Detection and substrate selectivity of new microbial D-amino acid oxidases

In order to screen for new microbial D-amino acid oxidase activities a selective and sensitive peroxidase/o-dianisidine assay, detecting the formation of hydrogen peroxide was developed. Catalase, which coexists with oxidases in the peroxisomes or the microsomes and, which competes with peroxidase for hydrogen peroxide, was completely inhibited by o-dianisidine up to a catalase activity of 500 nkat ml(-)(1). Thus, using the peroxidase/o-dianisidine assay and employing crude extracts of microorganisms in a microplate reader, a detection sensitivity for oxidase activity of 0.6 nkat ml(-)(1) was obtained.Wild type colonies which were grown on a selective medium containing D-alanine as carbon, energy and nitrogen source were examined for D-amino acid oxidase activity by the peroxidase/o-dianisidine assay. The oxidase positive colonies possessing an apparent oxidase activity > 2 nkat g dry biomass(-)(1) were isolated. Among them three new D-amino acid oxidase-producers were found and identified as Fusarium oxysporum, Verticilium lutealbum and Candida parapsilosis. The best new D-amino oxidase producer was the fungus F. oxysporum with a D-amino acid oxidase activity of about 900 nkat g dry biomass(-)(1) or 21 nkat mg protein(-)(1). With regard to the use as a biocatalytic tool in biotechnology the substrate specificities of the three new D-amino acid oxidases were compared with those of the known D-amino acid oxidases from Trigonopsis variabilis, Rhodotorula gracilis and pig kidney under the same conditions. All six D-amino acid oxidases accepted the D-enantiomers of alanine, valine, leucine, proline, phenylalanine, serine and glutamine as substrates and, except for the D-amino acid oxidase from V. luteoalbum, D-tryptophane, D-tyrosine, D-arginine and D-histidine were accepted as well. The relative highest activities (>95%) were measured versus D-alanine (C. parapsilosis, F. oxysporum, T. variabilis), D-methionine (V. luteoalbum, R. gracilis), D-valine (T. variabilis, R. gracilis) and D-proline (pig kidney). The D-amino oxidases from F. oxysporum and V. luteoalbum were able to react with the industrially important substrate cephalosporin C although the D-amino acid oxidase from T. variabilis was at least about 20-fold more active with this substrate.As the results of our studies, a reliable oxidase assay was developed, allowing high throughput screening in a microplate reader. Furthermore, three new microbial D-amino acid oxidase-producers with interesting broad substrate specificities were introduced in the field of biotechnology.     

Molecular characterization of D-amino acid oxidase from common carp Cyprinus carpio and its induction with exogenous free D-alanine

A full-length cDNA encoding D-amino acid oxidase (DAO, EC 1.4.3.3) was cloned and sequenced from the hepatopancreas of carp fed a diet supplemented with D-alanine. This clone contained an open reading frame encoding 347 amino acid residues. The deduced amino acid sequence exhibited about 60 and 19-29% identity to mammalian and microbial DAOs, respectively. The expression of full-length carp DAO cDNA in Escherichia coli resulted in a significant level of protein with DAO activity. In carp fed the diet with D-alanine for 14 days, DAO mRNA was strongly expressed in intestine followed by hepatopancreas and kidney, but not in muscle. During D-alanine administration, DAO gene was expressed quickly in hepatopancreas with the increase of DAO activity. The inducible nature of carp DAO indicates that it plays an important physiological role in metabolizing exogenous D-alanine that is abundant in their prey invertebrates, crustaceans, and mollusks.     

Presence of D-alanine in an endopeptidase from Streptococcus pyogenes

D-amino acids are commonly found in peptide antibiotics and the cell wall peptidoglycan of bacterial cell walls but have not been identified in proteins or enzymes. Here we report the presence of 6-7 A-alanine residues in an endopeptidase of Streptococcus pyogenes, a unique enzyme involved in surface protein attachment that we term LPXTGase. Using D-amino acid oxidase coupled with catalase for the deamination of D-alanine to pyruvic acid (a conversion unique to D-alanine), we were able to identify [14C]pyruvic acid in a [14C]alanine-labeled preparation of purified LPXTGase, which represents 27% of the amino acid composition. Because D-amino acids are not accommodated in ribosomal peptide synthesis, these results suggest that the same process used in assembling peptide antibiotics or a yet unidentified mechanism may synthesize the core protein of this endopeptidase.     

