d-Amino acids in the brain and mutant rodents lacking d-amino-acid oxidase activity

d-Amino acids are stereoisomers of l-amino acids. They are often called unnatural amino acids, but several d-amino acids have been found in mammalian brains. Among them, d-serine is abundant in the forebrain and functions as a co-agonist of NMDA receptors to enhance neurotransmission. d-Amino-acid oxidase (DAO), which degrades neutral and basic d-amino acids, is mainly present in the hindbrain. DAO catabolizes d-serine and, therefore, modulates neurotransmission. In the brains of mutant mice and rats lacking DAO activity, the amounts of d-serine and other d-amino acids are markedly increased. Mutant mice manifested behavioral changes characteristic of altered NMDA receptor activity, likely due to increased levels of d-serine. d-Serine and DAO have been demonstrated to play important roles in cerebellar development and synaptic plasticity. They have also implicated in amyotrophic lateral sclerosis and pain response. There have also been several lines of evidence correlating DAO with schizophrenia. Taken together, the experiments indicate that d-amino acids and DAO have pivotal functions in the central nervous system.     

The role of d-amino acids in amyotrophic lateral sclerosis pathogenesis: a review

A potential role for d-amino acids in motor neuron disease/amyotrophic lateral sclerosis (ALS) is emerging. d-Serine, which is an activator/co-agonist at the N-methyl-d-aspartate glutamate receptor subtype, is elevated both in spinal cord from sporadic cases of ALS and in an animal model of ALS. Furthermore, we have shown that a mutation in d-amino acid oxidase (DAO), an enzyme strongly localized to spinal cord motor neurons and brain stem motor nuclei, is associated with familial ALS. DAO plays an important role in regulating levels of d-serine, and its function is impaired by the presence of this mutation and this may contribute to the pathogenic process in ALS. In sporadic ALS cases, elevated d-serine may arise from induction of serine racemase, its synthetic enzyme, caused by cell stress and inflammatory processes thought to contribute to disease progression. Both these abnormalities in d-serine metabolism lead to an increase in synaptic d-serine which may contribute to disease pathogenesis.     

Serine racemase: an unconventional enzyme for an unconventional transmitter

The discovery of large amounts of d-serine in the brain challenged the dogma that only l-amino acids are relevant for eukaryotes. The levels of d-serine in the brain are higher than many l-amino acids and account for as much as one-third of l-serine levels. Several studies in the last decades have demonstrated a role of d-serine as an endogenous agonist of N-methyl-d-aspartate receptors (NMDARs). d-Serine is required for NMDAR activity during normal neurotransmission as well as NMDAR overactivation that takes place in neurodegenerative conditions. Still, there are many unanswered questions about d-serine neurobiology, including regulation of its synthesis, release and metabolism. Here, we review the mechanisms of d-serine synthesis by serine racemase and discuss the lessons we can learn from serine racemase knockout mice, focusing on the roles attributed to d-serine and its cellular origin.     

NMDA Receptor Activation: Two Targets for Two Co-Agonists

Neuronal N-methyl-d-aspartate receptors (NMDARs) play a critical role in synaptic plasticity. Their activation requires not only binding of their ligand glutamate and membrane depolarization but also the presence of a co-agonist, glycine or d-serine. An increasing body of experimental evidence suggests that different populations of NMDARs could be gated by different co-agonists. Here we discuss how the spatial distribution of co-agonist sources and uptake mechanisms, together with diffusional properties of the synaptic environment, could shape NMDAR co-agonist supply and therefore NMDAR-dependent plasticity.     

