mVps34 is activated following high-resistance contractions
about
The molecular basis for load-induced skeletal muscle hypertrophyAutophagy is essential to support skeletal muscle plasticity in response to endurance exerciseAge effect on myocellular remodeling: response to exercise and nutrition in humansDietary protein for athletes: from requirements to optimum adaptationNutritional and contractile regulation of human skeletal muscle protein synthesis and mTORC1 signalingThe actions of exogenous leucine on mTOR signalling and amino acid transporters in human myotubes.A limited role for PI(3,4,5)P3 regulation in controlling skeletal muscle mass in response to resistance exercise.Mechanisms involved in the enhancement of mammalian target of rapamycin signalling and hypertrophy in skeletal muscle of myostatin-deficient mice.Application of the [γ-32P] ATP kinase assay to study anabolic signaling in human skeletal muscleMolecular brakes regulating mTORC1 activation in skeletal muscle following synergist ablation.The muscle fiber type-fiber size paradox: hypertrophy or oxidative metabolism?The abundance and activation of mTORC1 regulators in skeletal muscle of neonatal pigs are modulated by insulin, amino acids, and age.Using molecular biology to maximize concurrent training.Exercise attenuates the major hallmarks of aging.Dose-dependent increases in p70S6K phosphorylation and intramuscular branched-chain amino acids in older men following resistance exercise and protein intake.Molecular mechanisms in exercise-induced cardioprotectionExercise, amino acids, and aging in the control of human muscle protein synthesis.Exercise and amino acid anabolic cell signaling and the regulation of skeletal muscle massHRP-3 protects the hepatoma cells from glucose deprivation-induced apoptosis.mTor signaling in skeletal muscle during sepsis and inflammation: where does it all go wrong?Skeletal muscle autophagy and protein breakdown following resistance exercise are similar in younger and older adultsHypertrophy-Promoting Effects of Leucine Supplementation and Moderate Intensity Aerobic Exercise in Pre-Senescent Mice.Nutrient ingestion increased mTOR signaling, but not hVps34 activity in human skeletal muscle after sprint exercise.Distinct amino acid-sensing mTOR pathways regulate skeletal myogenesis.Changes in muscle mass with mechanical load: possible cellular mechanisms.Molecular responses to strength and endurance training: are they incompatible?mTOR function in skeletal muscle: a focal point for overnutrition and exercise.Anabolic and catabolic pathways regulating skeletal muscle mass.The mechanical activation of mTOR signaling: an emerging role for late endosome/lysosomal targeting.Insulin increases mRNA abundance of the amino acid transporter SLC7A5/LAT1 via an mTORC1-dependent mechanism in skeletal muscle cells.Mechanotransduction and the regulation of mTORC1 signaling in skeletal muscleLeucine as a pharmaconutrient to prevent and treat sarcopenia and type 2 diabetes.Autophagy as a Potential Target for Sarcopenia.Autophagy-Dependent Beneficial Effects of Exercise.Skeletal muscle autophagy and apoptosis during aging: effects of calorie restriction and life-long exerciseWhey protein ingestion activates mTOR-dependent signalling after resistance exercise in young men: a double-blinded randomized controlled trial.The effect of concurrent training organisation in youth elite soccer players.Sirolimus and mTORC1: centre stage in the story of what makes muscles bigger?Signals mediating skeletal muscle remodeling by resistance exercise: PI3-kinase independent activation of mTORC1.Characterisation of L-Type Amino Acid Transporter 1 (LAT1) Expression in Human Skeletal Muscle by Immunofluorescent Microscopy.
