Learning in Aplysia: looking at synaptic plasticity from both sides.
about
Learning and memory in zebrafish larvae.Synaptic plasticity and NO-cGMP-PKG signaling coordinately regulate ERK-driven gene expression in the lateral amygdala and in the auditory thalamus following Pavlovian fear conditioning.Modulation of presynaptic plasticity and learning by the H-ras/extracellular signal-regulated kinase/synapsin I signaling pathwaySynaptic plasticity and NO-cGMP-PKG signaling regulate pre- and postsynaptic alterations at rat lateral amygdala synapses following fear conditioningRole of nitric oxide in classical conditioning of siphon withdrawal in Aplysia.Parallel evolution of nitric oxide signaling: diversity of synthesis and memory pathways.PKC-mediated GABAergic enhancement of dopaminergic responses: implication for short-term potentiation at a dual-transmitter synapse.Protein degradation by ubiquitin-proteasome system in formation and labilization of contextual conditioning memory.Associative cortex features in the first olfactory brain relay station.NMDA receptors mediate olfactory learning and memory in Drosophila.Specific requirement of NMDA receptors for long-term memory consolidation in Drosophila ellipsoid bodyThe NO-cGMP-PKG signaling pathway coordinately regulates ERK and ERK-driven gene expression at pre- and postsynaptic sites following LTP-inducing stimulation of thalamo-amygdala synapses.Protein kinase M maintains long-term sensitization and long-term facilitation in aplysiaUse of c-fos to identify activity-dependent spinal neurons after stepping in intact adult rats.Rescue of tau-induced synaptic transmission pathology by paclitaxel.Gene targeting of presynaptic proteins in synaptic plasticity and memory: across the great divide.Cellular, molecular, and epigenetic mechanisms in non-associative conditioning: implications for pain and memoryPKA has a critical role in synaptic delivery of GluR1- and GluR4-containing AMPARs during initial stages of acquisition of in vitro classical conditioning.AMPA receptor trafficking and learning.Roles of aminergic neurons in formation and recall of associative memory in crickets.Mapping molecular memory: navigating the cellular pathways of learning.Harnessing the power of neuroplasticity for intervention.Training with inedible food in Aplysia causes expression of C/EBP in the buccal but not cerebral ganglion.Memory-Relevant Mushroom Body Output Synapses Are CholinergicDifferent phases of long-term memory require distinct temporal patterns of PKA activity after single-trial classical conditioning.Effects of nerve injury and segmental regeneration on the cellular correlates of neural morphallaxis.Neuronal competition for action potential initiation sites in a circuit controlling simple learning.Surface expression of NMDA receptor changes during memory consolidation in the crab Neohelice granulata.NMDA-like receptors in the nervous system of the crab Neohelice granulata: a neuroanatomical description.Spinal NMDA receptor activation is necessary for de novo, but not the maintenance of, A2a receptor-mediated phrenic motor facilitation.MAPK signaling pathways mediate AMPA receptor trafficking in an in vitro model of classical conditioning.Serotonin induces memory-like, rapamycin-sensitive hyperexcitability in sensory axons of aplysia that contributes to injury responses.
P2860
Q26995406-3BE8C025-880E-441D-88CA-C8B005E75CB8Q30476100-B63153F9-86E8-45B7-A30E-407ECCA705C7Q33573694-ECA51AD0-D853-41CB-8272-BD9427A7E1E0Q33614718-A92B536D-9E73-431F-A11B-B3B95A516A68Q33625566-2C8A995D-08EE-4126-B7FA-4253707396FFQ33700502-2D3CC860-5BD6-47D8-A3D0-7F50E0F3C97EQ33781384-1B736890-3829-4112-91E5-31D4CC4A791AQ34067424-C0394A71-9F3E-4E24-A394-98CEA9D890F1Q34173167-47633053-ADEB-45F4-8C84-3C01463941EEQ34609071-13F4CE9C-5E7C-45F7-A645-C7FF5C0C1348Q34660163-4AA083AE-E457-4695-9574-F53C9F3A0119Q34725626-A8FC4CCD-8012-47B3-B230-2A925FCC24F8Q35008815-A85F0C78-C404-4465-B302-7B708162F16CQ35024522-5A21165A-5202-4C3A-93B1-B9CBFC90A32CQ35103703-98DD3CF7-A6BB-46A6-8FBC-EB37FD06B0ABQ36288486-CA160719-C19F-480C-8B6B-5B5D069AB304Q37161143-23C95BF5-BCC8-45DC-A4DA-E0CBE47A33B7Q37190521-C9A9A5AD-D119-4AB9-8766-91032657C192Q37700724-251BBB04-0A29-46A5-BE3F-6459C4B5F7F0Q37814097-6D77AAA7-0D31-4642-95FF-0D174048AB5EQ38001340-A75A4ABF-7085-4298-A932-D9E4B617CD45Q38229013-B6925380-E2D2-41F5-96F6-4ADFE88E8BCBQ38364586-49A36718-0DF7-4201-A759-DDCFB7A5D282Q39833649-7F5C43CD-AEC1-487C-9D64-BB7D5383482DQ42122847-3D0F8491-68DC-4294-BA32-D4DFDACD68E1Q42159842-95AFCAD2-0CB0-4CBC-9541-2AC636980618Q42161046-6C23CC07-B925-4153-A0FC-5E307F7DF949Q42416771-524E84F0-A882-4A0C-9526-59C4F8641313Q44918573-607ABF96-E2AB-4E23-9419-F8E0DA14979FQ46029698-F1E9618F-EC3F-4114-A5F6-866C6271F044Q48320055-0E4D7A67-B753-4DDB-89F8-45C186BE0B9AQ51973601-A0B0A9FF-1DB2-425E-95E9-6595CC41D694
P2860
Learning in Aplysia: looking at synaptic plasticity from both sides.
description
2003 nî lūn-bûn
@nan
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
2003年论文
@zh
2003年论文
@zh-cn
name
Learning in Aplysia: looking at synaptic plasticity from both sides.
@ast
Learning in Aplysia: looking at synaptic plasticity from both sides.
@en
type
label
Learning in Aplysia: looking at synaptic plasticity from both sides.
@ast
Learning in Aplysia: looking at synaptic plasticity from both sides.
@en
prefLabel
Learning in Aplysia: looking at synaptic plasticity from both sides.
@ast
Learning in Aplysia: looking at synaptic plasticity from both sides.
@en
P1476
Learning in Aplysia: looking at synaptic plasticity from both sides
@en
P2093
David L Glanzman
P304
P356
10.1016/J.TINS.2003.09.014
P577
2003-12-01T00:00:00Z