Engineering of human myotubes toward a mature metabolic and contractile phenotype

Skeletal muscle mediates the beneficial effects of exercise, thereby improving insulin sensitivity and reducing the risk for type 2 diabetes. Current human skeletal muscle models in vitro are incapable of fully recapitulating its physiological functions especially muscle contractility. By supplementation of insulin-like growth factor 1 (IGF1), a growth factor secreted by myofibers in vivo, we aimed to overcome these limitations. We monitored the differentiation process starting from primary human CD56-positive myoblasts in the presence/absence of IGF1 in serum-free medium in daily collected samples for 10 days. IGF1-supported differentiation formed thicker multinucleated myotubes showing physiological contraction upon electrical pulse stimulation following day 6. Myotubes without IGF1 were almost incapable of contraction. IGF1-treatment shifted the proteome toward skeletal muscle-specific proteins that contribute to myofibril and sarcomere assembly, striated muscle contraction, and ATP production. Elevated PPARGC1A, MYH7 and reduced MYH1/2 suggest a more oxidative phenotype further demonstrated by higher abundance of proteins of the respiratory chain and elevated mitochondrial respiration. IGF1-treatment also upregulated GLUT4 and increased insulin-dependent glucose uptake compared to myotubes differentiated without IGF1. To conclude, utilizing IGF1, we engineered human myotubes that recapitulate the physiological traits of skeletal muscle in vivo superior to established protocols and overcome limitations of previous standards. This novel “easy to use” model enables investigation of exercise on a molecular level.

[1]  Piero Carninci,et al.  Distinctive exercise-induced inflammatory response and exerkine induction in skeletal muscle of people with type 2 diabetes , 2022, Science advances.

[2]  P. Loskill,et al.  Developer’s Guide to an Organ-on-Chip Model , 2022, ACS biomaterials science & engineering.

[3]  E. Richter,et al.  Interactions between insulin and exercise. , 2021, The Biochemical journal.

[4]  C. S. Shaw,et al.  Translating glucose tolerance data from mice to humans: Insights from stable isotope labelled glucose tolerance tests , 2021, Molecular metabolism.

[5]  R. Seeley,et al.  Mice as experimental models for human physiology: when several degrees in housing temperature matter , 2021, Nature Metabolism.

[6]  P. Delafontaine,et al.  Mechanisms of IGF-1-Mediated Regulation of Skeletal Muscle Hypertrophy and Atrophy , 2020, Cells.

[7]  F. Schick,et al.  Response of mitochondrial respiration in adipose tissue and muscle to 8 weeks of endurance exercise in obese subjects. , 2020, The Journal of clinical endocrinology and metabolism.

[8]  Hongbing Shen,et al.  Pre-diagnostic circulating concentrations of insulin-like growth factor-1 and risk of COVID-19 mortality: results from UK Biobank , 2020, European Journal of Epidemiology.

[9]  Michael E. Miller,et al.  Critical Role of Type III Interferon in Controlling SARS-CoV-2 Infection in Human Intestinal Epithelial Cells , 2020, Cell Reports.

[10]  B. Pedersen,et al.  Muscle–Organ Crosstalk: The Emerging Roles of Myokines , 2020, Endocrine reviews.

[11]  G. Truskey,et al.  Glucose Uptake and Insulin Response in Tissue-engineered Human Skeletal Muscle , 2020, Tissue Engineering and Regenerative Medicine.

[12]  D. Lewis Animal experimentation: implementation and application of the 3Rs. , 2019, Emerging topics in life sciences.

[13]  Oliver Schneider,et al.  User-Friendly and Parallelized Generation of Human Induced Pluripotent Stem Cell-Derived Microtissues in a Centrifugal Heart-on-a-Chip , 2019, Tissue engineering. Part A.

[14]  Lauran R. Madden,et al.  Electrical stimulation increases hypertrophy and metabolic flux in tissue-engineered human skeletal muscle. , 2019, Biomaterials.

[15]  H. Häring,et al.  The effect of differentiation and TGFβ on mitochondrial respiration and mitochondrial enzyme abundance in cultured primary human skeletal muscle cells , 2018, Scientific Reports.

[16]  C. Weigert,et al.  Skeletal Muscle as an Endocrine Organ: The Role of Myokines in Exercise Adaptations. , 2017, Cold Spring Harbor perspectives in medicine.