Determination of D-amino acids using a D-amino acid oxidase biosensor with spectrophotometric and potentiometric detection

An amperometric and a colorimetric biosensor to detect and quantify D-amino acids selectively has been devised using D-amino acid oxidase from Rhodotorula gracilis. The sensor is characterised by a proportional response between 0.2-3 mM and 0.1-1 mM D-alanine for the amperometric (at a working potential of 1400 mV vs Ag/AgCl) and colorimetric system, respectively.     

Molecular cloning and sequence analysis of cDNA encoding human kidney D-amino acid oxidase

cDNA clones encoding D-amino acid oxidase were isolated from a human kidney cDNA library by hybridization with cDNA for the pig enzyme. The cDNA insert of 2.0 kilobase pairs long provided coding information for a protein consisting of 347 amino acids. The molecular mass of the enzyme was calculated to be 39,410 Da. The amino acid sequence similarity between the pig and human enzymes is 84.4%, and among the active site residues proposed from chemical modification studies, methionine-110 of the pig enzyme was replaced by threonine. Northern blot analysis confirmed the expression of an mRNA of 2.0 kilobases encoding the D-amino acid oxidase in human kidney.     

Distribution and characteristics of D-amino acid and D-aspartate oxidases in fish tissues

The distributions of D-amino acid oxidase (D-AAO, EC 1.4.3.3) and D-aspartate oxidase (D-AspO, EC 1.4.3.1) activities were examined on several tissues of various fish species. Both enzyme activities were commonly high in kidney and liver and low in intestine with some exceptions. After oral administration of D-alanine at 5 micromol /g body weight(-1)day(-1) to carp for 30 days, D-AAO activity increased by about 8-, 3-, and 1.5-fold in intestine, hepatopancreas, and kidney, respectively, whereas no increase was found in brain. In contrast, oral administration of D-glutamate or D-aspartate did not show any increase of D-AspO activity in any tissues. D-AAO and D-AspO of common carp kidney and hepatopancreas were subcellularly localized in peroxisomes, as clarified in mammals. D-proline was the best substrate for D-AAO in rainbow trout kidney, common carp kidney, and hepatopancreas, followed by D-alanine and D-phenylalanine. N-methyl-D-aspartate was the best substrate for D-AspO in rainbow trout kidney and common carp hepatopancreas. The optimal pH for D-AAO in rainbow trout kidney was broad, from 7.4 to 8.2, and that for D-AspO was around 10. D-AAO was inhibited by benzoate known as D-AAO inhibitor and D-AspO was strongly inhibited by meso-tartarate as D-AspO inhibitor. From these results, at least D-AAO in fish is considered to work as a metabolizing agent of exogenous and endogenous free D-alanine that is abundant in aquatic invertebrates such as crustaceans and bivalve mollusks, which are potential food sources of these fishes.     

Occurrence of D-amino acids in a few archaea and dehydrogenase activities in hyperthermophile Pyrobaculum islandicum

The contents of D-enantiomers of serine, alanine, proline, glutamate (glutamine) and aspartate (asparagine) were examined in the membrane fractions, soluble proteins and free amino acids from some species of archaea, Pyrobaculum islandicum, Methanosarcina barkeri and Halobacterium salinarium. Around 2% (D/D+L) of D-aspartate was found in the membrane fractions. In the soluble proteins, the D-amino acid content was higher in P. islandicum than that in the other archaeal cells: the concentrations in P. islandicum were 3 and 4% for D-serine and D-aspartate, respectively. High concentrations of free D-amino acids were found in P. islandicum and H. salinarium; the concentrations of D-serine (12-13%), D-aspartate (4-7%) and D-proline (3-4%) were higher than those of D-alanine and D-glutamate. This result showed a resemblance between these archaea and not bacterial, but eukaryotic cells. The presence of D-amino acids was confirmed by their digestion with D-amino acid oxidase and D-aspartate oxidase. The occurrence of D-amino acids was also confirmed by the presence of activities catalyzing catabolism of D-amino acids in the P. islandicum homogenate, as measured by 2-oxo acid formation. The catalytic activities oxidizing D-alanine, D-aspartate and D-serine at 90 degrees C were considerably high. Under anaerobic conditions, dehydrogenase activities of the homogenate were 69, 84 and 30% of the above oxidase activities toward D-alanine, D-aspartate and D-serine, respectively. Comparable or higher dehydrogenase activities were also detected with these D-amino acids as substrate by the reduction of 2, 6-dichlorophenolindophenol. No D-amino acid oxidase activity was detected in the homogenates of M. barkeri and H. salinarium.     

