MOUSE:NMDZ1

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Species (Taxon ID)	Mus musculus (Mouse). ([1])
Gene Name(s)	Grin1 (synonyms: Glurz1)
Protein Name(s)	Glutamate [NMDA] receptor subunit zeta-1 N-methyl-D-aspartate receptor subunit NR1 NMD-R1
External Links
EMBL	D10028 AL732309 AL732309 BC039157
IPI	IPI00118385 IPI00608056
PIR	S21104
RefSeq	NP_001171127.1 NP_001171128.1 NP_032195.1
UniGene	Mm.278672
ProteinModelPortal	P35438
SMR	P35438
DIP	DIP-31577N
IntAct	P35438
MINT	MINT-135802
STRING	P35438
PhosphoSite	P35438
PRIDE	P35438
Ensembl	ENSMUST00000028335 ENSMUST00000114312
GeneID	14810
KEGG	mmu:14810
UCSC	uc008iri.2 uc008irk.2
CTD	2902
MGI	MGI:95819
HOVERGEN	HBG052638
PhylomeDB	P35438
NextBio	286995
ArrayExpress	P35438
Bgee	P35438
CleanEx	MM_GRIN1
Genevestigator	P35438
GermOnline	ENSMUSG00000026959
GO	GO:0030054 GO:0030426 GO:0017146 GO:0030288 GO:0014069 GO:0045211 GO:0008021 GO:0019717 GO:0005262 GO:0005509 GO:0005516 GO:0005234 GO:0016594 GO:0004972 GO:0005102 GO:0008344 GO:0006874 GO:0021987 GO:0001661 GO:0035235 GO:0007616 GO:0060179 GO:0043524 GO:0008355 GO:0021586 GO:0045944 GO:0060134 GO:0050770 GO:0048814 GO:0060079 GO:0048169 GO:0043576 GO:0051963 GO:0007585 GO:0001975 GO:0043278 GO:0019233 GO:0035176 GO:0001967 GO:0035249 GO:0008542
InterPro	IPR001828 IPR018882 IPR019594 IPR001320 IPR001508 IPR001638
Pfam	PF01094 PF10562 PF00060 PF00497
PRINTS	PR00177
SMART	SM00918 SM00079

