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d-Aspartate Prevents Corticostriatal Long-Term Depression and Attenuates Schizophrenia-Like Symptoms Induced by Amphetamine and MK-801

Since their discovery in the mammalian CNS, d-aspartate and d-serine have aroused a strong interest with regard to their role as putative neuromodulatory molecules. Whereas the functional role of d-serine as an endogenous coagonist of NMDA receptors (NMDARs) has been elucidated, the biological significance of d-aspartate in the brain is still mostly unclear. In the present study, we demonstrated that nonphysiological high levels of d-aspartate (1) increased in vivo NMDAR activity, (2) attenuated prepulse inhibition deficits induced by amphetamine and MK-801 [(+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]-cyclohepten-5,10-imine hydrogen maleate], (3) produced striatal adaptations of glutamate synapses resembling those observed after chronic haloperidol treatment, and (4) enhanced hippocampal NMDAR-dependent memory. This evidence was obtained using two different experimental strategies that produced an abnormal increase of endogenous d-aspartate levels in the mouse: a genetic approach based on the targeted deletion of the d-aspartate oxidase gene and a pharmacological approach based on oral administration of d-aspartate. This work provides in vivo evidence of a neuromodulatory role exerted by d-aspartate on NMDAR signaling and raises the intriguing hypothesis that also this d-amino acid, like d-serine, could be used as a therapeutic agent in the treatment of schizophrenia-related symptoms.

Increased levels of d-aspartate in the hippocampus enhance LTP but do not facilitate cognitive flexibility.

In the present study, we demonstrate a direct role for d-aspartate in regulating hippocampal synaptic plasticity. These evidences were obtained using two different experimental strategies which enabled a non-physiological increase of endogenous d-aspartate levels in the mouse hippocampus: a genetic approach based on the targeted deletion of d-aspartate oxidase gene and another based on the oral administration of d-aspartate. Overall, our results indicate that increased d-aspartate content does not affect basal properties of synaptic transmission but enhances long-term potentiation in hippocampal slices from both genetic and pharmacological animal models. Besides electrophysiological data, behavioral analysis suggests that altered levels of d-aspartate in the hippocampus do not perturb basal spatial learning and memory abilities, but may selectively interfere with the dynamic NMDAR-dependent processes underlying cognitive flexibility.

The role and molecular mechanism of D-aspartic acid in the release and synthesis of LH and testosterone in humans and rats

BackgroundD-aspartic acid is an amino acid present in neuroendocrine tissues of invertebrates and vertebrates, including rats and humans. Here we investigated the effect of this amino acid on the release of LH and testosterone in the serum of humans and rats. Furthermore, we investigated the role of D-aspartate in the synthesis of LH and testosterone in the pituitary and testes of rats, and the molecular mechanisms by which this amino acid triggers its action.MethodsFor humans: A group of 23 men were given a daily dose of D-aspartate (DADAVIT®) for 12 days, whereas another group of 20 men were given a placebo. For rats: A group of 10 rats drank a solution of either 20 mM D-aspartate or a placebo for 12 days. Then LH and testosterone accumulation was determined in the serum and D-aspartate accumulation in tissues. The effects of D-aspartate on the synthesis of LH and testosterone were gauged on isolated rat pituitary and Leydig cells. Tissues were incubated with D-aspartate, and then the concentration (synthesis) of LH and cGMP in the pituitary and of testosterone and cAMP in the Leydig cells was determined.ResultsIn humans and rats, sodium D-aspartate induces an enhancement of LH and testosterone release. In the rat pituitary, sodium D-aspartate increases the release and synthesis of LH through the involvement of cGMP as a second messenger, whereas in rat testis Leydig cells, it increases the synthesis and release of testosterone and cAMP is implicated as second messenger. In the pituitary and in testes D-Asp is synthesized by a D-aspartate racemase which convert L-Asp into D-Asp. The pituitary and testes possesses a high capacity to trapping circulating D-Asp from hexogen or endogen sources.ConclusionD-aspartic acid is a physiological amino acid occurring principally in the pituitary gland and testes and has a role in the regulation of the release and synthesis of LH and testosterone in humans and rats.

Thyroid hormones and D-aspartic acid, D-aspartate oxidase, D-aspartate racemase, H2O2, and ROS in rats and mice.

Total concentrations of thyroid hormones T3 and T4, and of their free forms, FT3 and FT4, D‐aspartic acid (D‐Asp), D‐aspartate oxidase (D‐AspO), D‐aspartate racemase, H2O2, and ROS (reactive oxygen species) were determined in rats and mice. T3 and T4 were 1 and 50 ng/ml, respectively, in serum, and 750 and 40000 ng/g, respectively, in thyroid. Concentrations of the free forms FT3 and FT4 were ca. 250 times lower than their respective total concentrations. The endogenous content of D‐Asp in thyroid gland was ca. 100 nmol/g tissue, whereas the activity of D‐AspO was ca. 80 units/mg thyroid, and that of D‐aspartate racemase was ca. 15 units/mg thyroid. H2O2 Concentration in rat and mouse thyroid gland was ca. 290 pmol/g thyroid, and the concentration of ROS was ca. 10 pmol/DCF/min/mg protein. H2O2 is essential for the iodination of the tyrosyl residues to produce mono‐ and diiodotyrosine that are the precursors for the synthesis of T3 and T4. Production of H2O2 in thyroid glands occurs by oxidation of endogenous D‐Asp by D‐AspO (D‐Asp+O2+H2O→α‐oxaloacetate+NH3+H2O2). D‐Aspartate racemase catalyzes the in vivo production of D‐Asp from L‐Asp. Thus, interaction of endogenous D‐Asp, D‐AspO, and D‐aspartate racemase in thyroid gland constitutes an additional biochemical pathway for the production of H2O2 and consequently for the synthesis of thyroid hormones.