Kinetic properties of rat kidney D-amino acid oxidase associated with peroxisomes

In contrast to hog kidney D-amino acid oxidase, the v vs s plots of D-amino acid oxidase in homogenized rat kidney did not have the form of a rectangular hyperbola, and showed an apparent negative cooperativity. After subcellular fractionation of rat kidney, both of the oxidases in the supernatant fraction and the peroxisomal fraction showed Michaelis-Menten type kinetics. The Km values for D-alanine and D-proline of the peroxisomal fraction were significantly lower than those of the supernatant fraction. The partially purified enzyme from the peroxisomal fraction showed the same kinetic properties as the supernatant fraction. These facts suggest that the two types of rat kidney D-amino acid oxidase were originally identical and that some interaction between the enzyme and peroxisomes is physiologically important for the function of the enzyme.     

Properties of D-amino-acid oxidase from Rhodotorula gracilis

The flavoprotein D-amino-acid oxidase was purified to homogeneity from the yeast Rhodotorula gracilis by a highly reproducible procedure. The amino acid composition of the protein was determined; the protein monomer had a molecular mass of 39 kDa and contained one molecule of FAD. The ratio between A274/A455 was about 8.2. D-Amino-acid oxidase from yeast showed typical flavin spectral perturbations on binding of the competitive inhibitor benzoate and was reduced by D-alanine under anaerobiosis. The enzyme reacted readily with sulfite to form a covalent reversible adduct and stabilized the red anionic form of the flavin semiquinone on photoreduction in the presence of 5-deazariboflavin; the 3,4-dihydro-FAD form was not detectable after reduction with sodium borohydride. Thus D-amino-acid oxidase from yeast exhibited most of the general properties of the dehydrogenase/oxidase class of flavoproteins; at the same time, the enzyme showed some peculiar features with respect to the same protein from pig kidney.     

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.     

D-Amino acid oxidase activity form Rhodosporiduim toruloides

The D-amino acid oxidase activity of Rhodosporidium toruloides CCRC 20306 was studied. The enzyme could be induced by D-alanine, and had pH and temperature optima of 8.5 and 60C, respectively. D-Amino acids with polar uncharged and/or nonpolar side chain were good substrates for the D-amino acid oxidase of CCRC 20306, whereas those with polar charged side chain were poor substrates. Benzoic acid and its derivatives were inhibitory to the enzyme activity.     

荧光假单胞菌TM5-2中D-型氨基酸脱氢酶的鉴定和表达

从荧光假单胞菌TM5-2中得到一个含丙氨酸消旋酶基因的DNA片段(8.8kb),相邻的一个开读框(ORF)与甘氨酸/D-型氨基酸氧化酶基因相似。该ORF经过克隆、表达,并没有检测到甘氨酸/D-型氨基酸氧化酶的活性,推导而得的氨基酸序列与D-型氨基酸脱氢酶序列比较发现,ORF含有D-型氨基酸脱氢酶的所有重要的保守序列。经TTC培养基鉴定,其具有D-型氨基酸脱氢酶的活性,并对一系列D-型氨基酸有作用,最佳作用底物是D-组氨酸。     

Translation of messenger RNA of pig kidney D-amino acid oxidase in a cell-free system

In vitro synthesis of D-amino acid oxidase [D-amino acid: O2 oxidoreductase (deaminating), EC 1.4.3.3], one of the peroxisomal flavin enzymes, was performed using a rabbit reticulocyte lysate system in order to elucidate the biosynthetic pathway of the enzyme. The apparent molecular weight of the synthesized enzyme protein was the same as that of D-amino acid oxidase purified from pig kidney. On the other hand, the enzyme protein was not detectable when a wheat germ lysate system was used for the translation. Denaturation of pig kidney poly(A)+ RNA with methylmercury hydroxide prior to the translation was found to enhance the synthesis of the enzyme protein. These results suggest a tight conformational structure of the mRNA used.     

