Alignment of skeletal muscle myoblasts and myotubes using linear micropatterned surfaces ground with abrasives

Alignment of cells plays a significant key role in skeletal muscle tissue engineering because skeletal muscle tissue in vivo has a highly organized structure consisting of long parallel multinucleated myotubes formed through differentiation and fusion of myoblasts. In the present study, we developed an easy, simple, and low‐cost method for aligning skeletal muscle cells by using surfaces with linear microscale features fabricated by grinding. Iron blocks were ground in one direction with three kinds of abrasives (9 µm diamond suspension, #400 sandpaper, and #150 sandpaper) and then used as molds to make micropatterned polydimethylsiloxane (PDMS) substrates (type I, type II, and type III). Observation of the surface topography revealed that the PDMS substrates exhibited different degree of mean roughness (Ra), 0.03 µm for type I, 0.16 µm for type II, and 0.56 µm for type III, respectively. Murine skeletal muscle cell line C2C12 myoblasts were cultured and differentiated on the patterned PDMS substrates, and it was examined whether the alignment of C2C12 myoblasts and myotubes was possible. Although the cell growth and differentiation on the three types of patterned substrates were similar to those on the flat PDMS substrate as a control, the alignment of both C2C12 myoblasts and myotubes was obviously observed on types II and III, but not on type I or the control substrate. These results indicate that surfaces ground with abrasives will be useful for fabricating aligned skeletal muscle tissues. Biotechnol. Bioeng. 2009;103: 631–638. © 2009 Wiley Periodicals, Inc.     

A novel functional assessment of the differentiation of micropatterned muscle cells

Duchenne muscular dystrophy (DMD) is a lethal disease characterized by rapid, progressive atrophy of muscle tissues. Timely screening of therapeutic interventions is necessary for the development of effective treatment approaches for DMD. We have developed an in vitro model using a combination of micropatterning of C2C12 skeletal muscle cells and cell traction force microscopy (CTFM). In this model, C2C12 cells were micropatterned on a highly elongated adhesive island such that the cells assumed a shape typical of a myotube. During differentiation, these cells gradually fused together and began expressing dystrophin, a structural protein of myotubes, meanwhile, their contractile forces, represented by cell traction forces, continually increased until the myotubes reached maturation. In addition, the high-degree alignment of cells favored myotube differentiation and dystrophin expression. Since the fundamental structural unit of muscle tissue is myofiber, which is responsible for muscle contraction, such a technology that can directly quantify the contractile forces of the myotube, a precursor of myofiber, may constitute a fast and efficient screening approach for DMD therapies.     

The roles of RGD and grooved topography in the adhesion, morphology, and differentiation of C2C12 skeletal myoblasts

Both chemical and topographic cues are crucial for the development of skeletal muscle. In this study, the relative roles of both signals in regard to cell adhesion, morphology, and differentiation of C2C12 skeletal myoblasts were investigated. Grooved polystyrene substrates containing grooves with approximately 900 nm in width with 600 nm ridge spans and 665 nm in depth were conjugated with the cell adhesion peptide arginine-glycine-aspartic acid (RGD). RGD conjugation significantly enhanced the adhesion, growth and differentiation of C2C12 cells. On the other hand, anisotropic topography primarily directed the direction and alignment of myoblasts and myotubes. The results in this study provide information regarding the relative roles of chemical and topographic cues in musculoskeletal myogenesis, and are of interest to applications in muscle tissue engineering.     

Micropatterned substrates with physiological stiffness promote cell maturation and Pompe disease phenotype in human induced pluripotent stem cell-derived skeletal myocytes

Recent advances in bioengineering have enabled cell culture systems that more closely mimic the native cellular environment. Here, we demonstrated that human induced pluripotent stem cell (iPSC)-derived myogenic progenitors formed highly-aligned myotubes and contracted when seeded on two-dimensional micropatterned platforms. The differentiated cells showed clear nuclear alignment and formed elongated myotubes dependent on the width of the micropatterned lanes. Topographical cues from micropatterning and physiological substrate stiffness improved the formation of well-aligned and multinucleated myotubes similar to myofibers. These aligned myotubes exhibited spontaneous contractions specifically along the long axis of the pattern. Notably, the micropatterned platforms developed bundle-like myotubes using patient-derived iPSCs with a background of Pompe disease (glycogen storage disease type II) and even enhanced the disease phenotype as shown through the specific pathology of abnormal lysosome accumulations. A highly-aligned formation of matured myotubes holds great potential in further understanding the process of human muscle development, as well as advancing in vitro pharmacological studies for skeletal muscle diseases.     

