A Novel Mechanism for Cross-Adaptation between Heat and Altitude Acclimation: The Role of Heat Shock Protein 90

Salgado, Roy M.; White, Ailish C.; Schneider, Suzanne M.; Mermier, Christine M.

doi:10.1155/2014/121402

Cited by 13 publications

(11 citation statements)

References 83 publications

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“…In contrast, HIF‐1α is stimulated by exposure to systemic hypoxia and mediates molecular adaptations to upregulate angiogenesis, erythropoiesis (Goldberg & Schneider, ) and respiration (Wilson, Roy, & Lahiri, ). HSP90 interacts with the oxygen‐dependent HIF‐1α subunit, stabilizing HIF‐1α even in normoxic conditions (Salgado, White, Schneider, & Mermier, ). Other physiological adaptations underlying HA at a systemic level may be secondary to the expanded plasma volume (PV) and include improved exercise economy (Sawka, Pandolf, Avellini, & Shapiro, ), greater stroke volume (SV), lower heart rate (HR) (Lorenzo, Halliwill, Sawka, & Minson, ), and increased ventricular compliance and myocardial efficiency (Horowitz, Shimoni, Parnes, Gotsman, & Hasin, ).…”

Section: Introductionmentioning

confidence: 99%

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Heat acclimation does not affect maximal aerobic power in thermoneutral normoxic or hypoxic conditions

Sotiridis

Debevec

Ciuha

et al. 2019

Experimental Physiology

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New Findings What is the central question of this study?Controlled‐hyperthermia heat‐acclimation protocols induce an array of thermoregulatory and cardiovascular adaptations that facilitate exercise in hot conditions. We investigated whether this ergogenic potential can be transferred to thermoneutral normoxic or hypoxic exercise conditions. What is the main finding and its importance?We showed that heat acclimation did not affect maximal cardiac output or maximal aerobic power in thermoneutral normoxic or hypoxic conditions. Heat acclimation augmented the sweating response in thermoneutral normoxic conditions. The cross‐adaptation theory, according to which heat acclimation could facilitate hypoxic exercise capacity, is not supported by our data. Abstract Heat acclimation (HA) mitigates heat‐induced decrements in maximal aerobic power (V̇O2 peak ) and augments exercise thermoregulatory responses in the heat. Whether this beneficial effect of HA is observed in hypoxic or thermoneutral conditions remains unresolved. We explored the effects of HA on cardiorespiratory and thermoregulatory responses to exercise in normoxic, hypoxic and hot conditions. Twelve men [V̇O2 peak 54.7(standard deviation 5.7) ml kg−1 min−1] participated in a HA protocol consisting of 10 daily 90‐min controlled‐hyperthermia (target rectal temperature, Tre = 38.5°C) exercise sessions. Before and after HA, we determined V̇O2 peak in thermoneutral normoxic (NOR), thermoneutral hypoxic (fractional inspired O2 = 13.5%; HYP) and hot (35°C, 50% relative humidity; HE) conditions in a randomized and counterbalanced order. Preceding each maximal cycling test, a 30‐min steady‐state exercise bout at 40% of the NOR peak power output was used to evaluate thermoregulatory responses. Heat acclimation induced the expected adaptations in HE: reduced Tre and submaximal heart rate, enhanced sweating response and expanded plasma volume. However, HA did not affect V̇O2 peak or maximal cardiac output (P = 0.61). The peak power output was increased post‐HA in NOR (P < 0.001) and HE (P < 0.001) by 41 ± 21 and 26 ± 22 W, respectively, but not in HYP (P = 0.14). Gross mechanical efficiency was higher (P = 0.004), whereas resting Tre and sweating thresholds were lower (P < 0.01) post‐HA across environments. Nevertheless, the gain of the sweating response decreased (P = 0.05) in HYP. In conclusion, our data do not support a beneficial cross‐over effect of HA on V̇O2 peak in normoxic or hypoxic conditions.