P2860
Q26829477-7E229003-67E2-4D82-89E2-BAA68D445C6FQ27000625-6B0378E3-2774-49B8-B0A9-9FB4A9EB6886Q27024546-12BD8A86-7237-414F-977C-F8C482003A20Q28254825-01F47DAA-6DC4-4E31-A4FD-3179E2988712Q28307009-31E87B39-EA9D-4757-95BB-307E5F448E43Q31021169-A1E02E37-1735-4713-B5A8-8A4B3F15DFABQ33641237-9E5FF1F6-BC05-45B6-84E0-2DFB25B24FD1Q33869415-D25552D0-7A25-4B9F-8870-E281B227944FQ33976336-5342AA3D-1FD5-4434-B8D4-DD5DF174579FQ34062789-A3458F77-4A90-4CB3-98F1-B2A6C03E35A0Q34213640-68D5ED15-216B-4952-8DD4-39A0551BC7E5Q34305303-643433EC-34B4-42EE-B156-F4A60A2DA69EQ34422541-945FD16D-FA7F-4388-B613-5E6E15BB491DQ34449998-700A005A-F98B-40FE-90F0-8450BB739BCEQ34582362-72525C6B-F870-42BA-9E98-122CBA752A0AQ34635904-B1B4D412-A957-4323-9C8C-58ADE8707CAAQ35787793-42724651-9D12-4040-B6A8-AD4F67FA7B11Q36126438-DAE7C1D3-ACFC-4F75-9313-94B9D2C6191BQ36464432-8D726407-39AB-4C35-B520-18F219A45EBDQ36711877-E946FB44-8FEA-4131-8871-2CAFD8B70491Q36758018-8929D183-CDC7-4999-B71D-6FCDEADB4C8BQ36941694-1FAFF110-15F1-447D-87B6-2F3A6D4DED53Q37344096-A6AF5FF3-BBA6-4F02-914A-B2F6AE7491C8Q37348772-F18D5378-50BA-48F7-AD00-8B38C929CC1BQ37485980-9011224B-A204-431E-9E2F-5313ADD314CBQ37485998-FCDADA4F-7D96-4C20-BD95-629473557F45Q37638216-CAB39C73-3CCC-40D8-9AA3-433816BA2E94Q37692092-9F57BB44-FF46-4AC9-945F-712A302B436DQ37695028-512B9545-9F45-4B61-8AF8-ED89A84FC6C2Q37727865-7A4209CE-7C18-4156-9CD6-23AAF6FB8DE9Q37881444-387E62DE-54F5-481F-AFDD-082C0BE18AABQ37949691-6FD59B0B-A470-4056-B033-521D957A8A31Q38637495-8C1478A8-B717-4A26-BC7C-DE558C23FFB2Q39167062-9757E8BF-8344-40B7-A84B-67470C1DA3DCQ39326231-1E407790-4837-4620-9829-05D0F3D8330FQ40377091-007B5048-D513-4DB0-90BD-B46B4FE1B162Q40721214-C86A61E4-3F0F-4486-9F2D-FD7245060044Q46066667-AC69E319-D480-4F69-AAF1-92EEBB8ADE75Q46548247-102FC2C8-FB25-4CFB-AC78-9A6A187089D9Q47254310-694249CE-7C75-492B-A77B-1CF735B992D1
P2860
mVps34 is activated following high-resistance contractions
description
2009 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի հունվարին հրատարակված գիտական հոդված
@hy
artículu científicu espublizáu en 2009
@ast
im Januar 2009 veröffentlichter wissenschaftlicher Artikel
@de
scientific journal article
@en
vedecký článok (publikovaný 2009/01/15)
@sk
vědecký článek publikovaný v roce 2009
@cs
wetenschappelijk artikel (gepubliceerd op 2009/01/15)
@nl
наукова стаття, опублікована в січні 2009
@uk
مقالة علمية (نشرت في 15-1-2009)
@ar
name
mVps34 is activated following high-resistance contractions
@ast
mVps34 is activated following high-resistance contractions
@en
mVps34 is activated following high-resistance contractions
@nl
type
label
mVps34 is activated following high-resistance contractions
@ast
mVps34 is activated following high-resistance contractions
@en
mVps34 is activated following high-resistance contractions
@nl
prefLabel
mVps34 is activated following high-resistance contractions
@ast
mVps34 is activated following high-resistance contractions
@en
mVps34 is activated following high-resistance contractions
@nl
P2093
P2860
P3181
P1476
mVps34 is activated following high-resistance contractions
@en
P2093
Keith Baar
Matthew G MacKenzie
Peter M Taylor
P2860
P304
P3181
P356
10.1113/JPHYSIOL.2008.159830
P407
P577
2008-11-17T00:00:00Z