Simple micropatterning method for enhancing fusion efficiency and responsiveness to electrical stimulation of C2C12 myotubes

Cultured myotubes induced in vitro from myoblast cell lines have been widely used to investigate muscle functional properties and disease‐related biological phenotypes. Until now, several cell patterning techniques have been applied to regulate in vitro myotube structures. However, these previous studies required specific geometry patterns or soft materials for inducing efficient myotube formation. Thus, more simple and easy handling method will be promising. In this study, we aimed to provide a method to form C2C12 myotubes with regulated sizes and orientations in simple line patterns. We used a poly(dimethylsiloxane) (PDMS) stamp and a 2‐methacryloyloxyethyl phosphorylcholine (MPC) polymer solution to fabricate line patterns for myotube formation onto a culture dish. We confirmed that C2C12 myotubes of well‐defined size and orientation were reproducibly formed. In particular, myotubes formed in the micropatterned lines showed the increased fusion efficiency. Then, functional dynamics in the micropatterned myotubes were detected and analyzed using a calcium imaging method. We confirmed micropatterning in line patterns enhanced the responsiveness of myotubes to external electrical stimulations. These results indicate that micropatterning myoblasts with the MPC polymer is a simple and effective method to form functional myotube networks. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 31:220–225, 2015     

In vitro cell response to a polymer surface micropatterned by laser interference lithography

This presentation will introduce laser interference lithography to prepare a periodic line and point micropatterns for study of cell-surface interactions. This process provides a straightforward micropatterning technique based on selective laser ablation of polymers utilizing the periodic energy distribution of two or more beam interference patterns. The micropatterns were characterized by atomic force microscopy, while the surface chemical modification was analyzed using X-ray photoelectron spectroscopy. Human pulmonary fibroblasts cultured on the surface of polycarbonate bearing line micropatterns were elongated, spindlelike, and oriented themselves along the line patterns with all different groove widths. In contrast, cells cultured on point patterns were also bipolar but showed no orientation. Further investigations demonstrated that human pulmonary fibroblast cells cultured on line and point micropatterns showed inflammatory response.     

High-efficacy subcellular micropatterning of proteins using fibrinogen anchors

Protein micropatterning allows proteins to be precisely deposited onto a substrate of choice and is now routinely used in cell biology and in vitro reconstitution. However, drawbacks of current technology are that micropatterning efficiency can be variable between proteins and that proteins may lose activity on the micropatterns. Here, we describe a general method to enable micropatterning of virtually any protein at high specificity and homogeneity while maintaining its activity. Our method is based on an anchor that micropatterns well, fibrinogen, which we functionalized to bind to common purification tags. This enhances micropatterning on various substrates, facilitates multiplexed micropatterning, and dramatically improves the on-pattern activity of fragile proteins like molecular motors. Furthermore, it enhances the micropatterning of hard-to-micropattern cells. Last, this method enables subcellular micropatterning, whereby complex micropatterns simultaneously control cell shape and the distribution of transmembrane receptors within that cell. Altogether, these results open new avenues for cell biology.     

Myoblast structure affects subsequent skeletal myotube morphology and sarcomere assembly

Skeletal myogenesis is a precise procedure marked by specific changes in muscle cell morphology and cytoarchitecture. Cessation of proliferation by skeletal muscle precursor cells (myoblasts) coincides with the induction of fusion to form multinucleated myotubes and the initiation of differentiation, the process through which sarcomeres are formed. Concurrently, there is a distinct upregulation in expression of muscle-specific isoforms and an extreme downregulation of non-muscle-specific cytoskeletal isoforms. The sarcomere is the contractile unit of the cell and is comprised of a number of different proteins aggregated and aligned in very ordered arrays along the myotube. It is this rigorously controlled alignment that gives striated muscle its characteristic "striped" appearance. Previous studies, conducted predominantly in cardiac muscle, propose models for the development of the sarcomere that attribute little of the differentiative process to the myoblast morphology and cytoskeletal arrangement. In this study, perturbation of myoblast morphology and cytoskeletal arrangement by transfection with nonmuscle actin genes in the mouse skeletal muscle cell line C2 resulted in myotubes of both varied morphology and sarcomeric structure. The results presented herein not only provide novel insights into the formation of the sarcomere in skeletal muscle, but also suggest a role for myoblast morphology and cytoskeletal structure in the subsequent differentiation of the myotube.     

