about
Tumor necrosis factor alpha: a link between neuroinflammation and excitotoxicityCurrents through single glutamate receptor channels in outside-out patches from rat cerebellar granule cellsThe anticonvulsant MK-801 is a potent N-methyl-D-aspartate antagonistThe glutamate storyQuantitative studies on some antagonists of N-methyl D-aspartate in slices of rat cerebral cortexPrevention by NMDA receptor antagonists of the centrally-evoked increases of cardiac inotropic responses in rabbitsThe N-terminal domain of GluR6-subtype glutamate receptor ion channelsCrystal Structures of the Glutamate Receptor Ion Channel GluK3 and GluK5 Amino-Terminal DomainsStructure and Assembly Mechanism for Heteromeric Kainate ReceptorsConformational Analysis of NMDA Receptor GluN1, GluN2, and GluN3 Ligand-Binding Domains Reveals Subtype-Specific CharacteristicsStructural Insights into Competitive Antagonism in NMDA ReceptorsStructural basis of kainate subtype glutamate receptor desensitization.Glutamate stimulates inositol phosphate formation in striatal neuronesA new type of glutamate receptor linked to inositol phospholipid metabolismExcitatory amino acid receptors and depolarization-induced Ca2+ influx into hippocampal slicesCharacterization of ionotropic glutamate receptors in human lymphocytesExcitant activity of methyl derivatives of quinolinic acid on rat cortical neuronesPOSTER COMMUNICATIONSAn update of the classical and novel methods used for measuring fast neurotransmitters during normal and brain altered functionNMDA as well as non-NMDA receptor antagonists can prevent the phase-shifting effects of light on the circadian system of the golden hamster.GABAergic modulation of inferior colliculus excitability: role in the ethanol withdrawal audiogenic seizuresHPLC determination of acidic D-amino acids and their N-methyl derivatives in biological tissues.Synaptic transmission between rat cerebellar granule and Purkinje cells in dissociated cell culture: effects of excitatory-amino acid transmitter antagonistsBlock of N-methyl-D-aspartate-activated current by the anticonvulsant MK-801: selective binding to open channels.Rapid desensitization of glutamate receptors in vertebrate central neurons.Structure and synthesis of a potent glutamate receptor antagonist in wasp venom.Upregulation of glutamate receptors in rat cerebral cortex with neuronal migration disordersL-glutamate-induced depolarization in solitary photoreceptors: a process that may contribute to the interaction between photoreceptors in situ.Food toxins, ampa receptors, and motor neuron diseases.Modulation of the N-methyl-D-aspartate channel by extracellular H+.Fungal homoserine kinase (thr1Delta) mutants are attenuated in virulence and die rapidly upon threonine starvation and serum incubationConcanavalin A selectively reduces desensitization of mammalian neuronal quisqualate receptors.Puberty in monkeys is triggered by chemical stimulation of the hypothalamus.Unique properties of non-N-methyl-D-aspartate excitatory responses in cultured purkinje neuronsGlutamate transporter EAAC-1-deficient mice develop dicarboxylic aminoaciduria and behavioral abnormalities but no neurodegeneration.Current hypotheses on sigma receptors and their physiological role: possible implications in psychiatry.Loss of hippocampal CA3 pyramidal neurons in mice lacking STAM1.Glycine activated ion channel subunits encoded by ctenophore glutamate receptor genes.The IGF-derived tripeptide Gly-Pro-Glu is a weak NMDA receptor agonistGlycine-site antagonists and stroke.
P2860
Q21284512-47215B87-2D94-4D7B-8FC3-E671FCDA8CB1Q24532920-BBE577A1-1D81-4A41-BBFB-1934510CF811Q24629716-63015EBB-1C3A-42D3-90D3-608A7E975C64Q24670299-499D5145-9525-4D1E-9838-E4A539D24258Q24682445-4FC30A63-C227-4CEB-A15A-7BE956BBE37EQ27469178-887C96E7-FAEE-4CAF-B0F3-09654C3BC73DQ27655599-53674DD7-AEB0-4184-8B9E-23238E9CAC49Q27665081-D24F44E4-B6A6-4F03-B406-DCCEABAE44F3Q27671015-B325DE23-86C2-4C4D-A7C4-6ABB34736F57Q27679791-503E2D2F-7930-4D6F-AF77-EC885AFF8669Q27681450-D285E4F7-8324-405E-80BE-5F11054FE58FQ27727973-FF667061-D58F-4A19-8E83-891E44C3BD26Q28282165-1C10785C-110B-47E3-8C3E-787518AD83D8Q28282769-407B40D8-B573-4117-BB7E-B4F2E4B92092Q28304768-2A6C4C96-C9E1-4D25-96A1-380C0188071AQ28343936-0777AD52-4664-42F7-9ADA-B96A6F453132Q28366851-78994A55-8DAA-478A-AC6F-B1414E2E9A63Q29031985-B9BBFF3D-E192-4FFB-9AB3-E75455CC6B7CQ30410156-62918691-1EF4-49D5-93B1-C9B10F49AFE2Q30437822-4262E33C-079E-41C2-B709-BE52DB0EF098Q30477994-D1C4758F-9320-433A-85F6-C9439504D8B9Q33416995-17598E2A-6643-44F6-9400-5814E7D8E6E9Q33551362-8585D81F-A19B-4A5D-9718-D1C6B17211BCQ33554934-C8931EB8-5A0C-437D-8C4B-CA872442B24BQ33568172-3F80E24D-CC5F-401B-98BE-97E331A4D294Q33586627-B8C1A478-9207-466E-A2AB-6BA19A68BD54Q33631592-0717D9A2-4206-4287-A7D5-DB1A3AA8250BQ33633492-6D5DD450-DD07-445B-AD4E-5E8A717504E5Q33719813-1336A263-FDFC-4BC2-B52F-93B90C9B14E2Q33755785-86B34ED0-580D-40C6-95D9-644BC22B446AQ33827338-5F0827E1-CC95-4D5F-A886-17A2B1808843Q33839007-4A40C01A-731E-4B89-91FE-C2213F565B20Q33848959-7CD4A1EC-19C9-4060-8507-02C2117C2DFBQ33854930-0C4E1A2D-A7D8-4E9D-8F11-F46224177424Q33886917-D8C28F21-D0A4-4B4A-9A98-16908236C4A5Q33921280-12577EF0-4CB0-458C-BFCE-969EC4E36928Q33968380-46872F1A-D786-4EEA-B83C-13269AF7A103Q34045128-BCA4BAA0-B3C0-4BED-A5DF-B21D4FF6EA1FQ34063244-DD7DF2AA-7409-42CC-B217-967C33F6F9EAQ34119544-F9D6B97C-25F5-40D5-B38A-E995D72BB2D0
P2860
description
1981 nî lūn-bûn
@nan
1981年の論文
@ja
1981年論文
@yue
1981年論文
@zh-hant
1981年論文
@zh-hk
1981年論文
@zh-mo
1981年論文
@zh-tw
1981年论文
@wuu
1981年论文
@zh
1981年论文
@zh-cn
name
Excitatory amino acid transmitters.
@en
type
label
Excitatory amino acid transmitters.
@en
prefLabel
Excitatory amino acid transmitters.
@en
P1476
Excitatory amino acid transmitters.
@en
P2093
P304
P356
10.1146/ANNUREV.PA.21.040181.001121
P577
1981-01-01T00:00:00Z