Mice from lines selectively bred for voluntary exercise are not more resistant to muscle injury caused by either contusion or wheel running

Muscle injury can be caused by strenuous exercise, repetitive tasks or external forces. Populations that have experienced selection for high locomotor activity may have evolutionary adaptations that resist exercise-induced injury and/or enhance the ability to cope with injury. We tested this hypothesis with an experiment in which mice are bred for high voluntary wheel running. Mice from four high runner lines run ~three times more daily distance than those from four non-selected control lines. To test recovery from injury by external forces, mice experienced contusion via weight drop on the calf. After injury, running distance and speed were reduced in high runner but not control lines, suggesting that the ability of control mice to run exceeds their motivation. To test effects of injury from exercise, mice were housed with/without wheels for six days, then trunk blood was collected and muscles evaluated for injury and regeneration. Both high runner and control mice with wheels had increased histological indicators of injury in the soleus, and increased indicators of regeneration in the plantaris. High runner mice had relatively more central nuclei (regeneration indicator) than control in the soleus, regardless of wheel access. The subset of high runner mice with the mini-muscle phenotype (characterized by greatly reduced muscle mass and type IIb fibers) had lower plasma creatine kinase (indicator of muscle injury), more markers of injury in the deep gastrocnemius, and more markers of regeneration in the deep and superficial gastrocnemius than normal-muscled individuals. Contrary to our expectations, high runner mice were not more resistant to either type of injury.

[1]  Junaith S Mohamed,et al.  Voluntary wheel running increases satellite cell abundance and improves recovery from disuse in gastrocnemius muscles from mice. , 2018, Journal of applied physiology.

[2]  T. Garland,et al.  Biological/Genetic Regulation of Physical Activity Level: Consensus from GenBioPAC , 2017, Medicine and science in sports and exercise.

[3]  T. Garland,et al.  Maternal exposure to Western diet affects adult body composition and voluntary wheel running in a genotype-specific manner in mice , 2017, Physiology & Behavior.

[4]  Charles M. Bishop,et al.  Do Bar-Headed Geese Train for High Altitude Flights? , 2017, Integrative and comparative biology.

[5]  T. Garland,et al.  Selective Breeding and Short-Term Access to a Running Wheel Alter Stride Characteristics in House Mice , 2017, Physiological and Biochemical Zoology.

[6]  T. Garland,et al.  Effects of activity, genetic selection and their interaction on muscle metabolic capacities and organ masses in mice , 2017, Journal of Experimental Biology.

[7]  T. Garland,et al.  Circulating levels of endocannabinoids respond acutely to voluntary exercise, are altered in mice selectively bred for high voluntary wheel running, and differ between the sexes , 2017, Physiology & Behavior.

[8]  Elizabeth M. Dlugosz,et al.  Preference for Western diet coadapts in High Runner mice and affects voluntary exercise and spontaneous physical activity in a genotype-dependent manner , 2017, Behavioural Processes.

[9]  L. Halsey Do animals exercise to keep fit? , 2016, The Journal of animal ecology.

[10]  Elizabeth M. Dlugosz,et al.  Effects of voluntary exercise on spontaneous physical activity and food consumption in mice: Results from an artificial selection experiment , 2015, Physiology & Behavior.

[11]  E. Gomes,et al.  Moving and positioning the nucleus in skeletal muscle – one step at a time , 2015, Nucleus.

[12]  T. Garland,et al.  Myosin heavy chain isoform expression in adult and juvenile mini-muscle mice bred for high-voluntary wheel running , 2014, Mechanisms of Development.

[13]  T. Garland,et al.  Quantitative genomics of voluntary exercise in mice: transcriptional analysis and mapping of expression QTL in muscle. , 2014, Physiological genomics.

[14]  C. Gottfried,et al.  Muscle injury: review of experimental models. , 2013, Journal of electromyography and kinesiology : official journal of the International Society of Electrophysiological Kinesiology.

