Mitochondrial and performance adaptations to exercise training in mice lacking skeletal muscle LKB1.

LKB1 and its downstream targets of the AMP-activated protein kinase family are important regulators of many aspects of skeletal muscle cell function, including control of mitochondrial content and capillarity. LKB1 deficiency in skeletal and cardiac muscle (mLKB1-KO) greatly impairs exercise capacity. However, cardiac dysfunction in that genetic model prevents a clear assessment of the role of skeletal muscle LKB1 in the observed effects. Our purposes here were to determine whether skeletal muscle-specific knockout of LKB1 (skmLKB1-KO) decreases exercise capacity and mitochondrial protein content, impairs accretion of mitochondrial proteins after exercise training, and attenuates improvement in running performance after exercise training. We found that treadmill and voluntary wheel running capacity was reduced in skmLKB1-KO vs. control (CON) mice. Citrate synthase activity, succinate dehydrogenase activity, and pyruvate dehydrogenase kinase content were lower in KO vs. CON muscles. Three weeks of treadmill training resulted in significantly increased treadmill running performance in both CON and skmLKB1-KO mice. Citrate synthase activity increased significantly with training in both genotypes, but protein content and activity for components of the mitochondrial electron transport chain increased only in CON mice. Capillarity and VEGF protein was lower in skmLKB1-KO vs. CON muscles, but VEGF increased with training only in skmLKB1-KO. Three hours after an acute bout of muscle contractions, PGC-1α, cytochrome c, and VEGF gene expression all increased in CON but not skmLKB1-KO muscles. Our findings indicate that skeletal muscle LKB1 is required for accretion of some mitochondrial proteins but not for early exercise capacity improvements with exercise training.

[1]  M. Febbraio,et al.  Marked phenotypic differences of endurance performance and exercise-induced oxygen consumption between AMPK and LKB1 deficiency in mouse skeletal muscle: changes occurring in the diaphragm. , 2013, American journal of physiology. Endocrinology and metabolism.

[2]  J. Dyck,et al.  LKB1 Regulates Lipid Oxidation During Exercise Independently of AMPK , 2013, Diabetes.

[3]  J. Pinthus,et al.  Underexpression of tumour suppressor LKB1 in clear cell renal cell carcinoma is common and confers growth advantage in vitro and in vivo , 2013, British Journal of Cancer.

[4]  O. Gavrilova,et al.  Disruption of Hypoxia-Inducible Factor 1 in Adipocytes Improves Insulin Sensitivity and Decreases Adiposity in High-Fat Diet–Fed Mice , 2011, Diabetes.

[5]  M. Tarnopolsky,et al.  AMP-activated protein kinase (AMPK) β1β2 muscle null mice reveal an essential role for AMPK in maintaining mitochondrial content and glucose uptake during exercise , 2011, Proceedings of the National Academy of Sciences.

[6]  R. A. DiGiovanni,et al.  Effect of LKB1 deficiency on mitochondrial content, fibre type and muscle performance in the mouse diaphragm , 2011, Acta physiologica.

[7]  David Carling,et al.  Structure of Mammalian AMPK and its regulation by ADP , 2011, Nature.

[8]  S. Rohrbach,et al.  Mitochondrial Biogenesis and Peroxisome Proliferator–Activated Receptor-γ Coactivator-1α (PGC-1α) Deacetylation by Physical Activity , 2010, Diabetes.

[9]  S. Rohrbach,et al.  Mitochondrial Biogenesis and Peroxisome Proliferator–Activated Receptor-γ Coactivator-1α (PGC-1α) Deacetylation by Physical Activity , 2010, Diabetes.

[10]  H. Pilegaard,et al.  PGC-1{alpha} is required for AICAR-induced expression of GLUT4 and mitochondrial proteins in mouse skeletal muscle. , 2010, American journal of physiology. Endocrinology and metabolism.

[11]  N. Fujii,et al.  Sucrose nonfermenting AMPK-related kinase (SNARK) mediates contraction-stimulated glucose transport in mouse skeletal muscle , 2010, Proceedings of the National Academy of Sciences.

[12]  N. Fujii,et al.  Ablation of LKB1 in the heart leads to energy deprivation and impaired cardiac function. , 2010, Biochimica et biophysica acta.

[13]  W. Winder,et al.  Skeletal muscle dysfunction in muscle-specific LKB1 knockout mice. , 2010, Journal of applied physiology.

[14]  D. O'Gorman,et al.  Exercise intensity‐dependent regulation of peroxisome proliferator‐activated receptor γ coactivator‐1α mRNA abundance is associated with differential activation of upstream signalling kinases in human skeletal muscle , 2010, The Journal of physiology.

