D-aspartate oxidase gene duplication induces social recognition memory deficit in mice and intellectual disabilities in humans.

The D-aspartate oxidase (DDO) gene encodes the enzyme responsible for the catabolism of D-aspartate, an atypical amino acid enriched in the mammalian brain and acting as an endogenous NMDA receptor agonist. Considering the key role of NMDA receptors in neurodevelopmental disorders, recent findings suggest a link between D-aspartate dysmetabolism and schizophrenia. To clarify the role of D-aspartate on brain development and functioning, we used a mouse model with constitutive Ddo overexpression and D-aspartate depletion. In these mice, we found reduced number of BrdU-positive dorsal pallium neurons during corticogenesis, and decreased cortical and striatal gray matter volume at adulthood. Brain abnormalities were associated with social recognition memory deficit at juvenile phase, suggesting that early D-aspartate occurrence influences neurodevelopmental related phenotypes. We corroborated this hypothesis by reporting the first clinical case of a young patient with severe intellectual disability, thought disorders and autism spectrum disorder symptomatology, harboring a duplication of a chromosome 6 region, including the entire DDO gene.

Biochemical characterization of mouse d-aspartate oxidase.

D-amino acids research field has recently gained an increased interest since these atypical molecules have been discovered to play a plethora of different roles. In the mammalian central nervous system, d-aspartate (D-Asp) is critically involved in the regulation of glutamatergic neurotransmission by acting as an agonist of NMDA receptor. Accordingly, alterations in its metabolism have been related to different pathologies. D-Asp shows a peculiar temporal pattern of emergence during ontogenesis and soon after birth its brain levels are strictly regulated by the catabolic enzyme d-aspartate oxidase (DASPO), a FAD-dependent oxidase. Rodents have been widely used as in vivo models for deciphering molecular mechanisms and for testing novel therapeutic targets and drugs, but human targets can significantly differ. Based on these considerations, here we investigated the structural and functional properties of the mouse DASPO, in particular kinetic properties, ligand and flavin binding, oligomerization state and protein stability. We compared the obtained findings with those of the human enzyme (80% sequence identity) highlighting a different oligomeric state and a lower activity for the mouse DASPO, which apoprotein species exists in solution in two forms differing in FAD affinity. The features that distinguish mouse and human DASPO suggest that this flavoenzyme might control in a distinct way the brain D-Asp levels in different organisms.

Biochemical characterization of d-aspartate oxidase from Caenorhabditis elegans: its potential use in the determination of free d-glutamate in biological samples.

d-Aspartate oxidase (DDO) is a flavin adenine dinucleotide (FAD)-containing flavoprotein that stereospecifically acts on acidic d-amino acids (i.e., free d-aspartate and d-glutamate). Mammalian DDO, which exhibits higher activity toward d-aspartate than d-glutamate, is presumed to regulate levels of d-aspartate in the body and is not thought to degrade d-glutamate in vivo. By contrast, three DDO isoforms are present in the nematode Caenorhabditis elegans, DDO-1, DDO-2, and DDO-3, all of which exhibit substantial activity toward d-glutamate as well as d-aspartate. In this study, we optimized the Escherichia coli culture conditions for production of recombinant C. elegans DDO-1, purified the protein, and showed that it is a flavoprotein with a noncovalently but tightly attached FAD. Furthermore, C. elegans DDO-1, but not mammalian (rat) DDO, efficiently and selectively degraded d-glutamate in addition to d-aspartate, even in the presence of various other amino acids. Thus, C. elegans DDO-1 might be a useful tool for determining these acidic d-amino acids in biological samples.

D-Aspartate oxidase: distribution, functions, properties, and biotechnological applications.

Recently, substantial levels of acidic D-amino acids, such as D-aspartate and D-glutamate, have been identified in many organisms, from bacteria to mammals, suggesting that acidic D-amino acids have multiple physiological significances. Although acidic D-amino acids found in animals primarily originate from foodstuffs and/or bacteria, the D-aspartate-synthesizing enzyme aspartate racemase is identified in various animals. In eukaryotic organisms, acidic D-amino acids are primarily degraded by the flavoenzyme D-aspartate oxidase (DDO). DDO is found in multiple eukaryotic organisms and may play important roles in acidic D-amino acid utilization, elimination, and intracellular level regulation. Moreover, owing to its perfect enantioselectivity and stereoselectivity, DDO may be a valuable tool in several biotechnological applications, including the identification and quantification of acidic D-amino acids. In this mini-review, previous DDO reports are summarized and the potential bioengineering and biotechnological applications of DDO are discussed. Key Points ・Occurrence and distribution ofd-aspartate oxidase. ・Fundamental properties of d -aspartate oxidase of various eukaryotic organisms. ・Biotechnological applications and potential engineering ofd-aspartate oxidase.

