D-amino acid oxidase is the prototype of the FAD-dependent oxidases. It catalyses the oxidation of Damino acids to the corresponding a-ketoacids. The reducing equivalents are transferred to molecular oxygen with production of hydrogen peroxide. We have solved the crystal structure of the complex of D-amino acid oxidase with benzoate, a competitive inhibitor of the substrate, by single isomorphous replacement and eightfold averaging. Each monomer is formed by two domains with an overall topology similar to that ofp-hydroxybenzoate hydroxylase. The benzoate molecule lays parallel to the flavin ring and is held in position by a salt bridge with Arg-283. Analysis of the active site shows that no side chains are properly positioned to act as the postulated base required for the catalytic carboanion mechanism. On the contrary, the benzoate binding mode suggests a direct transfer of the substrate a-hydrogen to the flavin during the enzyme reductive half-reaction. The active site of D-amino acid oxidase exhibits a striking similarity with that of flavocytochrome b2, a structurally unrelated FMN-dependent flavoenzyme. The active site groups of these two enzymes are in fact superimposable once the mirror-image of the flavocytochrome b2 active site is generated with respect to the flavin plane. Therefore, the catalytic sites of D-amino acid oxidase and flavocytochrome b2 appear to have converged to a highly similar but enantiomeric architecture in order to catalyze similar reactions (oxidation of a-amino acids or a-hydroxy acids), although with opposite stereochemistry.Since the description of D-amino acid oxidase (EC 1.4.3.3; DAAO) activity in mammalian tissues by Krebs in 1935 (1), DAAO has been the subject of a number of biochemical, spectroscopic, and kinetic investigations, becoming the prototype for the oxidase class of the flavin-containing enzymes [for a recent review, see ref. 2]. Its primary structure has been determined and its gene has been cloned (3, 4). Its kinetic and mechanistic properties have been studied in detail by a variety of techniques, while information on the topology of the active site and on its three-dimensional structure have only been derived from chemical modification studies and site-directed mutagenesis of selected residues. Based on these approaches, a catalytic mechanism for DAAO has been proposed, although definitive evidence against alternative mechanisms has not been found (refs. 2 and 5 and references therein).The enzyme catalyzes the oxidation of D-a-amino acids into the corresponding a-ketoacids. The reaction formally proceeds according to the following scheme:E-FADH2 + 02-*E-FAD + H202[2]The reductive half reaction (Eq. 1), in which the noncovalently bound FAD becomes reduced, is followed by the oxidative step in which FAD is reoxidized by molecular oxygen, with the release of hydrogen peroxide (Eq. 2). The imino acid product spontaneously hydrolyzes to the ketoacid in a nonenzymatic process (Eq. 3). DAAO displays a broad substrate specificity, with a preference for D-amin...
The three-dimensional structure of the complex formed by two plasma proteins, transthyretin and retinol-binding protein, was determined from x-ray diffraction data to a nominal resolution of 3.1 angstroms. One tetramer of transthyretin was bound to two molecules of retinol-binding protein. The two retinol-binding protein molecules established molecular interactions with the same transthyretin dimer, and each also made contacts with one of the other two monomers. Thus, the other two potential binding sites in a transthyretin tetramer were blocked. The amino acid residues of the retinol-binding protein that were involved in the contacts were close to the retinol-binding site.
PAO specifically oxidizes substrates that have both primary and secondary amino groups. The complex with MDL72527 shows that the primary amino groups are essential for the proper alignment of the substrate with respect to the flavin. Conservation of an N-terminal sequence motif indicates that PAO is member of a novel family of flavoenzymes. Among these, monoamine oxidase displays significant sequence homology with PAO, suggesting a similar overall folding topology.
The shape of the active-site cavity controls substrate specificity by providing a 'size exclusion mechanism'. Inside the cavity, the substrate aromatic ring is positioned at an angle of 18 degrees to the flavin ring. This arrangement is ideally suited for a hydride transfer reaction, which is further facilitated by substrate deprotonation. Burying the substrate beneath the protein surface is a recurrent strategy, common to many flavoenzymes that effect substrate oxidation or reduction via hydride transfer.
Our results suggest that allosteric control of PK is accomplished through remarkable domain and subunit rotations. On transition from the T- to the R-state all 12 domains of the functional tetramer modify their relative orientations. These concerted motions are the molecular basis of the coupling between the active centre and the allosteric site.
The unusual heme distal site structure observed shows that previously undescribed molecular mechanisms of ligand stabilization are operative in VtHb. The polypeptide chain disorder observed in the CE region indicates a potential site of interaction with the FAD/NADH reductase partner, in analogy with observations in the chimeric flavohemoglobin from Alcaligenes eutrophus.
D-Amino acid oxidase (DAAO) is the prototype of the flavin-containing oxidases. It catalyzes the oxidative deamination of various D-amino acids, ranging from D-Ala to D-Trp. We have carried out the X-ray analysis of reduced DAAO in complex with the reaction product imino tryptophan (iTrp) and of the covalent adduct generated by the photoinduced reaction of the flavin with 3-methyl-2-oxobutyric acid (kVal). These structures were solved by combination of 8-fold density averaging and least-squares refinement techniques. The FAD redox state of DAAO crystals was assessed by single-crystal polarized absorption microspectrophotometry. iTrp binds to the reduced enzyme with the N, C alpha, C, and C beta atoms positioned 3.8 A from the re side of the flavin. The indole side chain points away from the cofactor and is bound in the active site through a rotation of Tyr224. This residue plays a crucial role in that it adapts its conformation to the size of the active site ligand, providing the enzyme with the plasticity required for binding a broad range of substrates. The iTrp binding mode is fully consistent with the proposal, inferred from the analysis of the native DAAO structure, that substrate oxidation occurs via direct hydride transfer from the C alpha to the flavin N5 atom. In this regard, it is remarkable that, even in the presence of the bulky iTrp ligand, the active center is made solvent inaccessible by loop 216-228. This loop is thought to switch between the "closed" conformation observed in the crystal structures and an "open" state required for substrate binding and product release. Loop closure is likely to have a role in catalysis by increasing the hydrophobicity of the active site, thus making the hydride transfer reaction more effective. Binding of kVal leads to keto acid decarboxylation and formation of a covalent bond between the keto acid C alpha and the flavin N5 atoms. Formation of this acyl adduct results in a nonplanar flavin, characterized by a 22 degrees angle between the pyrimidine and benzene rings. Thus, in addition to an adaptable substrate binding site, DAAO has the ability to bind a highly distorted cofactor. This ability is relevant for the enzyme's function as a highly efficient oxidase.
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