about
Oligodendrocyte, Astrocyte, and Microglia Crosstalk in Myelin Development, Damage, and RepairThe nitric oxide-cGKII system relays death and survival signals during embryonic retinal development via AKT-induced CREB1 activationNitric oxide modulates sodium vitamin C transporter 2 (SVCT-2) protein expression via protein kinase G (PKG) and nuclear factor-κB (NF-κB).Nitric oxide in the nervous system: biochemical, developmental, and neurobiological aspects.c-Src function is necessary and sufficient for triggering microglial cell activation.Calcium-permeable α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors trigger neuronal nitric-oxide synthase activation to promote nerve cell death in an Src kinase-dependent fashion.Dopamine promotes NMDA receptor hypofunction in the retina through D1 receptor-mediated Csk activation, Src inhibition and decrease of GluN2B phosphorylation.Corrigendum: Oligodendrocyte, Astrocyte and Microglia Crosstalk in Myelin Development, Damage, and Repairc-Src deactivation by the polyphenol 3-O-caffeoylquinic acid abrogates reactive oxygen species-mediated glutamate release from microglia and neuronal excitotoxicity.Glutamate and nitric oxide modulate ERK and CREB phosphorylation in the avian retina: evidence for direct signaling from neurons to Müller glial cells.Structure and function of a novel antioxidant peptide from the skin of tropical frogs.Methylphenidate-triggered ROS generation promotes caveolae-mediated transcytosis via Rac1 signaling and c-Src-dependent caveolin-1 phosphorylation in human brain endothelial cells.The ascorbate transporter SVCT2 to target microglia-dependent inflammation.Vitamin C modulates glutamate transport and NMDA receptor function in the retina.Microglia and alcohol meet at the crossroads: Microglia as critical modulators of alcohol neurotoxicity.Neuronal Rho GTPase Rac1 elimination confers neuroprotection in a mouse model of permanent ischemic stroke.Caveolin-1-mediated internalization of the vitamin C transporter SVCT2 in microglia triggers an inflammatory phenotype.Developmental regulation of neuronal survival by adenosine in the in vitro and in vivo avian retina depends on a shift of signaling pathways leading to CREB phosphorylation or dephosphorylation.Redox tuning of Ca2+ signaling in microglia drives glutamate release during hypoxia.Caffeine exposure alters adenosine system and neurochemical markers during retinal development.Dopamine Promotes Ascorbate Release from Retinal Neurons: Role of D1 Receptors and the Exchange Protein Directly Activated by cAMP type 2 (EPAC2).Dopamine-Induced Ascorbate Release From Retinal Neurons Involves Glutamate Release, Activation of AMPA/Kainate Receptors and Downstream Signaling PathwaysNovel Ocellatin Peptides Mitigate LPS-induced ROS Formation and NF-kB Activation in Microglia and Hippocampal NeuronsDopamine D1 receptor signaling and endocannabinoid cooperate to fuel striatal plasticity: An Editorial Highlight for "Cyclic AMP-dependent protein kinase and D1 dopamine receptors regulate diacylglycerol lipase-α and synaptic 2-arachidonoyl glycerolSomuncurins: Bioactive Peptides from the Skin of the Endangered Endemic Patagonian Frog Pleurodema somuncurenseProtein synthesis inhibition promotes nitric oxide generation and activation of CGKII-dependent downstream signaling pathways in the retina
P50
Q26739719-4D16F3B4-7446-4435-A276-C6DE7707F540Q33580106-62D2EEBD-06BE-4D87-A3A6-D644A579931FQ35763283-E514DF9E-A8D0-4899-8A79-CF839E37F099Q38246122-9E5103B1-69C0-4304-B666-FA198F53C337Q38938038-1A2AE4EB-E6D0-497C-BEC2-5B8F29BD1509Q41311919-9E8B583A-7E6C-4527-9016-4FC475203E5EQ41957673-E753E5B0-BBED-4562-B91B-EFA61B41928EQ42413592-3C8F5F0F-B4CE-432D-A272-34BCBA8C6693Q42469966-1D5BA5E6-8A74-4C41-8C54-552710372A59Q46243679-817B2CCE-1755-486D-8D9E-4855CCEDE2BBQ46256853-8C5B10D6-54B1-4A74-8EBB-7EFEE862B1B2Q46523431-96F41CBD-5540-4595-9BBD-088365C6137AQ47130526-5B651BB2-D750-46E3-BCA4-C28C3295D62EQ47375035-BF64EA91-42AB-4185-B794-4E4BCD050B60Q47617104-CB6787AA-8F36-40F4-A7D4-A2B30009BB9AQ47727115-EF8EDEAB-5916-48AC-8F78-1766AEE2CE99Q48350533-19B34619-55BD-4CF9-9900-EBC2346D6622Q51896284-53772E15-205B-4510-8C92-D3838E03D90DQ52675869-9B9E898E-1495-47BB-BE5B-AFE30E09538DQ53092792-3A397361-94F2-45B3-8D82-2A2E46E87EEDQ54983742-B357F59B-1147-44C2-97EE-405255C203B7Q64259896-C5E63071-37EA-4EC0-82E0-FC9E729CF5B8Q89723213-A0CA9783-041A-40D0-94FD-E2301C8322AEQ89853812-4AAB37E1-E836-43B2-BB02-B24306BB86AFQ90061765-175D6B9F-777A-4E3E-819A-65BF655173DFQ94492378-A66017C7-0EE1-469A-85A6-7A570E6CE972
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Renato Socodato
@ast
Renato Socodato
@en
Renato Socodato
@es
Renato Socodato
@nl
Renato Socodato
@sl
type
label
Renato Socodato
@ast
Renato Socodato
@en
Renato Socodato
@es
Renato Socodato
@nl
Renato Socodato
@sl
prefLabel
Renato Socodato
@ast
Renato Socodato
@en
Renato Socodato
@es
Renato Socodato
@nl
Renato Socodato
@sl
P1053
A-7237-2013
P106
P1153
57195332931
P21
P2798
P31
P3829
P3835
renato-socodato
P496
0000-0002-6882-5020