Amperometric microbiosensor as an alternative tool for investigation of d-serine in brain

This paper discusses the application of a reagentless, selective microbiosensor as a useful alternative tool for monitoring d-serine in neural samples. The main components of the 125-μm-diameter disk biosensor were d-amino acid oxidase for d-serine sensitivity (linear region slope, 61?±?7?μA?cm^–2?mM^–1; limit of detection, 20?nM), and poly-phenylenediamine for rejection of electroactive interference. The response time of the biosensor was of the order of 1?s, ideal for ‘real-time’ monitoring, and detection of systemically administered d-serine in brain extracellular fluid is demonstrated. Exploitation of this probe might resolve queries involving regulation of d-serine in excitotoxicity, and modulation of N-methyl-d-aspartate receptor function by d-serine and glycine in the central nervous system.     

Structure–function relationships in human d-amino acid oxidase

Since d-amino acids were identified in mammals, d-serine has been one of the most extensively studied “unnatural amino acids”. This brain-enriched transmitter-like molecule plays a pivotal role in the human central nervous system by modulating the activity of NMDA receptors. Physiological levels of d-serine are required for normal brain development and function; thus, any alterations in neuromodulator concentrations might result in NMDA receptor dysfunction, which is known to be involved in several pathological conditions, including neurodegeneration(s), epilepsy, schizophrenia, and bipolar disorder. In the brain, the concentration of d-serine stored in cells is defined by the activity of two enzymes: serine racemase (responsible for both the synthesis and degradation) and d-amino acid oxidase (which catalyzes d-serine degradation). Both enzymes emerged recently as new potential therapeutic targets for NMDA receptor-related diseases. In this review we have focused on human d-amino acid oxidase and provide an extensive overview of the biochemical and structural properties of this flavoprotein and their functional significance. Furthermore, we discuss the mechanisms involved in modulating enzyme activity and stability with the aim to substantiate the pivotal role of d-amino acid oxidase in brain d-serine metabolism in physiological and pathological conditions and to highlight its great significance for novel drug design/development.     

Catalytic mechanism of serine racemase from Dictyostelium discoideum

The eukaryotic serine racemase from Dictyostelium discoideum is a fold-type II pyridoxal 5′-phosphate (PLP)-dependent enzyme that catalyzes racemization and dehydration of both isomers of serine. In the present study, the catalytic mechanism and role of the active site residues of the enzyme were examined by site-directed mutagenesis. Mutation of the PLP-binding lysine (K56) to alanine abolished both serine racemase and dehydrase activities. Incubation of d- and l-serine with the resultant mutant enzyme, K56A, resulted in the accumulation of PLP-serine external aldimine, while less amounts of pyruvate, α-aminoacrylate, antipodal serine and quinonoid intermediate were formed. An alanine mutation of Ser81 (S81) located on the opposite side of K56 against the PLP plane converted the enzyme from serine racemase to l-serine dehydrase; S81A showed no racemase activity and had significantly reduced d-serine dehydrase activity, but it completely retained its l-serine dehydrase activity. Water molecule(s) at the active site of the S81A mutant enzyme probably drove d-serine dehydration by abstracting the α-hydrogen in d-serine. Our data suggest that the abstraction and addition of α-hydrogen to l- and d-serine are conducted by K56 and S81 at the si- and re-sides, respectively, of PLP.     

Evaluation of the E. coli d-serine ammonia lyase gene (Ec. dsdA) for use as a selectable marker in maize transformation

