scholarly article | Q13442814 |
P50 | author | Riki Ogasawara | Q57043257 |
P2093 | author name string | Satoshi Fujita | |
Troy A Hornberger | |||
Koichi Nakazato | |||
Yuhei Makanae | |||
Yu Kitaoka | |||
Ishii Naokata | |||
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LC3, a mammalian homologue of yeast Apg8p, is localized in autophagosome membranes after processing | Q24597817 | ||
Rapamycin-induced insulin resistance is mediated by mTORC2 loss and uncoupled from longevity | Q24598427 | ||
mTOR signaling in growth control and disease | Q24634174 | ||
Akt/mTOR pathway is a crucial regulator of skeletal muscle hypertrophy and can prevent muscle atrophy in vivo | Q28206290 | ||
Prolonged rapamycin treatment inhibits mTORC2 assembly and Akt/PKB | Q28306356 | ||
AMPK and mTOR regulate autophagy through direct phosphorylation of Ulk1 | Q28506431 | ||
Selective activation of AMPK-PGC-1alpha or PKB-TSC2-mTOR signaling can explain specific adaptive responses to endurance or resistance training-like electrical muscle stimulation | Q28582298 | ||
Regulation of the mTOR Complex 1 Pathway by Nutrients, Growth Factors, and Stress | Q29614493 | ||
mTOR controls mitochondrial oxidative function through a YY1-PGC-1alpha transcriptional complex | Q29617214 | ||
Ser-64 and Ser-111 in PHAS-I are dispensable for insulin-stimulated dissociation from eIF4E. | Q30311841 | ||
mTOR-dependent regulation of ribosomal gene transcription requires S6K1 and is mediated by phosphorylation of the carboxy-terminal activation domain of the nucleolar transcription factor UBF. | Q33973841 | ||
Critical roles for mTORC2- and rapamycin-insensitive mTORC1-complexes in growth and survival of BCR-ABL-expressing leukemic cells | Q34004994 | ||
The complexes of mammalian target of rapamycin. | Q34116818 | ||
Exercise metabolism and the molecular regulation of skeletal muscle adaptation | Q34326964 | ||
Mechanical stimulation induces mTOR signaling via an ERK-independent mechanism: implications for a direct activation of mTOR by phosphatidic acid | Q34450669 | ||
PGC-1alpha protects skeletal muscle from atrophy by suppressing FoxO3 action and atrophy-specific gene transcription | Q34575428 | ||
Novel insights into the regulation of skeletal muscle protein synthesis as revealed by a new nonradioactive in vivo technique | Q34592377 | ||
Aging impairs contraction-induced human skeletal muscle mTORC1 signaling and protein synthesis. | Q35166239 | ||
Reassessment of the role of TSC, mTORC1 and microRNAs in amino acids-meditated translational control of TOP mRNAs. | Q35358625 | ||
PGC-1α overexpression by in vivo transfection attenuates mitochondrial deterioration of skeletal muscle caused by immobilization | Q36051507 | ||
Initiation factor modifications in the preapoptotic phase | Q36131043 | ||
Myc coordinates transcription and translation to enhance transformation and suppress invasiveness | Q36393958 | ||
Rapamycin reverses elevated mTORC1 signaling in lamin A/C-deficient mice, rescues cardiac and skeletal muscle function, and extends survival. | Q36731585 | ||
Ribosome biogenesis: emerging evidence for a central role in the regulation of skeletal muscle mass. | Q36905257 | ||
Myc and mTOR converge on a common node in protein synthesis control that confers synthetic lethality in Myc-driven cancers | Q37031640 | ||
MYC, metabolism, cell growth, and tumorigenesis. | Q37040243 | ||
mTORC1 phosphorylation sites encode their sensitivity to starvation and rapamycin | Q37166913 | ||
Expression of growth-related genes in young and older human skeletal muscle following an acute stimulation of protein synthesis | Q37233128 | ||
mTOR complex 2 controls glycolytic metabolism in glioblastoma through FoxO acetylation and upregulation of c-Myc | Q37341834 | ||
Chronic rapamycin treatment or lack of S6K1 does not reduce ribosome activity in vivo. | Q37344807 | ||
Rapamycin passes the torch: a new generation of mTOR inhibitors | Q37950771 | ||
