Family of glucose-transporter genes. Implications for glucose homeostasis and diabetes.
about
Activity and genomic organization of human glucose transporter 9 (GLUT9), a novel member of the family of sugar-transport facilitators predominantly expressed in brain and leucocytes1-Phosphatidylinositol 3-kinase activity is required for insulin-stimulated glucose transport but not for RAS activation in CHO cellsCardiac hypertrophy with preserved contractile function after selective deletion of GLUT4 from the heartCharacterization of human glucose transporter (GLUT) 11 (encoded by SLC2A11), a novel sugar-transport facilitator specifically expressed in heart and skeletal muscleThe effects of propionate and valerate on insulin responsiveness for glucose uptake in 3T3-L1 adipocytes and C2C12 myotubes via G protein-coupled receptor 41GLUT8, a novel member of the sugar transport facilitator family with glucose transport activityIntracellular targeting of the insulin-regulatable glucose transporter (GLUT4) is isoform specific and independent of cell typeSLC2A10 genetic polymorphism predicts development of peripheral arterial disease in patients with type 2 diabetes. SLC2A10 and PAD in type 2 diabetes.Placental glucose transporter gene expression and metabolism in the rat.Anatomical and developmental patterns of facilitative glucose transporter gene expression in the rat kidney.Metastatic hepatocarcinoma he/de tumor model in rat.Overexpression of Glut4 protein in muscle increases basal and insulin-stimulated whole body glucose disposal in conscious mice.Divergent regulation of the Glut 1 and Glut 4 glucose transporters in isolated adipocytes from Zucker rats.Human cytomegalovirus activates glucose transporter 4 expression to increase glucose uptake during infectionRegulation of facilitative glucose transporters and AKT/MAPK/PRKAA signaling via estradiol and progesterone in the mouse uterine epitheliumImmunohistochemical assessment of intrinsic and extrinsic markers of hypoxia in reproductive tissue: differential expression of HIF1α and HIF2α in rat oviduct and endometrium.Facilitative glucose transporters: regulatory mechanisms and dysregulation in diabetesOverexpression of GLUT3 placental glucose transporter in diabetic rats.Phytanic acid stimulates glucose uptake in a model of skeletal muscles, the primary porcine myotubes.Regulation of gene expression by insulin.Diverse effects of Glut 4 ablation on glucose uptake and glycogen synthesis in red and white skeletal muscle.Glucagon-like peptide-1 can reverse the age-related decline in glucose tolerance in ratsMyocardial insulin resistance in patients with syndrome X.The ubiquitous glucose transporter GLUT-1 belongs to the glucose-regulated protein family of stress-inducible proteins.Hepatic expression and cellular distribution of the glucose transporter family.Photolabelling of the liver-type glucose-transporter isoform GLUT2 with an azitrifluoroethylbenzoyl-substituted bis-D-mannose.Di(2-ethylhexyl)phthalate exposure impairs insulin receptor and glucose transporter 4 gene expression in L6 myotubes.Regulation of glucose transporters by insulin and extracellular glucose in C2C12 myotubes.Metabolic handling of orally administered glucose in cirrhosis.Factors influencing [F-18] 2-fluoro-2-deoxy-D-glucose (F-18 FDG) uptake in melanoma cells: the role of proliferation rate, viability, glucose transporter expression and hexokinase activity.Dual control of glut1 glucose transporter gene expression by hypoxia and by inhibition of oxidative phosphorylation.Induction of GLUT-1 mRNA in response to inhibition of oxidative phosphorylation: role of increased [Ca2+]i.Substitution of conserved tyrosine residues in helix 4 (Y143) and 7 (Y293) affects the activity, but not IAPS-forskolin binding, of the glucose transporter GLUT4.Characterization of glucose transport system in Drosophila Kc cells.Polymorphisms at the GLUT1 (HepG2) and GLUT4 (muscle/adipocyte) glucose transporter genes and non-insulin-dependent diabetes mellitus (NIDDM).Differential regulation of the HepG2 and adipocyte/muscle glucose transporters in 3T3L1 adipocytes. Effect of chronic glucose deprivationDifferential targeting of glucose transporter isoforms heterologously expressed in Xenopus oocytes.Analysis of the structural requirements of sugar binding to the liver, brain and insulin-responsive glucose transporters expressed in oocytes.Kinetic resolution of the separate GLUT1 and GLUT4 glucose transport activities in 3T3-L1 cells.Serine-294 and threonine-295 in the exofacial loop domain between helices 7 and 8 of glucose transporters (GLUT) are involved in the conformational alterations during the transport process.