Annotations

Qualifier	GO ID	GO term name	Reference	Evidence Code	with/from	Aspect	Notes	Status
	GO:0001661	conditioned taste aversion	PMID:16101757^[1]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0001661	conditioned taste aversion	PMID:16101757^[1]	IMP: Inferred from Mutant Phenotype	MGI:MGI:3038374	P	Seeded From UniProt
	GO:0001964	startle response	PMID:10818139^[2]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928283	P	Seeded From UniProt
	GO:0001964	startle response	PMID:10818139^[2]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928284	P	Seeded From UniProt
	GO:0001967	suckling behavior	PMID:10777815^[3]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0001967	suckling behavior	PMID:8313466^[4]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0001967	suckling behavior	PMID:8713451^[5]	IMP: Inferred from Mutant Phenotype		P	Seeded From UniProt
	GO:0001975	response to amphetamine	PMID:15467708^[6]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928280	P	Seeded From UniProt
	GO:0001975	response to amphetamine	PMID:16638606^[7]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928280	P	Seeded From UniProt
	GO:0004872	receptor activity	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001508	F	Seeded From UniProt
	GO:0004872	receptor activity	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-0675	F	Seeded From UniProt
	GO:0004970	ionotropic glutamate receptor activity	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001320	F	Seeded From UniProt
	GO:0004970	ionotropic glutamate receptor activity	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR019594	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:10963597^[8]	IMP: Inferred from Mutant Phenotype		F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:12040087^[9]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:12040087^[9]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2387441	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:12832526^[10]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:1374164^[11]	IDA: Inferred from Direct Assay		F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:1374164^[11]	IGI: Inferred from Genetic Interaction	MGI:MGI:95820	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:1377365^[12]	IDA: Inferred from Direct Assay		F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:1377365^[12]	IGI: Inferred from Genetic Interaction	MGI:MGI:95820	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:1377365^[12]	IGI: Inferred from Genetic Interaction	MGI:MGI:95821	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:1377365^[12]	IGI: Inferred from Genetic Interaction	MGI:MGI:95822	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:1385220^[13]	IDA: Inferred from Direct Assay		F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:1532151^[14]	IDA: Inferred from Direct Assay		F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:15745956^[15]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:17313573^[16]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2448952	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:17313573^[16]	IMP: Inferred from Mutant Phenotype	MGI:MGI:3611337	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:7531804^[17]	IGI: Inferred from Genetic Interaction	MGI:MGI:95821	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:8060614^[18]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928327	F	Seeded From UniProt
	GO:0004972	N-methyl-D-aspartate selective glutamate receptor activity	PMID:8313466^[4]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	F	Seeded From UniProt
	GO:0005102	receptor binding	PMID:11754835^[19]	IPI: Inferred from Physical Interaction	UniProtKB:P54763	F	Seeded From UniProt
	GO:0005215	transporter activity	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001638	F	Seeded From UniProt
	GO:0005216	ion channel activity	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001508	F	Seeded From UniProt
	GO:0005216	ion channel activity	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-0407	F	Seeded From UniProt
	GO:0005234	extracellular-glutamate-gated ion channel activity	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001320	F	Seeded From UniProt
	GO:0005234	extracellular-glutamate-gated ion channel activity	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001508	F	Seeded From UniProt
	GO:0005234	extracellular-glutamate-gated ion channel activity	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR019594	F	Seeded From UniProt
	GO:0005261	cation channel activity	PMID:7531804^[17]	IGI: Inferred from Genetic Interaction	MGI:MGI:95821	F	Seeded From UniProt
	GO:0005262	calcium channel activity	PMID:1374164^[11]	IDA: Inferred from Direct Assay		F	Seeded From UniProt
	GO:0005262	calcium channel activity	PMID:1374164^[11]	IGI: Inferred from Genetic Interaction	MGI:MGI:95820	F	Seeded From UniProt
	GO:0005262	calcium channel activity	PMID:1532151^[14]	IDA: Inferred from Direct Assay		F	Seeded From UniProt
	GO:0005509	calcium ion binding	PMID:15663482^[20]	IDA: Inferred from Direct Assay		F	Seeded From UniProt
	GO:0005515	protein binding	PMID:10862698^[21]	IPI: Inferred from Physical Interaction	UniProtKB:Q62108	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:11754835^[19]	IPI: Inferred from Physical Interaction	UniProtKB:P54763	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:14645471^[22]	IPI: Inferred from Physical Interaction	UniProtKB:P35436	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:15663482^[20]	IPI: Inferred from Physical Interaction	UniProtKB:Q9QVP4	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:16332682^[23]	IPI: Inferred from Physical Interaction	UniProtKB:Q924X6	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:16554481^[24]	IPI: Inferred from Physical Interaction	UniProtKB:P35436	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:16554481^[24]	IPI: Inferred from Physical Interaction	UniProtKB:Q01097	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:17018287^[25]	IPI: Inferred from Physical Interaction	MGI:MGI:104684	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:18945678^[26]	IPI: Inferred from Physical Interaction	UniProtKB:Q6ZWQ9	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:8595214^[27]	IPI: Inferred from Physical Interaction	UniProtKB:Q01097	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:8595214^[27]	IPI: Inferred from Physical Interaction	UniProtKB:Q01098	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:9003035^[28]	IPI: Inferred from Physical Interaction	UniProtKB:P35436	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:9003035^[28]	IPI: Inferred from Physical Interaction	UniProtKB:Q01097	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:9458051^[29]	IPI: Inferred from Physical Interaction	UniProtKB:Q01098	F	Seeded From UniProt
	GO:0005515	protein binding	PMID:9458051^[29]	IPI: Inferred from Physical Interaction	UniProtKB:Q62108	F	Seeded From UniProt
	GO:0005516	calmodulin binding	PMID:15663482^[20]	IDA: Inferred from Direct Assay		F	Seeded From UniProt
	GO:0005624	membrane fraction	PMID:10846156^[30]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0005624	membrane fraction	PMID:17093100^[31]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0005624	membrane fraction	PMID:8840015^[32]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0005624	membrane fraction	PMID:9003035^[28]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0005737	cytoplasm	PMID:12414093^[33]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0005886	plasma membrane	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-1003	C	Seeded From UniProt
	GO:0005886	plasma membrane	GO_REF:0000023	IEA: Inferred from Electronic Annotation	SP_SL:SL-0039	C	Seeded From UniProt
