about
Disruption of Fyn SH3 domain interaction with a proline-rich motif in liver kinase B1 results in activation of AMP-activated protein kinaseFyn-dependent regulation of energy expenditure and body weight is mediated by tyrosine phosphorylation of LKB1The Deep Correlation between Energy Metabolism and Reproduction: A View on the Effects of Nutrition for Women FertilityLactate transport and signaling in the brain: potential therapeutic targets and roles in body-brain interactionAMP-activated protein kinase: a cellular energy sensor that comes in 12 flavoursmTOR signaling in tumorigenesisEffects of AMP-activated protein kinase in cerebral ischemiaPhosphorylation of Cytochrome c Threonine 28 Regulates Electron Transport Chain Activity in Kidney: IMPLICATIONS FOR AMP KINASEAMP-activated protein kinase mediates myogenin expression and myogenesis via histone deacetylase 5The last enzyme of the de novo purine synthesis pathway 5-aminoimidazole-4-carboxamide ribonucleotide formyltransferase/IMP cyclohydrolase (ATIC) plays a central role in insulin signaling and the Golgi/endosomes protein networkThe metabolic consequences of hepatic AMP-kinase phosphorylation in rainbow troutEffects of resveratrol in experimental and clinical non-alcoholic fatty liver diseaseSuppression of chemically induced and spontaneous mouse oocyte activation by AMP-activated protein kinase.AMP-activated protein kinase regulates intraocular pressure, extracellular matrix, and cytoskeleton in trabecular meshwork.AMPK as a metabolic tumor suppressor: control of metabolism and cell growth.Quantitative proteomics identification of phosphoglycerate mutase 1 as a novel therapeutic target in hepatocellular carcinoma.Targeted therapies of the LKB1/AMPK pathway for the treatment of insulin resistanceIdentification and validation of the pathways and functions regulated by the orphan nuclear receptor, ROR alpha1, in skeletal muscle.AMPKalpha2 deletion causes aberrant expression and activation of NAD(P)H oxidase and consequent endothelial dysfunction in vivo: role of 26S proteasomes.The outcome of renal ischemia-reperfusion injury is unchanged in AMPK-β1 deficient mice.Sestrin2 modulates AMPK subunit expression and its response to ionizing radiation in breast cancer cells.Folliculin (Flcn) inactivation leads to murine cardiac hypertrophy through mTORC1 deregulationEvolving Lessons on the Complex Role of AMPK in Normal Physiology and Cancer.The Murphy Roths Large (MRL) mouse strain is naturally resistant to high fat diet-induced hyperglycemiaAMP activated protein kinase is indispensable for myocardial adaptation to caloric restriction in mice.AMP-activated protein kinase suppresses matrix metalloproteinase-9 expression in mouse embryonic fibroblasts.AMP-activated protein kinase regulates beta-catenin transcription via histone deacetylase 5.NLRP3 inflammasome: from a danger signal sensor to a regulatory node of oxidative stress and inflammatory diseases.Augmented AMPK activity inhibits cell migration by phosphorylating the novel substrate Pdlim5AMP-activated protein kinase deficiency reduces ozone-induced lung injury and oxidative stress in mice.Caloric restriction mimetic 2-deoxyglucose antagonizes doxorubicin-induced cardiomyocyte death by multiple mechanisms.Activation of AMPKα2 is not crucial for mitochondrial uncoupling-induced metabolic effects but required to maintain skeletal muscle integrityIdentification of AMP-activated protein kinase targets by a consensus sequence search