Three‐dimensional co‐culture of C2C12/PC12 cells improves skeletal muscle tissue formation and function

Engineered muscle tissues demonstrate properties far from native muscle tissue. Therefore, fabrication of muscle tissues with enhanced functionalities is required to enable their use in various applications. To improve the formation of mature muscle tissues with higher functionalities, we co‐cultured C2C12 myoblasts and PC12 neural cells. While alignment of the myoblasts was obtained by culturing the cells in micropatterned methacrylated gelatin (GelMA) hydrogels, we studied the effects of the neural cells (PC12) on the formation and maturation of muscle tissues. Myoblasts cultured in the presence of neural cells showed improved differentiation, with enhanced myotube formation. Myotube alignment, length and coverage area were increased. In addition, the mRNA expression of muscle differentiation markers (Myf‐5, myogenin, Mefc2, MLP), muscle maturation markers (MHC‐IId/x, MHC‐IIa, MHC‐IIb, MHC‐pn, α‐actinin, sarcomeric actinin) and the neuromuscular markers (AChE, AChR‐ε) were also upregulated. All these observations were amplified after further muscle tissue maturation under electrical stimulation. Our data suggest a synergistic effect on the C2C12 differentiation induced by PC12 cells, which could be useful for creating improved muscle tissue. Copyright © 2014 John Wiley & Sons, Ltd.

[1]  S. Ostrovidov,et al.  Membrane-Based PDMS Microbioreactor for Perfused 3D Primary Rat Hepatocyte Cultures , 2004, Biomedical microdevices.

[2]  D. Allen,et al.  C2C12 co-culture on a fibroblast substratum enables sustained survival of contractile, highly differentiated myotubes with peripheral nuclei and adult fast myosin expression. , 2004, Cell motility and the cytoskeleton.

[3]  Endogenous musculoskeletal tissue regeneration , 2012, Cell and Tissue Research.

[4]  Shuichi Takayama,et al.  The effect of continuous wavy micropatterns on silicone substrates on the alignment of skeletal muscle myoblasts and myotubes. , 2006, Biomaterials.

[5]  Libera Berghella,et al.  Molecular control of neuromuscular junction development , 2011, Journal of cachexia, sarcopenia and muscle.

[6]  Teruo Fujii,et al.  Integration of a pump and an electrical sensor into a membrane-based PDMS microbioreactor for cell culture and drug testing , 2011, Biomedical microdevices.

[7]  G. Taglialatela,et al.  Nerve growth factor (NGF) influences differentiation and proliferation of myogenic cells in vitro via TrKA , 2000, International Journal of Developmental Neuroscience.

[8]  C. Erck,et al.  Evidence for the participation of nerve growth factor and its low‐affinity receptor (p75NTR) in the regulation of the myogenic program , 1998, Journal of cellular physiology.

[9]  F. Baaijens,et al.  Mechanoregulation of vascularization in aligned tissue-engineered muscle: a role for vascular endothelial growth factor. , 2011, Tissue engineering. Part A.

[10]  R. Choi,et al.  Transcriptional control of different subunits of AChE in muscles: signals triggered by the motor nerve-derived factors. , 2008, Chemico-biological interactions.

[11]  S. Eichhorn,et al.  Directing the morphology and differentiation of skeletal muscle cells using oriented cellulose nanowhiskers. , 2010, Biomacromolecules.

[12]  A. Landesberg,et al.  Improved vascular organization enhances functional integration of engineered skeletal muscle grafts , 2011, Proceedings of the National Academy of Sciences.

[13]  J. Veerkamp,et al.  Differentiation markers of mouse C2C12 and rat L6 myogenic cell lines and the effect of the differentiation medium , 1999, In Vitro Cellular & Developmental Biology - Animal.

[14]  Kazushi Ikeda,et al.  Induction of functional tissue-engineered skeletal muscle constructs by defined electrical stimulation , 2014, Scientific Reports.