Comparative effects of whey protein versus L-leucine on skeletal muscle protein synthesis and markers of ribosome biogenesis following resistance exercise | Q38421077 | ||
Impact of resistance exercise on ribosome biogenesis is acutely regulated by post-exercise recovery strategies. | Q38564905 | ||
Acute resistance exercise activates rapamycin-sensitive and -insensitive mechanisms that control translational activity and capacity in skeletal muscle | Q38821101 | ||
Rapamycin does not prevent increases in myofibrillar or mitochondrial protein synthesis following endurance exercise. | Q40677001 | ||
Mediation of IGF-1-induced skeletal myotube hypertrophy by PI(3)K/Akt/mTOR and PI(3)K/Akt/GSK3 pathways. | Q40767544 | ||
Target of Rapamycin Complex 2 regulates cell growth via Myc in Drosophila | Q40963188 | ||
Co-ingestion of carbohydrate and whey protein isolates enhance PGC-1α mRNA expression: a randomised, single blind, cross over study. | Q43243722 | ||
Resistance exercise induced mTORC1 signaling is not impaired by subsequent endurance exercise in human skeletal muscle | Q43788186 | ||
mTOR signaling response to resistance exercise is altered by chronic resistance training and detraining in skeletal muscle. | Q44521850 | ||
Resistance training enhances components of the insulin signaling cascade in normal and high-fat-fed rodent skeletal muscle | Q44715047 | ||
Resistance exercise increases muscle protein synthesis and translation of eukaryotic initiation factor 2Bepsilon mRNA in a mammalian target of rapamycin-dependent manner | Q45182905 | ||
Rapamycin administration in humans blocks the contraction-induced increase in skeletal muscle protein synthesis | Q46135983 | ||
Nutritional control of protein biosynthetic capacity by insulin via Myc in Drosophila. | Q46821350 | ||
Ursolic acid stimulates mTORC1 signaling after resistance exercise in rat skeletal muscle. | Q47897065 | ||
Roles of the mammalian target of rapamycin, mTOR, in controlling ribosome biogenesis and protein synthesis. | Q53191116 | ||
Skeletal muscle hypertrophy adaptations predominate in the early stages of resistance exercise training, matching deuterium oxide-derived measures of muscle protein synthesis and mechanistic target of rapamycin complex 1 signaling. | Q53428588 | ||
Ribosome biogenesis adaptation in resistance training-induced human skeletal muscle hypertrophy. | Q53509553 | ||
Resistance exercise increases AMPK activity and reduces 4E-BP1 phosphorylation and protein synthesis in human skeletal muscle. | Q53608576 | ||
Mechanical loading induces the expression of a Pol I regulon at the onset of skeletal muscle hypertrophy. | Q53647196 | ||
Resistance exercise enhances the molecular signaling of mitochondrial biogenesis induced by endurance exercise in human skeletal muscle. | Q54568265 | ||
Early activation of mTORC1 signalling in response to mechanical overload is independent of phosphoinositide 3-kinase/Akt signalling. | Q54614762 | ||
Mixed muscle protein synthesis and breakdown after resistance exercise in humans. | Q55067147 | ||
Differential effects of resistance and endurance exercise in the fed state on signalling molecule phosphorylation and protein synthesis in human muscle | Q61788535 | ||
The role of skeletal muscle mTOR in the regulation of mechanical load-induced growth | Q84984851 | ||
The order of concurrent endurance and resistance exercise modifies mTOR signaling and protein synthesis in rat skeletal muscle | Q87582780 | ||
P275 | copyright license | Creative Commons Attribution 4.0 International | Q20007257 |
P6216 | copyright status | copyrighted | Q50423863 |
P4510 | describes a project that uses | ImageJ | Q1659584 |
P407 | language of work or name | English | Q1860 |
P304 | page(s) | 31142 | |
P577 | publication date | 2016-08-09 | |
P1433 | published in | Scientific Reports | Q2261792 |
P1476 | title | The role of mTOR signalling in the regulation of skeletal muscle mass in a rodent model of resistance exercise | |
