Matrigel enhances myotube development in a serum-free defined medium

Aberrant evoked calcium signaling and nAChR cluster morphology in a SOD1 D90A hiPSC-derived neuromuscular model

Familial amyotrophic lateral sclerosis (ALS) is a progressive neuromuscular disorder that is due to mutations in one of several target genes, including SOD1. So far, clinical records, rodent studies, and in vitro models have yielded arguments for either a primary motor neuron disease, or a pleiotropic pathogenesis of ALS. While mouse models lack the human origin, in vitro models using human induced pluripotent stem cells (hiPSC) have been recently developed for addressing ALS pathogenesis. In spite of improvements regarding the generation of muscle cells from hiPSC, the degree of maturation of muscle cells resulting from these protocols has remained limited. To fill these shortcomings, we here present a new protocol for an enhanced myotube differentiation from hiPSC with the option of further maturation upon coculture with hiPSC-derived motor neurons. The described model is the first to yield a combination of key myogenic maturation features that are consistent sarcomeric organization in association with complex nAChR clusters in myotubes derived from control hiPSC. In this model, myotubes derived from hiPSC carrying the SOD1 D90A mutation had reduced expression of myogenic markers, lack of sarcomeres, morphologically different nAChR clusters, and an altered nAChR-dependent Ca2+ response compared to control myotubes. Notably, trophic support provided by control hiPSC-derived motor neurons reduced nAChR cluster differences between control and SOD1 D90A myotubes. In summary, a novel hiPSC-derived neuromuscular model yields evidence for both muscle-intrinsic and nerve-dependent aspects of neuromuscular dysfunction in SOD1-based ALS.

A simple method to isolate term trophoblasts and maintain them in extended culture

INTRODUCTION

Primary trophoblast cultures obtained from term placentae are an important research tool. Term trophoblasts, while isolated as mononuclear cells, spontaneously fuse to form multinucleated syncytial clusters. Since term trophoblast cells do not replicate in vitro, contaminating cells can overgrow the culture limiting the lifespan of primary trophoblast cultures to about seven days. We aimed to develop a method that would allow the prolonged culture of term trophoblasts.

METHODS

Trophoblasts were isolated from term placentae, following vaginal or cesarean section delivery, using either trypsin/DNase or dispase/DNase to digest the tissue. Purity of the trophoblasts was confirmed using flow cytometry prior to plating and during culture using immunocytochemistry. Cell death was examined with propidium iodide and trophoblast fusion monitored using PKH67 membrane stain.

RESULTS

Digestion of term villous tissue with dispase/DNase resulted in the release of significantly more trophoblasts than digestion with trypsin/DNase (n = 8, p = 0.0051). Viability of the trophoblasts was unaffected by enzyme choice. The use of Advanced DMEM/F12 supplemented with 2% fetal bovine serum allowed culture of the trophoblasts with minimal cell death or contamination for 30 days. Despite prolonged culture over half of the trophoblasts remained mononuclear.

DISCUSSION

We report a simple, optimized method to isolate and culture trophoblasts from term placentae for prolonged periods without substantial contamination with other cell types. Consistent with previous findings, trophoblasts cultured using our method were able to syncytialise, forming multi-nucleated syncytia. This extended growth time allows long term in vitro experimentation to further understand the nature of trophoblasts.

Engineered Human Contractile Myofiber Sheets as a Platform for Studies of Skeletal Muscle Physiology

Skeletal muscle physiology and the mechanisms of muscle diseases can be effectively studied by an in-vitro tissue model produced by muscle tissue engineering. Engineered human cell-based tissues are required more than ever because of the advantages they bring as tissue models in research studies. This study reports on a production method of a human skeletal myofiber sheet that demonstrates biomimetic properties including the aligned structure of myofibers, basement membrane-like structure of the extracellular matrix, and unidirectional contractile ability. The contractile ability and drug responsibility shown in this study indicate that this engineered muscle tissue has potential as a human cell-based tissue model for clinically relevant in-vitro studies in muscle physiology and drug discovery. Moreover, this engineered tissue can be used to better understand the relationships between mechanical stress and myogenesis, including muscle growth and regeneration. In this study, periodic exercise induced by continuous electrical pulse stimulation enhanced the contractile ability of the engineered myofibers and the secretion of interleukin-6 (IL-6) and vascular endothelial growth factor (VEGF) from the exercising myofibers. Since the physiology of skeletal muscle is directly related to mechanical stress, these features point to application as a tissue model and platform for future biological studies of skeletal muscle including muscle metabolism, muscle atrophy and muscle regeneration.