[15]  Nina L. Siow,et al.  Regulation of a Transcript Encoding the Proline-rich Membrane Anchor of Globular Muscle Acetylcholinesterase , 2007, Journal of Biological Chemistry.

[16]  M. S. Hansen,et al.  Connective tissue fibroblasts and Tcf4 regulate myogenesis , 2011, Development.

[17]  B. Nadal-Ginard,et al.  Characterization of a developmentally regulated perinatal myosin heavy-chain gene expressed in skeletal muscle. , 1984, The Journal of biological chemistry.

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

[19]  H. Kaminski,et al.  Molecular architecture of the neuromuscular junction , 2006, Muscle & nerve.

[20]  T. Mars,et al.  Neural agrin controls maturation of the excitation-contraction coupling mechanism in human myotubes developing in vitro. , 2008, American journal of physiology. Cell physiology.

[21]  Hong Guangxiang,et al.  Protective effects of ciliary neurotrophic factor on denervated skeletal muscle , 2008, Journal of Huazhong University of Science and Technology [Medical Sciences].

[22]  Benjamin Chu,et al.  Myotube assembly on nanofibrous and micropatterned polymers. , 2006, Nano letters.

[23]  Nenad Bursac,et al.  Soluble miniagrin enhances contractile function of engineered skeletal muscle , 2012, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[24]  L. Rubin,et al.  Regulation of acetylcholinesterase appearance at neuromuscular junctions in vitro , 1980, Nature.

[25]  Hyoungshin Park,et al.  Effects of electrical stimulation in C2C12 muscle constructs , 2008, Journal of tissue engineering and regenerative medicine.

[26]  T. Mars,et al.  Origin of acetylcholinesterase in the neuromuscular junction formed in the in vitro innervated human muscle , 2004, The European journal of neuroscience.

[27]  S. Rhodes,et al.  Identification of MRF4: a new member of the muscle regulatory factor gene family. , 1989, Genes & development.

[28]  C. Mantilla,et al.  Denervation-induced changes in myosin heavy chain expression in the rat diaphragm muscle. , 2003, Journal of applied physiology.

[29]  Makoto Kanzaki,et al.  Contractile C2C12 myotube model for studying exercise-inducible responses in skeletal muscle. , 2008, American journal of physiology. Endocrinology and metabolism.

[30]  Louise Deldicque,et al.  A novel bioreactor for stimulating skeletal muscle in vitro. , 2010, Tissue engineering. Part C, Methods.

[31]  F. Baaijens,et al.  Advanced maturation by electrical stimulation: Differences in response between C2C12 and primary muscle progenitor cells , 2011, Journal of tissue engineering and regenerative medicine.

[32]  P. Pregelj,et al.  The Role of Muscle Activation Pattern and Calcineurin in Acetylcholinesterase Regulation in Rat Skeletal Muscles , 2007, The Journal of Neuroscience.

[33]  H. Vandenburgh,et al.  High-content drug screening with engineered musculoskeletal tissues. , 2010, Tissue engineering. Part B, Reviews.

[34]  N. Miura,et al.  Screening of natural medicines that efficiently activate neurite outgrowth in PC12 cells in C2C12-cultured medium. , 2012, Biomedical research.

[35]  Rashid Bashir,et al.  Stereolithography‐Based Hydrogel Microenvironments to Examine Cellular Interactions , 2011 .

[36]  Ali Khademhosseini,et al.  Biomimetic tissues on a chip for drug discovery. , 2012, Drug discovery today.

[37]  Thomas D. Schmittgen,et al.  Analyzing real-time PCR data by the comparative CT method , 2008, Nature Protocols.

[38]  Adam J. Engler,et al.  Myotubes differentiate optimally on substrates with tissue-like stiffness , 2004, The Journal of cell biology.