	GO:0006810	transport	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001638	P	Seeded From UniProt
	GO:0006810	transport	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-0813	P	Seeded From UniProt
	GO:0006811	ion transport	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001508	P	Seeded From UniProt
	GO:0006811	ion transport	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-0406	P	Seeded From UniProt
	GO:0006812	cation transport	PMID:7531804^[17]	IGI: Inferred from Genetic Interaction	MGI:MGI:95821	P	Seeded From UniProt
	GO:0006816	calcium ion transport	PMID:1532151^[14]	IDA: Inferred from Direct Assay		P	Seeded From UniProt
	GO:0006816	calcium ion transport	PMID:15576450^[34]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2178083	P	Seeded From UniProt
	GO:0006816	calcium ion transport	PMID:15576450^[34]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2181422	P	Seeded From UniProt
	GO:0006874	cellular calcium ion homeostasis	PMID:8060614^[18]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928327	P	Seeded From UniProt
	GO:0007268	synaptic transmission	PMID:10846156^[30]	TAS: Traceable Author Statement		P	Seeded From UniProt
	GO:0007585	respiratory gaseous exchange	PMID:8313466^[4]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0007585	respiratory gaseous exchange	PMID:8713451^[5]	IMP: Inferred from Mutant Phenotype		P	Seeded From UniProt
	GO:0007611	learning or memory	PMID:17004940^[35]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0007611	learning or memory	PMID:17004940^[35]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2387441	P	Seeded From UniProt
	GO:0007612	learning	PMID:17015831^[36]	IMP: Inferred from Mutant Phenotype	MGI:MGI:3692441	P	Seeded From UniProt
	GO:0007613	memory	PMID:10700255^[37]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0007613	memory	PMID:10700255^[37]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2177650	P	Seeded From UniProt
	GO:0007613	memory	PMID:10719900^[38]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0007613	memory	PMID:17556551^[39]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0007616	long-term memory	PMID:15003177^[40]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0007616	long-term memory	PMID:15003177^[40]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2177650	P	Seeded From UniProt
	GO:0008021	synaptic vesicle	PMID:10846156^[30]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0008306	associative learning	PMID:12040087^[9]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0008306	associative learning	PMID:12040087^[9]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2387441	P	Seeded From UniProt
	GO:0008306	associative learning	PMID:12718863^[41]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0008306	associative learning	PMID:12718863^[41]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2387441	P	Seeded From UniProt
	GO:0008344	adult locomotory behavior	PMID:10481908^[42]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928280	P	Seeded From UniProt
	GO:0008344	adult locomotory behavior	PMID:10818139^[2]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928283	P	Seeded From UniProt
	GO:0008344	adult locomotory behavior	PMID:10818139^[2]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928284	P	Seeded From UniProt
	GO:0008355	olfactory learning	PMID:10700255^[37]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0008355	olfactory learning	PMID:10700255^[37]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2177650	P	Seeded From UniProt
	GO:0008355	olfactory learning	PMID:11248114^[43]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0008355	olfactory learning	PMID:11248114^[43]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2177650	P	Seeded From UniProt
	GO:0008542	visual learning	PMID:10818139^[2]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928283	P	Seeded From UniProt
	GO:0008542	visual learning	PMID:10818139^[2]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928284	P	Seeded From UniProt
	GO:0008542	visual learning	PMID:16611824^[44]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0008542	visual learning	PMID:17313573^[16]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2448952	P	Seeded From UniProt
	GO:0008542	visual learning	PMID:17313573^[16]	IMP: Inferred from Mutant Phenotype	MGI:MGI:3611337	P	Seeded From UniProt
	GO:0008542	visual learning	PMID:8980238^[45]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0008542	visual learning	PMID:8980238^[45]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2177650	P	Seeded From UniProt
	GO:0008542	visual learning	PMID:9054942^[46]	IGI: Inferred from Genetic Interaction	MGI:MGI:97306	P	Seeded From UniProt
	GO:0008542	visual learning	PMID:9246451^[47]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0010646	regulation of cell communication	PMID:16299502^[48]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0014069	postsynaptic density	GO_REF:0000023	IEA: Inferred from Electronic Annotation	SP_SL:SL-0297	C	Seeded From UniProt
	GO:0014069	postsynaptic density	PMID:15317856^[49]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0014069	postsynaptic density	PMID:15748150^[50]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0016020	membrane	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001320	C	Seeded From UniProt
	GO:0016020	membrane	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001508	C	Seeded From UniProt
	GO:0016020	membrane	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR019594	C	Seeded From UniProt
	GO:0016020	membrane	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-0472	C	Seeded From UniProt
	GO:0016020	membrane	PMID:1532151^[14]	IC: Inferred by Curator	GO:0004972	C	Seeded From UniProt
	GO:0016021	integral to membrane	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-0812	C	Seeded From UniProt
	GO:0016594	glycine binding	PMID:12586454^[51]	IMP: Inferred from Mutant Phenotype		F	Seeded From UniProt
	GO:0017146	N-methyl-D-aspartate selective glutamate receptor complex	PMID:9003035^[28]	IPI: Inferred from Physical Interaction	UniProtKB:P35436	C	Seeded From UniProt
	GO:0017146	N-methyl-D-aspartate selective glutamate receptor complex	PMID:9003035^[28]	IPI: Inferred from Physical Interaction	UniProtKB:Q01097	C	Seeded From UniProt
	GO:0019233	sensory perception of pain	PMID:12832526^[10]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0019717	synaptosome	PMID:14645471^[22]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0021586	pons maturation	PMID:8313466^[4]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0021987	cerebral cortex development	PMID:10963597^[8]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0021987	cerebral cortex development	PMID:10963597^[8]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928281	P	Seeded From UniProt
	GO:0021987	cerebral cortex development	PMID:12657691^[52]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2655232	P	Seeded From UniProt
	GO:0021987	cerebral cortex development	PMID:12657691^[52]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2655237	P	Seeded From UniProt
	GO:0030054	cell junction	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-0965	C	Seeded From UniProt
	GO:0030288	outer membrane-bounded periplasmic space	GO_REF:0000002	IEA: Inferred from Electronic Annotation	InterPro:IPR001638	C	Seeded From UniProt
	GO:0030426	growth cone	PMID:10480904^[53]	NAS: Non-traceable Author Statement		C	Seeded From UniProt
	GO:0035176	social behavior	PMID:10481908^[42]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928280	P	Seeded From UniProt
