Purification of Rhodotorula gracilis D-amino acid oxidase.

A protocol is presented for preparing Rhodotorula gracilis D-amino acid oxidase in homogeneous form and in high yield in 3 to 4 days. The method takes advantage of (a) cell rupture by alternate freeze-thawing, (b) use of DEAE-Sepharose to bind contaminants, and (c) enzyme binding to a Mono S column. The D-amino acid oxidase isolated by this means has the same spectral and catalytic properties as the enzyme previously obtained, and possesses improved long-term stability.     

The primary structure of D-amino acid oxidase from Rhodotorula gracilis

Summary The amino acid sequence of D-amino acid oxidase from Rhodotorula gracilis was determined by automated Edman degradation of peptides generated by enzymatic and chemical cleavage. The enzyme monomer contains 368 amino acid residues and its sequence is homologous to that of other known D-amino acid oxidases. Six highly conserved regions appear to have a specific role in binding of coenzyme FAD, in active site topology and in peroxisomal targeting. Moreover, Rhodotorula gracilis D-amino acid oxidase contains a region with a cluster of basic amino acids, probably exposed to solvent, which is absent in other D-amino acid oxidases.     

A study on apoenzyme from Rhodotorula gracilis D-amino acid oxidase.

The apoenzyme of D-amino acid oxidase from Rhodotorula gracilis was obtained at pH 7.5 by dialyzing the holoenzyme against 2 M KBr in 0.25 M potassium phosphate, 0.3 mM EDTA, 5 mM 2-mercaptoethanol and 20% glycerol. To recover a reconstitutable and highly stable apoprotein, it is essential that phosphate ions and glycerol be present at high concentrations. Apo-D-amino acid oxidase is entirely present as a monomeric protein, while the reconstituted holoenzyme is a dimer of 79 kDa. The equilibrium binding of FAD to apoprotein was measured from the quenching of flavin fluorescence and by differential spectroscopy: a Kd of 2.0 x 10(-8) M was calculated. The kinetics of formation of the apoprotein-FAD complex were studied by the quenching of protein and flavin fluorescence, by differential spectroscopy and by activity measurements. In all cases a two-stage process was shown to be present with a fairly rapid first phase, followed by a slow secondary change which represents only 4-6% of the total recombination process. In no conditions was a lag in the recovery of maximum catalytic activity observed. The process of FAD binding to yeast D-amino acid oxidase appears to be of the type Apo + FAD in equilibrium holoenzyme, even though the existence of a transient intermediate not detectable under our conditions cannot be ruled out.     

A process for bioconversion of cephalosporin C by Rhodotorula gracilis D-amino acid oxidase

Summary A process for the production (in a stirred tank reactor) of glutaryl-7-ACA from cephalosporin C using immobilized D-amino acid oxidase is described. Results so obtained under optimal conditions (1.2 mg coupled enzyme/L, pH 8.5, 2 mM cephalosporin C) point to a system which shows high conversion efficiency and a remarkable operational stability. No exogenous H₂O₂ is requested to shift the reaction equilibrium toward glutaryl-7-ACA production, nor any side product is detected. The immobilized system productivity was 54 g/day/mg of enzyme. This process represents the first reported case of a reactor successfully developed with a DAAO for bioconversion of cephalosporin C.     

Investigating the role of active site residues of Rhodotorula gracilis D-amino acid oxidase on its substrate specificity

D-amino acid oxidase (DAAO) is a flavoprotein that catalyzes stereospecifically the oxidative deamination of D-amino acids. The wild-type DAAO is mainly active on neutral D-amino acids, while basic D-amino acids are poor substrates and the acidic ones are virtually not oxidized. To present a comprehensive picture of how the active site residues can modulate the substrate specificity a number of mutants at position M213, Y223, Y238, R285, S335, and Q339 were prepared in the enzyme from the yeast Rhodotorula gracilis. All DAAO mutants have spectral properties similar to those of the wild-type enzyme and are catalytically active, thus excluding an essential role in catalysis; a lower activity on neutral and basic amino acids was observed. Interestingly, an increase in activity and (k(cat)/K(m))(app) ratio on D-aspartate was observed for all the mutants containing an additional charged residue in the active site. The active site of yeast DAAO appears to be a highly evolved scaffold built up through evolution to optimize the oxidative deamination of neutral D-amino acids without limiting its substrate specificity. It is noteworthy, that introduction of a sole, additional, positively charged residue in the active site is sufficient to optimize the reactivity on acidic D-amino acids, giving rise to kinetic properties similar to those of D-aspartate oxidase.     

