Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: CAS:6893-26-1 (glutamate)
73,096 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have cloned and characterized human genes (GAD1 and GAD2) encoding the two human glutamate decarboxylases, GAD67 and GAD65. The coding region of the GAD65 gene consists of 16 exons, spanning more than 79 kb of genomic DNA. Exon 1 contains the 5' untranslated region of GAD65 mRNA, and exon 16 specifies the protein's carboxy terminal and at least part of the mRNA's 3' untranslated sequence. Similarly, the coding region of the GAD67 gene consists of 16 exons, spread over more than 45 kb of genomic DNA. The GAD67 gene contains an additional exon (exon 0) that, together with part of exon 1, specifies the 5' untranslated region of GAD67 mRNA. Exon 16 specifies the entire 3' untranslated region of GAD67 mRNA. Exons 1-3 encode the most divergent region of GAD65 and GAD67. The remaining exon-intron boundaries occur at identical positions in the two cDNAs, suggesting that they derive from a common ancestral GAD gene.
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PMID:The exon-intron organization of the genes (GAD1 and GAD2) encoding two human glutamate decarboxylases (GAD67 and GAD65) suggests that they derive from a common ancestral GAD. 808 91

There is now ample evidence for long-term malfunctioning within five different brain GABAergic pathways in a monkey model for tardive dyskinesia (TD). Three of these GABA connections (GPe-STN, CP-SNr, and CP-GPi) are chronically downregulated during neuroleptic treatment and after some years they do not seem to regain their normal activity, even when the neuroleptics are discontinued. The persistent downregulation of these three GABA connections, evidenced by depressions of terminal GAD activity and GABA levels, appears to be a conceivable mechanism behind tardive parkinsonism (TP), often reported to coexist with TD in the clinic. The TD patients' well-known lack of awareness of their symptoms may be due to their parkinsonian "sensory neglect." Another two GABA malfunctioning connections were found in our monkey model: SNr-VA/VL and GPi-VA/VL. These pathways are upregulated during chronic neuroleptic treatment, partly due to an elevated glutamate release within subthalamofugal pathways. This chronic glutamatergic hyperactivity may have acted via an excitotoxic mechanism and consequently both GPi and VA/VL had a low synaptic activity in our dyskinetic monkeys, as measured by 2-deoxyglucose uptake, even 4 months after the last neuroleptic dose. It is hypothesized that TD may be due to an excitotoxic lesion of the inhibitory GABAergic VA/VL afferents, while TP has to do with persistent malfunctioning of downregulated SNr and GPi afferents.
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PMID:An animal model for coexisting tardive dyskinesia and tardive parkinsonism: a glutamate hypothesis for tardive dyskinesia. 809 82

Kinetics of uptake and release, rates of oxidation of glutamate and aspartate, activities of the enzymes of glutamate metabolism were studied in the mitochondrial, synaptosomal and cytosolic preparations of rat cerebellum. Transport of these amino acids into mitochondria was by a single low affinity carrier, whereas in synaptosomes both high and low affinity uptake systems were observed. The depolarization induced release of these amino acids from nerve terminals was observed to be calcium dependent. Mitochondria oxidized both these two amino acids at a higher rate than synaptosomes and the oxidation in cytosol was very minimal. Transamination appears to be the major reaction for the metabolism of glutamate and aspartate. Activities of GDH, GLNSE and GABA-T were highest in mitochondria, whereas activities of GS and GAD were highest in cytosol and synaptosomes respectively.
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PMID:Uptake, release and metabolism of glutamate and aspartate by rat cerebellar subcellular preparations. 809 41

Homogenates of pancreatic islets catalyzed breakdown of L-glutamate to GABA with a rate of 0.24 +/- 0.04 nmol.min-1 x mg-1 protein at 37 degrees C. The formation of GABA was stimulated by addition of pyridoxal phosphate in the range 0.05-1 microM (0.97 +/- 0.02 nmol.min-1 x mg protein-1 at a saturating cofactor concentration), which indicates that the process was catalyzed by glutamic acid decarboxylase. The half-maximal effect was obtained with 0.1 microM PLP. Kinetic analyses of the results showed that the Vmax and Km for the reaction were 1.12 nmol.min-1 x mg protein-1 and 0.66 mM, respectively. The pH optimum was 7.0. Subcellular fractionation revealed that 51% of GAD activity was present in the cytosol, 17% in microsomes, 9% in secretory granules, 5% in mitochondria, and 11% in cell debris. Comparison of the kinetic properties of the cytosolic and microsomal forms of the enzyme showed that their Km for glutamate was the same, but that the cytosolic GAD had a lower Km for PLP. GABA synthesis in the nominal absence of PLP was enhanced by malate (twofold increase at 5 mM) and citrate (threefold increase at 5 mM), but was unaffected by ATP and chloride. However, if the islet homogenate was prepared and incubated in the presence of PLP, neither malate nor citrate influenced enzyme activity. Aspartate and AOA were powerful inhibitors of glutamate breakdown. Freshly isolated islets contained approximately 4 mM GABA, whereas the concentration was < 0.1 mM in whole pancreas.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:GABA production in rat islets of Langerhans. 837 91