	GO:0035235	ionotropic glutamate receptor signaling pathway	PMID:16025111^[54]	IDA: Inferred from Direct Assay		P	Seeded From UniProt
	GO:0035249	synaptic transmission, glutamatergic	PMID:10963597^[8]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0035249	synaptic transmission, glutamatergic	PMID:10963597^[8]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928281	P	Seeded From UniProt
	GO:0035249	synaptic transmission, glutamatergic	PMID:8313466^[4]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:12040087^[9]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:12040087^[9]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2387441	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:12657691^[52]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2655232	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:12657691^[52]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2655237	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:12832526^[10]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:1532151^[14]	IDA: Inferred from Direct Assay		P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:15576450^[34]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2178083	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:15576450^[34]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2181422	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:17313573^[16]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2448952	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:17313573^[16]	IMP: Inferred from Mutant Phenotype	MGI:MGI:3611337	P	Seeded From UniProt
	GO:0042391	regulation of membrane potential	PMID:8060614^[18]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928327	P	Seeded From UniProt
	GO:0043197	dendritic spine	PMID:15663482^[20]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0043278	response to morphine	PMID:18423864^[55]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0043523	regulation of neuron apoptosis	PMID:10479699^[56]	IGI: Inferred from Genetic Interaction	MGI:MGI:95815	P	Seeded From UniProt
	GO:0043523	regulation of neuron apoptosis	PMID:16906136^[57]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0043524	negative regulation of neuron apoptosis	PMID:17077143^[58]	IGI: Inferred from Genetic Interaction	MGI:MGI:99702	P	Seeded From UniProt
	GO:0043524	negative regulation of neuron apoptosis	PMID:17077143^[58]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0043576	regulation of respiratory gaseous exchange	PMID:10777815^[3]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0045202	synapse	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-0770	C	Seeded From UniProt
	GO:0045202	synapse	PMID:16025111^[54]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0045202	synapse	PMID:16710293^[59]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0045211	postsynaptic membrane	GO_REF:0000004	IEA: Inferred from Electronic Annotation	SP_KW:KW-0628	C	Seeded From UniProt
	GO:0045211	postsynaptic membrane	GO_REF:0000023	IEA: Inferred from Electronic Annotation	SP_SL:SL-0219	C	Seeded From UniProt
	GO:0045211	postsynaptic membrane	PMID:11754836^[60]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0045211	postsynaptic membrane	PMID:12890763^[61]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0045211	postsynaptic membrane	PMID:15317856^[49]	IDA: Inferred from Direct Assay		C	Seeded From UniProt
	GO:0045944	positive regulation of transcription from RNA polymerase II promoter	PMID:7907365^[62]	IDA: Inferred from Direct Assay		P	Seeded From UniProt
	GO:0048167	regulation of synaptic plasticity	PMID:15003177^[40]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0048167	regulation of synaptic plasticity	PMID:15003177^[40]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2177650	P	Seeded From UniProt
	GO:0048167	regulation of synaptic plasticity	PMID:8980238^[45]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0048167	regulation of synaptic plasticity	PMID:8980238^[45]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2177650	P	Seeded From UniProt
	GO:0048167	regulation of synaptic plasticity	PMID:8980239^[63]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0048167	regulation of synaptic plasticity	PMID:9246451^[47]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0048168	regulation of neuronal synaptic plasticity	PMID:15576450^[34]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2178083	P	Seeded From UniProt
	GO:0048168	regulation of neuronal synaptic plasticity	PMID:15576450^[34]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2181422	P	Seeded From UniProt
	GO:0048169	regulation of long-term neuronal synaptic plasticity	PMID:10818139^[2]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928283	P	Seeded From UniProt
	GO:0048169	regulation of long-term neuronal synaptic plasticity	PMID:10818139^[2]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928284	P	Seeded From UniProt
	GO:0048169	regulation of long-term neuronal synaptic plasticity	PMID:17015831^[36]	IMP: Inferred from Mutant Phenotype	MGI:MGI:3692441	P	Seeded From UniProt
	GO:0048169	regulation of long-term neuronal synaptic plasticity	PMID:17313573^[16]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2448952	P	Seeded From UniProt
	GO:0048169	regulation of long-term neuronal synaptic plasticity	PMID:17313573^[16]	IMP: Inferred from Mutant Phenotype	MGI:MGI:3611337	P	Seeded From UniProt
	GO:0048814	regulation of dendrite morphogenesis	PMID:15745956^[15]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0050770	regulation of axonogenesis	PMID:15745956^[15]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0050905	neuromuscular process	PMID:8313466^[4]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928270	P	Seeded From UniProt
	GO:0051963	regulation of synapse assembly	PMID:12657691^[52]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2655232	P	Seeded From UniProt
	GO:0051963	regulation of synapse assembly	PMID:12657691^[52]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2655237	P	Seeded From UniProt
	GO:0055074	calcium ion homeostasis	PMID:7907365^[62]	IDA: Inferred from Direct Assay		P	Seeded From UniProt
	GO:0060079	regulation of excitatory postsynaptic membrane potential	PMID:14645471^[22]	IGI: Inferred from Genetic Interaction	MGI:MGI:95821	P	Seeded From UniProt
	GO:0060079	regulation of excitatory postsynaptic membrane potential	PMID:15003177^[40]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928279	P	Seeded From UniProt
	GO:0060079	regulation of excitatory postsynaptic membrane potential	PMID:15003177^[40]	IMP: Inferred from Mutant Phenotype	MGI:MGI:2177650	P	Seeded From UniProt
	GO:0060134	prepulse inhibition	PMID:15265649^[64]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928280	P	Seeded From UniProt
	GO:0060179	male mating behavior	PMID:10481908^[42]	IMP: Inferred from Mutant Phenotype	MGI:MGI:1928280	P	Seeded From UniProt
	GO:0070588	calcium ion transmembrane transport	PMID:1374164^[11]	IDA: Inferred from Direct Assay		P	Seeded From UniProt
	GO:0070588	calcium ion transmembrane transport	PMID:1374164^[11]	IGI: Inferred from Genetic Interaction	MGI:MGI:95820	P	Seeded From UniProt
	GO:0070588	calcium ion transmembrane transport	PMID:1532151^[14]	IDA: Inferred from Direct Assay		P	Seeded From UniProt
	GO:0030425	dendrite	PMID:17229826^[65]	IMP: Inferred from Mutant Phenotype		C	Wild type primary dendrites show labelling of NR1 by using immunofluorescence techniques, figure 6A. Figure 6B in reelin mutant mice showed decrease NR1 which was corrected by treating with reelin, figure 6C.	complete
	GO:0009986	cell surface	PMID:17229826^[65]	IMP: Inferred from Mutant Phenotype		C	Cell surface protein biotinylation and Western blotting was used, figure 3 A-C.	complete
edit table

