Mu opioid receptor activation of ERK1/2 is GRK3 and arrestin dependent in striatal neurons - Wikidata - wikimedia - TriplyDB

Mu opioid receptor activation of ERK1/2 is GRK3 and arrestin dependent in striatal neurons

Mu opioid receptor activation of ERK1/2 is GRK3 and arrestin dependent in striatal neurons

http://www.wikidata.org/entity/Q36184325

about

Ser/ Thr residues at α3/β5 loop of Gαs are important in morphine-induced adenylyl cyclase sensitization but not mitogen-activated protein kinase phosphorylation Beta-arrestins and heterotrimeric G-proteins: collaborators and competitors in signal transduction Endogenous opiates and behavior: 2006 Loss of morphine reward and dependence in mice lacking G protein-coupled receptor kinase 5.The protective signaling of metabotropic glutamate receptor 1 Is mediated by sustained, beta-arrestin-1-dependent ERK phosphorylation.Glycogen synthase kinase-3 and p38 MAPK are required for opioid-induced microglia apoptosis Opioid-induced mitogen-activated protein kinase signaling in rat enteric neurons following chronic morphine treatment.Change in functional selectivity of morphine with the development of antinociceptive tolerance.Protein kinase Czeta mediates micro-opioid receptor-induced cross-desensitization of chemokine receptor CCR5.A single mutation in arrestin-2 prevents ERK1/2 activation by reducing c-Raf1 binding.Functional selectivity at the μ-opioid receptor: implications for understanding opioid analgesia and tolerance.Arrestin development: emerging roles for beta-arrestins in developmental signaling pathways Analysis of opioid efficacy, tolerance, addiction and dependence from cell culture to human Inhibition of EGF-induced ERK/MAP kinase-mediated astrocyte proliferation by mu opioids: integration of G protein and beta-arrestin 2-dependent pathways.Opioid receptor internalization contributes to dermorphin-mediated antinociception Serine 363 is required for nociceptin/orphanin FQ opioid receptor (NOPR) desensitization, internalization, and arrestin signaling.Regulation of μ-opioid receptors: desensitization, phosphorylation, internalization, and tolerance.Ligand-biased activation of extracellular signal-regulated kinase 1/2 leads to differences in opioid induced antinociception and tolerance.Morphine-induced MOR-1X and ASF/SF2 Expressions Are Independent of Transcriptional Regulation: Implications for MOR-1X Signaling Molecular mechanisms of opioid receptor-dependent signaling and behavior.Activation of mu opioid receptors in the striatum differentially augments methamphetamine-induced gene expression and enhances stereotypic behavior.Characterization of methadone as a β-arrestin-biased μ-opioid receptor agonist.Extracellular signal-regulated kinase 1/2 activation counteracts morphine tolerance in the periaqueductal gray of the rat Neuronal extracellular signal-regulated kinase (ERK) activity as marker and mediator of alcohol and opioid dependence.Custom-designed proteins as novel therapeutic tools? The case of arrestins.Structural determinants of arrestin functions β-arrestins: regulatory role and therapeutic potential in opioid and cannabinoid receptor-mediated analgesia.NF1 Is a Direct G Protein Effector Essential for Opioid Signaling to Ras in the Striatum.Enhanced phosphorylation-independent arrestins and gene therapy.Constitutive activity of the cannabinoid CB1 receptor regulates the function of co-expressed Mu opioid receptors.Effect of acute fentanyl treatment on synaptic plasticity in the hippocampal CA1 region in rats.Opiate Drugs with Abuse Liability Hijack the Endogenous Opioid System to Disrupt Neuronal and Glial Maturation in the Central Nervous System.Differential Effects of Oxycodone, Hydrocodone, and Morphine on Activation Levels of Signaling Molecules.Preemptive intrathecal administration of endomorphins relieves inflammatory pain in male mice via inhibition of p38 MAPK signaling and regulation of inflammatory cytokines