The excitatory, glutamatergic granule cells of the hippocampal dentate gyrus are presumed to play central roles in normal learning and memory, and in the genesis of spontaneous seizure discharges that originate within the temporal lobe. In localizing the two GABA-producing forms of glutamate decarboxylase (GAD65 and GAD67) in the normal hippocampus as a prelude to experimental epilepsy studies, we unexpectedly discovered that, in addition to its presence in hippocampal nonprincipal cells, GAD67-like immunoreactivity (LI) was present in the excitatory axons (the mossy fibers) of normal dentate granule cells of rats, mice, and the monkey Macaca nemestrina. Using improved immunocytochemical methods, we were also able to detect GABA-LI in normal granule cell somata and processes. Conversely, GAD65-LI was undetectable in normal granule cells. Perforant pathway stimulation for 24 hours, which evoked population spikes and epileptiform discharges in both dentate granule cells and hippocampal pyramidal neurons, induced GAD65-, GAD67-, and GABA-LI only in granule cells. Despite prolonged excitation, normally GAD- and GABA-negative dentate hilar neurons and hippocampal pyramidal cells remained immunonegative. Induced granule cell GAD65-, GAD67-, and GABA-LI remained elevated above control immunoreactivity for at least 4 days after the end of stimulation. Pre-embedding immunocytochemical electron microscopy confirmed that GAD67- and GABA-LI were induced selectively within granule cells; granule cell layer glia and endothelial cells were GAD- and GABA-immunonegative. In situ hybridization after stimulation revealed a similarly selective induction of GAD65 and GAD67 mRNA in dentate granule cells. Neurochemical analysis of the microdissected dentate gyrus and area CA1 determined whether changes in GAD- and GABA-LI reflect changes in the concentrations of chemically identified GAD and GABA. Stimulation for 24 hours increased GAD67 and GABA concentrations sixfold in the dentate gyrus, and decreased the concentrations of the GABA precursors glutamate and glutamine. No significant change in GAD65 concentration was detected in the microdissected dentate gyrus despite the induction of GAD65-LI. The concentrations of GAD65, GAD67, GABA, glutamate and glutamine in area CA1 were not significantly different from control concentrations. These results indicate that dentate granule cells normally contain two "fast-acting" amino acid neurotransmitters, one excitatory and one inhibitory, and may therefore produce both excitatory and inhibitory effects. Although the physiological role of granule cell GABA is unknown, the discovery of both basal and activity-dependent GAD and GABA expression in glutamatergic dentate granule cells may have fundamental implications for physiological plasticity presumed to underlie normal learning and memory. Furthermore, the induction of granule cell GAD and GABA by afferent excitation may constitute a mechanism by which epileptic seizures trigger compensatory interictal network inhibition or GABA-mediated neurotrophic effects.
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PMID:Basal expression and induction of glutamate decarboxylase and GABA in excitatory granule cells of the rat and monkey hippocampal dentate gyrus. 888 46