Notes

References

See Help:References for how to manage references in GONUTS.

↑ ^1.0 ^1.1 Cui Z et al. (2005) Requirement of NMDA receptor reactivation for consolidation and storage of nondeclarative taste memory revealed by inducible NR1 knockout. Eur J Neurosci 22: 755-63 PubMed GONUTS page
↑ ^2.0 ^2.1 ^2.2 ^2.3 ^2.4 ^2.5 ^2.6 ^2.7 Kew JN et al. (2000) Functional consequences of reduction in NMDA receptor glycine affinity in mice carrying targeted point mutations in the glycine binding site. J Neurosci 20: 4037-49 PubMed GONUTS page
↑ ^3.0 ^3.1 Poon CS et al. (2000) NMDA receptor activity in utero averts respiratory depression and anomalous long-term depression in newborn mice. J Neurosci 20: RC73 PubMed GONUTS page
↑ ^4.0 ^4.1 ^4.2 ^4.3 ^4.4 ^4.5 Li Y et al. (1994) Whisker-related neuronal patterns fail to develop in the trigeminal brainstem nuclei of NMDAR1 knockout mice. Cell 76: 427-37 PubMed GONUTS page
↑ ^5.0 ^5.1 Tokita Y et al. (1996) Characterization of excitatory amino acid neurotoxicity in N-methyl-D-aspartate receptor-deficient mouse cortical neuronal cells. Eur J Neurosci 8: 69-78 PubMed GONUTS page
↑ Miyamoto S et al. (2004) Amphetamine-induced Fos is reduced in limbic cortical regions but not in the caudate or accumbens in a genetic model of NMDA receptor hypofunction. Neuropsychopharmacology 29: 2180-8 PubMed GONUTS page
↑ Moy SS et al. (2006) Amphetamine-induced disruption of prepulse inhibition in mice with reduced NMDA receptor function. Brain Res 1089: 186-94 PubMed GONUTS page
↑ ^8.0 ^8.1 ^8.2 ^8.3 ^8.4 Iwasato T et al. (2000) Cortex-restricted disruption of NMDAR1 impairs neuronal patterns in the barrel cortex. Nature 406: 726-31 PubMed GONUTS page
↑ ^9.0 ^9.1 ^9.2 ^9.3 ^9.4 ^9.5 Nakazawa K et al. (2002) Requirement for hippocampal CA3 NMDA receptors in associative memory recall. Science 297: 211-8 PubMed GONUTS page
↑ ^10.0 ^10.1 ^10.2 South SM et al. (2003) A conditional deletion of the NR1 subunit of the NMDA receptor in adult spinal cord dorsal horn reduces NMDA currents and injury-induced pain. J Neurosci 23: 5031-40 PubMed GONUTS page
↑ ^11.0 ^11.1 ^11.2 ^11.3 ^11.4 ^11.5 Meguro H et al. (1992) Functional characterization of a heteromeric NMDA receptor channel expressed from cloned cDNAs. Nature 357: 70-4 PubMed GONUTS page
↑ ^12.0 ^12.1 ^12.2 ^12.3 Kutsuwada T et al. (1992) Molecular diversity of the NMDA receptor channel. Nature 358: 36-41 PubMed GONUTS page
↑ Ikeda K et al. (1992) Cloning and expression of the epsilon 4 subunit of the NMDA receptor channel. FEBS Lett 313: 34-8 PubMed GONUTS page
↑ ^14.0 ^14.1 ^14.2 ^14.3 ^14.4 ^14.5 Yamazaki M et al. (1992) Cloning, expression and modulation of a mouse NMDA receptor subunit. FEBS Lett 300: 39-45 PubMed GONUTS page
↑ ^15.0 ^15.1 ^15.2 Lee LJ et al. (2005) NMDA receptor-dependent regulation of axonal and dendritic branching. J Neurosci 25: 2304-11 PubMed GONUTS page
↑ ^16.0 ^16.1 ^16.2 ^16.3 ^16.4 ^16.5 ^16.6 ^16.7 Niewoehner B et al. (2007) Impaired spatial working memory but spared spatial reference memory following functional loss of NMDA receptors in the dentate gyrus. Eur J Neurosci 25: 837-46 PubMed GONUTS page
↑ ^17.0 ^17.1 ^17.2 Tsuzuki K et al. (1994) Ion permeation properties of the cloned mouse epsilon 2/zeta 1 NMDA receptor channel. Brain Res Mol Brain Res 26: 37-46 PubMed GONUTS page
↑ ^18.0 ^18.1 ^18.2 Forrest D et al. (1994) Targeted disruption of NMDA receptor 1 gene abolishes NMDA response and results in neonatal death. Neuron 13: 325-38 PubMed GONUTS page
↑ ^19.0 ^19.1 Grunwald IC et al. (2001) Kinase-independent requirement of EphB2 receptors in hippocampal synaptic plasticity. Neuron 32: 1027-40 PubMed GONUTS page
↑ ^20.0 ^20.1 ^20.2 ^20.3 Amparan D et al. (2005) Direct interaction of myosin regulatory light chain with the NMDA receptor. J Neurochem 92: 349-61 PubMed GONUTS page
↑ Husi H et al. (2000) Proteomic analysis of NMDA receptor-adhesion protein signaling complexes. Nat Neurosci 3: 661-9 PubMed GONUTS page
↑ ^22.0 ^22.1 ^22.2 Köhr G et al. (2003) Intracellular domains of NMDA receptor subtypes are determinants for long-term potentiation induction. J Neurosci 23: 10791-9 PubMed GONUTS page
↑ Hoe HS et al. (2006) Apolipoprotein E receptor 2 interactions with the N-methyl-D-aspartate receptor. J Biol Chem 281: 3425-31 PubMed GONUTS page
↑ ^24.0 ^24.1 Son GH et al. (2006) Maternal stress produces learning deficits associated with impairment of NMDA receptor-mediated synaptic plasticity. J Neurosci 26: 3309-18 PubMed GONUTS page
↑ Offenhäuser N et al. (2006) Increased ethanol resistance and consumption in Eps8 knockout mice correlates with altered actin dynamics. Cell 127: 213-26 PubMed GONUTS page
↑ Bajaj G et al. (2009) N-methyl-D-aspartate receptor subunits are non-myosin targets of myosin regulatory light chain. J Biol Chem 284: 1252-66 PubMed GONUTS page
↑ ^27.0 ^27.1 Didier M et al. (1995) Differential expression and co-assembly of NMDA zeta 1 and epsilon subunits in the mouse cerebellum during postnatal development. Neuroreport 6: 2255-9 PubMed GONUTS page
↑ ^28.0 ^28.1 ^28.2 ^28.3 ^28.4 Chazot PL & Stephenson FA (1997) Biochemical evidence for the existence of a pool of unassembled C2 exon-containing NR1 subunits of the mammalian forebrain NMDA receptor. J Neurochem 68: 507-16 PubMed GONUTS page
↑ ^29.0 ^29.1 Sprengel R et al. (1998) Importance of the intracellular domain of NR2 subunits for NMDA receptor function in vivo. Cell 92: 279-89 PubMed GONUTS page
↑ ^30.0 ^30.1 ^30.2 Setou M et al. (2000) Kinesin superfamily motor protein KIF17 and mLin-10 in NMDA receptor-containing vesicle transport. Science 288: 1796-802 PubMed GONUTS page
↑ Lai C et al. (2006) Amyotrophic lateral sclerosis 2-deficiency leads to neuronal degeneration in amyotrophic lateral sclerosis through altered AMPA receptor trafficking. J Neurosci 26: 11798-806 PubMed GONUTS page
↑ Snell LD et al. (1996) Regional and subunit specific changes in NMDA receptor mRNA and immunoreactivity in mouse brain following chronic ethanol ingestion. Brain Res Mol Brain Res 40: 71-8 PubMed GONUTS page
