Functional interaction of regulatory factors with the Pgc-1alpha promoter in response to exercise by in vivo imaging.
about
Knock-in Luciferase Reporter Mice for In Vivo Monitoring of CREB ActivityCreb coactivators direct anabolic responses and enhance performance of skeletal muscleEffects of resveratrol and SIRT1 on PGC-1α activity and mitochondrial biogenesis: a reevaluationβ-Adrenergic stimulation does not activate p38 MAP kinase or induce PGC-1α in skeletal muscleMolecular mechanisms for mitochondrial adaptation to exercise training in skeletal muscle.Exercise, PGC-1alpha, and metabolic adaptation in skeletal muscle.PGC-1alpha plays a functional role in exercise-induced mitochondrial biogenesis and angiogenesis but not fiber-type transformation in mouse skeletal muscle.Regulation of exercise-induced fiber type transformation, mitochondrial biogenesis, and angiogenesis in skeletal musclePGC-1alpha regulation by exercise training and its influences on muscle function and insulin sensitivity.p38gamma mitogen-activated protein kinase is a key regulator in skeletal muscle metabolic adaptation in mice.Chronic AMP-activated protein kinase activation and a high-fat diet have an additive effect on mitochondria in rat skeletal musclep38 mitogen-activated protein kinase and calcium channels mediate signaling in depolarization-induced activation of peroxisome proliferator-activated receptor gamma coactivator-1alpha in neuronsPGC-1 coactivators and skeletal muscle adaptations in health and disease.PGC-1alpha-mediated regulation of gene expression and metabolism: implications for nutrition and exercise prescriptions.PGC-1alpha-induced improvements in skeletal muscle metabolism and insulin sensitivity.Regulation of skeletal muscle cell plasticity by the peroxisome proliferator-activated receptor γ coactivator 1α.Regulation of mitochondrial biogenesis and GLUT4 expression by exercise.Optimizing intramuscular adaptations to aerobic exercise: effects of carbohydrate restriction and protein supplementation on mitochondrial biogenesis.Regulation of PGC-1α Isoform Expression in Skeletal Muscles.Transcriptome and translational signaling following endurance exercise in trained skeletal muscle: impact of dietary protein.Molecular mechanisms underlying protective effects of quercetin against mitochondrial dysfunction and progressive dopaminergic neurodegeneration in cell culture and MitoPark transgenic mouse models of Parkinson's Disease.Postexercise cold water immersion modulates skeletal muscle PGC-1α mRNA expression in immersed and nonimmersed limbs: evidence of systemic regulation.Coregulator-mediated control of skeletal muscle plasticity - A mini-reviewKnockout of the predominant conventional PKC isoform, PKCalpha, in mouse skeletal muscle does not affect contraction-stimulated glucose uptake.Is sprint exercise a leptin signaling mimetic in human skeletal muscle?Interactions between the consumption of a high-fat diet and fasting in the regulation of fatty acid oxidation enzyme gene expression: an evaluation of potential mechanisms.A novel and complex mechanism regulating PGC-1α4 expression.Exercise intensity-dependent regulation of peroxisome proliferator-activated receptor coactivator-1 mRNA abundance is associated with differential activation of upstream signalling kinases in human skeletal muscle.
P2860
Q27335935-61A7A027-E1D6-4E6B-945E-045FF878E19CQ28507328-27F431F1-F498-4150-B755-29E35B4C71C3Q28534558-5409643D-6A22-4404-8447-2013BAD40323Q28568738-D5F7DCFB-FF25-455C-A809-E603A01862B8Q30278688-19F223C6-C752-4637-B201-1453C78572BFQ30426878-FB7A3E26-0ACB-429A-BBFC-03ED62C1D92BQ30426890-2091B2D0-4F73-498B-BEBB-8E3F5A4CC9A7Q30428955-8A2E0C8A-E529-4B21-9924-0A1D155CD5A3Q30431199-96128D11-3B57-4590-961A-157C6FE8A067Q30437834-31547103-22CF-4B5D-AF2F-3AD849786BA3Q34085463-BCF9DB8B-FFE9-47EB-8E94-48AACAAF1462Q37010156-656C9C47-A0D5-4BF0-B1C3-37C68B882C37Q37265277-C7564050-4F77-49BD-8D3C-96F52995E8DAQ37299286-0DA96D89-9EEC-47A5-9D99-DBD256211836Q37485965-F3BE5D81-EAC3-4B21-8929-E9242E3E8063Q37697191-207DFD45-5CAF-43FE-91E5-1EC5C155DC10Q38112060-B991E1BF-BB92-4466-8551-D4596176F2D0Q38162447-18DDEEC1-CE99-4DFC-BB6A-71E70A7940F6Q38450914-5BBFA14C-F418-48BD-9DA5-C1D9AEEDDA77Q38501558-0DE558A5-D479-48FB-BD45-79455B6E47B5Q38708951-D236CB5C-C71E-41B5-B078-B96ACB809CCAQ38762794-15A1920D-6AA0-47B8-A2B0-90D0D3EB6D8AQ39069079-C867B3C3-C6E7-487A-8B67-F644A512A2BBQ46003366-98C4201F-DE9D-4CE6-8215-235A1899C0BEQ51372261-D3F398E7-DC56-473D-947E-D7F617E32559Q51386796-70DFB741-A309-438B-AB3E-72DF58B665EFQ52769910-AEB22AB5-334C-44FA-8AD2-05EAAD5855F3Q54685224-F8D08584-528B-4CE1-AF0A-4901FB918A05
P2860
Functional interaction of regulatory factors with the Pgc-1alpha promoter in response to exercise by in vivo imaging.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
2008年论文
@zh
2008年论文
@zh-cn
name
Functional interaction of regu ...... o exercise by in vivo imaging.
@ast
Functional interaction of regu ...... o exercise by in vivo imaging.
@en
type
label
Functional interaction of regu ...... o exercise by in vivo imaging.
@ast
Functional interaction of regu ...... o exercise by in vivo imaging.
@en
prefLabel
Functional interaction of regu ...... o exercise by in vivo imaging.
@ast
Functional interaction of regu ...... o exercise by in vivo imaging.
@en
P2093
P2860
P1476
Functional interaction of regu ...... o exercise by in vivo imaging.
@en
P2093
Takayuki Akimoto
P2860
P304
P356
10.1152/AJPCELL.00104.2008
P577
2008-04-23T00:00:00Z