5‐Hydroxymethylfurfural reduces skeletal muscle superoxide production and modifies force production in rats exposed to hypobaric hypoxia

Decreased blood‐tissue oxygenation at high altitude (HA) increases mitochondrial oxidant production and reduces exercise capacity. 5‐Hydroxymethylfurfural (5‐HMF) is an antioxidant that increases hemoglobin's binding affinity for oxygen. For these reasons, we hypothesized that 5‐HMF would improve muscle performance in rats exposed to a simulated HA of ~5500 m. A secondary objective was to measure mitochondrial activity and dynamic regulation of fission and fusion because they are linked processes impacted by HA. Fisher 344 rats received 5‐HMF (40 mg/kg/day) or vehicle during exposure to sea level or HA for 72 h. Right ankle plantarflexor muscle function was measured pre‐ and post‐exposure. Post‐exposure measurements included arterial blood gas and complete blood count, flexor digitorum brevis myofiber superoxide production and mitochondrial membrane potential (ΔΨm), and mitochondrial dynamic regulation in the soleus muscle. HA reduced blood oxygenation, increased superoxide levels and lowered ΔΨm, responses that were accompanied by decreased peak isometric torque and force production at frequencies >75 Hz. 5‐HMF increased isometric force production and lowered oxidant production at sea level. In HA exposed animals, 5‐HMF prevented a decline in isometric force production at 75–125 Hz, prevented an increase in superoxide levels, further decreased ΔΨm, and increased mitochondrial fusion 2 protein expression. These results suggest that 5‐HMF may prevent a decrease in hypoxic force production during submaximal isometric contractions by an antioxidant mechanism.

[1]  G. Millet,et al.  Adaptive responses to hypoxia and/or hyperoxia in humans. , 2022, Antioxidants & redox signaling.

[2]  T. Haller,et al.  Dose- and Sex-Dependent Changes in Hemoglobin Oxygen Affinity by the Micronutrient 5-Hydroxymethylfurfural and α-Ketoglutaric Acid , 2021, Nutrients.

[3]  J. Swift,et al.  Cardiovascular Parameters in a Swine Model of Normobaric Hypoxia Treated With 5-Hydroxymethyl-2-Furfural (5-HMF) , 2019, Front. Physiol..

[4]  P. Deuster,et al.  Astaxanthin but not quercetin preserves mitochondrial integrity and function, ameliorates oxidative stress, and reduces heat‐induced skeletal muscle injury , 2019, Journal of cellular physiology.

[5]  P. Deuster,et al.  Acclimation of C2C12 myoblasts to physiological glucose concentrations for in vitro diabetes research , 2018, Life sciences.

[6]  S. Gan,et al.  5-Hydroxymethylfurfural (HMF) levels in honey and other food products: effects on bees and human health , 2018, Chemistry Central Journal.

[7]  M. Hogan,et al.  A mitochondrial‐targeted antioxidant improves myofilament Ca2+ sensitivity during prolonged low frequency force depression at low PO2 , 2018, The Journal of physiology.

[8]  K. Raghavendran,et al.  Benefits of 21% Oxygen Compared with 100% Oxygen for Delivery of Isoflurane to Mice (Mus musculus) and Rats (Rattus norvegicus). , 2017, Journal of the American Association for Laboratory Animal Science : JAALAS.

[9]  M. Reid Reactive Oxygen Species as Agents of Fatigue. , 2016, Medicine and science in sports and exercise.

[10]  F. Brocherie,et al.  High Altitude Increases Alteration in Maximal Torque but Not in Rapid Torque Development in Knee Extensors after Repeated Treadmill Sprinting , 2016, Front. Physiol..

[11]  T. Wai,et al.  Mitochondrial Dynamics and Metabolic Regulation , 2016, Trends in Endocrinology & Metabolism.

[12]  J. Losa-Reyna,et al.  What limits performance during whole‐body incremental exercise to exhaustion in humans? , 2015, The Journal of physiology.

[13]  Judy E. Anderson,et al.  Protocol for rat single muscle fiber isolation and culture. , 2015, Analytical biochemistry.

[14]  Ka Chen,et al.  Protective Effects of Myricetin on Acute Hypoxia-Induced Exercise Intolerance and Mitochondrial Impairments in Rats , 2015, PloS one.

[15]  P. Liu,et al.  Dihydromyricetin improves physical performance under simulated high altitude. , 2014, Medicine and science in sports and exercise.

[16]  B. Dawson,et al.  Effect of different simulated altitudes on repeat-sprint performance in team-sport athletes. , 2014, International journal of sports physiology and performance.

[17]  K. Mileva,et al.  Acute physiological and performance responses to repeated sprints in varying degrees of hypoxia. , 2014, Journal of science and medicine in sport.

[18]  M. Gassmann,et al.  Disturbed eating at high altitude: influence of food preferences, acute mountain sickness and satiation hormones , 2013, European Journal of Nutrition.