In this study, the d-serine ammonia lyase (dsdA) gene from Escherichia coli was evaluated as a selectable marker for maize transformation. Plants are incapable of utilizing the D-form of most amino acids, and d-serine has recently been demonstrated to be phytoinhibitory to plant growth. d-Serine ammonia lyase detoxifies d-serine via a substrate-specific reaction to pyruvate, ammonia, and water. d-Serine inhibits germination of isolated maize immature embryos and growth of embryogenic callus from wild-type plants at concentrations about approx. 2?C15 mM. Transgenic plants were recovered in the presence of d-serine in tissue culture media with dsdA as the selection marker at efficiencies comparable to using a mutated acetohydroxy acid synthase selection marker gene and selection in the presence of imidazolinone herbicides. Immature embryos infected with an Agrobacterium strain containing an acetohydroxy acid synthase gene construct without dsdA did not yield any transgenic events on the selection medium with 10 mM d-serine, indicating that d-serine provided selection tight enough to prevent escapes. Molecular analysis confirmed the integration of the dsdA gene into the genome of the transgenic plants. No adverse phenotypes were observed in the greenhouse, and expression of the dsdA marker had no affect on agronomic characteristics or grain yield in multi-location field trials. Seed compositional analysis demonstrated no significant differences in the contents of seed protein, starch, fatty acids, fiber, phytic acid, and free amino acids between transgenic and non-transgenic control plants. These data indicate that the dsdA gene is properly expressed in maize and the d-serine ammonia lyase (DSDA) enzyme functions appropriately to metabolize d-serine during in vitro selection. Preliminary safety assessments indicated that no adverse affects would be expected if humans were exposed to the DSDA protein in the diet from an allergenicity or toxicity perspective. The dsdA gene in combination with phytoinhibitory levels of d-serine represents a new and effective selectable marker system for maize transformation.     

Synthesis of 3-O-β-d-xylopyranosyl-l-serine (xylosylserine) andO-β-d-galactopyranosyl-(1-4)-O-β-d-xylopyranosyl-l-serine (galactosylxylosylserine) and use of the synthetic products for detection of galactosyltransferase I activity in rat liver

3-O-β-d-Xylopyranosyl-l-serine (xylosylserine) was synthesized by the following three-step procedure: 1) 2,3,4-tri-O-benzoyl-α-d-xylopyranosyl bromide (benzobromoxylose) was condensed withN-carbobenzoxy-l-serine benzyl ester using the silver triflate-collidine complex as promoter; 2) theN-carbobenzoxy and benzyl ester groups in the resultant glycoside were cleaved by transfer hydrogenation with palladium black as catalyst and ammonium formate as hydrogen donor; and 3) the benzoyl groups were removed with methanolic ammonia. Xylosylserine was obtained in an overall yield of 70%. O-β-d-Galactopyranosyl-(1-4)-O-β-d-xylopyranosyl-(1-3)-l-serine (galactosylxylosylserine) was also synthesized by this methodology and was characterized by 2-dimensional (2D) NMR spectroscopy techniques. The two serine glycosides (xylosylserine and galactosylxylosylserine) were used in detection and partial purification of galactosyltransferase I (UDP-d-galactose:d-xylose galactosyltransferase) from adult rat liver.     

Increasing effects of S-methyl-l-cysteine on the extracellular d-serine concentrations in the rat medial frontal cortex

In an in vivo dialysis experiment, the intra-medial frontal cortex infusion of a system A and Asc-1 transporter inhibitor, S-methyl-l-cysteine, caused a concentration-dependent increase in the dialysate contents of an endogenous coagonist for the N-methyl-d-aspartate (NMDA) type glutamate receptor, d-serine, in the cortical portion. These results suggest that these neutral amino acid transporters could control the extracellular d-serine signaling in the brain and be a target for the development of a novel threapy for neuropsychiatric disorders with an NMDA receptor dysfunction.     

d-Amino Acid-Induced Expression of d-Amino Acid Oxidase in the Yeast Schizosaccharomyces pombe

We investigated d-amino acid oxidase (DAO) induction in the popular model yeast Schizosaccharomyces pombe. The product of the putative DAO gene of the yeast expressed in E.?coli displayed oxidase activity to neutral and basic d-amino acids, but not to an l-amino acid or acidic d-amino acids, showing that the putative DAO gene encodes catalytically active DAO. DAO activity was weakly detected in yeast cells grown on a culture medium without d-amino acid, and was approximately doubled by adding d-alanine. The elimination of ammonium chloride from culture medium induced activity by up to eight-fold. l-Alanine also induced the activity, but only by about half of that induced by d-alanine. The induction by d-alanine reached a maximum level at 2?h cultivation; it remained roughly constant until cell growth reached a stationary phase. The best inducer was d-alanine, followed by d-proline and then d-serine. Not effective were N-carbamoyl-d,l-alanine (a better inducer of DAO than d-alanine in the yeast Trigonopsis variabilis), and both basic and acidic d-amino acids. These results showed that S. pombe DAO could be a suitable model for analyzing the regulation of DAO expression in eukaryotic organisms.     