Preferential Adhesion to and Survival on Patterned Laminin Organizes Myogenesisin Vitro

We have examined a potential role for differential adhesiveness in muscle development using anin vitromodel which employed the culture of myoblasts and myotubes, (conditionally immortal myogenic cells,H2k^b-tsA58), on micropatterned surfaces. These surfaces are made up of multiple alternating tracks of hydrophobic organosilane-treated glass and untreated glass (track width ranging from 5 to 100 μm). We found that myoblasts were aligned on patterns in the presence of serum, by adhering to the tracks of untreated glass, which had preferentially adsorbed serum attachment factors. However, as serum attachment factors are not sufficient for maintenance of adhesion of mature myotubes, we determined whether precoating patterns with laminin, which maintains adhesion, could still provide a differential adhesive cue. Laminin preferentially adsorbs to the hydrophobic regions resulting in alternating tracks that have adsorbed laminin or serum attachment factors. Myoblasts were less well aligned on these patterns as they could adhere both to the untreated glass and to laminin on the previously hydrophobic tracks, but did show a preference for laminin. However, cell alignment increased upon differentiation into myotubes and continued to increase as the myotubes matured. We found that the alignment of myoblasts and myotubes on patterns increased as track width increased. In addition, adhesion to laminin was required for long term survival of the myotubes. Myotubes that had formed on nonlaminin surfaces began to detach after 2 days of differentiation. Although we found that myoblasts preferentially clustered on laminin tracks, this arrangement did not influence the diameter of the myotubes formed, upon differentiation. Instead, the number of myotubes per track increased with track width, while the myotube diameter remained constant. This uniformity of myotube diameter suggests that a mechanism exists which restricts the ability of myoblasts to undergo lateral fusion. Overall, these findings suggest that differential adhesiveness could be an important mechanism for formation and survival of myotubes, and by using these patterns we have demonstrated a mechanism controlling the formation of linear myotubes by restricting the geometry of cell–cell adhesion.     

Ceramide 1-phosphate stimulates proliferation of C2C12 myoblasts

Recent studies have established specific cellular functions for different bioactive sphingolipids in skeletal muscle cells. Ceramide 1-phosphate (C1P) is an important bioactive sphingolipid that has been involved in cell growth and survival. However its possible role in the regulation of muscle cell homeostasis has not been so far investigated. In this study, we show that C1P stimulates myoblast proliferation, as determined by measuring the incorporation of tritiated thymidine into DNA, and progression of the myoblasts through the cell cycle. C1P induced phosphorylation of glycogen synthase kinase-3β and the product of retinoblastoma gene, and enhanced cyclin D1 protein levels. The mitogenic action of C1P also involved activation of phosphatidylinositol 3-kinase/Akt, ERK1/2 and the mammalian target of rapamycin. These effects of C1P were independent of interaction with a putative G(i)-coupled C1P receptor as pertussis toxin, which maintains G(i) protein in the inactive form, did not affect C1P-stimulated myoblast proliferation. By contrast, C1P was unable to inhibit serum starvation- or staurosporine-induced apoptosis in the myoblasts, and did not affect myogenic differentiation. Collectively, these results add up to the current knowledge on cell types targeted by C1P, which so far has been mainly confined to fibroblasts and macrophages, and extend on the mechanisms by which C1P exerts its mitogenic effects. Moreover, the biological activities of C1P described in this report establish that this phosphosphingolipid may be a relevant cue in the regulation of skeletal muscle regeneration, and that C1P-metabolizing enzymes might be important targets for developing cellular therapies for treatment of skeletal muscle degenerative diseases, or tissue injury.     