Evaluation of D-amino acid oxidase from Rhodotorula gracilis for the production of alpha-keto acids: a reactor system

The study reports on the development of a bioreactor for the production of alpha-keto acids from D,L- or D-amino acids using Rhodotorula gracilis D-amino acid oxidase. D-Amino acid oxidase was co-immobilized with catalase on Affi-Gel 10 matrix, and the reactor was operated as a continuous-stirred tank reactor (CSTR) or stirred tank with medium recycling conditions. The optimum substrate concentration and quantity of biocatalyst were determined (5 mM and 1.2 mg/L, respectively). Under optimum operating conditions, product formation was linearly related to both substrate and enzyme concentration, showing the system to be highly flexible. Under these conditions, in a stirred tank, over 90% conversion was achieved in 30 min with a maximum production of 0.23 g of pyruvic acid/day/enzyme units. Product was recovered by ion exchange chromatography. The operational stability of the reactor was high (up to 9.5 h of operation without loss of activity) and the inactivation half-life was not reached even after 18 h or 36 bioconversion cycles. This represents the first case of a reactor developed successfully with a D-amino acid oxidase. (c) 1994 John Wiley & Sons, Inc.     

On the mechanism of Rhodotorula gracilis D-amino acid oxidase: role of the active site serine 335

Serine 335 at the active site of D-amino acid oxidase from the yeast Rhodotorula gracilis (RgDAAO) is not conserved in other DAAO sequences. To assess its role in catalysis, it was mutated to Gly, the residue present in mammalian DAAO, an enzyme with a 35-fold lower turnover number with D-alanine. The spectral and ligand binding properties of the S335G mutant are similar to those of wild-type enzyme, suggesting an active site with minimally altered electrostatic properties. The S335G mutant is catalytically active, excluding an essential role of S335 in catalysis. However, S335-OH contributes to the high efficiency of the mutant enzyme since the catalytic activity of the latter is lower due to a decreased rate of flavin reduction relative to wild-type RgDAAO. Catalytic rates are pH-dependent and appear to converge to very low, but finite and similar values at low pH for both wild-type and S335G RgDAAO. While this dependence exhibits two apparent pKs with wild-type RgDAAO, with the S335G mutant a single, apparent pK approximately 8 is observed, which is attributed to the ionization of the alphaNH2 group of the bound substrate. Removal of S335-OH thus suppresses an apparent pK approximately 6. Both wild-type RgDAAO and the S335G mutant exhibit a substantial deuterium solvent kinetic isotope effect (> or =4) at pH<7 that disappears with increasing pH and reflects a pKapp=6.9 +/- 0.4. Interestingly, the substitution suppresses the activity towards d-lactate, suggesting a role of the serine 335 in removal of the substrate alpha-OH hydrogen.     

Tryptophan 243 affects interprotein contacts, cofactor binding and stability in D-amino acid oxidase from Rhodotorula gracilis

The flavoenzyme d-amino acid oxidase from Rhodotorula gracilis is a homodimeric protein whose dimeric state has been proposed to occur as a result of (a) the electrostatic interactions between positively charged residues of the betaF5-betaF6 loop of one monomer and negatively charged residues belonging to the alpha-helices I3' and I3' of the other monomer, and (b) the interaction of residues (e.g. Trp243) belonging to the two monomers at the mixed interface region. The role of Trp243 was investigated by substituting it with either tyrosine or isoleucine: both substitutions were nondisruptive, as confirmed by the absence of significant changes in catalytic activity, but altered the tertiary structure (yielding a looser conformation) and decreased the stability towards temperature and denaturants. The change in conformation interferes both with the interaction of the coenzyme to the apoprotein moiety (although the kinetics of the apoprotein-FAD complex reconstitution process are similar between wild-type and mutant D-amino acid oxidases) and with the interaction between monomers. Our results indicate that, in the folded holoenzyme, Trp243 is situated at a position optimal for increasing the interactions between monomers by maximizing van der Waals interactions and by efficiently excluding solvent.     

Expression of D-amino acid oxidase in Rhodotorula gracilis under induction conditions: a biochemical and cytochemical study.

D-amino acid oxidase is expressed to a high level in the yeast Rhodotorula gracilis (0.3% of total cell protein) through induction by D-alanine in a defined growth medium. Monospecific polyclonal antibodies against pure enzyme were obtained. Western blot analysis showed that the enzyme is synthesized as the mature polypeptide. The localization of the enzyme was investigated by immunoelectron microscopy using the postembedding immunogold technique and by submicroscopic enzyme cytochemistry. D-Amino acid oxidase was detected in peroxisomes, and quantitation of immunoelectron microscopic data indicated that the enzyme is exclusively confined to these organelles. Immunoelectron microscopic observations are in complete agreement with biochemical data showing that the enzyme is not expressed in the absence of D-alanine. Morphometric analysis demonstrated that induction of D-amino acid oxidase synthesis is associated with a 241% increase of peroxisome volume density and with a 31% increase of peroxisome size as compared to cells grown on non-inducing medium.     