[15]  T. Garland,et al.  LIMITS TO BEHAVIORAL EVOLUTION: THE QUANTITATIVE GENETICS OF A COMPLEX TRAIT UNDER DIRECTIONAL SELECTION , 2013, Evolution; international journal of organic evolution.

[16]  Freddie H. Fu,et al.  Intramuscular Transplantation of Muscle-Derived Stem Cells Accelerates Skeletal Muscle Healing After Contusion Injury via Enhancement of Angiogenesis , 2011, The American journal of sports medicine.

[17]  T. Garland,et al.  The biological control of voluntary exercise, spontaneous physical activity and daily energy expenditure in relation to obesity: human and rodent perspectives , 2011, Journal of Experimental Biology.

[18]  T. Garland,et al.  Sex-Specific Heterosis in Line Crosses of Mice Selectively Bred for High Locomotor Activity , 2010, Behavior genetics.

[19]  M. Umer,et al.  Muscle healing and nerve regeneration in a muscle contusion model in the rat. , 2010, The Journal of bone and joint surgery. British volume.

[20]  M. Boninger,et al.  The synergistic effect of treadmill running on stem-cell transplantation to heal injured skeletal muscle. , 2010, Tissue engineering. Part A.

[21]  Y. Epstein,et al.  Relationship between serum creatine kinase activity following exercise-induced muscle damage and muscle fibre composition , 2010, Journal of sports sciences.

[22]  T. Garland,et al.  Endurance capacity of mice selectively bred for high voluntary wheel running , 2009, Journal of Experimental Biology.

[23]  T. Garland,et al.  Locomotor trade-offs in mice selectively bred for high voluntary wheel running , 2009, Journal of Experimental Biology.

[24]  Elizabeth M. Dlugosz,et al.  Changes in efficiency and myosin expression in the small-muscle phenotype of mice selectively bred for high voluntary running activity , 2009, Journal of Experimental Biology.

[25]  T. Garland,et al.  Glycogen storage and muscle glucose transporters (GLUT-4) of mice selectively bred for high voluntary wheel running , 2009, Journal of Experimental Biology.

[26]  T. Garland,et al.  Differential response to a selective cannabinoid receptor antagonist (SR141716: rimonabant) in female mice from lines selectively bred for high voluntary wheel-running behaviour , 2008, Behavioural pharmacology.

[27]  T. Garland,et al.  Altered fibre types in gastrocnemius muscle of high wheel-running selected mice with mini-muscle phenotypes. , 2008, Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology.

[28]  V. Mougios,et al.  Reference intervals for serum creatine kinase in athletes , 2007, British Journal of Sports Medicine.

[29]  T. Garland,et al.  Maximal oxygen consumption in relation to subordinate traits in lines of house mice selectively bred for high voluntary wheel running. , 2006, Journal of applied physiology.

[30]  T. Garland,et al.  Morphometry, ultrastructure, myosin isoforms, and metabolic capacities of the "mini muscles" favoured by selection for high activity in house mice. , 2006, Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology.

[31]  T. Garland,et al.  Experimental evolution and phenotypic plasticity of hindlimb bones in high‐activity house mice , 2006, Journal of morphology.

[32]  T. Garland,et al.  Contractile abilities of normal and “ mini ” triceps surae muscles from mice ( Mus domesticus ) selectively bred for high voluntary wheel running , 2005 .

[33]  T. Garland,et al.  Selection Experiments as a Tool in Evolutionary and Comparative Physiology: Insights into Complex Traits—an Introduction to the Symposium1 , 2005, Integrative and comparative biology.

[34]  Teppo L N Järvinen,et al.  Muscle Injuries , 2005, The American journal of sports medicine.

[35]  T. Garland,et al.  Opioid-mediated pain sensitivity in mice bred for high voluntary wheel running , 2004, Physiology & Behavior.

[36]  Jason G. Belter,et al.  Effects of voluntary exercise and genetic selection for high activity levels on HSP72 expression in house mice. , 2004, Journal of applied physiology.