Glucosamine induces lipid accumulation and adipogenic change in C2C12 myoblasts

Hyperglycemia-induced activation of hexosamine biosynthesis pathway (HBP) has been implicated in the development of insulin resistance in skeletal muscles. In the present study, the content of uridine-5'-diphospho-N-acetylglucosamine, the end product of the HBP, was elevated in skeletal muscle of obese diabetic KKA(y) mice, compared with control mice. To elucidate the effect of elevated HBP in the skeletal muscle, we treated C2C12 myoblasts with glucosamine, an intermediate metabolite of the HBP. Glucosamine induced lipid accumulation and significantly increased the mRNA expression levels of peroxisome proliferator-activated receptor gamma, adiponectin, and aP2 in C2C12 myoblasts. Similar mRNA changes were observed in skeletal muscles of Sprague-Dawley rats treated with glucosamine infusion. Our results provide a possible explanation of hyperglycemia-induced insulin resistance in skeletal muscle.     

Geometrical microfeature cues for directing tubulogenesis of endothelial cells

Angiogenesis, the formation of new blood vessels by sprouting from pre-existing ones, is critical for the establishment and maintenance of complex tissues. Angiogenesis is usually triggered by soluble growth factors such as VEGF. However, geometrical cues also play an important role in this process. Here we report the induction of angiogenesis solely by SVVYGLR peptide micropatterning on polymer surfaces. SVVYGLR peptide stripes were micropatterned onto polymer surfaces by photolithography to study their effects on endothelial cell (EC) behavior. Our results showed that the EC behaviors (cell spreading, orientation and migration) were significantly more guided and regulated on narrower SVVYGLR micropatterns (10 and 50 μm) than on larger stripes (100 μm). Also, EC morphogenesis into tube formation was switched on onto the smaller patterns. We illustrated that the central lumen of tubular structures can be formed by only one-to-four cells due to geometrical constraints on the micropatterns which mediated cell-substrate adhesion and generated a correct maturation of adherens junctions. In addition, sprouting of ECs and vascular networks were also induced by geometrical cues on surfaces micropatterned with SVVYGLR peptides. These micropatterned surfaces provide opportunities for mimicking angiogenesis by peptide modification instead of exogenous growth factors. The organization of ECs into tubular structures and the induction of sprouting angiogenesis are important towards the fabrication of vascularized tissues, and this work has great potential applications in tissue engineering and tissue regeneration.     

Micropatterned thermoresponsive polymer brush surfaces for fabricating cell sheets with well-controlled orientational structures

Newly developed fabrication technique of thermoresponsive surface using RAFT-mediated block copolymerization and photolithography achieved stripe-like micropatterning of poly(N-isopropylacrylamide) (PIPAAm) brush domains and poly(N-isopropylacrylamide)-b-poly(N-acryloylmorpholine) domains. Normal human dermal fibroblasts were aligned on the physicochemically patterned surfaces simply by one-pot cell seeding. Fluorescence images showed the well-controlled orientation of actin fibers and fibronectin in the confluent cell layers with associated extracellular matrix (ECM) on the surfaces. Furthermore, the aligned cells were harvested as a tissue-like cellular monolayer, called "cell sheet" only by reducing temperature below PIPAAm's lower critical solution temperature (LCST) to 20 °C. The cell sheet harvested from the micropatterned surface possessed a different shrinking rate between vertical and parallel sides of the cell alignment (approximately 3:1 of aspect ratio). This indicates that the cell sheet maintains the alignment of cells and related ECM proteins, promising to show the mechanical and biological aspects of cell sheets harvested from the functionalized thermoresponsive surfaces.     

Evidence for the involvement of cathepsin B in skeletal myoblast differentiation

Our previous studies suggest that the cysteine protease cathepsin B (catB) is involved in skeletal myoblast differentiation (myogenesis). To test this hypothesis, we examined the effect of trapping one of the two catB alleles on the ability of C2C12 cells to differentiate. During differentiation, catB gene-trapped C2C12 mouse myoblasts (RT-27) demonstrated a similar pattern of intracellular catB activity and protein expression compared to that observed in control C2C12 myoblasts and myoblasts trapped in a gene other than catB. However, compared to control myoblast cell lines, levels of catB activity and protein at each stage of RT-27 differentiation were reduced. The reductions in levels of catB were associated with reductions in several myogenic phenotypes including reduced levels of creatine phosphokinase activity and myosin heavy chain protein, two late biochemical markers of myogenesis, and reduced myotube size and extent of myotube formation over time. Comparable reductions were not observed for myogenin protein, an early biochemical marker of myogenesis, or in myokinase activity and catB related cathepsin L-type activity, two non-specific proteins. Finally, both control and catB gene-trapped myoblasts secreted active catB at pH 7.0. However levels of active pericellular/secreted catB were 50% lower in catB gene-trapped myoblasts. Collectively, these results support a functional link between catB expression and skeletal myogenesis and suggest a role for active pericellular/secreted catB in myoblast fusion.     