Alteration of intrinsic amounts of d-serine in the mice lacking serine racemase and d-amino acid oxidase

For elucidation of the regulation mechanisms of intrinsic amounts of d-serine (d-Ser) which modulates the neuro-transmission of N-methyl-d-aspartate receptors in the brain, mutant animals lacking serine racemase (SRR) and d-amino acid oxidase (DAO) were established, and the amounts of d-Ser in the tissues and physiological fluids were determined. d-Ser amounts in the frontal brain areas were drastically decreased followed by reduced SRR activity. On the other hand, a moderate but significant decrease in d-Ser amounts was observed in the cerebellum and spinal cord of SRR knock-out (SRR^?/?) mice compared with those of control mice, although the amounts of d-Ser in these tissues were low. The amounts of d-Ser in the brain and serum were not altered with aging. To clarify the uptake of exogenous d-Ser into the brain tissues, we have determined the d-Ser of SRR^?/? mice after oral administration of d-Ser for the first time, and a drastic increase in d-Ser amounts in all the tested tissues was observed. Because both DAO and SRR are present in some brain areas, we have established the double mutant mice lacking SRR and DAO for the first time, and the contribution of both enzymes to the intrinsic d-Ser amounts was investigated. In the frontal brain, most of the intrinsic d-Ser was biosynthesized by SRR. On the other hand, half of the d-Ser present in the hindbrain was derived from the biosynthesis by SRR. These results indicate that the regulation of intrinsic d-Ser amounts is different depending on the tissues and provide useful information for the development of treatments for neuronal diseases.     

New insights on the role of free d-aspartate in the mammalian brain

Free d-aspartate (d-Asp) occurs in substantial amounts in the brain at the embryonic phase and in the first few postnatal days, and strongly decreases in adulthood. Temporal reduction of d-Asp levels depends on the postnatal onset of d-aspartate oxidase (DDO) activity, the only enzyme able to selectively degrade this d-amino acid. Several results indicate that d-Asp binds and activates N-methyl-d-aspartate receptors (NMDARs). Accordingly, recent studies have demonstrated that deregulated, higher levels of d-Asp, in knockout mice for Ddo gene and in d-Asp-treated mice, modulate hippocampal NMDAR-dependent long-term potentiation (LTP) and spatial memory. Moreover, similarly to d-serine, administration of d-Asp to old mice is able to rescue the physiological age-related decay of hippocampal LTP. In agreement with a neuromodulatory action of d-Asp on NMDARs, increased levels of this d-amino acid completely suppress long-term depression at corticostriatal synapses and attenuate the prepulse inhibition deficits produced in mice by the psychotomimetic drugs, amphetamine and MK-801. Based on the evidence which points to the ability of d-Asp to act as an endogenous agonist on NMDARs and considering the abundance of d-Asp during prenatal and early life, future studies will be crucial to address the effect of this molecule in the developmental processes of the brain controlled by the activation of NMDARs.     

d-Amino acids in brain neurotransmission and synaptic plasticity

Far from our initial view of d-amino acids as being limited to invertebrates, they are now considered active molecules at synapses of mammalian central and peripheral nervous systems, capable of modulating synaptic communication within neuronal networks. In particular, experimental data accumulated in the last few decades show that through the regulation of glutamatergic neurotransmission, d-serine influences the functional plasticity of cerebral circuitry throughout life. In addition, the modulation of NMDA-R-dependent signalling by d-aspartate has been demonstrated by pharmacological studies and after the targeted deletion of the d-aspartate-degrading enzyme. Considering the major contribution of the glutamatergic system to a wide range of neurological disorders such as schizophrenia, Alzheimer’s disease and amyotrophic lateral sclerosis, an improved understanding of the mechanisms of d-amino-acid-dependent neuromodulation will certainly offer new insights for the development of relevant strategies to treat these neurological diseases.     