P2860

Q24300079-00EDB085-8CF3-40C5-A242-39CDD6759044 Q24653656-BC1BD861-74E5-43B3-9B9A-17D7474656D3 Q28752585-8F3A491E-C66B-4B1E-B0B7-343A3E5DE6AB Q33993802-46BA7789-A0C8-4371-9FB6-8B4C5CE851E2 Q34074283-630780FC-9300-45CA-BFAE-7CFAEF46B128 Q34158930-4E94DF00-2AB7-4559-BCCC-6BD840E0F57A Q34323667-FF1BFC08-FFDE-47B9-B3A3-1ECC4C22EA2C Q34939824-3EE6227F-A337-49B9-A4E1-ECEC1F91FC6F Q35063329-2D2AE0B3-5B83-4722-A78A-1B05D58FC457 Q35156778-338D6800-0DCD-4136-9086-6EE007CF6CE2 Q35264421-47150959-FF23-4072-894F-D0C378BE2A98 Q35565885-B02D8C6A-8993-4B90-A182-A887D1C1E767 Q35589969-E816F1F1-2FA3-4E09-896F-A55D67867D91 Q35609910-A4E33644-E151-427B-9812-C3C1D5BC924C Q35853157-02CA988B-FC4D-4B89-92C4-1B74FEBF467A Q36451963-3EFB7FC3-B06C-4D2B-BF52-5586B8D50CA4 Q36591603-28522A70-406C-436A-AF04-444C992C5DBE Q36654621-2753F599-4442-4BB2-A5AA-E4C8EE940087 Q36712009-C0897E64-600A-4DDF-B3CE-DEDB01167462 Q36974487-69C6D52B-FB3A-4835-AA31-A3F63B06056B Q37011569-9989FB5A-59C6-4979-8375-1571D8A8266C Q37115757-52C18284-CB4D-460F-9ED6-CD18F4762FBB Q37416451-6295C264-32C5-48ED-A8B1-5C8288F7A4CE Q37629743-2C34B3AA-B9A9-4BF9-A099-AAB01A29FCB4 Q37735949-CD72F3F3-E4C0-4A28-BFE7-C2EF0D94B548 Q38114211-0559FBFC-E21C-49B2-960E-EDCB8E8E6C39 Q38167644-7D3F68F8-69A0-4292-8293-31FFB96328BD Q38435406-AB7C52FC-736B-4DD0-B703-BE528102DF2B Q42394084-FBF3EA3A-88DD-4117-8D15-D387C3509D11 Q42525438-971D5C48-94F2-4F32-9A6D-510390A73BF6 Q43196005-2223ABF8-DFEE-42AC-88DC-E50C2157CF18 Q49270407-EC9E6C6B-B62F-4924-9699-B38A591A8F50 Q50568726-C25CD110-436F-49BA-8408-1B835715BDC7 Q59135901-F7B4B9E5-D097-44F8-97B1-889811470000

P2860

Mu opioid receptor activation of ERK1/2 is GRK3 and arrestin dependent in striatal neurons