Characterization and putative role of a type I gonadotropin-releasing hormone in the cephalochordate amphioxus.

GnRH, originally isolated from mammalian hypothalamus, is a key player in the control of vertebrate reproduction. Employing reverse-phase chromatography, we purified a peptide of relative molecular mass of 1182.60 Da from the cephalochordate amphioxus Branchiostoma lanceolatum. We found that its amino acid sequence (pGlu-His-Trp-Ser-Tyr-Gly-Leu-Arg-Pro-Gly-NH(2)) was identical to that of mammalian GnRH. The highest concentrations (4.04 +/- 0.3 microg/g tissue), localized in the anterior part of the body, occurred in November, a time when amphioxus gonads prepare for the seasonal spawning. Furthermore, the biological activity of amphioxus GnRH was investigated by examining its capability to elicit LH release from the rodent pituitary gland. The origins of GnRH can be traced back to the origins of chordates. The seasonal variations of amphioxus GnRH also suggest an ancient role of this peptide in the control of reproduction in chordates, even before the evolution of a proper pituitary gland.

Elevated forebrain excitatory l-glutamate, l-aspartate and d-aspartate in the Naples high-excitability rats

The Naples high-excitability (NHE) rats are thought to model the mesocortical variant of attention-deficit hyperactivity disorder (ADHD). The aim of this study was to investigate forebrain level of L-glutamate, L-aspartate and D-aspartate, in NHE vs. Naples random bred (NRB) control rats. Thus, prepuberal NHE and NRB rats were daily handled in the 5th and 6th week of postnatal life. Then rats were exposed to two spatial novelties i.e. a Làt and a Olton maze for 10 min. Amino acids were detected by HPLC in the prefrontal cortex (PFC), striatum (STR), hippocampus (HPC) and hypothalamus (HYP). Results indicate that all amino acids were higher in NHE than in NRB rats. This, in turn, may explain the behavioural hyperactivity and attention deficit of this animal model of ADHD.

N-Methyl-D-aspartic Acid (NMDA) in the nervous system of the amphioxus Branchiostoma lanceolatum

BackgroundNMDA (N-methyl-D-aspartic acid) is a widely known agonist for a class of glutamate receptors, the NMDA type. Synthetic NMDA elicits very strong activity for the induction of hypothalamic factors and hypophyseal hormones in mammals. Moreover, endogenous NMDA has been found in rat, where it has a role in the induction of GnRH (Gonadotropin Releasing Hormone) in the hypothalamus, and of LH (Luteinizing Hormone) and PRL (Prolactin) in the pituitary gland.ResultsIn this study we show evidence for the occurrence of endogenous NMDA in the amphioxus Branchiostoma lanceolatum. A relatively high concentration of NMDA occurs in the nervous system of this species (3.08 ± 0.37 nmol/g tissue in the nerve cord and 10.52 ± 1.41 nmol/g tissue in the cephalic vesicle). As in rat, in amphioxus NMDA is also biosynthesized from D-aspartic acid (D-Asp) by a NMDA synthase (also called D-aspartate methyl transferase).ConclusionGiven the simplicity of the amphioxus nervous and endocrine systems compared to mammalian, the discovery of NMDA in this protochordate is important to gain insights into the role of endogenous NMDA in the nervous and endocrine systems of metazoans and particularly in the chordate lineage.

Differential prepuberal handling modifies behaviour and excitatory amino acids in the forebrain of the Naples High-Excitability rats

Naples High-Excitability (NHE) rats model the mesocortical variant of Attention-Deficit Hyperactivity Disorder (ADHD). Recently, a high level of excitatory amino acids (EAA) has been found in the forebrain of NHE rats. The aim of this study was to verify the effect of postnatal stimulation in prepuberal rats on forebrain EAA. Thus, prepuberal NHE and Naples Random Bred (NRB) control rats were daily handled (PS) or they were left undisturbed throughout (NO-PS). One hour after the last stimulation, PS and NO-PS rats were exposed to a spatial novelty in a Làt-maze and one day later to a non-reinforced Olton maze. In both tests the horizontal (HA) and vertical (frequency - VA and duration of rearing - RD) components of behaviour indexed activity and non-selective attention (NSA). Moreover, in the Olton maze the position of the number of arms visited before first repetition (FE) and to criterion (NVTC), indexed selective spatial attention (SSA). Amino acids were detected by HPLC in prefrontal cortex (PFC), striatum (STR), hippocampus (HPC) and hypothalamus (HYP). Results indicate that (i) in the Làt-maze, only for HA, NO-PS NHE rats were more active than PS, (ii) in the Olton maze NO-PS rats of both lines showed shorter rearing durations than PS, (iii) EAA level was higher in NHE than in NRB rats and (iv) NO-PS vs. PS treatment increased level of EAA across the forebrain in both rat lines. In contrast in NHE NO-PS rats L-glutamate (L-Glu) decreased in HYP and L-aspartate (L-Asp) decreased in HPC. In conclusion, postnatal stimulation in prepuberal rats significantly affects forebrain excitatory amino acids and behaviour in NHE line. Thus EAA are modulated by genetic determinants and environmental (epigenetic) factors.