The purpose of this study was to survey distribution and density of the barosensitive and chemosensitive neurons in the medulla of rats anesthetized with fentanyl/midazolam, using immunohistochemical methods. After stimulation of the arterial baroreceptor or the chemoreceptor, we identified c-Fos-labeled neurons with immunoreactions to antisera of glutamate. PNMT, GAD and calbindin in the nucleus tractus solitarii (NTS) and the ventrolateral medulla (VLM). The double labeled neurons were located in the medical part of the NTS, and in the lateral part of the paragigantocellular reticular nucleus and the ventral division of the ambiguus nucleus. Main findings were as follows: (1) No significant difference was found in distribution and density of glutamatergic, adrenergic and calbindin-containing neurons between the barosensitive and chemosensitivie types; (2) a few GABAergic neurons were distributed almost evenly in the NTS and VLM, and in these neurons the barosensitive type outnumbered the chemosensitive one; (3) glutamatergic and calbindin-containing neurons were dominant in the NTS; adrenergic neurons in the VLM. (4) as for the adrenergic neurons in the NTS, the chemosensitive type significantly outnumbered the barosensitive one. This study showed that distribution and density of the barosensitive neurons, either glutamatergic, adrenergic, or calbindin-containing neurons, overlapped with those of the chemosensitive corresponding neurons, suggesting presence of the neural matrix of the cardiopulmonary interaction. Exceptionally, the number of the barosensitive GABAergic neurons was significantly larger than that of the chemosensitive GABAergic ones.
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PMID:Barosensitive and chemosensitive neurons in the rat medulla: a double labeling study with c-Fos/glutamate, GAD, PNMT and calbindin. 891 49

We have previously reported direct glutamate (Glu) synapses upon GnRH-containing neurons in the primate hypothalamus, and extensive interactions between Glu and aminobutyric acid (GABA) neurons in areas associated with reproductive function. Both Glu and GABA are known to affect peripubertal GnRH neurohormone release, but their relative roles remain unclear. In a developmental survey, estrogen receptors (ER) and progesterone receptors (PR) were virtually undetectable after immunostaining the hypothalamus of prepubertal monkeys, but were clearly evident in neurons of adults. We hypothesized, therefore, that Glu and GABA neurons which develop ER or PR expression during puberty may participate in reactivation of the hypothalamic-pituitary-gonadal axis. To identify those neurons in midpubertal female cynomolgus monkeys, we performed immunofluorescence staining for ER or for PR in separate sets of hypothalamic sections, and then immunostained for Glu or for glutamate decarboxylase (GAD, to identify GABA neurons) using a contrasting fluorophore. ER and PR were localized in the cytoplasm and nuclei of Glu and GAD neurons in nine hypothalamic and related brain regions. Quantitation revealed intranuclear ER in an average of 80% of the Glu neurons in all regions analyzed, and an average of 84% of the GAD neurons in all regions except the supraoptic nucleus (28%). Intranuclear PR expression was more variable, occurring in an average of 93% of the Glu neurons in seven regions, but in only 41% in the medial preoptic area, and 0% in the arcuate-periventicular zone. In addition, while intranuclear PR was seen in 96% of the GAD neurons in the septum, it appeared in 67% of the GAD neurons in the paraventricular nucleus, 47% in the medial preoptic area, 40% in the periventricular zone, and was absent from neurons in the supraoptic nucleus and mammillary bodies. In summary, certain subpopulations of Glu and GABA neurons in principal hypothalamic regions of the female monkey express ER and PR at midpuberty. Taken together with previous findings, these results suggest that Glu and GABA neurons which become sensitive to steroid hormones may help regulate GnRH neurohormone release and promote the onset of puberty. Since neuronal expression of ER or PR connotes sensitivity to gonadal feedback, and intranuclear translocation signals transcriptional activation, these results provide insights into the specific neuronal events involved in the peripubertal transition in primates.
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PMID:Expression of estrogen and progesterone receptors in glutamate and GABA neurons of the pubertal female monkey hypothalamus. 915 63

The bipolar cells in vertebrate retinas are considered to be excitatory in nature and use L-glutamate as their neurotransmitter. Our earlier studies have provided evidence demonstrating that a small but significant population of orthotopic bipolar cells in salamander retina may be gamma-aminobutyric acid (GABA)ergic. In this work, the stratification levels of axon terminals in the inner plexiform layer (IPL) of single L-glutamic acid decarboxylase-immunoreactive (GAD-IR) and GABA-immunoreactive (GABA-IR) bipolar cells in the salamander retinal slices were studied. GAD-IR and GABA-IR bipolar cells marked by a fluorescent probe, Texas Red, were injected with Lucifer Yellow (LY) through a patch pipette under visual control. A total number of 42 GAD-IR bipolar cells in 24 slices and 84 GABA-IR bipolar cells in 56 slices were injected. Among these, terminals of nine GAD-IR bipolar cells and 22 GABA-IR bipolar cells were sufficiently filled with LY for determination of the stratification levels in the IPL. The stratification patterns and levels of GAD-IR and GABA-IR bipolar cells were very similar. GAD-IR and GABA-IR orthotopic type I and type II bipolar cells (soma located in the most distal or middle of the inner nuclear layer [INL], respectively), had their axon terminals stratified in sublamina a and sublamina b of the IPL with comparable frequency. Axonal processes were restricted largely to either the distal or the proximal region within sublaminae a and b. In addition, three of the bipolar cells had their terminals located in the middle region of the IPL. The similarities of stratification patterns and levels between GAD-IR and GABA-IR type I and type II bipolar cells indicate that they represent the same population of presumed GABAergic bipolar cells. Based on comparative stratifications of GABA bipolar cells reported here and those derived from electrophysiological studies (Hensley et al. [1993] J. Neurophysiol. 69:2086-2098), it is suggested that putative GABAergic bipolar cells represent cone-dominated and rod-dominated ON- and OFF-bipolar cells and that they subserve a broad role in the ON- and OFF-visual pathways in the retina.
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PMID:L-glutamic acid decarboxylase- and gamma-aminobutyric acid-immunoreactive bipolar cells in tiger salamander retina are of ON- and OFF-response types as inferred from Lucifer Yellow injection. 930 11