[17]  C. S. Shaw,et al.  Exercise Increases Human Skeletal Muscle Insulin Sensitivity via Coordinated Increases in Microvascular Perfusion and Molecular Signaling , 2017, Diabetes.

[18]  F. Schick,et al.  TGF-β Contributes to Impaired Exercise Response by Suppression of Mitochondrial Key Regulators in Skeletal Muscle , 2016, Diabetes.

[19]  K. Häkkinen,et al.  Effects of resistance training on expression of IGF-I splice variants in younger and older men , 2016, European journal of sport science.

[20]  S. Hauck,et al.  The Proteome of Native Adult Müller Glial Cells From Murine Retina* , 2015, Molecular & Cellular Proteomics.

[21]  S. Kuang,et al.  mTOR is necessary for proper satellite cell activity and skeletal muscle regeneration. , 2015, Biochemical and biophysical research communications.

[22]  Concha Gil,et al.  General statistical framework for quantitative proteomics by stable isotope labeling. , 2014, Journal of proteome research.

[23]  W. Evans,et al.  Mechano-growth factor peptide, the COOH terminus of unprocessed insulin-like growth factor 1, has no apparent effect on myoblasts or primary muscle stem cells. , 2014, American journal of physiology. Endocrinology and metabolism.

[24]  M. D. de Angelis,et al.  Cytokine response of primary human myotubes in an in vitro exercise model. , 2013, American journal of physiology. Cell physiology.

[25]  E. Richter,et al.  Exercise, GLUT4, and skeletal muscle glucose uptake. , 2013, Physiological reviews.

[26]  G. H. Thoresen,et al.  Are cultured human myotubes far from home? , 2013, Cell and Tissue Research.

[27]  N. Zanou,et al.  Skeletal muscle hypertrophy and regeneration: interplay between the myogenic regulatory factors (MRFs) and insulin-like growth factors (IGFs) pathways , 2013, Cellular and Molecular Life Sciences.

[28]  J. Zierath,et al.  Exercise metabolism and the molecular regulation of skeletal muscle adaptation. , 2013, Cell metabolism.

[29]  J. Gumucio,et al.  Atrogin-1, MuRF-1, and sarcopenia , 2013, Endocrine.

[30]  G. H. Thoresen,et al.  Electrical Pulse Stimulation of Cultured Human Skeletal Muscle Cells as an In Vitro Model of Exercise , 2012, PloS one.

[31]  J. Eckel,et al.  Contractile activity of human skeletal muscle cells prevents insulin resistance by inhibiting pro-inflammatory signalling pathways , 2012, Diabetologia.

[32]  M. Gautel,et al.  Transcriptional mechanisms regulating skeletal muscle differentiation, growth and homeostasis , 2011, Nature Reviews Molecular Cell Biology.

[33]  G. Butler-Browne,et al.  Mechano Growth Factor E peptide (MGF-E), derived from an isoform of IGF-1, activates human muscle progenitor cells and induces an increase in their fusion potential at different ages , 2011, Mechanisms of Ageing and Development.

[34]  C. Mammucari,et al.  Regulation of skeletal muscle growth by the IGF1-Akt/PKB pathway: insights from genetic models , 2011, Skeletal Muscle.

[35]  Erno Pungor,et al.  Proteomic Analysis for the Assessment of Different Lots of Fetal Bovine Serum as a Raw Material for Cell Culture. Part IV. Application of Proteomics to the Manufacture of Biological Drugs , 2008, Biotechnology progress.

[36]  Marco Sandri,et al.  Signaling in muscle atrophy and hypertrophy. , 2008, Physiology.

[37]  L. C. V. van Loon,et al.  Exercise: the brittle cornerstone of type 2 diabetes treatment , 2008, Diabetologia.

[38]  J. Hawley,et al.  Exercise training‐induced improvements in insulin action , 2007, Acta physiologica.

[39]  D. Guttridge Faculty Opinions recommendation of Skeletal muscle fiber-type switching, exercise intolerance, and myopathy in PGC-1alpha muscle-specific knock-out animals. , 2007 .

[40]  G. Butler-Browne,et al.  IL-13 mediates the recruitment of reserve cells for fusion during IGF-1-induced hypertrophy of human myotubes , 2007, Journal of Cell Science.

[41]  T. Rando,et al.  Stem cells in postnatal myogenesis: molecular mechanisms of satellite cell quiescence, activation and replenishment. , 2005, Trends in cell biology.