Structure and kinetic properties of human d-aspartate oxidase, the enzyme-controlling d-aspartate levels in brain.

d-Amino acids are the "wrong" enantiomers of amino acids as they are not used in proteins synthesis but evolved in selected functions. On this side, d-aspartate (d-Asp) plays several significant roles in mammals, especially as an agonist of N-methyl-d-aspartate receptors (NMDAR), and is involved in relevant diseases, such as schizophrenia and Alzheimer's disease. In vivo modulation of d-Asp levels represents an intriguing task to cope with such pathological states. As little is known about d-Asp synthesis, the only option for modulating the levels is via degradation, which is due to the flavoenzyme d-aspartate oxidase (DASPO). Here we present the first three-dimensional structure of a DASPO enzyme (from human) which belongs to the d-amino acid oxidase family. Notably, human DASPO differs from human d-amino acid oxidase (attributed to d-serine degradation, the main coagonist of NMDAR) showing peculiar structural features (a specific active site charge distribution), oligomeric state and kinetic mechanism, and a higher FAD affinity and activity. These results provide useful insights into the structure-function relationships of human DASPO: modulating its activity represents now a feasible novel therapeutic target.

Characterization and improvement of substrate-binding affinity of D-aspartate oxidase of the thermophilic fungus Thermomyces dupontii.

D-Aspartate oxidase (DDO) is a valuable enzyme that can be utilized in the determination of acidic D-amino acids and the optical resolution of a racemic mixture of acidic amino acids, which require its higher stability, higher catalytic activity, and higher substrate-binding affinity. In the present study, we identified DDO gene (TdDDO) of a thermophilic fungus, Thermomyces dupontii, and characterized the recombinant enzyme expressed in Escherichia coli. In addition, we generated a variant that has a higher substrate-binding affinity. The recombinant TdDDO expressed in E. coli exhibited oxidase activity toward acidic D-amino acids and a neutral D-amino acid, D-Gln, with the highest activity toward D-Glu. The Km and kcat values for D-Glu were 2.16 mM and 217 s-1, respectively. The enzyme had an optimum pH and temperature 8.0 and 60 °C, respectively, and was stable between pH 5.0 and 10.0, with a T50 of ca. 51 °C, which was much higher than that in DDOs from other origins. Enzyme stability decreased following a decrease in protein concentration, and externally added FAD could not repress the destabilization. The mutation of Phe248, potentially located in the active site of TdDDO, to Tyr residue, conserved in DDOs and D-amino acid oxidases, markedly increased substrate-binding affinity. The results showed the great potential of TdDDO and the variant for practical applications.

Structure-function relationships in human d-aspartate oxidase: characterisation of variants corresponding to known single nucleotide polymorphisms.

d-Aspartate oxidase (DDO) is a degradative enzyme that is stereospecific for the acidic amino acid d-aspartate, an endogenous agonist of the N-methyl-d-aspartate (NMDA) receptor. Dysregulation of NMDA receptor-mediated neurotransmission has been implicated in the onset of various neuropsychiatric disorders including schizophrenia and in chronic pain. Thus, appropriate regulation of the amount of d-aspartate is believed to be important for maintaining proper neural activity in the nervous system. Herein, the effects of the non-synonymous single nucleotide polymorphisms (SNPs) R216Q and S308N on several properties of human DDO were examined. Analysis of the purified recombinant enzyme showed that the R216Q and S308N substitutions reduce enzyme activity towards acidic d-amino acids, decrease the binding affinity for the coenzyme flavin adenine dinucleotide and decrease the temperature stability. Consistent with these findings, further experiments using cultured mammalian cells revealed elevated d-aspartate in cultures of R216Q and S308N cells compared with cells expressing wild-type DDO. Furthermore, accumulation of several amino acids other than d-aspartate also differed between these cultures. Thus, expression of DDO genes carrying the R216Q or S308N SNP substitutions may increase the d-aspartate content in humans and alter homeostasis of several other amino acids. This work may aid in understanding the correlation between DDO activity and the risk of onset of NMDA receptor-related diseases.