↑ Puyal J et al. (2002) Distribution of alpha-amino-3-hydroxy-5-methyl-4 isoazolepropionic acid and N-methyl-D-aspartate receptor subunits in the vestibular and spiral ganglia of the mouse during early development. Brain Res Dev Brain Res 139: 51-7 PubMed GONUTS page
↑ ^34.0 ^34.1 ^34.2 ^34.3 ^34.4 ^34.5 Pawlak V et al. (2005) Impaired synaptic scaling in mouse hippocampal neurones expressing NMDA receptors with reduced calcium permeability. J Physiol 562: 771-83 PubMed GONUTS page
↑ ^35.0 ^35.1 Cravens CJ et al. (2006) CA3 NMDA receptors are crucial for rapid and automatic representation of context memory. Eur J Neurosci 24: 1771-80 PubMed GONUTS page
↑ ^36.0 ^36.1 Dang MT et al. (2006) Disrupted motor learning and long-term synaptic plasticity in mice lacking NMDAR1 in the striatum. Proc Natl Acad Sci U S A 103: 15254-9 PubMed GONUTS page
↑ ^37.0 ^37.1 ^37.2 ^37.3 Rampon C et al. (2000) Enrichment induces structural changes and recovery from nonspatial memory deficits in CA1 NMDAR1-knockout mice. Nat Neurosci 3: 238-44 PubMed GONUTS page
↑ Huerta PT et al. (2000) Formation of temporal memory requires NMDA receptors within CA1 pyramidal neurons. Neuron 25: 473-80 PubMed GONUTS page
↑ McHugh TJ et al. (2007) Dentate gyrus NMDA receptors mediate rapid pattern separation in the hippocampal network. Science 317: 94-9 PubMed GONUTS page
↑ ^40.0 ^40.1 ^40.2 ^40.3 ^40.4 ^40.5 Cui Z et al. (2004) Inducible and reversible NR1 knockout reveals crucial role of the NMDA receptor in preserving remote memories in the brain. Neuron 41: 781-93 PubMed GONUTS page
↑ ^41.0 ^41.1 Nakazawa K et al. (2003) Hippocampal CA3 NMDA receptors are crucial for memory acquisition of one-time experience. Neuron 38: 305-15 PubMed GONUTS page
↑ ^42.0 ^42.1 ^42.2 Mohn AR et al. (1999) Mice with reduced NMDA receptor expression display behaviors related to schizophrenia. Cell 98: 427-36 PubMed GONUTS page
↑ ^43.0 ^43.1 Rondi-Reig L et al. (2001) CA1-specific N-methyl-D-aspartate receptor knockout mice are deficient in solving a nonspatial transverse patterning task. Proc Natl Acad Sci U S A 98: 3543-8 PubMed GONUTS page
↑ Rondi-Reig L et al. (2006) Impaired sequential egocentric and allocentric memories in forebrain-specific-NMDA receptor knock-out mice during a new task dissociating strategies of navigation. J Neurosci 26: 4071-81 PubMed GONUTS page
↑ ^45.0 ^45.1 ^45.2 ^45.3 Tsien JZ et al. (1996) The essential role of hippocampal CA1 NMDA receptor-dependent synaptic plasticity in spatial memory. Cell 87: 1327-38 PubMed GONUTS page
↑ Silva AJ et al. (1997) A mouse model for the learning and memory deficits associated with neurofibromatosis type I. Nat Genet 15: 281-4 PubMed GONUTS page
↑ ^47.0 ^47.1 Tonegawa S et al. (1996) Hippocampal CA1-region-restricted knockout of NMDAR1 gene disrupts synaptic plasticity, place fields, and spatial learning. Cold Spring Harb Symp Quant Biol 61: 225-38 PubMed GONUTS page
↑ Arumugam H et al. (2005) NMDA receptors regulate developmental gap junction uncoupling via CREB signaling. Nat Neurosci 8: 1720-6 PubMed GONUTS page
↑ ^49.0 ^49.1 Abe M et al. (2004) NMDA receptor GluRepsilon/NR2 subunits are essential for postsynaptic localization and protein stability of GluRzeta1/NR1 subunit. J Neurosci 24: 7292-304 PubMed GONUTS page
↑ Trinidad JC et al. (2005) Phosphorylation state of postsynaptic density proteins. J Neurochem 92: 1306-16 PubMed GONUTS page
↑ Kiefer F et al. (2003) Involvement of NMDA receptors in alcohol-mediated behavior: mice with reduced affinity of the NMDA R1 glycine binding site display an attenuated sensitivity to ethanol. Biol Psychiatry 53: 345-51 PubMed GONUTS page
↑ ^52.0 ^52.1 ^52.2 ^52.3 ^52.4 ^52.5 Rudhard Y et al. (2003) Absence of Whisker-related pattern formation in mice with NMDA receptors lacking coincidence detection properties and calcium signaling. J Neurosci 23: 2323-32 PubMed GONUTS page
↑ Chen LT et al. (1999) A candidate target for G protein action in brain. J Biol Chem 274: 26931-8 PubMed GONUTS page
↑ ^54.0 ^54.1 Snyder EM et al. (2005) Regulation of NMDA receptor trafficking by amyloid-beta. Nat Neurosci 8: 1051-8 PubMed GONUTS page
↑ Quintero GC et al. (2008) Evaluation of morphine analgesia and motor coordination in mice following cortex-specific knockout of the N-methyl-D-aspartate NR1-subunit. Neurosci Lett 437: 55-8 PubMed GONUTS page
↑ Jensen P et al. (1999) Rescue of cerebellar granule cells from death in weaver NR1 double mutants. J Neurosci 19: 7991-8 PubMed GONUTS page
↑ Tashiro A et al. (2006) NMDA-receptor-mediated, cell-specific integration of new neurons in adult dentate gyrus. Nature 442: 929-33 PubMed GONUTS page
↑ ^58.0 ^58.1 de Rivero Vaccari JC et al. (2006) NMDA receptors promote survival in somatosensory relay nuclei by inhibiting Bax-dependent developmental cell death. Proc Natl Acad Sci U S A 103: 16971-6 PubMed GONUTS page
↑ Nakazawa T et al. (2006) NR2B tyrosine phosphorylation modulates fear learning as well as amygdaloid synaptic plasticity. EMBO J 25: 2867-77 PubMed GONUTS page
↑ Henderson JT et al. (2001) The receptor tyrosine kinase EphB2 regulates NMDA-dependent synaptic function. Neuron 32: 1041-56 PubMed GONUTS page
↑ Tao YX et al. (2003) Impaired NMDA receptor-mediated postsynaptic function and blunted NMDA receptor-dependent persistent pain in mice lacking postsynaptic density-93 protein. J Neurosci 23: 6703-12 PubMed GONUTS page
↑ ^62.0 ^62.1 Bulleit RF et al. (1994) NMDA receptor activation in differentiating cerebellar cell cultures regulates the expression of a new POU gene, Cns-1. J Neurosci 14: 1584-95 PubMed GONUTS page
↑ McHugh TJ et al. (1996) Impaired hippocampal representation of space in CA1-specific NMDAR1 knockout mice. Cell 87: 1339-49 PubMed GONUTS page
↑ Duncan GE et al. (2004) Deficits in sensorimotor gating and tests of social behavior in a genetic model of reduced NMDA receptor function. Behav Brain Res 153: 507-19 PubMed GONUTS page
↑ ^65.0 ^65.1 Qiu S & Weeber EJ (2007) Reelin signaling facilitates maturation of CA1 glutamatergic synapses. J Neurophysiol 97: 2312-21 PubMed GONUTS page

