cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
about
Single amino acids in the carboxyl terminal domain of aquaporin-1 contribute to cGMP-dependent ion channel activationSyntrophin mutation associated with long QT syndrome through activation of the nNOS-SCN5A macromolecular complexS-nitrosothiols modulate G protein-coupled receptor signaling in a reversible and highly receptor-specific manner.Nitric Oxide-Mediated Posttranslational Modifications: Impacts at the SynapseThe role of nitric oxide in pre-synaptic plasticity and homeostasisNitric oxide suppresses cerebral vasomotion by sGC-independent effects on ryanodine receptors and voltage-gated calcium channelsModulation of voltage-gated Ca2+ current in vestibular hair cells by nitric oxideLight-evoked S-nitrosylation in the retina.Redox mechanism of S-nitrosothiol modulation of neuronal CaV3.2 T-type calcium channels.Mobilisation of Ca2+ stores and flagellar regulation in human sperm by S-nitrosylation: a role for NO synthesised in the female reproductive tractFunctional regulation of T-type calcium channels by s-nitrosothiols in the rat thalamus.Nitric oxide modulation of GABAergic synaptic transmission in mechanically isolated rat auditory cortical neuronsVentromedial hypothalamic nitric oxide production is necessary for hypoglycemia detection and counterregulationTranscriptional dysregulation in striatal projection- and interneurons in a mouse model of Huntington's disease: neuronal selectivity and potential neuroprotective role of HAP1.Modulatory effects of nitric oxide-active drugs on the anticonvulsant activity of lamotrigine in an experimental model of partial complex epilepsy in the ratTRPV1 and TRPA1 mediate peripheral nitric oxide-induced nociception in mice.Nitric oxide regulates BDNF release from nodose ganglion neurons in a pattern-dependent and cGMP-independent manner.Sensory adaptation and short term plasticity as Bayesian correction for a changing brain.Nitric oxide donor protects against acetic acid-induced gastric ulcer in rats via S-nitrosylation of TRPV1 on vagus nerve.Effects of nitric oxide on magnocellular neurons of the supraoptic nucleus involve multiple mechanismsTranscriptional changes in Huntington disease identified using genome-wide expression profiling and cross-platform analysisStimulation of neuronal KATP channels by cGMP-dependent protein kinase: involvement of ROS and 5-hydroxydecanoate-sensitive factors in signal transduction.Modulation of inhibitory activity by nitric oxide in the thalamusAntagonism of soluble guanylyl cyclase attenuates cutaneous vasodilation during whole body heat stress and local warming in humans.Headache-type adverse effects of NO donors: vasodilation and beyondS-nitrosylation regulates nuclear translocation of chloride intracellular channel protein CLIC4.Neuroprotective effects of tadalafil on gerbil dopaminergic neurons following cerebral ischemiaNeuronal-derived nitric oxide modulates the activity of mouse detrusor smooth muscle.A nanoparticle delivery vehicle for S-nitroso-N-acetyl cysteine: sustained vascular responseNitric oxide signalling augments neuronal voltage-gated L-type (Ca(v)1) and P/q-type (Ca(v)2.1) channels in the mouse medial nucleus of the trapezoid body.On the regulation of NMDA receptors by nitric oxide.NO stimulation of ATP-sensitive potassium channels: Involvement of Ras/mitogen-activated protein kinase pathway and contribution to neuroprotection.Nitric oxide has differential effects on currents in different subsets of Manduca sexta antennal lobe neurons.ATP induces NO production in hippocampal neurons by P2X(7) receptor activation independent of glutamate signaling.Acid-sensing ion channel 1 and nitric oxide synthase are in adjacent layers in the wall of rat and human cerebral arteries.Two faces of nitric oxide: implications for cellular mechanisms of oxygen toxicity.The nitric oxide donor SNAP-induced amino acid neurotransmitter release in cortical neurons. Effects of blockers of voltage-dependent sodium and calcium channelsStatistical assessment of the stability of neural movement representationsTranscriptional responses of olive flounder (Paralichthys olivaceus) to low temperature.Nitric oxide and memory.