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.     

Role of tyrosine 238 in the active site of Rhodotorula gracilis D-amino acid oxidase. A site-directed mutagenesis study.

Y238, one of the very few conserved residues in the active site of d-amino acid oxidases (DAAO), was mutated to phenylalanine and serine in the enzyme from the yeast Rhodotorula gracilis. The mutated proteins are catalytically competent thus eliminating Tyr238 as an active-site acid/base catalyst. Y238F and Y238S mutants exhibit a threefold slower turnover on d-alanine as substrate, which can be attributed to a slower rate of product release relative to the wild-type enzyme (a change of the rate constants for substrate binding was also evident). The Y238 DAAO mutants have spectral properties similar to those of the wild-type enzyme but the degree of stabilization of the flavin semiquinone and the redox properties in the free form of Y238S are different. The binding of the carboxylic acid competitive inhibitors and the substrate d-alanine are changed only slightly, suggesting that the overall substrate binding pocket remains intact. In agreement with data from the pH dependence of ligand binding and with the protein crystal structure, site-directed mutagenesis results emphasize the importance of residue Y238 in controlling access to the active site instead of a role in the substrate/ligand interaction.     

Conversion of the dimeric D-amino acid oxidase from Rhodotorula gracilis to a monomeric form. A rational mutagenesis approach

Endothelial cells (ECs) secrete numerous bioactive peptides that are initially synthesized as inactive precursor proteins. One of these, proendothelin-1 (proET-1), undergoes proteolysis at specific pairs of basic amino acids. Here, we wished to examine the role of mammalian convertases in this event. Northern blot analysis shows that only furin and PC7 are expressed in ECs. In vitro cleavage of proET-1 by furin or PC7 demonstrated that both enzymes efficiently and specifically process proET-1. These data reveal that furin and PC7 have similar specificities towards proET-1 and suggest that both enzymes may participate in the maturation of proET-1 in ECs.     

The cytochemical demonstration of catalase and D-amino acid oxidase in the microbodies of teleost kidney cells

Synopsis The distribution of catalase and D-amino acid oxidase, marker enzymes for peroxisomes, was determined cytochemically in the kidney tubules of an euryhaline teleost, the three-spined stickleback.Catalase activity was localized with the diaminobenzidine technique. The presence of D-amino acid oxidase was determined using H₂O₂ generated by the enzyme, D-alanine as a substrate, and cerous ions for the formation of an electron-dense precipitate. Both enzymes appeared to be located in microbodies. The combined presence of these enzymes characterizes the microbodies as peroxisomes. Biochemically and cytochemically, no urate oxidase or glycolate-oxidizing L--hydroxy acid oxidase could be demonstrated.Stereological analysis of the epithelia lining the renal tubules showed that the fractional volume of the microbodies is 5 to 10 times higher in the cells of the second proximal tubules than in the other nephronic segments or the ureter. The fractional volume of the microbodies was similar in kidneys of freshwater and seawater fishes.     

High-level expression of Rhodotorula gracilis d-amino acid oxidase in Pichia pastoris

By combining gene design and heterologous over-expression of Rhodotorula gracilis D-amino acid oxidase (RgDAO) in Pichia pastoris, enzyme production was enhanced by one order of magnitude compared to literature benchmarks, giving 350 kUnits/l of fed-batch bioreactor culture with a productivity of 3.1 kUnits/l h. P. pastoris cells permeabilized by freeze-drying and incubation in 2-propanol (10% v/v) produce a highly active (1.6 kUnits/g dry matter) and stable oxidase preparation. Critical bottlenecks in the development of an RgDAO catalyst for industrial applications have been eliminated.     

Effect of hydrogen peroxide on d-amino acid oxidase from Rhodotorula gracilis

D-amino acid oxidase from Rhodotorula gracilis is a FAD-containing enzyme that belongs to the oxidase class that is characterized by the ability of the reduced flavin to react quickly with oxygen, yielding hydrogen peroxide and the oxidized cofactor. Hydrogen peroxide, necessary for the production of glutaryl-7-ACA from cephalosporin C had a deleterious effect on the enzyme. H(2)O(2) induced the oxidation of tryptophan and cysteine residues of the protein that could be involved in the dimerization process, required for the attainment of a fully competent enzyme. H(2)O(2) had also a kinetic effect on the reaction catalyzed by D-amino acid oxidase. It was a pure noncompetitive inhibitor; the corresponding inhibition constants were K(is) = 0.52 mM and K(ii) = 0.70 mM.     

