Effects of exercise preconditioning and HSP72 on diaphragm muscle function during mechanical ventilation

Smuder, Ashley J.; Morton, Aaron B.; Hall, Sophie; Wiggs, Michael P.; Ahn, Bumsoo; Wawrzyniak, Nicholas R.; Sollanek, Kurt J.; Min, Kisuk; Kwon, Oh Sung; Nelson, W. Bradley; Powers, Scott K.

doi:10.1002/jcsm.12427

Cited by 27 publications

(28 citation statements)

References 58 publications

(135 reference statements)

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“…showed that exercise increases the expression of heat shock protein 72 (HSP72), which reduces the expression of atrophic transcript factors and oxidative stress. These responses preserve diaphragm muscle function in animals with diaphragm dysfunction . Molecular adaptations in respiratory muscles were out of the scope of our study.…”

Section: Discussionmentioning

confidence: 92%

Effects of aerobic and inspiratory training on skeletal muscle microRNA‐1 and downstream‐associated pathways in patients with heart failure

Antunes‐Correa

Trevizan

Bacurau

et al. 2019

J cachexia sarcopenia muscle

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Background The exercise intolerance in chronic heart failure with reduced ejection fraction (HFrEF) is mostly attributed to alterations in skeletal muscle. However, the mechanisms underlying the skeletal myopathy in patients with HFrEF are not completely understood. We hypothesized that (i) aerobic exercise training (AET) and inspiratory muscle training (IMT) would change skeletal muscle microRNA‐1 expression and downstream‐associated pathways in patients with HFrEF and (ii) AET and IMT would increase leg blood flow (LBF), functional capacity, and quality of life in these patients. Methods Patients age 35 to 70 years, left ventricular ejection fraction (LVEF) ≤40%, New York Heart Association functional classes II–III, were randomized into control, IMT, and AET groups. Skeletal muscle changes were examined by vastus lateralis biopsy. LBF was measured by venous occlusion plethysmography, functional capacity by cardiopulmonary exercise test, and quality of life by Minnesota Living with Heart Failure Questionnaire. All patients were evaluated at baseline and after 4 months. Results Thirty‐three patients finished the study protocol: control (n = 10; LVEF = 25 ± 1%; six males), IMT (n = 11; LVEF = 31 ± 2%; three males), and AET (n = 12; LVEF = 26 ± 2%; seven males). AET, but not IMT, increased the expression of microRNA‐1 (P = 0.02; percent changes = 53 ± 17%), decreased the expression of PTEN (P = 0.003; percent changes = −15 ± 0.03%), and tended to increase the p‐AKTser473/AKT ratio (P = 0.06). In addition, AET decreased HDAC4 expression (P = 0.03; percent changes = −40 ± 19%) and upregulated follistatin (P = 0.01; percent changes = 174 ± 58%), MEF2C (P = 0.05; percent changes = 34 ± 15%), and MyoD expression (P = 0.05; percent changes = 47 ± 18%). AET also increased muscle cross‐sectional area (P = 0.01). AET and IMT increased LBF, functional capacity, and quality of life. Further analyses showed a significant correlation between percent changes in microRNA‐1 and percent changes in follistatin mRNA (P = 0.001, rho = 0.58) and between percent changes in follistatin mRNA and percent changes in peak VO2 (P = 0.004, rho = 0.51). Conclusions AET upregulates microRNA‐1 levels and decreases the protein expression of PTEN, which reduces the inhibitory action on the PI3K‐AKT pathway that regulates the skeletal muscle tropism. The increased levels of microRNA‐1 also decreased HDAC4 and increased MEF2c, MyoD, and follistatin expression, improving skeletal muscle regeneration. These changes associated with the increase in muscle cross‐sectional area and LBF contribute to the attenuation in skeletal myopathy, and the improvement in functional capacity and quality of life in patients with HFrEF. IMT caused no changes in microRNA‐1 and in the downstream‐associated pathway. The increased functional capacity provoked by IMT seems to be associated with amelioration in the respiratory function instead of changes in skeletal muscle. http://ClinicalTrials.gov (Identifier: NCT01747395)

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Section: Discussionmentioning

confidence: 92%

Effects of aerobic and inspiratory training on skeletal muscle microRNA‐1 and downstream‐associated pathways in patients with heart failure

