about
Angiotensin II inhibits the Na+-K+ pump via PKC-dependent activation of NADPH oxidaseReversible oxidative modification: a key mechanism of Na+-K+ pump regulationActivation of cAMP-dependent signaling induces oxidative modification of the cardiac Na+-K+ pump and inhibits its activity.Identification of electric-field-dependent steps in the Na(+),K(+)-pump cycle.FXYD proteins reverse inhibition of the Na+-K+ pump mediated by glutathionylation of its beta1 subunit.Oxidative inhibition of the vascular Na+-K+ pump via NADPH oxidase-dependent β1-subunit glutathionylation: implications for angiotensin II-induced vascular dysfunctionStimulation of the cardiac myocyte Na+-K+ pump due to reversal of its constitutive oxidative inhibition.β3-Adrenoceptor activation relieves oxidative inhibition of the cardiac Na+-K+ pump in hyperglycemia induced by insulin receptor blockade.Kinetic comparisons of heart and kidney Na+,K(+)-ATPases.Glutathionylation-Dependence of Na(+)-K(+)-Pump Currents Can Mimic Reduced Subsarcolemmal Na(+) Diffusion.β3 Adrenergic Stimulation Restores Nitric Oxide/Redox Balance and Enhances Endothelial Function in Hyperglycemia.Extracellular allosteric Na(+) binding to the Na(+),K(+)-ATPase in cardiac myocytesRedox-dependent regulation of the Na⁺-K⁺ pump: new twists to an old target for treatment of heart failure.Complete Sertoli cell proliferation induced by follicle-stimulating hormone (FSH) independently of luteinizing hormone activity: evidence from genetic models of isolated FSH action.Electrostatic Stabilization Plays a Central Role in Autoinhibitory Regulation of the Na+,K+-ATPase.Protein kinase-dependent oxidative regulation of the cardiac Na+-K+ pump: evidence from in vivo and in vitro modulation of cell signalling.The voltage-sensitive dye RH421 detects a Na+,K+-ATPase conformational change at the membrane surface.The nitric oxide donor sodium nitroprusside stimulates the Na+-K+ pump in isolated rabbit cardiac myocytes.Opposing effects of coupled and uncoupled NOS activity on the Na+-K+ pump in cardiac myocytes.Interaction of N-terminal peptide analogues of the Na+,K+-ATPase with membranesMembrane accessibility of glutathioneAlloxan-induced diabetes reduces sarcolemmal Na+-K+ pump function in rabbit ventricular myocytesStimulation of Na+,K+-ATPase Activity as a Possible Driving Force in Cholesterol EvolutionEvidence for ATP Interaction with Phosphatidylcholine BilayersCompeting for the same space: protons and alkali ions at the interface of phospholipid bilayers
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Q24336297-F74A3524-2B7C-42D5-B472-7598517B9923Q24338803-24B2E895-DC7C-405E-97F0-EB898C31084BQ33810067-BA9CD5CD-6191-4DAE-A087-125AE1B8A672Q34203746-B3A9C1C9-BF1F-4EC7-9F7F-04B924553D7DQ34998062-568DC45C-71C8-469B-8F36-50B1EFCFCF5CQ35760065-8C0550BF-BB11-4ADE-AABA-7C6D4B5FBA49Q35958555-AC5B19F7-9C36-4BAF-83DF-9E32B78A961FQ36017635-7CC27393-73F7-4959-97E6-8AC21851DBF8Q36238151-1D7682A6-A61B-4048-BAAA-57303A6B9D7BQ36678683-74068D4D-8B2B-4064-A785-8D7333E7BE5CQ36714097-A55DDDB1-5651-4BE5-B905-19E69F43AA83Q37440301-8128C884-37E7-4243-B7B8-1B16FA1023FCQ38111160-B11F658F-E728-4A8C-8CA3-6016949B13BEQ40598917-78DA9968-0865-4677-AD36-FD52867E60F6Q44151727-DDB1B9F6-546E-4348-A9C0-1EFDD6285559Q45842086-636CF93F-94DE-4408-AC21-05A88C0E302CQ46128965-D3D4D980-8697-461D-A700-3AACC0A4AA36Q46427654-5025DC14-16A1-42AC-A435-702A5F2C5A5BQ46868100-3170B182-EABA-4E63-B18D-E117B724AE1FQ60194853-FC0A0BF7-26AC-4197-9C3E-6D1CB3BDD9A2Q60194866-9D148876-AC15-4547-B4C8-E6DCCACD41DDQ61623634-15DD7563-F1F3-4DBA-BD93-0F59AC54EEBCQ61985870-82E49940-C113-44BA-B76B-46A00EEEAE3FQ91766523-282809ED-2B65-4C0E-BB67-56C7DC9F9196Q92210379-B47049D5-A361-4608-B820-F2785BE52327
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description
onderzoeker
@nl
researcher ORCID ID = 0000-0002-1159-4567
@en
name
Alvaro Garcia
@ast
Alvaro Garcia
@en
Alvaro Garcia
@es
Alvaro Garcia
@nl
type
label
Alvaro Garcia
@ast
Alvaro Garcia
@en
Alvaro Garcia
@es
Alvaro Garcia
@nl
prefLabel
Alvaro Garcia
@ast
Alvaro Garcia
@en
Alvaro Garcia
@es
Alvaro Garcia
@nl
P106
P21
P31
P496
0000-0002-1159-4567