about
A synthetic chloride channel restores chloride conductance in human cystic fibrosis epithelial cellsUpregulation of Angiotensin (1-7)-Mediated Signaling Preserves Endothelial Function Through Reducing Oxidative Stress in Diabetes.Biological properties of baicalein in cardiovascular systemPhysiology and cell biology of acupuncture observed in calcium signaling activated by acoustic shear waveTRPV4, TRPC1, and TRPP2 assemble to form a flow-sensitive heteromeric channelAbolition of endothelium-dependent relaxation in the rat aorta by tetraoctylammonium ions.Gastrodin Inhibits Store-Operated Ca2+ Entry and Alleviates Cardiac Hypertrophy.Cyclic nucleotide-gated channels contribute to thromboxane A2-induced contraction of rat small mesenteric arteries.Essential role for TrpC5-containing extracellular vesicles in breast cancer with chemotherapeutic resistance.Primary structure and functional expression of a cGMP-gated potassium channel.TRPC5-induced autophagy promotes drug resistance in breast carcinoma via CaMKKβ/AMPKα/mTOR pathwayVasorelaxant effects of cardamonin and alpinetin from Alpinia henryi K. Schum.Effect of hydrogen peroxide and superoxide anions on cytosolic Ca2+: comparison of endothelial cells from large-sized and small-sized arteriesUncoupling protein-2 mediates DPP-4 inhibitor-induced restoration of endothelial function in hypertension through reducing oxidative stress.Role of TRPM2 in H(2)O(2)-induced cell apoptosis in endothelial cells.Stimulation of histamine H2 receptors activates TRPC3 channels through both phospholipase C and phospholipase D.Cilnidipine, a slow-acting Ca2+ channel blocker, induces relaxation in porcine coronary artery: role of endothelial nitric oxide and [Ca2+]iA small synthetic molecule forms selective potassium channels to regulate cell membrane potential and blood vessel tone.Plasma membrane mechanical stress activates TRPC5 channels.Role of TRPV1 in the Differentiation of Mouse Embryonic Stem Cells into Cardiomyocytes.Apigenin, a plant-derived flavone, activates transient receptor potential vanilloid 4 cation channel.Conserved function of the lysine-based KXD/E motif in Golgi retention for endomembrane proteins among different organisms.PPARδ activation protects endothelial function in diabetic mice.Store-operated calcium entry in vascular smooth muscle.TRPV4 and the regulation of vascular toneRegulation of canonical transient receptor potential isoform 3 (TRPC3) channel by protein kinase G.Oxidative stress-dependent cyclooxygenase-2-derived prostaglandin f(2α) impairs endothelial function in renovascular hypertensive rats.Raloxifene, tamoxifen and vascular tone.Raloxifene protects endothelial cell function against oxidative stressTRPC5 channels participate in pressure-sensing in aortic baroreceptors.Chronic black tea extract consumption improves endothelial function in ovariectomized ratsTranslocation of PKG1α acts on TRPV4-C1 heteromeric channels to inhibit endothelial Ca(2+) entryThe mechanism of transactivation regulation due to polymorphic short tandem repeats (STRs) using IGF1 promoter as a model.Role of cyclic nucleotides in the control of cytosolic Ca2+ levels in vascular endothelial cells.An upregulation in the expression of vanilloid transient potential channels 2 enhances hypotonicity-induced cytosolic Ca²⁺ rise in human induced pluripotent stem cell model of Hutchinson-Gillford Progeria.TRP channels in vascular endothelial cells.Histone deacetylase (HDAC) inhibitors relax mouse aorta partly by their inhibitory action on L-type Ca2+ channels.Rosuvastatin improves endothelial function in db/db mice: role of angiotensin II type 1 receptors and oxidative stress.Zeranol induces COX-2 expression through TRPC-3 activation in the placental cells JEG-3.Inhibition of miR-200c Restores Endothelial Function in Diabetic Mice Through Suppression of COX-2.
