scholarly article | Q13442814 |
P356 | DOI | 10.1152/JAPPLPHYSIOL.00811.2015 |
P698 | PubMed publication ID | 26679615 |
P2093 | author name string | Mark Hargreaves | |
Mark A Febbraio | |||
Darren C Henstridge | |||
P2860 | cites work | HSP72 protects cells from ER stress-induced apoptosis via enhancement of IRE1alpha-XBP1 signaling through a physical interaction | Q21145793 |
The unfolded protein response: integrating stress signals through the stress sensor IRE1α | Q24293771 | ||
Chaperoning to the metabolic party: The emerging therapeutic role of heat-shock proteins in obesity and type 2 diabetes | Q28251174 | ||
Extracellular Hsp72 concentration relates to a minimum endogenous criteria during acute exercise-heat exposure | Q28299626 | ||
Exercise increases serum Hsp72 in humans | Q28345140 | ||
Exercise training and experimental diabetes modulate heat shock protein response in brain | Q28583889 | ||
Hsp72 preserves muscle function and slows progression of severe muscular dystrophy | Q28591442 | ||
XBP1 controls diverse cell type- and condition-specific transcriptional regulatory networks | Q28591575 | ||
Membrane-lipid therapy in operation: the HSP co-inducer BGP-15 activates stress signal transduction pathways by remodeling plasma membrane rafts | Q28741590 | ||
The exercise-induced stress response of skeletal muscle, with specific emphasis on humans. | Q30380947 | ||
Human skeletal muscle HSP70 response to training in highly trained rowers | Q31935112 | ||
Exercise induces hepatosplanchnic release of heat shock protein 72 in humans | Q59326285 | ||
Activating HSP72 in rodent skeletal muscle increases mitochondrial number and oxidative capacity and decreases insulin resistance | Q33646728 | ||
Exercise induces the release of heat shock protein 72 from the human brain in vivo | Q33716849 | ||
Role of the dorsal medial habenula in the regulation of voluntary activity, motor function, hedonic state, and primary reinforcement | Q34067359 | ||
Increased temperature and protein oxidation lead to HSP72 mRNA and protein accumulation in the in vivo exercised rat heart | Q34139568 | ||
Single muscle fiber gene expression with run taper | Q34277356 | ||
Heat shock proteins and heat adaptation of the whole organism | Q34447069 | ||
Glutamine and heat shock protein expression | Q34554295 | ||
Heat shock proteins: modifying factors in physiological stress responses and acquired thermotolerance | Q34605740 | ||
The unfolded protein response mediates adaptation to exercise in skeletal muscle through a PGC-1α/ATF6α complex | Q34673344 | ||
Restoring HSP70 deficiencies improves glucose tolerance in diabetic monkeys | Q34979395 | ||
Genetic manipulation of cardiac Hsp72 levels does not alter substrate metabolism but reveals insights into high-fat feeding-induced cardiac insulin resistance | Q35529105 | ||
HSP72 protects against obesity-induced insulin resistance | Q36446531 | ||
Heat shock protein 72: release and biological significance during exercise. | Q36992110 | ||
Heat shock proteins and exercise: a primer | Q37299302 | ||
Heat shock protein 70 is necessary to improve mitochondrial bioenergetics and reverse diabetic sensory neuropathy following KU-32 therapy | Q37550709 | ||
HSP72 is a mitochondrial stress sensor critical for Parkin action, oxidative metabolism, and insulin sensitivity in skeletal muscle | Q37715573 | ||
HSP70 expression: does it a novel fatigue signalling factor from immune system to the brain? | Q37849717 | ||
Integrative biology of exercise | Q38270563 | ||
Effect of blood handling on extracellular Hsp72 concentration after high-intensity exercise in humans. | Q40245107 | ||
Exosome-dependent trafficking of HSP70: a novel secretory pathway for cellular stress proteins | Q40436107 | ||
Heat shock protein 70 kDa: molecular biology, biochemistry, and physiology | Q40833247 | ||
Hsp70 expression in human skeletal muscle after exercise | Q40931518 | ||
Muscle fiber type-specific response of Hsp70 expression in human quadriceps following acute isometric exercise | Q42519809 | ||
Mild heat stress induces mitochondrial biogenesis in C2C12 myotubes. | Q42621761 | ||