http://www.wikidata.org/entity/Q36184325

description

2006 nî lūn-bûn

@nan

2006年の論文

@ja

2006年論文

@yue

2006年論文

@zh-hant

2006年論文

@zh-hk

2006年論文

@zh-mo

2006年論文

@zh-tw

2006年论文

@wuu

2006年论文

@zh

2006年论文

@zh-cn

name

Mu opioid receptor activation ...... dependent in striatal neurons

@ast

Mu opioid receptor activation ...... dependent in striatal neurons

@en

type

label

Mu opioid receptor activation ...... dependent in striatal neurons

@ast

Mu opioid receptor activation ...... dependent in striatal neurons

@en

prefLabel

Mu opioid receptor activation ...... dependent in striatal neurons

@ast

Mu opioid receptor activation ...... dependent in striatal neurons

@en

P1433

Q36184325-7A9E9598-826E-4823-BAA7-2E2519AAE23D

P1476

Q36184325-3344921A-962C-4BAF-9119-CBE4ACDFA999

P2093

Q36184325-705A78D4-3E05-43D0-86A2-36FF954F8ED3

Q36184325-9430E94F-2138-4EC8-BB05-3E06A0611646

Q36184325-D6A51C7F-8EFF-4C81-B281-7B581AAE50E7

P2860

Q36184325-1C592899-E90D-4BA3-8CF3-0B1FAD6C0225

Q36184325-1EE34B5E-CCC2-4395-A115-8913D8748650

Q36184325-299E5FAE-9972-41E9-8EB1-A0D24A6A919C

Q36184325-2C9A806E-5FBA-4726-B90B-3DF8E1317353

Q36184325-2CCD7E0C-C7B3-4982-BCE0-1BDDA1554C82

Q36184325-311C4CED-8539-4757-9382-718C2217BDE7

Q36184325-33744274-E2B8-4465-808D-DB689A95C69F

Q36184325-36B67B0A-88F5-4FFC-9408-D21BAF969158

Q36184325-42C8BCFB-E315-4402-BA4B-7059E27DEF29

Q36184325-534E4F53-B4E2-4FE6-8A80-0F6AC75AF4FB

P304

Q36184325-8A502424-3F26-4B06-B131-77294A992673

P31

Q36184325-D1546B5E-4026-42A3-A0CF-E40A0B95C6C7

P356

Q36184325-037E67CE-0FF1-44B4-ADE7-7B9291D80BB0

P407

Q36184325-4F192F0F-0A79-4853-9E0E-EAC10CF95357

P433

Q36184325-E45A990E-0CC9-47F9-BD1A-9CFF71740AF9

P478

Q36184325-1D814F60-FEF0-49DE-B269-4263BA4BBD25

P577

Q36184325-F6640A8D-B5DE-4E23-A730-CAC2C45BA9E5

P698

Q36184325-6FAA7806-E334-4F51-980A-C98A6D1C55E9

P921

Q36184325-BF2DC22B-3447-4781-8F7F-B697834482D7

P932

Q36184325-7C5082B0-2480-4569-9D60-8BDBBCB94B89

P356

P1433

Journal of Biological Chemistry

P1476

Mu opioid receptor activation ...... dependent in striatal neurons

@en

P2093

Charles Chavkin

http://www.w3.org/2001/XMLSchema#string

Janet D Lowe

http://www.w3.org/2001/XMLSchema#string

Tara A Macey

http://www.w3.org/2001/XMLSchema#string

P2860

An Akt/beta-arrestin 2/PP2A signaling complex mediates dopaminergic neurotransmission and behavior

Activation and targeting of extracellular signal-regulated kinases by beta-arrestin scaffolds

Kappa opioid receptor activation of p38 MAPK is GRK3- and arrestin-dependent in neurons and astrocytes

Morphine promotes rapid, arrestin-dependent endocytosis of mu-opioid receptors in striatal neurons

Preferential Interaction between the dopamine D2 receptor and Arrestin2 in neostriatal neurons

A PCR primer bank for quantitative gene expression analysis.

The stress-activated protein kinase pathways.

Functional dissociation of mu opioid receptor signaling and endocytosis: implications for the biology of opiate tolerance and addiction.

Beta-Arrestins: new roles in regulating heptahelical receptors' functions.

beta-arrestin-dependent, G protein-independent ERK1/2 activation by the beta2 adrenergic receptor.

P304

34515-34524

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1074/JBC.M604278200

http://www.w3.org/2001/XMLSchema#string

P407

P433

45

http://www.w3.org/2001/XMLSchema#string

P478

281

http://www.w3.org/2001/XMLSchema#string

P577

2006-09-18T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

16982618

http://www.w3.org/2001/XMLSchema#string

P921

corpus striatum

P932

2104781

http://www.w3.org/2001/XMLSchema#string