Antunes‐Correa

Trevizan

Bacurau

et al. 2019

J cachexia sarcopenia muscle

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“…It is risky to limit the examples of how ACSM colleagues have advanced science and medicine, since other important contributions are easily and unintentionally omitted. Nevertheless, contributions of the following individuals to physiology, and sports medicine should not be overlooked: Jere Mitchell, in cardiovascular physiology and medicine; 186 John Holloszy, in mitochondrial biogenesis; 187 L. Bruce Gladden, in the regulation of intermediary metabolism; 18 , 188 Jim Barnard, V. Reggie Edgerton, and Ken Baldwin, in muscle fiber heterogeneity; 47 , 48 Scott Powers, in redox signaling and preconditioning of the heart to cardiovascular insults; 189 Karl Wasserman and Jerry Dempsey, in pulmonary physiology and medicine; 25 , 190 Tom Fahey, in translating the lessons of physiology and sports medicine to the literature for health care professionals and the lay public; 191 , 192 , 193 and Tim White, in the administration of higher education ( https://www2.calstate.edu/csu-system/chancellor/Pages/meet-the-chancellor.aspx ). In the aggregate, our scientists, clinicians, and staff at the ACSM know well how the body works under stress, in illness, and after injury.…”

Section: Resultsmentioning

confidence: 99%

The tortuous path of lactate shuttle discovery: From cinders and boards to the lab and ICU

Brooks

2020

Journal of Sport and Health Science

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Highlights In the 2019 American College of Sports Medicine Wolffe lecture George Brooks described history Lactate Shuttle development. Lactate is a fuel energy source, the main gluconeogenic precursor, and a signaling molecule with autocrine, paracrine, and endocrine functions. Endurance training develops the capacities to produce, remove and utilize lactate. Lactate is favored as a fuel by working red muscle, heart, liver, and brain. Clinical trials are under way to improve outcomes in traumatic brain injury patients using lactate supplementation. The importance of Lactate Shuttle in normal physiology is emphasized by the realization that dysfunctional lactate shuttling is involved in cancer, metabolic inflexibility, and inflammation.

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“…Thus, Hsp70/90 are considered mainly intracellular molecular chaperones, which makes them cytoprotective against stressful stimuli. In skeletal muscle cells, overexpression of Hsp70 protects against muscle damage and age-related muscle dysfunction [111] as well as disuse or mechanical ventilation-induced muscle atrophy [112,113,114]. However, under pathological conditions, Hsp70 and Hsp90 can be released into extracellular space where they act as DAMPs [115].…”

Section: Cachectic Cancers Induce Muscle Catabolism By Activatingmentioning

confidence: 99%

Cancer Takes a Toll on Skeletal Muscle by Releasing Heat Shock Proteins—An Emerging Mechanism of Cancer-Induced Cachexia

Sin

Zhang

et al. 2019

Cancers

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Cancer-associated cachexia (cancer cachexia) is a major contributor to the modality and mortality of a wide variety of solid tumors. It is estimated that cachexia inflicts approximately ~60% of all cancer patients and is the immediate cause of ~30% of all cancer-related death. However, there is no established treatment of this disorder due to the poor understanding of its underlying etiology. The key manifestations of cancer cachexia are systemic inflammation and progressive loss of skeletal muscle mass and function (muscle wasting). A number of inflammatory cytokines and members of the TGFβ superfamily that promote muscle protein degradation have been implicated as mediators of muscle wasting. However, clinical trials targeting some of the identified mediators have not yielded satisfactory results. Thus, the root cause of the muscle wasting associated with cancer cachexia remains to be identified. This review focuses on recent progress of laboratory studies in the understanding of the molecular mechanisms of cancer cachexia that centers on the role of systemic activation of Toll-like receptor 4 (TLR4) by cancer-released Hsp70 and Hsp90 in the development and progression of muscle wasting, and the downstream signaling pathways that activate muscle protein degradation through the ubiquitin–proteasome and the autophagy–lysosome pathways in response to TLR4 activation. Verification of these findings in humans could lead to etiology-based therapies of cancer cachexia by targeting multiple steps in this signaling cascade.

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Effects of exercise preconditioning and HSP72 on diaphragm muscle function during mechanical ventilation

Cited by 27 publications

References 58 publications

Effects of aerobic and inspiratory training on skeletal muscle microRNA‐1 and downstream‐associated pathways in patients with heart failure

Effects of aerobic and inspiratory training on skeletal muscle microRNA‐1 and downstream‐associated pathways in patients with heart failure

The tortuous path of lactate shuttle discovery: From cinders and boards to the lab and ICU

Cancer Takes a Toll on Skeletal Muscle by Releasing Heat Shock Proteins—An Emerging Mechanism of Cancer-Induced Cachexia

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