P50
Q27305063-936B0613-5E3C-48B0-A7B4-C64BF64A5A2AQ27308039-862EF2E5-7F44-4A0D-81DD-1760670F89E6Q28246946-3C41DBB4-34BD-4CD2-92F6-6CCAFCE22607Q30474058-85EF6797-6F53-4099-A6E2-F412331BC780Q30593487-AA729C0C-DADF-4C18-BC87-339ABBA42E58Q30912231-4EB7FD68-188D-4F55-889A-A8478737F38BQ33601764-97332CB8-990E-4FE2-BB36-1CD8492B0E2DQ33608615-A99AD12E-55B0-47EE-B927-FF4B8CA4531EQ33674156-392753DD-60B0-4265-8E48-3D0A2F783F4EQ33717689-7950CDE9-CF8C-4D6D-AC04-C8B3A14B8397Q33784625-AE75C523-7FD3-40D2-AE76-6A8962681EF0Q33945388-A190E809-1869-40D8-9703-8B057BF7B7AFQ34038341-E4DA00F5-79E1-4FD2-BB9C-94143574156CQ34240788-B942EA52-C911-4965-9806-EAE70A9B1008Q34391387-68CB3763-8DB2-4A99-8E1C-2DFD8D5EA6C0Q34888474-32F0B642-AC0F-4D8A-A80A-A26CFFD49795Q35098576-EC63606B-FFAA-44F8-BFCE-F0E061D85390Q35237233-59090896-C5C3-4AE7-83D4-704C4C43F867Q35596439-B6F4AAB9-81E2-40CA-A3FB-CF90CBCCF9C2Q35711987-DCF2107D-348F-4907-A0AB-FC17606B7229Q36153290-854147C9-FD9D-40B3-9083-2945A4EA4F74Q36274527-9A27FE67-3DCE-4899-A40E-E46754FD0EEBQ36410664-9F4BAC49-3423-4A52-A144-2B2EA7F0906FQ36495122-4E5D83A0-514B-4526-ADD5-3D212A8CA8A3Q36589012-56DA143C-C450-4827-980E-F064CCA760A2Q36603171-203F86EE-B0B9-4F9D-9B57-599DC2E1489BQ36645351-74BE7D2B-3764-4064-B6CB-D5F041EE58DBQ36864691-F664E94F-E4CE-4FAA-AA61-FBDB1F219062Q36938443-6F21CA42-8F99-4599-B2BB-F07109881F81Q37099484-59CBCCF2-5499-4E60-B04F-E0CDBAE1530BQ37104653-3CF8A885-DAFD-4BC5-92D9-7DA2A8D5245EQ37254565-A0DE9067-615B-48B0-8588-7DE1184DACCCQ37464766-CAB4F4B0-B88A-48A5-A382-40AB36717656Q37469141-237A0030-9502-4CB2-9163-E1280FB0B956Q37521095-D41E123B-D76A-4DD4-8759-AD2E1B552DA4Q37835166-ABCEE360-C329-4471-9F0A-F6552362975EQ38599132-036901A8-7498-4347-9F00-F29F1B9B6C87Q38649864-FEB50FD4-AF55-4324-A1B7-B482259E5CFBQ38768480-3F113A16-99DA-493F-BFCF-7F468AFC4A0EQ38798591-5520A78A-9A3D-45E1-8CE2-A25E737DD0A6
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Xiaoqiang Yao
@ast
Xiaoqiang Yao
@en
Xiaoqiang Yao
@es
Xiaoqiang Yao
@nl
type
label
Xiaoqiang Yao
@ast
Xiaoqiang Yao
@en
Xiaoqiang Yao
@es
Xiaoqiang Yao
@nl
prefLabel
Xiaoqiang Yao
@ast
Xiaoqiang Yao
@en
Xiaoqiang Yao
@es
Xiaoqiang Yao
@nl
P106
P31
P496
0000-0002-0687-8186