Possible role of a histidine residue in the substrate specificity of yeast d-aspartate oxidase.

D-Aspartate oxidase (DDO) catalyzes the oxidative deamination of acidic D-amino acids, whereas neutral and basic D-amino acids are substrates of D-amino acid oxidase (DAO). DDO of the yeast Cryptococcus humicola (ChDDO) has much higher substrate specificity to D-aspartate, but the structural features that confer this specificity have not been elucidated. A three-dimensional model of ChDDO suggested that a histidine residue (His56) in the active site might be involved in the unique substrate specificity, possibly through the interaction with the substrate side chain in the active site. His56 mutants with several different amino acid residues (H56A, H56D, H56F, H56K and H56N) exhibited no significant activity toward acidic D-amino acids, but H56A and H56N mutants gained the ability to utilize neutral D-amino acids as substrates, such as D-methionine, D-phenylalanine and D-glutamine, showing the conversion of ChDDO to DAO by these mutations. This conversion was also demonstrated by the sensitivity of these mutants to competitive inhibitors of DAO. These results and kinetic properties of the mutants show that His56 is involved in the substrate specificity of ChDDO and possibly plays a role in the higher substrate specificity toward D-aspartate.

Identification of Novel D-Aspartate Oxidase Inhibitors by in Silico Screening and Their Functional and Structural Characterization in Vitro.

D-Aspartate oxidase (DDO) is a degradative enzyme that is stereospecific for acidic D-amino acids, including D-aspartate, a potential agonist of the N-methyl-D-aspartate (NMDA) receptor. Dysfunction of NMDA receptor-mediated neurotransmission has been implicated in the onset of various mental disorders, such as schizophrenia. Hence, a DDO inhibitor that increases the brain levels of D-aspartate and thereby activates NMDA receptor function is expected to be a useful compound. To search for potent DDO inhibitor(s), a large number of compounds were screened in silico, and several compounds were identified as candidates. They were then characterized and evaluated as novel DDO inhibitors in vitro (e.g., the inhibitor constant value of 5-aminonicotinic acid for human DDO was 3.80 µM). The present results indicate that some of these compounds may serve as lead compounds for the development of a clinically useful DDO inhibitor and as active site probes to elucidate the structure-function relationships of DDO.

Characterization of the enzymatic and structural properties of human D-aspartate oxidase and comparison with those of the rat and mouse enzymes.

D-Aspartate (D-Asp), a free D-amino acid found in mammals, plays crucial roles in the neuroendocrine, endocrine, and central nervous systems. Recent studies have implicated D-Asp in the pathophysiology of infertility and N-methyl-D-Asp receptor-related diseases. D-Asp oxidase (DDO), a degradative enzyme that is stereospecific for acidic D-amino acids, is the sole catabolic enzyme acting on D-Asp in mammals. Human DDO is considered an attractive therapeutic target, and DDO inhibitors may be potential lead compounds for the development of new drugs against the aforementioned diseases. However, human DDO has not been characterized in detail and, although preclinical studies using experimental rodents are prerequisites for evaluating the in vivo effects of potential inhibitors, the existence of species-specific differences in the properties of human and rodent DDOs is still unclear. Here, the enzymatic activity and characteristics of purified recombinant human DDO were analyzed in detail. The kinetic and inhibitor-binding properties of this enzyme were also compared with those of purified recombinant rat and mouse DDOs. In addition, structural models of human, rat, and mouse DDOs were generated and compared. It was found that the differences among these DDO proteins occur in regions that appear involved in migration of the substrate/product in and out of the active site. In summary, detailed characterization of human DDO was performed and provides useful insights into the use of rats and mice as experimental models for evaluating the in vivo effects of DDO inhibitors.

Crystallization and preliminary crystallographic analysis of D-aspartate oxidase from porcine kidney.

D-Aspartate oxidase (DDO) from porcine kidney was crystallized by the sitting-drop vapour-diffusion method using PEG 8000 as a precipitant. The crystal belonged to space group P2(1), with unit-cell parameters a = 79.38, b = 144.0, c = 80.46 Å, ß = 101.1°, and diffracted to 1.80 Å resolution. Molecular-replacement trials using the structure of human D-amino-acid oxidase, which is 42% identical in sequence to DDO, as a search model provided a satisfactory solution.