An acylic polyisoprenoid derivative, geranylgeranylacetone protects against visceral adiposity and insulin resistance in high-fat-fed mice. | Q42934822 | ||
Effects of body temperature during exercise training on myocardial adaptations | Q43572782 | ||
Reduced glycogen availability is associated with an elevation in HSP72 in contracting human skeletal muscle | Q43875696 | ||
Exercise improves postischemic cardiac function in males but not females: consequences of a novel sex-specific heat shock protein 70 response | Q43978634 | ||
Habitual physical activity facilitates stress-induced HSP72 induction in brain, peripheral, and immune tissues | Q44193708 | ||
Expression of the molecular chaperone Hsp70 in detergent-resistant microdomains correlates with its membrane delivery and release | Q44394452 | ||
A transgenic mouse model for monitoring endoplasmic reticulum stress | Q44711192 | ||
Whey protein hydrolysate enhances the exercise-induced heat shock protein (HSP70) response in rats | Q45096016 | ||
Hsp70 release from peripheral blood mononuclear cells. | Q45098360 | ||
Subcellular movement and expression of HSP27, alphaB-crystallin, and HSP70 after two bouts of eccentric exercise in humans. | Q45982025 | ||
HSP70 and other possible heat shock or oxidative stress proteins are induced in skeletal muscle, heart, and liver during exercise. | Q46043779 | ||
Inducible isoform of HSP70 is constitutively expressed in a muscle fiber type specific pattern | Q46116553 | ||
Exercising mammals synthesize stress proteins | Q46124522 | ||
Elevated core and muscle temperature to levels comparable to exercise do not increase heat shock protein content of skeletal muscle of physically active men. | Q46201770 | ||
Exercise training modulates heat shock protein response in diabetic rats | Q47788938 | ||
HSP70 expression in the CNS in response to exercise and heat stress in rats | Q48477398 | ||
Increased temperature, not cardiac load, activates heat shock transcription factor 1 and heat shock protein 72 expression in the heart | Q48661443 | ||
Postexercise whole body heat stress additively enhances endurance training-induced mitochondrial adaptations in mouse skeletal muscle. | Q51706896 | ||
HSP72 as a complementary protection against oxidative stress induced by exercise in the soleus muscle of rats. | Q54032435 | ||
Exercise treatment for depression | Q56536197 | ||
P433 | issue | 6 | |
P407 | language of work or name | English | Q1860 |
P304 | page(s) | 683-691 | |
P577 | publication date | 2015-12-17 | |
P1433 | published in | Journal of Applied Physiology | Q1091719 |
P1476 | title | Heat shock proteins and exercise adaptations. Our knowledge thus far and the road still ahead | |
P478 | volume | 120 |
Q41985668 | Acute exercise boosts cell proliferation and the heat shock response in lymphocytes: correlation with cytokine production and extracellular-to-intracellular HSP70 ratio. |
Q46597040 | Common mechanisms for the adaptive responses to exercise and heat stress |
Q38733278 | Cross-Adaptation: Heat and Cold Adaptation to Improve Physiological and Cellular Responses to Hypoxia |
Q36902232 | Cytosolic calcium transients are a determinant of contraction-induced HSP72 transcription in single skeletal muscle fibers. |
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Q54958045 | Extreme Terrestrial Environments: Life in Thermal Stress and Hypoxia. A Narrative Review. |
Q38795296 | HSP70: therapeutic potential in acute and chronic cardiac disease settings |
Q58608502 | High intensity resistance training causes muscle damage and increases biomarkers of acute kidney injury in healthy individuals |
Q41600602 | Hsp72 and Hsp90α mRNA transcription is characterised by large, sustained changes in core temperature during heat acclimation |
Q89977038 | Hsp90 Relieves Heat Stress-Induced Damage in Mouse Kidneys: Involvement of Antiapoptotic PKM2-AKT and Autophagic HIF-1α Signaling |
Q58797174 | Increased Circulation and Adipose Tissue Levels of DNAJC27/RBJ in Obesity and Type 2-Diabetes |
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Q49917356 | Understanding Key Mechanisms of Exercise-Induced Cardiac Protection to Mitigate Disease: Current Knowledge and Emerging Concepts |
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