In vitro extracellular matrix model to evaluate stroma cell response to transvaginal mesh

AIMS

The use of surgical mesh for female pelvic floor reconstruction has increased in recent years. However, there is paucity of information about the biological responses of host stroma cells to different meshes. This study was aimed to establish an in vitro experimental model to study the micro-environment of extracellular matrix (ECM) with embedded mesh and the stroma cell behaviors to different synthetic meshes.

METHODS

Matrigel multi-cellular co-culture system with embedded mesh was used to evaluate the interaction of stroma cells and synthetic mesh in a simulated ECM environment. Human umbilical vein endothelial cells (HUVEC) and NIH3T3 fibroblasts were inoculated in the system. The established multi-cellular Matrigel co-culture system was used to detect stroma cell recruitment and tube formation ability for different synthetic meshes.

RESULTS

HUVEC and NIH3T3 cells were recruited into the mesh interstices and organized into tube-like structures in type I mesh material from Perigee, Marlex and Prolift 24 hr after cell inoculation. On the contrary, there was little recruitment of HUVEC and NIH3T3 cells into the type III mesh of intra-vaginal sling (IVS).

CONCLUSIONS

The Matrigel multi-cellular co-culture system with embedded mesh offers a useful in vitro model to study the biological behaviors of stroma cells in response to different types of synthetic meshes. The system can help to select ideal mesh candidates before actual implantation into the human body.

Efficient transfection of mouse-derived C2C12 myoblasts using a matrigel basement membrane matrix

Myogenic cell lines have been used widely in the study of myogenic differentiation, muscle regeneration and homeostasis, but, myoblasts and myotubes are difficult to transfect using conventional techniques. We have used liposome-based transfection method to introduce a green fluorescence protein (GFP)-expressing plasmid into Matrigel basement membrane matrix-coated C2C12 mouse myoblast cells. Myoblasts adhered and proliferated more rapidly on a Matrigel; thus, a dramatic increase in transfection efficiency can be obtained compared to Matrigel-untreated cells. Transfection efficiency was determined by counting fluorescent and total cells from six random fields for each condition. This protocol results in efficient (up to 60-70%) transfection of C2C12 myoblasts, high levels of GFP expression and low rate of cell death (10%). This technique is rapid, reliable, uses a lipid-based transfection reagent, and yields high transfection rates in a previously hard-to-transfect cell type.

The influence of extracellular matrix derived from skeletal muscle tissue on the proliferation and differentiation of myogenic progenitor cells ex vivo

Skeletal muscle relies upon regeneration to maintain homeostasis and repair injury. This process involves the recruitment of the tissue's resident stem cell, the muscle progenitor cell, and a subsequent proliferative response by newly generated myoblasts, which must then align and fuse to generate new muscle fibers. During regeneration, cells rely on environmental input for direction. Extracellular matrix (ECM) represents a crucial component of a cell's microenvironment that aids in guiding muscle regeneration. We hypothesized that ECM extracted from skeletal muscle would provide muscle progenitor cells and myoblasts with an ideal substrate for growth and differentiation ex vivo. To test this hypothesis, we developed a method to extract ECM from the large thigh muscles of adult rats and present it to cells as a surface coating. Myogenic cells cultured on ECM extract experienced enhanced proliferation and differentiation relative to standard growth surfaces. As the methodology can be applied to any size muscle, these results demonstrate that bioactive ECM can be readily obtained from skeletal muscle and used to develop biomaterials that enhance muscle regeneration. Furthermore, the model system demonstrated here can be applied to the study of interactions between the ECM of a particular tissue and a cell population of interest.

C2C12 skeletal muscle cells adopt cardiac-like sodium current properties in a cardiac cell environment

Intracardiac transplantation of undifferentiated skeletal muscle cells (myoblasts) has emerged as a promising therapy for myocardial infarct repair and is already undergoing clinical trials. The fact that cells originating from skeletal muscle have different electrophysiological properties than cardiomyocytes, however, may considerably limit the success of this therapy and, in addition, cause side effects. Indeed, a major problem observed after myoblast transplantation is the occurrence of ventricular arrhythmias. The most often transient nature of these arrhythmias may suggest that, once transplanted into cardiac tissue, skeletal muscle cells adopt more cardiac-like electrophysiological properties. To test whether a cardiac cell environment can indeed modify electrophysiological parameters of skeletal muscle cells, we treated mouse C(2)C(12) myocytes with medium preconditioned by primary cardiocytes and compared their functional sodium current properties with those of control cells. We found this treatment to significantly alter the activation and inactivation properties of sodium currents from "skeletal muscle" to more "cardiac"-like ones. Sodium currents of cardiac-conditioned cells showed a reduced sensitivity to block by tetrodotoxin. These findings and reverse transcription PCR experiments suggest that an upregulation of the expression of the cardiac sodium channel isoform Na(v)1.5 versus the skeletal muscle isoform Na(v)1.4 is responsible for the observed changes in sodium current function. We conclude that cardiomyocytes alter sodium channel isoform expression of skeletal muscle cells via a paracrine mechanism. Thereby, skeletal muscle cells with more cardiac-like sodium current properties are generated.