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Section: Introductionmentioning

confidence: 99%

“…1994) and respiration (Wilson, Roy, & Lahiri, 2005). HSP90 interacts with the oxygen-dependent HIF-1 subunit, stabilizing HIF-1 even in normoxic conditions (Salgado, White, Schneider, & Mermier, 2014).…”

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Heat acclimation does not affect maximal aerobic power in thermoneutral normoxic or hypoxic conditions

Sotiridis

Debevec

Ciuha

et al. 2019

Experimental Physiology

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“…Heat acclimation (HA), and acclimatization interventions, carried out by repeated exercise in hot conditions (58), reproducibly reduce physiological strain in hot and cooler conditions (32,33,39). Recent reviews support a novel adaptive pathway whereby HA may reduce physiological strain in hypoxia (14,56,73). Mechanistic pathways can be subdivided into crossacclimation, whereby HA attenuates physiological strain (73) and cross-tolerance, whereby cellular responses to HA provide cytoprotection during hypoxia (14).…”

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confidence: 99%

Heat acclimation attenuates physiological strain and the HSP72, but not HSP90α, mRNA response to acute normobaric hypoxia

Gibson

Turner

Tuttle

et al. 2015

Journal of Applied Physiology

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Heat acclimation (HA) attenuates physiological strain in hot conditions via phenotypic and cellular adaptation. The aim of this study was to determine whether HA reduced physiological strain, and heat shock protein (HSP) 72 and HSP90α mRNA responses in acute normobaric hypoxia. Sixteen male participants completed ten 90-min sessions of isothermic HA (40°C/40% relative humidity) or exercise training [control (CON); 20°C/40% relative humidity]. HA or CON were preceded (HYP1) and proceeded (HYP2) by a 30-min normobaric hypoxic exposure [inspired O2 fraction = 0.12; 10-min rest, 10-min cycling at 40% peak O2 uptake (V̇O2 peak), 10-min cycling at 65% V̇O2 peak]. HA induced greater rectal temperatures, sweat rate, and heart rates (HR) than CON during the training sessions. HA, but not CON, reduced resting rectal temperatures and resting HR and increased sweat rate and plasma volume. Hemoglobin mass did not change following HA nor CON. HSP72 and HSP90α mRNA increased in response to each HA session, but did not change with CON. HR during HYP2 was lower and O2 saturation higher at 65% V̇O2 peak following HA, but not CON. O2 uptake/HR was greater at rest and 65% V̇O2 peak in HYP2 following HA, but was unchanged after CON. At rest, the respiratory exchange ratio was reduced during HYP2 following HA, but not CON. The increase in HSP72 mRNA during HYP1 did not occur in HYP2 following HA. In CON, HSP72 mRNA expression was unchanged during HYP1 and HYP2. In HA and CON, increases in HSP90α mRNA during HYP1 were maintained in HYP2. HA reduces physiological strain, and the transcription of HSP72, but not HSP90α mRNA in acute normobaric hypoxia.

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“…Hot and hypoxic cross-tolerance has been a subject of recent interest for military personnel and/or athletes who work or compete in both hot and high-altitude environments. 4 , 5 However, the link between the observed cellular cross-tolerance and systemic acclimatory responses to hot or hypoxic environments has not been fully elucidated. Currently, cross-tolerance is primarily attributed to changes at the cellular level.…”

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confidence: 99%

Heat acclimation and cross tolerance to hypoxia

et al. 2014

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Recent research has suggested a potential for some of the physiological and cellular responses to heat acclimation to carry over to improved tolerance of the novel stresses of another environment. This cross-tolerance is evident in heat-acclimated animals that exhibit enhanced tolerance to either hypoxic or ischemic stress, and is primarily attributed to shared cellular stress response pathways. These pathways include Hypoxia-Inducible Factor-1 (HIF-1) and Heat Shock Proteins (HSP). Whether these shared cellular stress response pathways translate to systemic cross-tolerance (improved exercise tolerance, reduced risk of environment-associated illness) has not been clearly shown, particularly in humans. This review highlights the HIF-1 and HSP pathways and their relationship with systemic acclimation responses, and further examines the potential cellular and systemic adaptations that may result in cross-tolerance between hot and hypoxic environments.

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A Novel Mechanism for Cross-Adaptation between Heat and Altitude Acclimation: The Role of Heat Shock Protein 90

Cited by 13 publications

References 83 publications

Heat acclimation does not affect maximal aerobic power in thermoneutral normoxic or hypoxic conditions

Heat acclimation does not affect maximal aerobic power in thermoneutral normoxic or hypoxic conditions

Heat acclimation attenuates physiological strain and the HSP72, but not HSP90α, mRNA response to acute normobaric hypoxia

Heat acclimation and cross tolerance to hypoxia

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