[42]  C. Stewart,et al.  Isolation and validation of human prepubertal skeletal muscle cells: maturation and metabolic effects of IGF‐I, IGFBP‐3 and TNFα , 2005, The Journal of physiology.

[43]  S. Kandarian,et al.  The molecular basis of skeletal muscle atrophy. , 2004, American journal of physiology. Cell physiology.

[44]  A. Bigot,et al.  IGF-1 induces human myotube hypertrophy by increasing cell recruitment. , 2004, Experimental Cell Research.

[45]  C. Stewart,et al.  Differential signalling mechanisms predisposing primary human skeletal muscle cells to altered proliferation and differentiation: roles of IGF-I and TNFalpha. , 2004, Experimental cell research.

[46]  R W Orrell,et al.  Expression of IGF‐I splice variants in young and old human skeletal muscle after high resistance exercise , 2003, The Journal of physiology.

[47]  D. Glass Signalling pathways that mediate skeletal muscle hypertrophy and atrophy , 2003, Nature Cell Biology.

[48]  H. Arnqvist,et al.  Circulating IGF-I concentrations are low and not correlated to glycaemic control in adults with type 1 diabetes. , 2000, European journal of endocrinology.

[49]  E. Richter,et al.  Fiber type-specific expression of GLUT4 in human skeletal muscle: influence of exercise training. , 2000, Diabetes.

[50]  H. Klein,et al.  Insulin signaling and action in cultured skeletal muscle cells from lean healthy humans with high and low insulin sensitivity. , 2000, Diabetes.

[51]  P. Poulsen,et al.  Direct evidence of fiber type-dependent GLUT-4 expression in human skeletal muscle. , 2000, American journal of physiology. Endocrinology and metabolism.

[52]  D. Barritault,et al.  Growth factors in skeletal muscle regeneration. , 1996, Cytokine & growth factor reviews.

[53]  R. Henry,et al.  Insulin Action and Glucose Metabolism in Nondiabetic Control and NIDDM Subjects: Comparison Using Human Skeletal Muscle Cell Cultures , 1995, Diabetes.

[54]  P. Jap,et al.  Differentiation of human skeletal muscle cells in culture: maturation as indicated by titin and desmin striation , 1992, Cell and Tissue Research.

[55]  Lawrence A Leiter,et al.  Glucose transport in human skeletal muscle cells in culture. Stimulation by insulin and metformin. , 1992, The Journal of clinical investigation.

[56]  J. Veerkamp,et al.  The biochemical and structural maturation of human skeletal muscle cells in culture: the effect of the serum substitute Ultroser G. , 1991, Experimental cell research.

[57]  R. DeFronzo,et al.  Synergistic interaction between exercise and insulin on peripheral glucose uptake. , 1981, The Journal of clinical investigation.

[58]  H. Blau,et al.  Isolation and characterization of human muscle cells. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[59]  E. Thompson,et al.  A quantitative technique for growing human adult skeletal muscle in culture starting from mononucleated cells , 1977, Journal of the Neurological Sciences.

[60]  W. Engel,et al.  A new program for investigating adult human skeletal muscle grown aneurally in tissue culture , 1975, Neurology.

[61]  V. Dubowitz,et al.  Morphological studies on normal and diseased human muscle in culture. , 1971, Journal of the neurological sciences.

[62]  R. Jacobs,et al.  Adaptations of skeletal muscle mitochondria to exercise training , 2016, Experimental physiology.

[63]  H. Vandenburgh,et al.  In vitro Differentiation of Functional Human Skeletal Myotubes in a Defined System. , 2014, Biomaterials science.

[64]  R Core Team,et al.  R: A language and environment for statistical computing. , 2014 .

[65]  G. H. Thoresen,et al.  Chronic hyperglycemia reduces substrate oxidation and impairs metabolic switching of human myotubes. , 2011, Biochimica et biophysica acta.

[66]  C. Eyers Universal sample preparation method for proteome analysis , 2009 .

[67]  C. Bouchard,et al.  Effects of exercise training on glucose homeostasis: the HERITAGE Family Study. , 2005, Diabetes care.

[68]  Jiandie D. Lin,et al.  Transcriptional co-activator PGC-1 alpha drives the formation of slow-twitch muscle fibres. , 2002, Nature.