Construction of an l-serine producing Escherichia coli via metabolic engineering

l-Serine is a nonessential amino acid, but plays a crucial role as a building block for cell growth. Currently, l-serine production is mainly dependent on enzymatic or cellular conversion. In this study, we constructed a recombinant Escherichia coli that can fermentatively produce l-serine from glucose. To accumulate l-serine, sdaA encoding the l-serine dehydratase, iclR encoding the isocitrate lyase regulator, and arcA encoding the aerobic respiration control protein were deleted in turn. In batch fermentation, the engineered E. coli strain YF-5 exhibited obvious l-serine accumulation but poor cell growth. To restore cell growth, aceB encoding the malate synthase was knocked out, and the engineered strain was then transformed with plasmid that overexpressed serA ^FR , serB, and serC genes. The resulting strain YF-7 produced 4.5 g/L l-serine in batch cultivation and 8.34 g/L l-serine in fed-batch cultivation.     

Pressor response to l-cysteine injected into the cisterna magna of conscious rats involves recruitment of hypothalamic vasopressinergic neurons

The sulfur-containing non-essential amino acid l-cysteine injected into the cisterna magna of adult conscious rats produces an increase in blood pressure. The present study examined if the pressor response to l-cysteine is stereospecific and involves recruitment of hypothalamic vasopressinergic neurons and medullary noradrenergic A1 neurons. Intracisternally injected d-cysteine produced no cardiovascular changes, while l-cysteine produced hypertension and tachycardia in freely moving rats, indicating the stereospecific hemodynamic actions of l-cysteine via the brain. The double labeling immunohistochemistry combined with c-Fos detection as a marker of neuronal activation revealed significantly higher numbers of c-Fos-positive vasopressinergic neurons both in the supraoptic and paraventricular nuclei and tyrosine hydroxylase containing medullary A1 neurons, of l-cysteine-injected rats than those injected with d-cysteine as iso-osmotic control. The results indicate that the cardiovascular responses to intracisternal injection of l-cysteine in the conscious rat are stereospecific and include recruitment of hypothalamic vasopressinergic neurons both in the supraoptic and paraventricular nuclei, as well as of medullary A1 neurons. The findings may suggest a potential function of l-cysteine as an extracellular signal such as neuromodulators in central regulation of blood pressure.     

Enantiomer-specific selection of amino acids

Dietary intake of l-amino acids impacts on several physiological functions, including the control of gastrointestinal motility, pancreatic secretion, and appetite. However, the biological mechanisms regulating behavioral predilections for certain amino acid types remain poorly understood. We tested the hypothesis that, in mice, the potency with which a given glucogenic amino acid increases glucose utilization reflects its rewarding properties. We have found that: (1) during long-, but not short-, term preference tests, l-alanine and l-serine were preferred over their d-enantiomer counterparts, while no such effect was observed for l-threonine vs. d-threonine; (2) these behavioral patterns were closely associated with the ability of l-amino acids to promote increases in respiratory exchange ratios such that those, and only those, l-amino acids able to promote increases in respiratory exchange ratios were preferred over their d-isomers; (3) these behavioral preferences were independent of gustatory influences, since taste-deficient Trpm5 knockout mice displayed ingestive responses very similar to those of their wild-type counterparts. We conclude that the ability to promote increases in respiratory exchange ratios enhances the reward value of nutritionally relevant amino acids and suggest a mechanistic link between substrate utilization and amino acid preferences.     

