggests that the rate of transfer of hydrogen from the alcohol to NAD+ is increased with the 1S,3S isomer. Modeling of the three-dimensional structure of the ternary complex of the enzyme suggests that the 1S,3S isomer should only bind in a productive, reactive mode, whereas the 1R,3R isomer would bind predominantly in a nonproductive, inhibitory mode.     

Self-association of lyophilized horse liver alcohol dehydrogenase.

The molecular weights of lyophilized and non-lyophilized horse liver alcohol dehydrogenase have been compared by quasi-elastic light scattering, and ultracentrifugation. Whereas the non-lyophilized enzyme has the expected molecular weight of 78 000, the lyophilized enz)me has an initial molecular weight of about 10(6) which increases with time by an endothermic process. This result shows that any physical measurement using lyophilized liver alcohol dehydrogenase to investigate the enzyme mechanism, which relies upon the molecular size, will be invalid.     

Reactive lysine residues in horse liver alcohol dehydrogenase

Horse liver alcohol dehydrogenase was modified under various conditions with ¹⁴C-labelled formaldehyde in the presence of sodium borohydride. Changes in the enzymatic activity were correlated with incorporated label and modified residues were characterized. It is shown that most of the lysine residues react and that many are affected by the binding of coenzymes and inhibitors to the protein. Reactive residues are reported and possible structural and functional interpretations given.     

Interaction of ethanolamine with alcohol dehydrogenase from the horse liver

The pattern of kinetic behaviour of ethanolamine (EA), an ethanol structural analog, in the alcohol dehydrogenase reaction has been studied. EA has been shown to manifest a mixed type inhibition versus ethanol and a noncompetitive behaviour towards the second substrate, NAD. A graphical analysis of the experimental results as well as the construction of secondary graphs provide evidence in favour of a mechanism, according to which the interaction between EA and the enzyme results in a dead-end complex formation (ESI). A direct conversion into reaction products can be achieved only after EA separation from the complex. The Ki value for the E-EA complex is 1.3 mM; that for EA release from the E-EA is 1.8 mM. An analysis of competitive interactions with NAD showed these constants to be equal in values (2 mM). Taking account of real concentrations of tissue EA and of experimental values of Ki, a conclusion is drawn on possible participation of EA in the alcohol dehydrogenase reaction control.     

Cobalt exchange in horse liver alcohol dehydrogenase.

The preparation of metal hybrid species of horse liver alcohol dehydrogenase is made possible by the development of carefully delineated systems of metal in equilibrium metal exchange employing equilibrium dialysis. The conditions which are optimal for the site-specific replacement of the catalytic and/or noncatalytic zinc atoms of the native enzyme by cobalt are not identical with those which are utilized for substitution with 65Zn. Thus, while certain 65Zn hybrids can be prepared by exploiting the differential effects of buffer anions, the cobalt hybrids are generated by critical adjustments in the pH of the dialysate. Factors which may determine the mechanism of metal replacement reactions include acid-assisted, ligand-assisted, and metal-assisted dechelation, steric restriction, and ligand denticity as well as physicochemical properties of the enzyme itself. The spectral characteristics of the catalytic and noncatalytic cobalt atoms reflect both the geometry of the coordination complexes and the nature of the ligands and serve as sensitive probes of these loci in the enzyme.     

Covalent binding of an NAD+ analogue to horse liver alcohol dehydrogenase in a ternary complex with pyrazole

Examination of the model of the fixation site of the adenosine phosphate part of NAD+ on horse liver alcohol dehydrogenase led us to synthesize a NAD+ analogue N6-[N-(8-amino-3,6-dioxaoctyl)carbamoylmethyl]-NAD+ in order to alkylate the carboxylic acid group of Asp-273 and to convert the normally dissociable coenzyme into a permanently bound prosthetic group. This NAD+ analogue is coupled to the horse liver alcohol dehydrogenase in the ternary complex formed with pyrazole. In these conditions the degree of fixation varies between 0.4 and 0.58 coenzyme molecule/enzyme subunit molecule. The N6-[N-(8-amino-3,6-dioxaoctyl)carbamoylmethyl]NAD+ acts as a true prosthetic group which can be reduced and reoxidized by a coupled substrate reaction and the internal activity of this holoenzyme corresponds to the amount of analogue incorporated.