about
Suppression of PKR promotes network excitability and enhanced cognition by interferon-γ-mediated disinhibitionMechanisms of CaMKII action in long-term potentiationDoes PKM(zeta) maintain memory?In search of a recognition memory engramMemory as a new therapeutic targetTargeting memory processes with drugs to prevent or cure PTSDRole of signal transduction crosstalk between adenylyl cyclase and MAP kinase in hippocampus-dependent memoryConsolidation and translation regulationEpigenetic Mechanisms of Serotonin Signaling.Undercover: gene control by metabolites and metabolic enzymesCommonalities between pain and memory mechanisms and their meaning for understanding chronic painA biological perspective on memoryMemory maintenance by PKMζ--an evolutionary perspectiveA Memory Retrieval-Extinction Procedure to Prevent Drug Craving and RelapseCorrelation of expression of hypoxia-related proteins with prognosis in oral squamous cell carcinoma patients.Psychological and neural mechanisms of experimental extinction: a selective reviewIntra-hippocampal administration of ZIP alleviates depressive and anxiety-like responses in an animal model of posttraumatic stress disorder.Seeking a spotless mind: extinction, deconsolidation, and erasure of fear memoryMemory reconsolidation and its maintenance depend on L-voltage-dependent calcium channels and CaMKII functions regulating protein turnover in the hippocampus.Very long-term memories may be stored in the pattern of holes in the perineuronal net.Suppression of eIF2α kinases alleviates Alzheimer's disease-related plasticity and memory deficits.Long-term memory search across the visual brain.Long-term potentiation decay and memory loss are mediated by AMPAR endocytosis.Visual recognition memory, manifested as long-term habituation, requires synaptic plasticity in V1The Role of Proteases in Hippocampal Synaptic Plasticity: Putting Together Small Pieces of a Complex Puzzle.Selective, retrieval-independent disruption of methamphetamine-associated memory by actin depolymerization.KIBRA: In the brain and beyondControl of metastatic niche formation by targeting APBA3/Mint3 in inflammatory monocytes.The role of nuclear PKMζ in memory maintenance.BDNF facilitates L-LTP maintenance in the absence of protein synthesis through PKMζ.Biliverdin Reductase-A correlates with inducible nitric oxide synthasein in atorvastatin treated aged canine brain.Immunohistochemistry profiles of breast ductal carcinoma: factor analysis of digital image analysis data.The slow afterhyperpolarization: a target of β1-adrenergic signaling in hippocampus-dependent memory retrieval.Long-lasting LTP requires neither repeated trains for its induction nor protein synthesis for its developmentMolecular constraints on synaptic tagging and maintenance of long-term potentiation: a predictive model.Involvement of ryanodine receptors in neurotrophin-induced hippocampal synaptic plasticity and spatial memory formationReinstatement of long-term memory following erasure of its behavioral and synaptic expression in AplysiaTime-dependent changes in gene expression induced by secreted amyloid precursor protein-alpha in the rat hippocampusDifferent patterns of electrical activity lead to long-term potentiation by activating different intracellular pathways.Protein kinase M maintains long-term sensitization and long-term facilitation in aplysia
P2860
Q24622825-962EFB64-44C5-42FA-9FA7-58E031DC4F8CQ26998387-FED07070-BD5F-497B-8E40-EE5142013A52Q27008989-FC2E92A1-0A47-4577-92F8-8F07A5A0034BQ27010528-F5027924-9FA6-4107-9BA1-10F00F1E92FCQ27013731-C3D9EECC-E026-419B-A445-BEC55AE0C663Q27016155-3608DCD2-3365-4255-95D1-41D8C1E1CD56Q27022037-7A15BE15-1B21-45C2-B631-659174D4D1FEQ27025904-5F693FF8-0156-4310-BF7C-0472474E1004Q27027985-ADF0D1ED-E833-4FE3-A97A-5F55CF98B51CQ28072281-0D20FAF9-4FC9-4525-85CF-807C8BB5385BQ28083722-56AE0BBF-784D-4695-99D2-EDA9E6977A02Q28588858-16591A5A-9D9F-4C94-B3D4-22923BF2B375Q28710372-FA828D06-7DD3-45AC-81AE-47948CE3B98FQ28972241-7EF6A132-40E0-4F7C-BFD9-5CC982B70F64Q30318094-13C83392-4FAD-42BE-A69C-A11498B3EEA3Q30419931-9E1C6D25-062F-4209-BFB8-2D642CA08C9CQ30431105-3F6860B5-CF8C-4FFA-8249-FF38365222DAQ30466738-3FA8EBD8-D5F7-4B30-AEC7-977AFBE3E805Q30539056-0670D272-C8AC-465E-9AE1-EE5F250AB33DQ30541839-C8B97974-B935-4C4C-ADD9-7BEAB17424A9Q30543820-10714018-3FD9-4EAA-B0F9-0D81C1EDD395Q30558054-DC9E5370-7B3F-4D09-9AED-41886523C3ACQ30634653-23D54D85-A621-4181-8E5D-8F710E41824EQ30635024-027D0CA5-EBD1-4813-9607-60D913690CE5Q33361879-DC1620DB-34E8-4AEE-9C42-B6450A471DCAQ33621852-D9D95A99-68D3-4267-831C-7F0B3BB4EAA4Q33656456-6A9D5FC2-3055-4E76-A5D8-C218CAC57569Q33782573-29CD6C50-FA84-4BB1-B62E-3875AF44BA4DQ33880347-275B5F46-EF88-4CEF-B83C-DA453F1FD0A8Q33957927-EA8A66D3-59FE-4CFE-A9D7-F697C60B0009Q34094516-48239456-7039-4BAF-BB36-132D7494CD05Q34198351-85151064-28F0-43B1-9C8A-16D5F5B1839DQ34332796-1DCB8A32-7CB4-4E76-BF6A-C5F012C6A3FEQ34336692-DEE32EFE-F467-489F-8933-A053897E8A63Q34372273-CE696B38-E976-4533-9A1B-49A8B193D8A6Q34582715-82B036A3-F2C3-47E2-AFCD-26824493C426Q34729414-10F0B043-54F1-4B55-A42E-361E6B6143ACQ34761829-87268BFA-7EB5-4064-8B82-9B72BC0D858CQ34946280-0EA414B7-3184-44C5-9D09-ABF17D254FEBQ35008815-57387A65-C5C3-4444-AA91-EEAEE959FE07
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
gotara zanistî
@ku-latn
scientific article published on December 2010
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
name
How does PKMζ maintain long-term memory?
@en
How does PKMζ maintain long-term memory?
@nl
type
label
How does PKMζ maintain long-term memory?
@en
How does PKMζ maintain long-term memory?
@nl
prefLabel
How does PKMζ maintain long-term memory?
@en
How does PKMζ maintain long-term memory?
@nl
P2860
P356
P1476
How does PKMζ maintain long-term memory?
@en
P2093
Todd C Sacktor
P2860
P2888
P356
10.1038/NRN2949
P407
P577
2010-12-01T00:00:00Z