[37]  P. Bogner,et al.  Metabolic changes induced by regular submaximal aerobic exercise in meat-type rabbits. , 2003, Acta veterinaria Hungarica.

[38]  D. Allen,et al.  Loss of desmin leads to impaired voluntary wheel running and treadmill exercise performance. , 2003, Journal of applied physiology.

[39]  M. Nikolaidis,et al.  Hematologic and biochemical profile of juvenile and adult athletes of both sexes: implications for clinical evaluation. , 2003, International journal of sports medicine.

[40]  T. Mcloughlin,et al.  Downhill running in rats: influence on neutrophils, macrophages, and MyoD+ cells in skeletal muscle , 2003, European Journal of Applied Physiology.

[41]  Y. Epstein,et al.  Plasma antioxidant status and cell injury after severe physical exercise , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[42]  T. Koh Do Small Heat Shock Proteins Protect Skeletal Muscle from Injury? , 2002, Exercise and sport sciences reviews.

[43]  Jason G. Belter,et al.  EVOLUTION OF A SMALL‐MUSCLE POLYMORPHISM IN LINES OF HOUSE MICE SELECTED FOR HIGH ACTIVITY LEVELS , 2002, Evolution; international journal of organic evolution.

[44]  T. Garland,et al.  Selection for high voluntary wheel-running increases speed and intermittency in house mice (Mus domesticus). , 2001, The Journal of experimental biology.

[45]  B. Kłapcińska,et al.  The effects of sprint (300 m) running on plasma lactate, uric acid, creatine kinase and lactate dehydrogenase in competitive hurdlers and untrained men. , 2001, The Journal of sports medicine and physical fitness.

[46]  T. Koh,et al.  Lengthening contractions are not required to induce protection from contraction-induced muscle injury. , 2001, American journal of physiology. Regulatory, integrative and comparative physiology.

[47]  J. Fridén,et al.  Serum creatine kinase level is a poor predictor of muscle function after injury , 2001, Scandinavian journal of medicine & science in sports.

[48]  K. Fallon,et al.  The biochemistry of runners in a 1600 km ultramarathon. , 1999, British journal of sports medicine.

[49]  T. Garland,et al.  Artificial Selection for Increased Wheel-Running Behavior in House Mice , 1998, Behavior genetics.

[50]  J. D. Richardson,et al.  Cannabinoids reduce hyperalgesia and inflammation via interaction with peripheral CB1 receptors , 1998, Pain.

[51]  C. Kasper Sarcolemmal disruption in reloaded atrophic skeletal muscle. , 1995, Journal of applied physiology.

[52]  V. Vihko,et al.  Training-Induced Protection and Effect of Terminated Training on Exercise-Induced Damage and Water Content in Mouse Skeletal Muscles , 1995, International journal of sports medicine.

[53]  V. Vihko,et al.  Exercise-induced necrotic muscle damage and enzyme release in the four days following prolonged submaximal running in rats , 1994, Pflügers Archiv.

[54]  M. Panjabi,et al.  A Muscle Contusion Injury Model , 1994, The American journal of sports medicine.

[55]  R. Abresch,et al.  Effects of exhaustive concentric and eccentric exercise on murine skeletal muscle. , 1994, Archives of physical medicine and rehabilitation.

[56]  M. Lehto,et al.  The Effects of Early Mobilisation and Immobilisation on the Healing Process Following Muscle Injuries , 1993, Sports medicine.

[57]  D. Wahlsten Sample Size to Detect a Planned Contrast and a One Degree-of-Freedom Interaction Effect , 1991 .

[58]  T. Yoshioka,et al.  Profiles of creatine kinase isoenzyme compositions in single muscle fibres of different types , 1991, Journal of Muscle Research & Cell Motility.

[59]  D. Slaaf,et al.  Exercise-induced swelling of rat soleus muscle: its relationship with intramuscular pressure. , 1990, Journal of applied physiology.