Coimmobilization of D-amino acid oxidase and catalase by entrapment ofTrigonopsis variabilis in radiation polymerised Polyacrylamide beads

Trigonopsis variabilis induced for D-amino acid oxidase and catalase was immobilized by entrapment in Polyacrylamide beads obtained by radiation polymerisation. Permeabilization of the cells was found to be essential for optimal activity of the enzymes in free cells. However, the process of entrapment itself was found to eliminate the permeability barrier of cells immobilized in Polyacrylamide. The two enzymes exhibited a differential response on Polyacrylamide entrapment. Thus, D-amino acid oxidase activity was stabilized to heat inactivation whereas catalase in the same cells showed a destabilization on entrapment in Polyacrylamide. The coimmobilized enzyme preparation showed an operational half life of 7–9 days after which the D-amino acid oxidase activity remained stable at a value 35–40% of that of the initial activity for a study period of 3 weeks. Coimmobilization of MnO₂ was not effective in enhancing the operational life of the enzyme preparation.     

原玻璃蝇节杆菌D-氨基酸氧化酶及突变体的酶学特性

【目的】研究原玻璃蝇节杆菌(DSM 20168)中D-氨基酸氧化酶的酶学特性。【方法】通过PCR从原玻璃蝇节杆菌(DSM 15035,20168)中克隆获得D-氨基酸氧化酶基因apdaao-1和apdaao-2,构建原核表达载体,以表达质粒pET-ApDAAO-2为模板,采用QuickChange Site-Directed Mutagenesis技术构建定点突变体,经过原核表达及纯化获得重组型和突变体酶蛋白,分析其酶学特性。【结果】通过原核表达及纯化成功获得了2个重组蛋白和4个突变体酶蛋白,SDS-PAGE检测显示其分子量均约为36 kDa;酶学特性分析表明,ApDAAO-2和突变体蛋白的最适反应温度为30℃;ApDAAO-2和T286A的最适反应pH范围为7.0-11.0,其它突变体为8.0-11.0;ApDAAO-2和突变体都具有较广泛的底物特异性,除T256K的最适底物为D-Phe外,其余均为D-Met;动力学参数测定结果显示,以二级表观常数kcat/Km表示,对于底物D-Met或D-Phe,ApDAAO-2和4个突变体的kcat/Km值均比ApDAAO-1和pKDAAO高数倍以上。【结论】ApDAAO-2及突变体具有比ApDAAO-1和pKDAAO更广泛的底物特异性和较高的催化效率,有一定的商业应用价值。     

Dissection of the structural determinants involved in formation of the dimeric form of D-amino acid oxidase from Rhodotorula gracilis: role of the size of the betaF5-betaF6 loop

The role of the long loop connecting beta-strands F5 and F6 (21 amino acids, Pro302-Leu-Asp-Arg-Thr-Lys-Ser-Pro-Leu-Ser-Leu-Gly-Arg-Gly-Ser-Ala-Arg-Ala-Ala-Lys-Glu322) present in Rhodotorula gracilis d-amino acid oxidase (RgDAAO) was investigated by site-directed mutagenesis. This loop was proposed to play an important role in the 'head-to-tail' monomer-monomer interaction of this dimeric flavoenzyme: in particular, by means of electrostatic interactions between positively charged residues of the betaF5-betaF6 loop of one monomer and negatively charged residues belonging to the alpha-helices I3' and I3" of the other monomer. We produced a mutant of RgDAAO (namely, DAAO-DeltaLOOP2), in which only minor structural perturbations were introduced (only five amino acids were deleted; new sequence of the betaF5-betaF6 loop is Pro302-Leu-Asp-Arg-Thr-Leu-Gly-Arg-Gly-Ser-Ala-Arg-Ala-Ala-Lys-Glu317), and the charge of the betaF5-betaF6 loop not modified. The DeltaLOOP2 mutant is monomeric, has a weaker binding with the FAD cofactor, a decrease of the kinetic efficiency, and slight modifications in its spectral properties. The short version of the loop does not allow a correct monomer-monomer interaction, and its presence in the monomeric DAAO is a destabilizing structural element since the DeltaLOOP2 mutant is highly susceptible to proteolysis. These results, confirming the role of this loop in the subunits interaction and thus in stabilization of the sole dimeric form of RgDAAO, put forward the evidence that even a short deletion of the loop generates a consistent variation of the enzyme structure-function properties.