P2860
Q24297851-A5C744B6-F419-45D4-BE05-92F3B3748548Q24308697-204D351A-591A-4160-A301-CDB38579FCE0Q24798999-A048008A-14F9-46A0-AD0F-144E689662C2Q26774569-13BCBD7C-CE4B-4D5F-BFFE-ABD2EAD46DA6Q26863770-667ADBA0-CD0D-4899-A800-217733B599C2Q27345356-9C96228B-CC86-44C6-8448-84C9B4275F58Q28565990-6847EA0D-521B-471B-99BD-BEE0DD83D034Q30373234-5E143C38-2232-44A3-A86D-713D9F648CA5Q30410507-849A1A76-8D7E-4FD5-B99D-651470B78552Q30437866-DE7E602D-E5DA-4FF1-B516-E1AF6227B465Q30442880-08B7FD79-8B79-4393-BE1F-99AD79886965Q30484185-08B054DA-F8DF-48E4-85F1-1AD5CC510E9EQ30492859-E445318C-2C1F-45CF-B1FB-21BA0BE122BAQ31129663-88E3CA03-528C-4DE6-A670-FC8B6C02FC9FQ33289683-0AB9DD73-6F84-4F9F-96AC-B9CAAE481107Q33515254-EE8D8C34-7EE1-4FBC-92C9-E418E5AE9BD3Q33695410-59F3499E-CBCC-4921-BF7B-F555E0C744BCQ33701638-34F09DF7-9912-4705-AC48-41AFA4C3FCA9Q33704642-315D9CA0-904D-4CA6-83F2-954520952599Q33732302-8169C879-5443-4934-AE25-C655DE8C5B89Q33755822-81DA2FE5-9553-47BF-A890-FA77B1E46853Q33783529-2A0507B5-29BA-4FB3-9404-F70C8D979822Q33807996-EC32FC96-81E3-4947-A342-1C9DF87D607FQ33811590-0DAEA2F6-4597-43DB-9312-8B907092133EQ33812736-062F58CA-3187-42B3-BD80-1EC5EEFD26D4Q34025221-95F1E0CC-78D9-41C2-9B8C-AC4B49304E31Q34095331-C735E497-3BA0-4C55-93A9-DEDD2948DEA4Q34139716-885ED195-7464-44F4-9721-E8DD3B470DE6Q34141284-258485BC-07E1-4284-BDBD-0E56E6DB35D9Q34184527-9E26712E-DE84-42B1-82C6-1DDDFE8AC974Q34312682-1FCE657C-B044-4AEA-BDB1-8AEDADEC9488Q34337942-4673A155-B141-4A60-83C1-898929244F0FQ34374328-19B44910-A666-4274-B8FE-8E1C6A6DD853Q34614397-3FCCA00A-372E-4AB3-BF10-14026DBA32FFQ34715568-C837C77F-638E-4D31-B3F0-24D1A30ED2E7Q34849962-F6C13B77-9E29-4227-9533-D15108C0D449Q35112044-865C0F42-2616-4856-8013-7827148EB7ABQ35160550-CE5C6466-B662-4028-8DE3-825793DE05C5Q35299333-C54F0600-3FBA-4A9C-98B5-1538CA4A891CQ35740541-8DA28192-CC61-4454-A32C-3732F35E36A2
P2860
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
description
2002 nî lūn-bûn
@nan
2002 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2002 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
name
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@ast
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@en
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@nl
type
label
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@ast
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@en
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@nl
prefLabel
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@ast
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@en
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@nl
P2093
P1476
cGMP and S-nitrosylation: two routes for modulation of neuronal excitability by NO.
@en
P2093
Gerard P Ahern
Meyer B Jackson
Vitaly A Klyachko
P304
P356
10.1016/S0166-2236(02)02254-3
P577
2002-10-01T00:00:00Z