[19]  P. Cabrales,et al.  Increased hemoglobin O2 affinity protects during acute hypoxia. , 2012, American journal of physiology. Heart and circulatory physiology.

[20]  J. Quadrilatero,et al.  Rapid Determination of Myosin Heavy Chain Expression in Rat, Mouse, and Human Skeletal Muscle Using Multicolor Immunofluorescence Analysis , 2012, PloS one.

[21]  Shakir Ali,et al.  Chronic hypobaric hypoxia mediated skeletal muscle atrophy: role of ubiquitin–proteasome pathway and calpains , 2012, Molecular and Cellular Biochemistry.

[22]  Shakir Ali,et al.  Chronic hypobaric hypoxia mediated skeletal muscle atrophy: role of ubiquitin–proteasome pathway and calpains , 2012, Molecular and Cellular Biochemistry.

[23]  A. Lampen,et al.  Toxicology and risk assessment of 5-Hydroxymethylfurfural in food. , 2011, Molecular nutrition & food research.

[24]  Ming-ming Li,et al.  The protective role of 5-hydroxymethyl-2-furfural (5-HMF) against acute hypobaric hypoxia , 2011, Cell stress & chaperones (Print).

[25]  M. Brand,et al.  Assessing mitochondrial dysfunction in cells , 2011, The Biochemical journal.

[26]  J. Swift,et al.  Simulated resistance training during hindlimb unloading abolishes disuse bone loss and maintains muscle strength , 2010, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[27]  C. Lundby,et al.  Air to muscle O2 delivery during exercise at altitude. , 2009, High altitude medicine & biology.

[28]  Michael P. Murphy,et al.  How mitochondria produce reactive oxygen species , 2008, The Biochemical journal.

[29]  J. Hoff,et al.  Human skeletal muscle intracellular oxygenation: the impact of ambient oxygen availability , 2006, The Journal of physiology.

[30]  R. de Cabo,et al.  Calorie restriction induces mitochondrial biogenesis and bioenergetic efficiency. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[31]  A. Ascensão,et al.  Acute and severe hypobaric hypoxia increases oxidative stress and impairs mitochondrial function in mouse skeletal muscle. , 2005, Journal of applied physiology.

[32]  P. Schumacker,et al.  Mitochondrial complex III is required for hypoxia-induced ROS production and cellular oxygen sensing. , 2005, Cell metabolism.

[33]  D. Abraham,et al.  5‐hydroxymethyl‐2‐furfural modifies intracellular sickle haemoglobin and inhibits sickling of red blood cells †,‡ , 2005, British journal of haematology.

[34]  A. Lombès,et al.  Membrane topology and mitochondrial targeting of mitofusins, ubiquitous mammalian homologs of the transmembrane GTPase Fzo. , 2002, Journal of cell science.

[35]  E Hultman,et al.  Regulation of glycogen phosphorylase and PDH during exercise in human skeletal muscle during hypoxia. , 2000, American journal of physiology. Endocrinology and metabolism.

[36]  R. Richardson,et al.  Human muscle performance and PCr hydrolysis with varied inspired oxygen fractions: a 31P-MRS study. , 1999, Journal of applied physiology.

[37]  T. Nosek,et al.  Increased superoxide production during fatigue in the perfused rat diaphragm. , 1997, American journal of respiratory and critical care medicine.

[38]  B. Sjödin,et al.  Reduced oxygen availability during high intensity intermittent exercise impairs performance. , 1994, Acta physiologica Scandinavica.

[39]  J. Mortola,et al.  Metabolism and ventilation in hypoxic rats: effect of body mass. , 1994, Respiration physiology.

[40]  P. Diaz,et al.  Hydroxylation of salicylate by the in vitro diaphragm: evidence for hydroxyl radical production during fatigue. , 1993, Journal of applied physiology.

[41]  M. Reid,et al.  Reactive oxygen in skeletal muscle. I. Intracellular oxidant kinetics and fatigue in vitro. , 1992, Journal of applied physiology.

[42]  A. Dimarco,et al.  Effect of N-acetylcysteine on diaphragm fatigue. , 1990, Journal of applied physiology.

[43]  P. Cerretelli,et al.  III : Effects of chronic hypoxia on muscle enzyme activities , 1990 .

[44]  M. Dallman,et al.  ACTH secretion and ventilation increase at similar arterial PO2 in conscious rats. , 1989, Journal of applied physiology.

[45]  S. Tenney,et al.  Acute and chronic pulmonary pressor responses to hypoxia: the role of blunting in acclimatization. , 1986, Respiration physiology.

[46]  D. Schnakenberg,et al.  Effects of time and duration of exposure to 12% O2 and prior food deprivation on hypoxic hypophagia of rats. , 1982, Aviation Space and Environmental Medicine.

[47]  P. Cerretelli,et al.  Effect of chronic hypoxia on muscle enzyme activities. , 1990, International journal of sports medicine.

[48]  S. Ogale,et al.  Effect of N , 1987 .

[49]  M D Blaufox,et al.  Blood volume in the rat. , 1985, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.