[39]  Guoping Feng,et al.  The Histone Deacetylase HDAC4 Connects Neural Activity to Muscle Transcriptional Reprogramming* , 2007, Journal of Biological Chemistry.

[40]  William E Kraus,et al.  Morphology and ultrastructure of differentiating three‐dimensional mammalian skeletal muscle in a collagen gel , 2007, Muscle & nerve.

[41]  Ali Khademhosseini,et al.  Myotube formation on gelatin nanofibers - multi-walled carbon nanotubes hybrid scaffolds. , 2014, Biomaterials.

[42]  J. Beier,et al.  Expression of Trisk 51, agrin and nicotinic-acetycholine receptor ε-subunit during muscle development in a novel three-dimensional muscle-neuronal co-culture system , 2003, Cell and Tissue Research.

[43]  John Rasmussen,et al.  Uniaxial cyclic strain drives assembly and differentiation of skeletal myocytes. , 2011, Tissue engineering. Part A.

[44]  Victor K. Lin,et al.  Myogenin, a factor regulating myogenesis, has a domain homologous to MyoD , 1989, Cell.

[45]  M. Greenberg,et al.  Nerve growth factor and epidermal growth factor induce rapid transient changes in proto-oncogene transcription in PC12 cells. , 1985, The Journal of biological chemistry.

[46]  P. Pregelj,et al.  Junctional and extrajunctional acetylcholinesterase in skeletal muscle fibers. , 2005, Chemico-biological interactions.

[47]  Makoto Kanzaki,et al.  Accelerated de novo sarcomere assembly by electric pulse stimulation in C2C12 myotubes. , 2007, Experimental cell research.

[48]  Yasunori Yamamoto,et al.  Functional evaluation of artificial skeletal muscle tissue constructs fabricated by a magnetic force-based tissue engineering technique. , 2011, Tissue engineering. Part A.

[49]  P. Clark,et al.  Alignment of myoblasts on ultrafine gratings inhibits fusion in vitro. , 2002, The international journal of biochemistry & cell biology.

[50]  Z. Andrews,et al.  Analysis of mRNAs that are enriched in the post-synaptic domain of the neuromuscular junction , 2005, Molecular and Cellular Neuroscience.

[51]  N. Bursac,et al.  Effect of Electromechanical Stimulation on the Maturation of Myotubes on Aligned Electrospun Fibers , 2008, Cellular and molecular bioengineering.

[52]  Rashid Bashir,et al.  Patterning the differentiation of C2C12 skeletal myoblasts. , 2011, Integrative biology : quantitative biosciences from nano to macro.

[53]  T. Lømo,et al.  γ-AChR/ϵ-AChR Switch at Agrin-Induced Postsynaptic-like Apparatus in Skeletal Muscle , 1997, Molecular and Cellular Neuroscience.

[54]  Ali Khademhosseini,et al.  Skeletal muscle tissue engineering: methods to form skeletal myotubes and their applications. , 2014, Tissue engineering. Part B, Reviews.

[55]  G. Hannon,et al.  Correlation of terminal cell cycle arrest of skeletal muscle with induction of p21 by MyoD , 1995, Science.

[56]  Xiufang Guo,et al.  Neuromuscular junction formation between human stem cell-derived motoneurons and human skeletal muscle in a defined system. , 2011, Biomaterials.

[57]  James J Hickman,et al.  A defined long-term in vitro tissue engineered model of neuromuscular junctions. , 2010, Biomaterials.

[58]  Frank P T Baaijens,et al.  Effects of a combined mechanical stimulation protocol: Value for skeletal muscle tissue engineering. , 2010, Journal of biomechanics.

[59]  S. Pirkmajer,et al.  Synaptogenetic mechanisms controlling postsynaptic differentiation of the neuromuscular junction are nerve-dependent in human and nerve-independent in mouse C2C12 muscle cultures. , 2008, Chemico-biological interactions.