Myotube formation is delayed but not prevented in MyoD-deficient skeletal muscle: studies in regenerating whole muscle grafts of adult mice

We compared the time course of myogenic events in vivo in regenerating whole muscle grafts in MyoD(-/-) and control BALB/c adult mice using immunohistochemistry and electron microscopy. Immunohistochemistry with antibodies to desmin and myosin revealed a striking delay by about 3 days in the formation of myotubes in MyoD(-/-) autografts compared with BALB/c mice. However, myotube formation was not prevented, and autografts in both strains appeared similar by 8 days. Electron microscopy confirmed myotube formation in 8- but not 5-day MyoD(-/-) grafts. This pattern was not influenced by cross-transplantation experiments between strains examined at 5 days. Antibodies to proliferating cell nuclear antigen demonstrated an elevated level of replication by MyoD(-/-) myoblasts in autografts, and replication was sustained for about 3 days compared with controls. These data indicate that the delay in the onset of differentiation and hence fusion is related to extended proliferation of the MyoD(-/-) myoblasts. Overall, although muscle regeneration was delayed it was not impaired in MyoD(-/-) mice in this model.

Exposure to tissue culture conditions can adversely affect myoblast behavior in vivo in whole muscle grafts: implications for myoblast transfer therapy

The effects of tissue culture conditions on the viability of myoblasts in whole muscles transplanted in vivo were investigated. Whole male (SJL/J) donor muscles were exposed to various tissue culture reagents and proteolytic enzymes, and allografted into female (SJL/J) host mice. Desmin immunohistochemistry was used to assess the numbers of myogenic cells (as an index of myoblast viability and the extent of regeneration) in tissue sections of whole-muscle grafts sampled on days 7 and 14. DNA quantitation with a Y-chromosome-specific probe was used to determine the total Y-1 sequence DNA (as an index of myoblast survival and proliferation) in whole-muscle grafts sampled on days 1, 3, and 7. In grafts exposed to serum-free medium, there was a delay in myoblast fusion at 7 days that was recovered by 14 days, but exposure to serum (10% or 20%) had a prolonged adverse effect on myotube formation at 14 days. DNA quantitation demonstrated that either serum-free culture medium or 10% serum enhanced the number of male cells within whole-muscle grafts at 7 days. Proteolytic digestion (even for 5 min) of whole muscles prior to grafting was extremely detrimental to myoblast survival and viability at 7 and 14 days. The unexpected finding of adverse effects of tissue culture conditions on the regeneration of whole-muscle grafts in vivo appears to parallel the major problem of the rapid death of isolated cultured donor myoblasts after injection in myoblast transfer therapy. The use of whole-muscle grafts provides an alternative and sensitive model to analyze the crucial effects of various tissue culture components on the subsequent survival and proliferation of myogenic cells in vivo.

Up-regulation of type XIX collagen in rhabdomyosarcoma cells accompanies myogenic differentiation

Rhabdomyosarcomas are known to recapitulate some of the early events in skeletal muscle embryogenesis, and cultures derived from these tumors have been extensively used to elucidate processes associated with the differentiation of primitive mesenchymal cells. These neoplasms have also provided important systems for studying different collagen types. This aspect is particularly relevant to type XIX collagen, which was originally identified from rhabdomyosarcoma cDNA clones. Although this collagen has been localized in vivo to basement membrane zones in a wide variety of tissues, including skeletal muscle, the tumor cells appear to be a unique source of its expression in vitro. We have found that one particular cell line-derived from a peritesticular embryonal rhabdomyosarcoma-produced relatively large amounts of type XIX collagen, especially in those rare instances in which these cells appear to spontaneously differentiate. To characterize this phenomenon, tumor cells were grown under conditions known to induce differentiation in normal myoblast cultures. In response to this treatment, the typical tumor cell morphology consistently and reproducibly switched from polygonal to round/spindle-shaped with the subsequent appearance of some structures resembling myotubes. Concurrently, the cultures commenced a dramatic up-regulation of type XIX collagen and skeletal muscle myosin heavy chain and alpha-actinin in a time-dependent fashion, whereas protein and mRNA levels of other matrix proteins were either decreased or unchanged. Moreover, immunocytochemical analysis revealed that only a subpopulation of the cells was responsible for the increased synthesis of type XIX collagen, alpha-actinin, and myosin, and that the same cells which stained positive for the collagen also stained positive for the muscle proteins. Taken together, the results suggested that type XIX collagen may be involved in the initial stages of skeletal muscle cell differentiation.