P478 | volume | 6 |
Q91763004 | Adaptive responses of histone modifications to resistance exercise in human skeletal muscle |
Q39167062 | Autophagy-Dependent Beneficial Effects of Exercise |
Q55415253 | Concurrent treatment with ursolic acid and low-intensity treadmill exercise improves muscle atrophy and related outcomes in rats. |
Q91910488 | Dietary Aronia melanocarpa extract enhances mTORC1 signaling, but has no effect on protein synthesis and protein breakdown-related signaling, in response to resistance exercise in rat skeletal muscle |
Q38780238 | Effect of resistance exercise under conditions of reduced blood insulin on AMPKα Ser485/491 inhibitory phosphorylation and AMPK pathway activation. |
Q47709618 | Effects of contraction mode and stimulation frequency on electrical stimulation-induced skeletal muscle hypertrophy. |
Q98565444 | Effects of electrical stimulation-induced resistance exercise training on white and brown adipose tissues and plasma meteorin-like concentration in rats |
Q57155650 | Establishment of an acute extraocular muscle injury model in cats |
Q47852677 | Impact of β-adrenergic signaling in PGC-1α-mediated adaptations in mouse skeletal muscle. |
Q93098906 | Influence of shortened recovery between resistance exercise sessions on muscle-hypertrophic effect in rat skeletal muscle |
Q58721057 | Lactate administration activates the ERK1/2, mTORC1, and AMPK pathways differentially according to skeletal muscle type in mouse |
Q92628963 | Mechanical loading stimulates hypertrophy in tissue-engineered skeletal muscle: Molecular and phenotypic responses |
Q42365569 | Molecular, neuromuscular, and recovery responses to light versus heavy resistance exercise in young men. |
Q60950906 | Nutmeg Extract Increases Skeletal Muscle Mass in Aging Rats Partly via IGF1-AKT-mTOR Pathway and Inhibition of Autophagy |
Q47811763 | Pharmacological targeting of exercise adaptations in skeletal muscle: Benefits and pitfalls |
Q90424487 | Regulation of Ribosome Biogenesis in Skeletal Muscle Hypertrophy |
Q50879152 | Relationship between exercise volume and muscle protein synthesis in a rat model of resistance exercise. |
Q47129256 | Repeated bouts of resistance exercise with short recovery periods activates mTOR signaling, but not protein synthesis, in mouse skeletal muscle. |
Q89997557 | Resistance Exercise's Ability to Reverse Cancer-Induced Anabolic Resistance |
Q96303267 | Response of Resistance Exercise-Induced Muscle Protein Synthesis and Skeletal Muscle Hypertrophy Are Not Enhanced After Disuse Muscle Atrophy in Rat |
Q47186430 | Satellite cell activation and mTOR signaling pathway response to resistance and combined exercise in elite weight lifters |
Q55247971 | Searching for a mitochondrial root to the decline in muscle function with ageing. |
Q64102498 | The Effect of Changing the Contraction Mode During Resistance Training on mTORC1 Signaling and Muscle Protein Synthesis |
Q39038160 | The Role of Exercise and TFAM in Preventing Skeletal Muscle Atrophy. |
Q90267521 | The Role of the IGF-1 Signaling Cascade in Muscle Protein Synthesis and Anabolic Resistance in Aging Skeletal Muscle |
Q38639794 | The effect of different acute muscle contraction regimens on the expression of muscle proteolytic signaling proteins and genes. |
Q91853494 | The order of concurrent training affects mTOR signaling but not mitochondrial biogenesis in mouse skeletal muscle |
Q90220620 | The role of raptor in the mechanical load-induced regulation of mTOR signaling, protein synthesis, and skeletal muscle hypertrophy |
Q47573911 | Therapeutic potency of mTOR signaling pharmacological inhibitors in the treatment of proinflammatory diseases, current status, and perspectives. |
Q92066515 | Type 2 diabetes causes skeletal muscle atrophy but does not impair resistance training-mediated myonuclear accretion and muscle mass gain in rats |
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