Purification, characterization, gene cloning and nucleotide sequencing of D-stereospecific amino acid amidase from soil bacterium: Delftia acidovorans

The D-amino acid amidase-producing bacterium was isolated from soil samples using an enrichment culture technique in medium broth containing D-phenylalanine amide as a sole source of nitrogen. The strain exhibiting the strongest activity was identified as Delftia acidovorans strain 16. This strain produced intracellular D-amino acid amidase constitutively. The enzyme was purified about 380-fold to homogeneity and its molecular mass was estimated to be about 50 kDa, on sodium dodecyl sulfate polyacrylamide gel electrophoresis. The enzyme was active preferentially toward D-amino acid amides rather than their L-counterparts. It exhibited strong amino acid amidase activity toward aromatic amino acid amides including D-phenylalanine amide, D-tryptophan amide and D-tyrosine amide, yet it was not specifically active toward low-molecular-weight D-amino acid amides such as D-alanine amide, L-alanine amide and L-serine amide. Moreover, it was not specifically active toward oligopeptides. The enzyme showed maximum activity at 40 degrees C and pH 8.5 and appeared to be very stable, with 92.5% remaining activity after the reaction was performed at 45 degrees C for 30 min. However, it was mostly inactivated in the presence of phenylmethanesulfonyl fluoride or Cd2+, Ag+, Zn2+, Hg2+ and As3+ . The NH2 terminal and internal amino acid sequences of the enzyme were determined; and the gene was cloned and sequenced. The enzyme gene damA encodes a 466-amino-acid protein (molecular mass 49,860.46 Da); and the deduced amino acid sequence exhibits homology to the D-amino acid amidase from Variovorax paradoxus (67.9% identity), the amidotransferase A subunit from Burkholderia fungorum (50% identity) and other enantioselective amidases.     

Production of a new D-amino acid oxidase from the fungus Fusarium oxysporum.

The fungus Fusarium oxysporum produced a D-amino acid oxidase (EC 1. 4.3.3) in a medium containing glucose as the carbon and energy source and ammonium sulfate as the nitrogen source. The specific D-amino acid oxidase activity was increased up to 12.5-fold with various D-amino acids or their corresponding derivatives as inducers. The best inducers were D-alanine (2.7 microkat/g of dry biomass) and D-3-aminobutyric acid (2.6 microkat/g of dry biomass). The addition of zinc ions was necessary to permit the induction of peroxisomal D-amino acid oxidase. Bioreactor cultivations were performed on a 50-liter scale, yielding a volumetric D-amino acid oxidase activity of 17 microkat liter(-1) with D-alanine as an inducer. Under oxygen limitation, the volumetric activity was increased threefold to 54 microkat liter(-1) (3,240 U liter(-1)).     

Analyzing the D-amino acid content in biological samples by engineered enzymes

The aim of our present research is to produce mutant forms of D-amino acid oxidase from Rhodotorula gracilis in order to determine D-amino acid content in different biological samples. During the past few years, our group has produced yeast D-amino acid oxidase variants with altered substrate specificity (e.g., active on acidic, or hydrophobic, or on all D-amino acids) both by rational design and directed evolution methods. Now, the kinetic constants for a number of amino acids (even for unnatural ones) of the most relevant D-amino acid oxidase variants have been investigated. This information constitutes the basis for considering potential analytical applications in this important field.     

Occurrence and some properties of a novel γ-glutamyltransferase responsible for the syntheis of γ-L-glutamul-D-alanine in pea seedlings

Occurrence of a novel γ-glutamyltransferase responsible for the formation of γ-L-glutamyl-D-alanine was demonstrated in pea seedlings, and the enzyme was purified 600-fold. The enzyme preparation catalyzed the transfer of the γ-glutamyl moiety of L-glutamine and other γ-glutamyl compounds to D-amino acids. In the formation of γ-L-glutamyl peptides of D-amino acids, L-glutamine served as the most effective γ-glutamyl donor and D-alanine acted as a highly-specific acceptor. The maximum activity of the γ-glutamyl transfer reaction between L-glutamine and D-alanine was observed at pH 9.5 and the apparent K_m values for these amino acids were estimated to be 2.0 and 2.9mM, respectively. This unique γ-glutamyltransferase activity was always accompanied by the catalytic activities of the known γ-glutamyltransferases during the purification procedure.     