[PMID:16101757-0] 1.0 ^1.1 Cui Z et al. (2005) Requirement of NMDA receptor reactivation for consolidation and storage of nondeclarative taste memory revealed by inducible NR1 knockout. Eur J Neurosci 22: 755-63 PubMed GONUTS page

[PMID:10818139-1] 2.0 ^2.1 ^2.2 ^2.3 ^2.4 ^2.5 ^2.6 ^2.7 Kew JN et al. (2000) Functional consequences of reduction in NMDA receptor glycine affinity in mice carrying targeted point mutations in the glycine binding site. J Neurosci 20: 4037-49 PubMed GONUTS page

[PMID:10777815-2] 3.0 ^3.1 Poon CS et al. (2000) NMDA receptor activity in utero averts respiratory depression and anomalous long-term depression in newborn mice. J Neurosci 20: RC73 PubMed GONUTS page

[PMID:8313466-3] 4.0 ^4.1 ^4.2 ^4.3 ^4.4 ^4.5 Li Y et al. (1994) Whisker-related neuronal patterns fail to develop in the trigeminal brainstem nuclei of NMDAR1 knockout mice. Cell 76: 427-37 PubMed GONUTS page

[PMID:8713451-4] 5.0 ^5.1 Tokita Y et al. (1996) Characterization of excitatory amino acid neurotoxicity in N-methyl-D-aspartate receptor-deficient mouse cortical neuronal cells. Eur J Neurosci 8: 69-78 PubMed GONUTS page

[PMID:15467708-5] Miyamoto S et al. (2004) Amphetamine-induced Fos is reduced in limbic cortical regions but not in the caudate or accumbens in a genetic model of NMDA receptor hypofunction. Neuropsychopharmacology 29: 2180-8 PubMed GONUTS page

[PMID:16638606-6] Moy SS et al. (2006) Amphetamine-induced disruption of prepulse inhibition in mice with reduced NMDA receptor function. Brain Res 1089: 186-94 PubMed GONUTS page

[PMID:10963597-7] 8.0 ^8.1 ^8.2 ^8.3 ^8.4 Iwasato T et al. (2000) Cortex-restricted disruption of NMDAR1 impairs neuronal patterns in the barrel cortex. Nature 406: 726-31 PubMed GONUTS page

[PMID:12040087-8] 9.0 ^9.1 ^9.2 ^9.3 ^9.4 ^9.5 Nakazawa K et al. (2002) Requirement for hippocampal CA3 NMDA receptors in associative memory recall. Science 297: 211-8 PubMed GONUTS page

[PMID:12832526-9] 10.0 ^10.1 ^10.2 South SM et al. (2003) A conditional deletion of the NR1 subunit of the NMDA receptor in adult spinal cord dorsal horn reduces NMDA currents and injury-induced pain. J Neurosci 23: 5031-40 PubMed GONUTS page