of the proteome.Impaired expression of uncoupling protein 2 causes defective postischemic angiogenesis in mice deficient in AMP-activated protein kinase α subunitsLoss of AMP-activated protein kinase induces mitochondrial dysfunction and proinflammatory response in unstimulated Abcd1-knockout mice mixed glial cells.Angiotensin II activates AMPK for execution of apoptosis through energy-dependent and -independent mechanismsCompartmentalized AMPK signaling illuminated by genetically encoded molecular sensors and actuatorsAMPK protects proximal tubular cells from stress-induced apoptosis by an ATP-independent mechanism: potential role of Akt activation.AMP-Activated Protein Kinase Regulates the Cell Surface Proteome and Integrin Membrane Traffic.Deletion of CaMKK2 from the liver lowers blood glucose and improves whole-body glucose tolerance in the mouse
P2860
Q21132307-B3A02F27-0623-4981-8C6A-829A119E2BF5Q24634669-BEDAF5D8-AD10-40CE-8931-B898CFF961C9Q26766160-F2ED36A5-AC3A-4317-873B-EFDB971E27E3Q26851808-6D4EB289-AFB4-457F-BFDC-C124DD8AEB1DQ28074581-4BD4BEC6-07C9-4DEE-B041-507E4350A083Q28252695-6657CA2F-5077-44BA-BB67-34E7014BF3BCQ28394686-5DA9CB44-DE46-45DB-A4E9-AF46EE40294DQ28397825-47AD65AD-DDC8-4AFD-AE05-2AD4D30651E5Q28506793-1C86C9A8-DD1E-45AF-882A-4256F0352B65Q28573050-96992187-9E33-4862-A5A3-03323871A099Q28744383-B86116F3-B9F0-4848-969B-7DDDFB82B651Q33563877-2A479A32-5898-4560-AE92-A508298B849CQ33581534-E407A944-FBBB-4927-B4EB-99F7AAE6A681Q33621882-DD357E04-05F2-420C-9663-F76A1DDBC9D0Q33789079-5106D36D-9272-44F8-B0D3-14C84B5D2101Q33864148-20D22775-D547-4FA5-857D-FFBD12843590Q34004470-6A93766C-E7CC-444A-8F93-6857432A8F62Q34020241-401CAB8A-6C95-48B8-88C9-B94E71ED0BEBQ34059872-99A421A0-E279-4D38-8DF6-D9DA989F530CQ34130765-B037D8C9-1FEB-44A7-B407-EB165FF97109Q34171596-12E4FB0C-777F-4D88-9D71-A987B439BB16Q34307302-32D11832-E162-42EF-9825-1A59788C30B2Q34506762-E0A2A260-E1AD-4E02-8342-2B43D70F444AQ34614691-9D593854-9DA6-46AD-A376-3C59C13BF6FEQ34635436-16235753-0A81-4857-A8D3-1E2C46FE4EE6Q34963339-D2E4608B-3687-44D0-B33C-0E72098F6719Q34963731-A499C2B8-DADE-4506-B2DA-DC6053A6F19EQ35045146-3EF0BD83-1F7B-4CB8-B612-CB606564209BQ35050467-D3946C0C-5856-4DDA-9F1D-35355E94909AQ35061128-E37F0140-ED22-4F2C-A74C-C60EA0A65D06Q35063002-2C0E9A84-5086-4552-B04F-C93D03E4C885Q35147707-59BE716F-3018-4C7D-B24B-DBFD3B9637F3Q35169812-FBE16DF5-C185-4D33-8287-D62AA20F6D32Q35173223-42C209B3-014F-463D-8635-5B5B47BD4C3BQ35227024-48B83613-A7A6-466D-A05C-8DEF05A395D1Q35543598-904A5CEA-BAF0-453E-B33A-56D2CE3992D8Q35561785-B8958159-425D-44CA-B45A-D44DA07A9100Q35601626-7666FE01-F209-407D-93A6-139C55CD2C6BQ35641071-6AA16BEE-D352-4023-8E10-94D6A4FE0858Q35744039-86FA3EFE-68B5-496D-A712-4C6BF834BB12
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on January 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
AMPK: Lessons from transgenic and knockout animals
@en
AMPK: Lessons from transgenic and knockout animals.
@nl
type
label
AMPK: Lessons from transgenic and knockout animals
@en
AMPK: Lessons from transgenic and knockout animals.
@nl
prefLabel
AMPK: Lessons from transgenic and knockout animals
@en
AMPK: Lessons from transgenic and knockout animals.
@nl
P2093
P2860
P50
P356
P1476
AMPK: Lessons from transgenic and knockout animals
@en
P2093
Christophe Beauloye
Elham Zarrinpashneh
Fabrizio Andreelli
Jocelyne Devin-Leclerc
Louise Lantier
Luc Bertrand
Remi Mounier
Renee Ventura-Clapier
Sandrine Horman
Sophie Hebrard
P2860
P356
10.2741/3229
P577
2009-01-01T00:00:00Z