Cholesterol oxidase from Brevibacterium sterolicum. The relationship between covalent flavinylation and redox properties.

Brevibacterium sterolicum possesses two forms of cholesterol oxidase, one containing noncovalently bound FAD, the second containing a FAD covalently linked to His(69) of the protein backbone. The functional role of the histidyl-FAD bond in the latter cholesterol oxidase was addressed by studying the properties of the H69A mutant in which the FAD is bound tightly, but not covalently, and by comparison with native enzyme. The mutant retains catalytic activity, but with a turnover rate decreased 35-fold; the isomerization step of the intermediate 3-ketosteroid to the final product is also preserved. Stabilization of the flavin semiquinone and binding of sulfite are markedly decreased, this correlates with a lower midpoint redox potential (-204 mV compared with -101 mV for wild-type). Reconstitution with 8-chloro-FAD led to a holoenzyme form of H69A cholesterol oxidase with a midpoint redox potential of -160 mV. In this enzyme form, flavin semiquinone is newly stabilized, and a 3.5-fold activity increase is observed, this mimicking the thermodynamic effects induced by the covalent flavin linkage. It is concluded that the flavin 8alpha-linkage to a (N1)histidine is a pivotal factor in the modulation of the redox properties of this cholesterol oxidase to increase its oxidative power.

Role of arginine 285 in the active site of Rhodotorula gracilis D-amino acid oxidase. A site-directed mutagenesis study.

Arg(285), one of the very few conserved residues in the active site of d-amino acid oxidases, has been mutated to lysine, glutamine, aspartate, and alanine in the enzyme from the yeast Rhodotorula gracilis (RgDAAO). The mutated proteins are all catalytically competent. Mutations of Arg(285) result in an increase ( approximately 300-fold) of K(m) for the d-amino acid and in a large decrease ( approximately 500-fold) of turnover number. Stopped-flow analysis shows that the decrease in turnover is paralleled by a similar decrease in the rate of flavin reduction (k(2)), the latter still being the rate-limiting step of the reaction. In agreement with data from the protein crystal structure, loss of the guanidinium group of Arg(285) in the mutated DAAOs drastically reduces the binding of several carboxylic acids (e.g. benzoate). These results highlight the importance of this active site residue in the precise substrate orientation, a main factor in this redox reaction. Furthermore, Arg(285) DAAO mutants have spectral properties similar to those of the wild-type enzyme, but show a low degree of stabilization of the flavin semiquinone and a change in the redox properties of the free enzyme. From this, we can unexpectedly conclude that Arg(285) in the free enzyme form is involved in the stabilization of the negative charge on the N(1)-C(2)=O locus of the isoalloxazine ring of the flavin. We also suggest that the residue undergoes a conformational change in order to bind the carboxylate portion of the substrate/ligand in the complexed enzyme.