Replication-defective Moloney murine leukemia virus expressing the GAD67 gene under the control of the GFAP promoter was produced using selected clones of a fibroblast-packaging cell line. A spontaneously immortalized astrocyte cell line was infected with this virus and cellular clones expressing GAD67 selected. Astrocyte and fibroblast clones expressed functional GAD (detected by glutamic acid decarboxylation), but only fibroblasts were able to also produce GABA in the extracellular medium. When exposed to 200 microM glutamate, despite an observed difference in the rates of glutamate accumulation in control and GAD67-expressing astrocytes, similar proportions of glutamate taken up were detected. In GAD67-expressing astrocytes, the glutamate was mainly converted into GABA, suggesting GAD transgene activity to be dominant over other glutamate metabolic pathways, such as glutamine synthetase and glutamate dehydrogenase. Moreover, rapid GABA release into the cell medium was also observed, suggesting the involvement of reverse GABA transporters. The use of the GFAP promoter might be able to take advantage of its activation in response to factors inducing reactive gliosis observed in pathological insults. GAD67-expressing astrocytes might therefore be used for future grafting in pathological situations in which an excess of glutamate results in neuronal dysfunction or cell death.
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PMID:Glutamate-modulated production of GABA in immortalized astrocytes transduced by a glutamic acid decarboxylase-expressing retrovirus. 943 90

High-affinity uptake of glutamate from the synaptic cleft plays a crucial role in regulating neuronal activity in physiological and pathological conditions. We have used affinity-purified specific polyclonal antibodies raised against a synthetic peptide corresponding to the C-terminal region of rabbit and rat EAAC1, a glutamate (Glu) transporter believed to be exclusively neuronal, to investigate its cellular and subcellular localization and whether it is expressed exclusively in glutamatergic cells of infragranular layers, as suggested by previous studies. Light microscopic studies revealed that EAAC1 immunoreactivity (ir) is localized to neurons and punctate elements in the neuropil. EAAC1-positive neurons were more numerous in layers II-III and V-VI, i.e. throughout all projection layers. Most EAAC1-positive neurons were pyramidal, although nonpyramidal cells were also observed. Some EAAC1-positive non-pyramidal neurons stained positively with an antiserum to GAD, thus demonstrating that EAAC1 is not confined to glutamatergic neurons. Non-neuronal EAAC1-positive cells were also observed in the white matter, and some of them stained positively with an antiserum to GFAP. Ultrastructural studies showed that EAAC1-ir was in neuronal cell bodies, dendrites and dendritic spines, but not in axon terminals, i.e. exclusively postsynaptic. Analysis of the type of axon terminals synapsing on EAAC1-ir profiles showed that 97% of them formed asymmetric contacts, thus indicating that EAAC1 is located at the very sites of excitatory amino acid release. Unexpectedly, EAAC1-ir was also found in a few astrocytic processes located in both the gray and the white matter. The localization of EAAC1 may explain the pathological symptoms that follow EAAC knockout (seizures and mild toxicity), as seizures could be due to the loss of EAAC1-mediated fine regulation of neuronal excitability at axodendritic and axospinous synapses, whereas the mild toxicity may be related to the functional inactivation of astrocytic EAAC1.
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PMID:EAAC1, a high-affinity glutamate tranporter, is localized to astrocytes and gabaergic neurons besides pyramidal cells in the rat cerebral cortex. 954 90


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