[15]  W. Winder,et al.  Effects of excess corticosterone on LKB1 and AMPK signaling in rat skeletal muscle. , 2010, Journal of applied physiology.

[16]  H. Pilegaard,et al.  PGC-1 is required for AICAR-induced expression of GLUT4 and mitochondrial proteins in mouse skeletal muscle , 2010 .

[17]  J. Dyck,et al.  Cardiac-specific Deletion of LKB1 Leads to Hypertrophy and Dysfunction , 2009, The Journal of Biological Chemistry.

[18]  Robert S. Balaban,et al.  p53 Improves Aerobic Exercise Capacity and Augments Skeletal Muscle Mitochondrial DNA Content , 2009, Circulation research.

[19]  L. Westerkamp,et al.  AMPK regulates basal skeletal muscle capillarization and VEGF expression, but is not necessary for the angiogenic response to exercise , 2008, The Journal of physiology.

[20]  T. Kizaki,et al.  Acute exercise induces biphasic increase in respiratory mRNA in skeletal muscle. , 2008, Biochemical and biophysical research communications.

[21]  D. Hardie,et al.  Normal hypertrophy accompanied by phosphoryation and activation of AMP‐activated protein kinase α1 following overload in LKB1 knockout mice , 2008, The Journal of physiology.

[22]  Y. Hellsten,et al.  PGC-1α is not mandatory for exercise- and training-induced adaptive gene responses in mouse skeletal muscle , 2008 .

[23]  J. D. Brown,et al.  LKB1 and the regulation of malonyl-CoA and fatty acid oxidation in muscle. , 2007, American journal of physiology. Endocrinology and metabolism.

[24]  G. McConell,et al.  NOS isoform‐specific regulation of basal but not exercise‐induced mitochondrial biogenesis in mouse skeletal muscle , 2007, The Journal of physiology.

[25]  N. Fujii,et al.  Skeletal Muscle Adaptation to Exercise Training , 2007, Diabetes.

[26]  B. Spiegelman,et al.  AMP-activated protein kinase (AMPK) action in skeletal muscle via direct phosphorylation of PGC-1α , 2007, Proceedings of the National Academy of Sciences.

[27]  Malay Haldar,et al.  A conditional mouse model of synovial sarcoma: insights into a myogenic origin. , 2007, Cancer cell.

[28]  S. Rodriguez-Cuenca,et al.  Expression of mitochondrial biogenesis-signaling factors in brown adipocytes is influenced specifically by 17beta-estradiol, testosterone, and progesterone. , 2007, American journal of physiology. Endocrinology and metabolism.

[29]  W. Winder,et al.  Skeletal muscle and heart LKB1 deficiency causes decreased voluntary running and reduced muscle mitochondrial marker enzyme expression in mice. , 2007, American journal of physiology. Endocrinology and metabolism.

[30]  B. Spiegelman,et al.  AMP-activated protein kinase (AMPK) action in skeletal muscle via direct phosphorylation of PGC-1alpha. , 2007, Proceedings of the National Academy of Sciences of the United States of America.

[31]  B. Viollet,et al.  Role of AMPKalpha2 in basal, training-, and AICAR-induced GLUT4, hexokinase II, and mitochondrial protein expression in mouse muscle. , 2007, American journal of physiology. Endocrinology and metabolism.

[32]  L. Westerkamp,et al.  Soleus, plantaris and gastrocnemius VEGF mRNA responses to hypoxia and exercise are preserved in aged compared with young female C57BL/6 mice , 2006, Acta physiologica.

[33]  C. Kahn,et al.  Skeletal Muscle-Selective Knockout of LKB1 Increases Insulin Sensitivity, Improves Glucose Homeostasis, and Decreases TRB3 , 2006, Molecular and Cellular Biology.

[34]  H. Esumi,et al.  Muscle contractions, AICAR, and insulin cause phosphorylation of an AMPK-related kinase. , 2005, American journal of physiology. Endocrinology and metabolism.

[35]  P. Neufer,et al.  Effects of α‐AMPK knockout on exercise‐induced gene activation in mouse skeletal muscle , 2005 .

[36]  Kei Sakamoto,et al.  Deficiency of LKB1 in skeletal muscle prevents AMPK activation and glucose uptake during contraction , 2005, The EMBO journal.

[37]  K. Walsh,et al.  AMP-Activated Protein Kinase Signaling Stimulates VEGF Expression and Angiogenesis in Skeletal Muscle , 2005, Circulation research.