[60]  Douglas Wahlsten,et al.  Insensitivity of the analysis of variance to heredity-environment interaction , 1990, Behavioral and Brain Sciences.

[61]  R. Armstrong,et al.  Rat skeletal muscle mitochondrial [Ca2+] and injury from downhill walking. , 1990, Journal of applied physiology.

[62]  C. Purdam,et al.  Hamstring injuries in sprinting - the role of eccentric exercise. , 1989, The Journal of orthopaedic and sports physical therapy.

[63]  R. Armstrong,et al.  Lesions in the rat soleus muscle following eccentrically biased exercise. , 1988, The American journal of anatomy.

[64]  W. Akeson,et al.  Residual muscular swelling after repetitive eccentric contractions , 1988, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[65]  A. Irintchev,et al.  Muscle damage and repair in voluntarily running mice: strain and muscle differences , 1987, Cell and Tissue Research.

[66]  J. Lott,et al.  Changes in serum enzymes, lactate, and haptoglobin following acute physical stress in international-class athletes. , 1987, Clinical biochemistry.

[67]  B H Jones,et al.  Metabolic changes following eccentric exercise in trained and untrained men. , 1986, Journal of applied physiology.

[68]  D. Newham,et al.  Experimental human muscle damage: morphological changes in relation to other indices of damage. , 1986, The Journal of physiology.

[69]  J A Faulkner,et al.  Injury to skeletal muscle fibers of mice following lengthening contractions. , 1985, Journal of applied physiology.

[70]  W. Evans,et al.  Skeletal muscle injury and repair in marathon runners after competition. , 1985, The American journal of pathology.

[71]  R. Armstrong,et al.  Effect of training on skeletal muscle injury from downhill running in rats , 1983 .

[72]  S. Cattaneo,et al.  Changes in serum myoglobin, total creatine kinase, lactate dehydrogenase and creatine kinase MB levels in runners. , 1983, Clinical biochemistry.

[73]  T. Oei,et al.  Exercise-induced changes in common laboratory tests. , 1982, American journal of clinical pathology.

[74]  J. Rantamäki,et al.  Exhaustive physical exercise and acid hydrolase activity in mouse skeletal muscle , 1978, Histochemistry.

[75]  Zoe Thompson The Neurobiological Basis of Voluntary Exercise in Selectively-Bred High Runner Mice , 2017 .

[76]  Mao-tsun Lin,et al.  Transgenic overexpression of heat shock protein 72 in mouse muscle protects against exhaustive exercise-induced skeletal muscle damage. , 2013, Journal of the Formosan Medical Association = Taiwan yi zhi.

[77]  K. Nosaka,et al.  Repeated bout effect: research update and future perspective , 2011 .

[78]  Nicola Maffulli,et al.  Creatine kinase monitoring in sport medicine. , 2007, British medical bulletin.

[79]  P. Apor,et al.  Metabolic enzyme activity patterns in muscle biopsy samples in different athletes , 2006, European Journal of Applied Physiology and Occupational Physiology.

[80]  J. Malisch,et al.  Maximal metabolic rates during voluntary exercise, forced exercise, and cold exposure in house mice selectively bred for high wheel-running , 2005, Journal of Experimental Biology.

[81]  T. Ohkuwa,et al.  Plasma LDH and CK activities after 400 m sprinting by well-trained sprint runners , 2004, European Journal of Applied Physiology and Occupational Physiology.

[82]  J. D. Richardson,et al.  Cannabinoids modulate pain by multiple mechanisms of action , 2000 .

[83]  V. Vihko,et al.  Lysosomal changes related to exercise injuries and training-induced protection in mouse skeletal muscle. , 1984, Acta physiologica Scandinavica.

[84]  R. Armstrong,et al.  Eccentric exercise-induced injury to rat skeletal muscle. , 1983, Journal of applied physiology: respiratory, environmental and exercise physiology.