[60]  A S G Curtis,et al.  Investigating the limits of filopodial sensing: a brief report using SEM to image the interaction between 10 nm high nano‐topography and fibroblast filopodia , 2004, Cell biology international.

[61]  R. Dennis,et al.  Functional evaluation of nerve-skeletal muscle constructs engineered in vitro , 2007, In Vitro Cellular & Developmental Biology - Animal.

[62]  A. Lassar,et al.  Regulatory mechanisms that coordinate skeletal muscle differentiation and cell cycle withdrawal. , 1994, Current opinion in cell biology.

[63]  A E Schaffner,et al.  Acetylcholine receptor aggregation at nerve-muscle contacts in mammalian cultures: induction by ventral spinal cord neurons is specific to axons , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[64]  Matsuhiko Nishizawa,et al.  Hydrogel-supported skeletal muscle cell-based bioassay system , 2011, 2011 International Symposium on Micro-NanoMechatronics and Human Science.

[65]  Vahid Hosseini,et al.  Skeletal Muscle Tissue Engineering: Methods to Form Skeletal Myotubes and Their Applications , 2014 .

[66]  M. Das,et al.  Skeletal muscle tissue engineering: a maturation model promoting long-term survival of myotubes, structural development of the excitation-contraction coupling apparatus and neonatal myosin heavy chain expression. , 2009, Biomaterials.

[67]  Robert G. Dennis,et al.  Excitability and isometric contractile properties of mammalian skeletal muscle constructs engineered in vitro , 2000, In Vitro Cellular & Developmental Biology - Animal.

[68]  M. Midrio The denervated muscle: facts and hypotheses. A historical review , 2006, European Journal of Applied Physiology.

[69]  R G Dennis,et al.  Excitability and contractility of skeletal muscle engineered from primary cultures and cell lines. , 2001, American journal of physiology. Cell physiology.

[70]  Ali Khademhosseini,et al.  Engineered contractile skeletal muscle tissue on a microgrooved methacrylated gelatin substrate. , 2012, Tissue engineering. Part A.

[71]  J. Massoulie,et al.  Cholinesterases and the basal lamina at vertebrate neuromuscular junctions. , 2009, Current opinion in pharmacology.

[72]  Nina L. Siow,et al.  Muscle Induces Neuronal Expression of Acetylcholinesterase in Neuron-Muscle Co-culture , 2003, Journal of Biological Chemistry.

[73]  Nenad Bursac,et al.  The role of extracellular matrix composition in structure and function of bioengineered skeletal muscle. , 2011, Biomaterials.

[74]  C. Wilkinson,et al.  Topographical control of cell behaviour: II. Multiple grooved substrata. , 1990, Development.

[75]  Ali Khademhosseini,et al.  Gelatin methacrylate as a promising hydrogel for 3D microscale organization and proliferation of dielectrophoretically patterned cells. , 2012, Lab on a chip.

[76]  Tadashi Sasagawa,et al.  Design of prevascularized three-dimensional cell-dense tissues using a cell sheet stacking manipulation technology. , 2010, Biomaterials.

[77]  H. S. Neto,et al.  Ciliary neurotrophic factor stimulates in vivo myotube formation in mice , 1997, Neuroscience Letters.

[78]  Stanley Salmons,et al.  Functional electrical stimulation of denervated muscles: basic issues. , 2005, Artificial organs.

[79]  R. Pareta,et al.  Protocol and cell responses in three-dimensional conductive collagen gel scaffolds with conductive polymer nanofibres for tissue regeneration , 2014, Interface Focus.

[80]  L. Greene,et al.  Establishment of a noradrenergic clonal line of rat adrenal pheochromocytoma cells which respond to nerve growth factor. , 1976, Proceedings of the National Academy of Sciences of the United States of America.

[81]  V. Dhawan,et al.  Neurotization improves contractile forces of tissue-engineered skeletal muscle. , 2007, Tissue engineering.