Immobilization and characterization of D-amino acid oxidase.

Optimal conditions with respect to pH, concentration of glutaraldehyde and enzyme, and order of addition of enzyme and crosslinking reagent were established for the immobilization of hog kidney D-amino acid oxidase to an attapulgite support. Yields of 40 to 70% were generally attained although when low concentrations of enzyme were used yields were consistently greater than 100%. It is suggested that this is due to a dimer leads to monomer shift at low protein concentrations. The stability of soluble D-amino acid oxidase was dependent on the buffer in which it was stored (pyrophosphate-phosphate greater than borate greater than Tris). Stability of immobilized enzyme was less than soluble in pyrophosphate-phosphate buffer, but storage in the presence of FAD improved stability. In addition, treatment of stored, immobilized enzyme with FAD before assay restored some of its activity. The immobilized D-amino acid oxidase was less stable to heat (50 degrees C) than the soluble enzyme from pH 6 to 8 but was more stable above and below these values. Apparent Km values for D-alanine, D-valine, and D-tryptophan decreased for the immobilized enzyme compared to the soluble.     

A biosensor for all D-amino acids using evolved D-amino acid oxidase

Determination of the D-amino acid content in foods and in biological samples is a very important task. In order to achieve this goal we developed a biosensor employing the flavoenzyme D-amino acid oxidase from the yeast Rhodotorula gracilis. To produce a device in which the D-amino acid composition does not alter the results, both the wild-type and a number of mutants obtained by rational design and directed evolution approaches were used. An analysis of D-amino acid oxidase mutants activity on D-amino acid mixtures containing various ratios of neutral, acidic, and basic substrates identified the Amberzyme-immobilized T60A/Q144R/K152E and M213G mutants as the best choice: their response shows an only limited dependence on the solution composition when at least 20% of the D-amino acid is made up of D-alanine (standard error is approximately 5-9%). This is the first report, to our knowledge, demonstrating that the entire D-amino acid content can be determined by using a screen-printed electrode amperometric biosensor, with a detection limit of 0.25 mM and a mean response time of 10-15 min. The D-amino acid assay based on R. gracilis DAAO-biosensor is inexpensive, simple to perform, and rapid: the D-amino acid concentration of a variety of biological samples can be investigated using this assay.     

Reconstitution of Escherichia coli membrane vesicles with D-amino acid dehydrogenase

When purified D-amino acid dehydrogenase [Olsiewski, P. J., Kaczorowski, G. J., & Walsh, C. T. (1980) J. Biol. Chem. 255, 4487] is incubated with right-side-out membrane vesicles from Escherichia coli, the enzyme binds to the membrane in a time- and concentration-dependent manner. As a result, the vesicles acquire the ability to oxidize D-alanine and catalyze D-alanine-dependent active transport. Similarly, incubation of D-amino acid dehydrogenase with inside-out vesicles results in binding of enzyme and D-alanine oxidase activity. Antibody inhibition studies indicate that the enzyme is bound exclusively to the inner cytoplasmic surface of the membrane in native vesicles (i.e., membrane vesicles prepared from cells induced for D-amino acid dehydrogenase). In contrast, similar studies with reconstituted vesicles demonstrate that enzyme binds to the surface exposed to the medium regardless of the orientation of the membrane. Thus, enzyme bound to right-side-out vesicles is located on the opposite side of the membrane from where it is normally found. Remarkably, in the presence of D-alanine, reconstituted right-side-out and inside-out vesicles generate electrochemical proton gradients of similar magnitude but opposite polarity, indicating that enzyme bound to either surface of the membrane is physiologically functional. The results suggest that vectorial proton translocation via the respiratory chain occurs at a point distal to the site where electrons enter the respiratory chain from the primary dehydrogenase, a conclusion that is inconsistent with the notion that the dehydrogenase forms part of a proton-translocating loop.