d-Aspartate acts as a signaling molecule in nervous and neuroendocrine systems

d-Aspartate (d-Asp) is an endogenous amino acid in the central nervous and reproductive systems of vertebrates and invertebrates. High concentrations of d-Asp are found in distinct anatomical locations, suggesting that it has specific physiological roles in animals. Many of the characteristics of d-Asp have been documented, including its tissue and cellular distribution, formation and degradation, as well as the responses elicited by d-Asp application. d-Asp performs important roles related to nervous system development and hormone regulation; in addition, it appears to act as a cell-to-cell signaling molecule. Recent studies have shown that d-Asp fulfills many, if not all, of the definitions of a classical neurotransmitter—that the molecule’s biosynthesis, degradation, uptake, and release take place within the presynaptic neuron, and that it triggers a response in the postsynaptic neuron after its release. Accumulating evidence suggests that these criteria are met by a heterogeneous distribution of enzymes for d-Asp’s biosynthesis and degradation, an appropriate uptake mechanism, localization within synaptic vesicles, and a postsynaptic response via an ionotropic receptor. Although d-Asp receptors remain to be characterized, the postsynaptic response of d-Asp has been studied and several l-glutamate receptors are known to respond to d-Asp. In this review, we discuss the current status of research on d-Asp in neuronal and neuroendocrine systems, and highlight results that support d-Asp’s role as a signaling molecule.     

Detection of d-amino acids in purified proteins synthesized in Escherichia coli

It has long been believed that amino acids comprising proteins of all living organisms are only of the l-configuration, except for Gly. However, peptidyl d-amino acids were observed in hydrolysates of soluble high molecular weight fractions extracted from cells or tissues of various organisms. This strongly suggests that significant amounts of d-amino acids are naturally present in usual proteins. Thus we analyzed the d-amino acid contents of His-tag-purified β-galactosidase and human urocortin, which were synthesized by Escherichia coli grown in controlled synthetic media. After acidic hydrolysis for various times at 110°C, samples were derivatized with 4-fluoro-7-nitro-2, 1, 3-benzoxadiazole (NBD-F) and separated on a reverse-phase column followed by a chiral column into d- and l-enantiomers. The contents of d-enantiomers of Ala, Leu, Phe, Val, Asp, and Glu were determined by plotting index d/(d + l) against the incubation time for hydrolysis and extrapolating the linear regression line to 0 h to eliminate the effect of racemization of amino acids during the incubation. Significant contents of d-amino acids were reproducibly detected, the d-amino acid profile being specific to an individual protein. This finding indicated the likelihood that d-amino acids are in fact present in the purified proteins. On the other hand, the d-amino acid contents of proteins were hardly influenced by the addition of d- or l-amino acids to the cultivation medium, whereas intracellular free d-amino acids sensitively varied according to the extracellular conditions. The origin of these d-amino acids detected in proteins was discussed.     

Central administration of l- and d-aspartate attenuates stress behaviors by social isolation and CRF in neonatal chicks

Intracerebroventricular (i.c.v.) administration of l-aspartate (l-Asp) attenuates stress responses in neonatal chicks, but the mechanism has not been clarified. In the present study, three behavioral experiments were carried out under socially isolated stressful conditions exacerbated by the use of corticotrophin-releasing factor (CRF). In Experiment 1, i.c.v. injection of l-Asp attenuated behavioral stress responses (distress vocalization and active wakefulness) in a dose-dependent manner. Furthermore, l-Asp increased time spent standing/sitting motionless with eyes open and sitting motionless with head dropped (sleeping posture) in comparison with the group receiving CRF alone. In Experiment 2, i.c.v. injection of d-Asp dose-dependently decreased the number of distress vocalizations and the amount of time spent in active wakefulness. d-Asp increased the time spent standing/sitting motionless with eyes open compared with the group receiving CRF alone. In Experiment 3, we directly compared the effect of l-Asp with that of d-Asp. Both l- and d-Asp induced sedative effects under an acutely stressful condition. However, l-Asp, but not d-Asp, increased the time spent in a sleeping posture. These results indicate that both l- and d-Asp, when present in the brain, could induce a sedative effect, while the mechanism for hypnosis in neonatal chicks may be different for l-Asp in comparison with d-Asp.