Role of the active site residues arginine-216 and arginine-237 in the substrate specificity of mammalian D-aspartate oxidase.

D-aspartate oxidase (DDO) and D-amino acid oxidase (DAO) are flavin adenine dinucleotide-containing flavoproteins that catalyze the oxidative deamination of D-amino acids. Unlike DAO, which acts on several neutral and basic D-amino acids, DDO is highly specific for acidic D-amino acids. Based on molecular modeling and simulated annealing docking analyses, a recombinant mouse DDO carrying two substitutions (Arg-216 to Leu and Arg-237 to Tyr) was generated (R216L-R237Y variant). This variant and two previously constructed single-point mutants of mouse DDO (R216L and R237Y variants) were characterized to investigate the role of Arg-216 and Arg-237 in the substrate specificity of mouse DDO. The R216L-R237Y and R216L variants acquired a broad specificity for several neutral and basic D-amino acids, and showed a considerable decrease in activity against acidic D-amino acids. The R237Y variant, however, did not show any additional specificity for neutral or basic D-amino acids and its activity against acidic D-amino acids was greatly reduced. The kinetic properties of these variants indicated that the Arg-216 residue is important for the catalytic activity and substrate specificity of mouse DDO. However, Arg-237 is, apparently, only marginally involved in substrate recognition, but is important for catalytic activity. Notably, the substrate specificity of the R216L-R237Y variant differed significantly from that of the R216L variant, suggesting that Arg-237 has subsidiary effects on substrate specificity. Additional experiments using several DDO and DAO inhibitors also suggested the involvement of Arg-216 in the substrate specificity and catalytic activity of mouse DDO and that Arg-237 is possibly involved in substrate recognition by this enzyme. Collectively, these results indicate that Arg-216 and Arg-237 play crucial and subsidiary role(s), respectively, in the substrate specificity of mouse DDO.

Thiolactomycin inhibits D-aspartate oxidase: a novel approach to probing the active site environment.

D-Aspartate oxidase (DDO) and D-amino acid oxidase (DAO) are flavin adenine dinucleotide (FAD)-containing flavoproteins that catalyze the oxidative deamination of D-amino acids. While several functionally and structurally important amino acid residues have been identified in the DAO protein, little is known about the structure-function relationships of DDO. In the search for a potent DDO inhibitor as a novel tool for investigating its structure-function relationships, a large number of biologically active compounds of microbial origin were screened for their ability to inhibit the enzymatic activity of mouse DDO. We discovered several compounds that inhibited the activity of mouse DDO, and one of the compounds identified, thiolactomycin (TLM), was then characterized and evaluated as a novel DDO inhibitor. TLM reversibly inhibited the activity of mouse DDO with a mixed type of inhibition more efficiently than meso-tartrate and malonate, known competitive inhibitors of mammalian DDOs. The selectivity of TLM was investigated using various DDOs and DAOs, and it was found that TLM inhibits not only DDO, but also DAO. Further experiments with apoenzymes of DDO and DAO revealed that TLM is most likely to inhibit the activities of DDO and DAO by competition with both the substrate and the coenzyme, FAD. Structural models of mouse DDO/TLM complexes supported this finding. The binding mode of TLM to DDO was validated further by site-directed mutagenesis of an active site residue, Arg-237. Collectively, our findings show that TLM is a novel, active site-directed DDO inhibitor that will be useful for elucidating the molecular details of the active site environment of DDO.

Comparative characterization of three D-aspartate oxidases and one D-amino acid oxidase from Caenorhabditis elegans.

Previously, we cloned cDNAs for four Caenorhabditis elegans genes (F20 Hp, C47Ap, F18Ep, and Y69Ap genes) that were annotated in the database as encoding D-amino acid oxidase (DAO) or D-aspartate oxidase (DDO) proteins. These genes were expressed in Escherichia coli, and the recombinant C47Ap and F18Ep were shown to have functional DDO activities, while Y69Ap had functional DAO activity. In this study, we improved the E. coli culture conditions for the production of recombinant F20 Hp and, following purification of the protein, revealed that it has functional DDO activity. The kinetic properties of recombinant C47Ap (DDO-1), F18Ep (DDO-2), F20 Hp (DDO-3), and Y69Ap (DAO) were also determined and compared with recombinant human DDO and DAO. In contrast to the low catalytic efficiency of human DDO for D-Glu, all three C. elegans DDOs showed higher catalytic efficiencies for D-Glu than D-Asp or N-methyl-D-Asp. The catalytic efficiency of C. elegans DAO for D-Ser was substantially lower than that of human DAO, while the C. elegans DAO was more efficient at deamination of basic D-amino acids (D-Arg and D-His) than human DAO. Collectively, our results indicate that C. elegans contains at least three genes that encode functional DDOs, and one gene encoding a functional DAO, and that these enzymes have different and distinctive properties.