miR-143-3p促进C2C12成肌细胞分化

MicroRNAs (miRNAs) 是一类小非编码RNA,近年研究发现其在骨骼肌发育调控中发挥重要作用.为探明miR-143-3p在C2C12成肌细胞分化中的调控作用,采用 real-time PCR 检测了miR-143-3p在小鼠各组织及C2C12成肌细胞分化过程中的表达;使用miR-143-3p 的模拟物和特异性抑制剂分别处理细胞,采用 real-time PCR 和 Western印迹分别检测成肌因子 MyoG和成肌标志基因 MyHC mRNA和蛋白水平的变化;用免疫荧光染色的方法观察肌管的形成.结果显示,miR-143-3p在小鼠各组织中均有表达,并且随着细胞分化表达量逐渐增加;C2C12成肌细胞过表达 miR-143-3p,与对照组相比,成肌调控因子MyoG和成肌标志基因MyHC 的mRNA和蛋白表达均显著升高,肌管数量明显增多;抑制剂处理结果显示,细胞分化被显著抑制.检测miR-143-3p对MyHC各亚型表达的影响发现,miR-143-3p表达的变化并不直接影响MyHC各亚型的表达.以上结果说明, miR-143-3p在骨骼肌和成肌细胞中均有表达,能够促进C2C12成肌细胞分化,但并不直接调控MyHCs的表达.     

Fabrication of skeletal muscle constructs by topographic activation of cell alignment

Skeletal muscle fiber construction for tissue-engineered grafts requires assembly of unidirectionally aligned juxtaposed myotubes. To construct such a tissue, a polymer microchip with linearly aligned microgrooves was fabricated that could direct myoblast adaptation under stringent conditions. The closely spaced microgrooves fabricated by a modified replica molding process guided linear cellular alignment. Examination of the myoblasts by immunofluorescence microscopy demonstrated that the microgrooves with subcellular widths and appropriate height-to-width ratios were required for practically complete linear alignment of myoblasts. The topology-dependent cell alignment encouraged differentiation of myoblasts into multinucleate, myosin heavy chain positive myotubes. The monolayer of myotubes formed on the microstructured chips allowed attachment, growth and differentiation of subsequent layers of linearly arranged myoblasts, parallel to the primary monolayer of myotubes. The consequent deposition of additional myoblasts on the previous layer of myotubes resulted in three-dimensional multi-layered structures of myotubes, typical of differentiated skeletal muscle tissue. The findings demonstrate that the on-chip device holds promise for providing an efficient means for guided muscle tissue construction.     

Myotube Formation on Micro-patterned Glass: Intracellular Organization and Protein Distribution in C2C12 Skeletal Muscle Cells

Proliferation and fusion of myoblasts are needed for the generation and repair of multinucleated skeletal muscle fibers in vivo. Studies of myocyte differentiation, cell fusion, and muscle repair are limited by an appropriate in vitro muscle cell culture system. We developed a novel cell culture technique [two-dimensional muscle syncytia (2DMS) technique] that results in formation of myotubes, organized in parallel much like the arrangement in muscle tissue. This technique is based on UV lithography–produced micro-patterned glass on which conventionally cultured C2C12 myoblasts proliferate, align, and fuse to neatly arranged contractile myotubes in parallel arrays. Combining this technique with fluorescent microscopy, we observed alignment of actin filament bundles and a perinuclear distribution of glucose transporter 4 after myotube formation. Newly formed myotubes contained adjacently located MyoD-positive and MyoD-negative nuclei, suggesting fusion of MyoD-positive and MyoD-negative cells. In comparison, the closely related myogenic factor Myf5 did not exhibit this pattern of distribution. Furthermore, cytoplasmic patches of MyoD colocalized with bundles of filamentous actin near myotube nuclei. At later stages of differentiation, all nuclei in the myotubes were MyoD negative. The 2DMS system is thus a useful tool for studies on muscle alignment, differentiation, fusion, and subcellular protein localization. (J Histochem Cytochem 56:881–892, 2008)