[PMID:1374164-10] 11.0 ^11.1 ^11.2 ^11.3 ^11.4 ^11.5 Meguro H et al. (1992) Functional characterization of a heteromeric NMDA receptor channel expressed from cloned cDNAs. Nature 357: 70-4 PubMed GONUTS page

[PMID:1377365-11] 12.0 ^12.1 ^12.2 ^12.3 Kutsuwada T et al. (1992) Molecular diversity of the NMDA receptor channel. Nature 358: 36-41 PubMed GONUTS page

[PMID:1385220-12] Ikeda K et al. (1992) Cloning and expression of the epsilon 4 subunit of the NMDA receptor channel. FEBS Lett 313: 34-8 PubMed GONUTS page

[PMID:1532151-13] 14.0 ^14.1 ^14.2 ^14.3 ^14.4 ^14.5 Yamazaki M et al. (1992) Cloning, expression and modulation of a mouse NMDA receptor subunit. FEBS Lett 300: 39-45 PubMed GONUTS page

[PMID:15745956-14] 15.0 ^15.1 ^15.2 Lee LJ et al. (2005) NMDA receptor-dependent regulation of axonal and dendritic branching. J Neurosci 25: 2304-11 PubMed GONUTS page

[PMID:17313573-15] 16.0 ^16.1 ^16.2 ^16.3 ^16.4 ^16.5 ^16.6 ^16.7 Niewoehner B et al. (2007) Impaired spatial working memory but spared spatial reference memory following functional loss of NMDA receptors in the dentate gyrus. Eur J Neurosci 25: 837-46 PubMed GONUTS page

[PMID:7531804-16] 17.0 ^17.1 ^17.2 Tsuzuki K et al. (1994) Ion permeation properties of the cloned mouse epsilon 2/zeta 1 NMDA receptor channel. Brain Res Mol Brain Res 26: 37-46 PubMed GONUTS page

[PMID:8060614-17] 18.0 ^18.1 ^18.2 Forrest D et al. (1994) Targeted disruption of NMDA receptor 1 gene abolishes NMDA response and results in neonatal death. Neuron 13: 325-38 PubMed GONUTS page

[PMID:11754835-18] 19.0 ^19.1 Grunwald IC et al. (2001) Kinase-independent requirement of EphB2 receptors in hippocampal synaptic plasticity. Neuron 32: 1027-40 PubMed GONUTS page

[PMID:15663482-19] 20.0 ^20.1 ^20.2 ^20.3 Amparan D et al. (2005) Direct interaction of myosin regulatory light chain with the NMDA receptor. J Neurochem 92: 349-61 PubMed GONUTS page

[PMID:10862698-20] Husi H et al. (2000) Proteomic analysis of NMDA receptor-adhesion protein signaling complexes. Nat Neurosci 3: 661-9 PubMed GONUTS page

[PMID:14645471-21] 22.0 ^22.1 ^22.2 Köhr G et al. (2003) Intracellular domains of NMDA receptor subtypes are determinants for long-term potentiation induction. J Neurosci 23: 10791-9 PubMed GONUTS page

[PMID:16332682-22] Hoe HS et al. (2006) Apolipoprotein E receptor 2 interactions with the N-methyl-D-aspartate receptor. J Biol Chem 281: 3425-31 PubMed GONUTS page

[PMID:16554481-23] 24.0 ^24.1 Son GH et al. (2006) Maternal stress produces learning deficits associated with impairment of NMDA receptor-mediated synaptic plasticity. J Neurosci 26: 3309-18 PubMed GONUTS page

[PMID:17018287-24] Offenhäuser N et al. (2006) Increased ethanol resistance and consumption in Eps8 knockout mice correlates with altered actin dynamics. Cell 127: 213-26 PubMed GONUTS page

[PMID:18945678-25] Bajaj G et al. (2009) N-methyl-D-aspartate receptor subunits are non-myosin targets of myosin regulatory light chain. J Biol Chem 284: 1252-66 PubMed GONUTS page

[PMID:8595214-26] 27.0 ^27.1 Didier M et al. (1995) Differential expression and co-assembly of NMDA zeta 1 and epsilon subunits in the mouse cerebellum during postnatal development. Neuroreport 6: 2255-9 PubMed GONUTS page

[PMID:9003035-27] 28.0 ^28.1 ^28.2 ^28.3 ^28.4 Chazot PL & Stephenson FA (1997) Biochemical evidence for the existence of a pool of unassembled C2 exon-containing NR1 subunits of the mammalian forebrain NMDA receptor. J Neurochem 68: 507-16 PubMed GONUTS page

[PMID:9458051-28] 29.0 ^29.1 Sprengel R et al. (1998) Importance of the intracellular domain of NR2 subunits for NMDA receptor function in vivo. Cell 92: 279-89 PubMed GONUTS page

[PMID:10846156-29] 30.0 ^30.1 ^30.2 Setou M et al. (2000) Kinesin superfamily motor protein KIF17 and mLin-10 in NMDA receptor-containing vesicle transport. Science 288: 1796-802 PubMed GONUTS page

[PMID:17093100-30] Lai C et al. (2006) Amyotrophic lateral sclerosis 2-deficiency leads to neuronal degeneration in amyotrophic lateral sclerosis through altered AMPA receptor trafficking. J Neurosci 26: 11798-806 PubMed GONUTS page

[PMID:8840015-31] Snell LD et al. (1996) Regional and subunit specific changes in NMDA receptor mRNA and immunoreactivity in mouse brain following chronic ethanol ingestion. Brain Res Mol Brain Res 40: 71-8 PubMed GONUTS page

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