Serum-free culture conditions for analysis of secretory proteinases during myogenic differentiation of mouse C2C12 myoblasts

We have been studying extracellular proteins such as proteinases and attachment factors under serum-free culture conditions. A number of studies on myogenesis using an in vitro culture system have reported that proteinases and ECM components play significant roles in muscle differentiation. However, most of the studies were performed in the presence of serum. Serum is abundant in the aforementioned proteins and its use in serum-free culture affects many cellular functions significantly. In this study, we tried to establish serum-free culture conditions for analyzing extracellular proteins involved in mouse myogenic differentiation. By evaluating media, supplements, and procedure of cell inoculation under serum-free conditions and by comparing the resultant conditions with conventional conditions on differentiated characteristics of the cells, it was revealed that serum-free Dulbecco's modified Eagle's medium/Ham's F-12 plus insulin more efficiently supported myogenesis morphologically and biochemically than conventional 2% horse serum-containing culture and that secretory proteinases obtained from our serum-free culture were different from those obtained utilizing conventional serum-free cultures in their activities and patterns. Since our serum-free medium consists of simple components, the medium is low cost and easy to prepare. Furthermore, the results suggest that our culture conditions are superior to conventional conditions biochemically and morphologically and will provide more precise and accurate information on extracellular proteins involved in myogenesis.

Satellite cells from slow rat muscle express slow myosin under appropriate culture conditions

Satellite cells were isolated at high yields from slow-twitch soleus and fast-twitch tibialis anterior (TA) muscles of adult male Wistar rats. The number of satellite cells isolated from soleus muscle exceeded that from TA muscles by a factor of three. A comparison of satellite cells grown on gelatin- or Matrigel-coated dishes revealed that Matrigel greatly enhances the maturation of the satellite-cell-derived myotubes. As judged from immunohistochemistry, myosin heavy chain electrophoresis and immunoblot analyses, only cells grown on Matrigel, but not on gelatin, expressed adult myosin isoforms. Slow myosin expression was only detected in Matrigel cultures. Soleus cultures contained, in addition to the majority of myotubes expressing fast myosin, a small fraction (maximally 10%) of myotubes coexpressing fast and slow myosins. The number of fast/slow myosin-containing myotubes was negligible in TA cultures. The expression of slow myosin increased with age. Slow myosin was nonuniformly distributed along the length of specific myotubes and accumulated around some myonuclei. These results point to the existence of myotubes with a heterogeneous population of myonuclei, probably resulting from fusion of differently preprogrammed satellite cells. We suggest that the patch-like expression of slow myosin results from local accumulation of myonuclei of slow-type satellite cells.

Regulation of NCAM by growth factors in serum-free myotube cultures

Regulation of the neural cell adhesion molecule (NCAM) was examined in primary cultures of chick skeletal muscle grown in serum-free defined medium. Relative levels of NCAM (per microgram protein) increased 20-30% in myotubes grown on Matrigel, a reconstituted basement membrane preparation, compared to those grown on collagen; total NCAM levels on Matrigel were increased 40-55% due to the additional increase in total protein. A dose dependent increase in relative NCAM levels in myotubes grown on Matrigel in defined medium was observed with the addition of adsorbed horse serum, while relative NCAM levels in myotubes grown on collagen were unaffected by altering the serum concentration. Thus, extracellular matrix molecules and soluble factors exert trophic effects on myotube NCAM expression. Similar developmental changes in the expression of the different molecular size forms of NCAM occurred in myotubes grown on collagen and Matrigel: levels of 150K and 135K Mr forms decreased during development, while 125K remained prominent in older myotubes. Relative NCAM levels were specifically enhanced 11-26% by several factors: nerve growth factor, thyroxine, insulin-like growth factor II, dibutyryl cyclic AMP, veratridine (a sodium ion channel agonist), and nisoldipine (a calcium ion channel agonist). Total protein and overall myotube development in serum-free cultures were enhanced by fetuin, insulin-like growth factor II, acidic fibroblast growth factor, calcitonin gene-related peptide, dibutyryl cyclic AMP, and veratridine. Thus, changes in extracellular matrix, intracellular calcium, and sodium ions, as well as extracellular trophic factors, such as nerve growth factor, thyroxine, and insulin-like growth factor II, may regulate muscle NCAM expression during embryonic development.