P2860
Q24290176-2C6FC657-DD9D-44DA-8969-8A63EF07D230Q24316333-07A310A7-58BF-4475-AD16-C4F61FF9A300Q24562618-B7AC5478-F008-43E7-9C88-1E7628C439A6Q28360910-791F21A1-1416-4172-9D0C-2F63F13DA13AQ28588479-D22127AC-35AC-41D3-9E55-DED9565A55E1Q28593285-CC6956BB-9602-4D31-9EF1-A392CB333D06Q33235315-EEBC9B9C-9704-4079-9488-265E85D17844Q33671571-2B13E36E-FB21-427A-91BD-9286C3053D99Q33892661-B60B9F8A-98E8-4781-A04C-BF5ED6CD95EEQ33897182-85332343-B320-45A5-9CBE-A8AC409F6EBDQ33935210-8F1211B6-A972-4D39-880D-4087D4C6A5F7Q34196736-B2085AF5-AB1E-4F08-B5D3-85AC20E9F792Q34221280-98D90C2D-3B4E-42F1-B9E9-518F35CA4C34Q34529843-8010D212-A911-4CA2-92E0-34E0FD057A77Q34979443-FEAB8F87-2B66-4784-BE35-247636311FC3Q35106512-AB0E53B9-A6B9-4742-8D58-87E1FFCF68E1Q35601498-6DA17FFD-4C94-463C-8A54-F7859F6DEEC4Q35750602-F32F8CC4-E412-4A2B-852F-025B89AD8CC8Q36710644-BA9B3366-1D29-4B78-B0B7-33AF91B8A624Q37317125-677D40B2-8E38-4F4C-AA87-42213169601FQ37358078-E5EBDAA2-5264-423B-9CCF-4F3DC95C67A3Q37368678-392BCA83-3CD4-4AC7-A2FC-DAF8706ABEDAQ37373278-CD76DA17-E69E-430A-8C29-0C3266C4D8BBQ37448743-F1EC34DE-E550-4318-A103-080012598D29Q38067388-03D9F692-6B8E-4AAA-A5DB-3526D93DE2ADQ38326219-1F9D1FD6-61C9-4061-8FFB-C524602E19D4Q39077948-0F59F899-B6BC-4EDE-A118-28D60C786D1FQ40273694-2AE89379-5036-4DEC-8CE8-D51E344F7962Q40303746-34926182-574B-42CB-8002-CD9029E958BAQ40393387-CE3637E2-7C42-4BF8-818E-43ACE1F86EF9Q41126616-BC78BF85-7763-44F2-856A-32F2AAAE5E19Q41250160-99B6E938-9E01-4B67-AC7A-A68AD45EA7A5Q41455306-89C78D3F-AC0A-439C-924D-0D1BD9F9CBF3Q41573681-62A65F30-FD28-484D-BABE-FE95AEF40FA8Q41638161-F01154A1-7DD1-4121-AA78-0257F9D6E1B3Q41719193-239307D8-90DA-48F7-AFA9-4C5E007E6891Q41866053-03C2F16A-F73B-4C33-9C42-B44DED475A09Q41941880-C7B8E988-E98D-45E5-A823-5863F2F6B950Q42012336-28B89AAA-4D8A-426D-919C-E4FEBAB02A7CQ42042404-C2B13089-6645-42B4-8A94-8B2503269CA0
P2860
Family of glucose-transporter genes. Implications for glucose homeostasis and diabetes.
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Family of glucose-transporter genes. Implications for glucose homeostasis and diabetes.
@en
Family of glucose-transporter genes. Implications for glucose homeostasis and diabetes.
@nl
type
label
Family of glucose-transporter genes. Implications for glucose homeostasis and diabetes.
@en
Family of glucose-transporter genes. Implications for glucose homeostasis and diabetes.
@nl
prefLabel
Family of glucose-transporter genes. Implications for glucose homeostasis and diabetes.
@en
Family of glucose-transporter genes. Implications for glucose homeostasis and diabetes.
@nl
P356
P1433
P1476
Family of glucose-transporter genes. Implications for glucose homeostasis and diabetes.
@en
P2093
Mueckler M
P356
10.2337/DIACARE.39.1.6
P407
P577
1990-01-01T00:00:00Z