[38]  P. Neufer,et al.  Effects of alpha-AMPK knockout on exercise-induced gene activation in mouse skeletal muscle. , 2005, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[39]  M. Gassmann,et al.  HIF and VEGF relationships in response to hypoxia and sciatic nerve stimulation in rat gastrocnemius , 2004, Respiratory Physiology & Neurobiology.

[40]  Jérôme Boudeau,et al.  LKB1 is a master kinase that activates 13 kinases of the AMPK subfamily, including MARK/PAR‐1 , 2004, The EMBO journal.

[41]  A. Marette,et al.  The AMP‐activated protein kinase activator AICAR does not induce GLUT4 translocation to transverse tubules but stimulates glucose uptake and p38 mitogen‐activated protein kinases α and β in skeletal muscle , 2003 .

[42]  David Carling,et al.  Activation of yeast Snf1 and mammalian AMP-activated protein kinase by upstream kinases , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[43]  D. Hood,et al.  PPARγ coactivator-1α expression during thyroid hormone-and contractile activity-induced mitochondrial adaptations , 2003 .

[44]  A. Marette,et al.  The AMP-activated protein kinase activator AICAR does not induce GLUT4 translocation to transverse tubules but stimulates glucose uptake and p38 mitogen-activated protein kinases alpha and beta in skeletal muscle. , 2003, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[45]  Robert V Farese,et al.  Activation of the ERK Pathway and Atypical Protein Kinase C Isoforms in Exercise- and Aminoimidazole-4-carboxamide- 1-β-d-riboside (AICAR)-stimulated Glucose Transport* , 2002, The Journal of Biological Chemistry.

[46]  W. Winder,et al.  Phosphorylation-activity relationships of AMPK and acetyl-CoA carboxylase in muscle. , 2002, Journal of applied physiology.

[47]  G. Shulman,et al.  Chronic activation of AMP kinase results in NRF-1 activation and mitochondrial biogenesis. , 2001, American journal of physiology. Endocrinology and metabolism.

[48]  H. Brenner,et al.  Induction of multiple signaling loops by MuSK during neuromuscular synapse formation , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[49]  R. Devine,et al.  Concentration dependence of the dielectric constant in mixed oxides MxOyMp′Oq , 2001 .

[50]  D. Hood,et al.  Effects of contractile activity on mitochondrial transcription factor A expression in skeletal muscle. , 2001, Journal of applied physiology.

[51]  D. Hood,et al.  Selected Contribution: Effects of contractile activity on mitochondrial transcription factor A expression in skeletal muscle , 2001 .

[52]  W. Winder,et al.  Activation of AMP-activated protein kinase increases mitochondrial enzymes in skeletal muscle. , 2000, Journal of applied physiology.

[53]  T. Gustafsson,et al.  Exercise-induced expression of angiogenesis-related transcription and growth factors in human skeletal muscle. , 1999, American journal of physiology. Heart and circulatory physiology.

[54]  S. Hawley,et al.  Characterization of the AMP-activated Protein Kinase Kinase from Rat Liver and Identification of Threonine 172 as the Major Site at Which It Phosphorylates AMP-activated Protein Kinase* , 1996, The Journal of Biological Chemistry.

[55]  P. Wagner,et al.  Angiogenic growth factor mRNA responses in muscle to a single bout of exercise. , 1996, Journal of applied physiology.

[56]  D. Hardie,et al.  Inactivation of acetyl-CoA carboxylase and activation of AMP-activated protein kinase in muscle during exercise. , 1996, The American journal of physiology.

[57]  F. Cobb,et al.  Skeletal muscle biochemistry and histology in ambulatory patients with long-term heart failure. , 1990, Circulation.

[58]  David Carling,et al.  A common bicyclic protein kinase cascade inactivates the regulatory enzymes of fatty acid and cholesterol biosynthesis , 1987, FEBS letters.

[59]  S. Salmons,et al.  Regulation of nuclear and mitochondrial gene expression by contractile activity in skeletal muscle. , 1986, The Journal of biological chemistry.

[60]  M. Danson,et al.  Citrate synthase. , 2020, Current topics in cellular regulation.

[61]  P. Srere,et al.  [1] Citrate synthase. [EC 4.1.3.7. Citrate oxaloacetate-lyase (CoA-acetylating)] , 1969 .

[62]  J. Holloszy Biochemical adaptations in muscle. Effects of exercise on mitochondrial oxygen uptake and respiratory enzyme activity in skeletal muscle. , 1967, The Journal of biological chemistry.