Hyperactive mutants of mouse D-aspartate oxidase: mutagenesis of the active site residue serine 308.

The role of Ser-308 of murine D-aspartate oxidase (mDASPO), particularly its side chain hydroxyl group, was investigated through the use of site-specific mutational analysis of Ser-308. Recombinant mDASPO carrying a substitution of Gly, Ala, or Tyr for Ser-308 was generated, and fused to either His (His-mDASPO), or glutathione S-transferase, His, and S (GHS-mDASPO) at its N-terminus. Wild-type His-mDASPO or GHS-mDASPO or their mutant derivatives were expressed in Escherichia coli and purified by affinity chromatography. All purified recombinant proteins had functional DASPO activity. The Gly-308 and Ala-308 mutants had significantly higher catalytic efficiency towards D-Asp and N-methyl-D-Asp, and a higher affinity for flavin adenine dinucleotide (FAD) compared to the wild-type enzyme. The Tyr-308 mutant had lower catalytic efficiency and binding capacity. These results suggest that the side chain hydroxyl group of a critical residue of mDASPO, Ser-308, down-regulates enzymatic activity, substrate binding, and FAD binding. This study provides information on the active site of DASPO that will considerably enhance our understanding of the biological significance of this enzyme.

Molecular cloning of a cDNA encoding mouse D-aspartate oxidase and functional characterization of its recombinant proteins by site-directed mutagenesis.

The cDNA encoding D-aspartate oxidase (DASPO) was cloned from mouse kidney RNA by RT-PCR. Sequence analysis showed that it contained a 1023-bp open reading frame encoding a protein of 341 amino acid residues. The protein was expressed in Escherichia coli with or without an N-terminal His-tag and had functional DASPO activity that was highly specific for D-aspartate and N-methyl-D-aspartate. To investigate the roles of the Arg-216 and Arg-237 residues of the mouse DASPO (mDASPO), we generated clones with several single amino acid substitutions of these residues in an N-terminally His-tagged mDASPO. These substitutions significantly reduced the activity of the recombinant enzyme against acidic D-amino acids and did not confer any additional specificity to other amino acids. These results suggest that the Arg-216 and Arg-237 residues of mDASPO are catalytically important for full enzyme activity.

Functional and structural characterization of D-aspartate oxidase from porcine kidney: non-Michaelis kinetics due to substrate activation.

D-aspartate oxidase (DDO, EC 1.4.3.1) catalyzes dehydrogenation of D-aspartate to iminoaspartate and the subsequent re-oxidation of reduced FAD with O2 to produce hydrogen peroxide. In the mammalian neuroendocrine system, D-aspartate, a natural substrate, plays important roles in the regulation of the synthesis and secretion of hormones. To elucidate the kinetic and structural properties of native DDO, we purified DDO from porcine kidney to homogeneity, cloned the cDNA, and overexpressed the enzyme in Escherichia coli. The purified DDO was a homotetramer with tightly-bound FAD. The enzyme consisted of 341 amino acids and had GAGVMG as the dinucleotide binding motif and a C-terminal SKL peroxisomal-targeting signal sequence. Porcine DDO showed a strong affinity for meso-tartrate (Kd = 118 microM). The oxidase exhibited pronounced substrate activation at D-aspartate and D-glutamate concentrations, [S], higher than 0.2 and 4 mM, respectively, and the [S]/v versus [S] plot showed marked downward curvature (v, the initial velocity), whereas substrate inhibition occurred with N-methyl-D-aspartate. These kinetic properties of DDO suggested that at high substrate concentrations, the FAD-reduced form of the enzyme also catalyzes the reaction: the oxidative half-reaction precedes the reductive one. The present direct approach to the analysis of non-Michaelis kinetics is indispensable for understanding the functional properties of DDO.