The effect of different collagen types used as substrata on myogenesis in tissue culture

Encapsulation matrices for neurotrophic factor-secreting myoblast cells

Encapsulated-cell therapy is an emerging technology that entails implantation of cell-containing devices that secrete therapeutic factors. One potential application of this technology is the delivery of neurotrophic factors to treat neurodegenerative disease. These devices typically use an internal matrix to serve as a cell scaffold. This study compares collagen-coated polyethylene terephthalate (PET) yarn scaffold versus collagen as a matrix for engineered C2C12 myoblasts. C2C12 cells transfected to secrete ciliary neurotrophic factor (CNTF) were immobilized in matrices and encapsulated into hollow fiber membrane devices. Encapsulated cells were monitored in vitro for viability, morphology, and factor secretion. Two independent methods (histology assessment and metabolic assay) were used to estimate viable cell density; a high correlation between the methods was found. After 4 weeks, encapsulated devices with PET scaffold had an almost nine-fold greater number of viable cells compared to collagen. PET matrix devices contained a thick annulus of compact, highly oriented cells. Collagen matrix devices contained sparse viable cells in a thin rim. Secretion assays showed cells in PET matrix released approximately four-fold the amount of CNTF versus cells in collagen (averaging 542 and 129 ng/day per device for PET and collagen matrix, respectively). The choice of encapsulation matrix was found to have a profound effect on cell morphology, level of secreted factor, and viability of encapsulated C2C12 cells.

Muscle cell peeling from micropatterned collagen: direct probing of focal and molecular properties of matrix adhesion

To quantitatively elucidate attributes of myocyte-matrix adhesion, muscle cells were controllably peeled from narrow strips of collagen-coated glass. Initial growth of primary quail myoblasts on collagen strips was followed by cell alignment, elongation and end-on fusion between neighbors. This geometric influence on differentiation minimized lateral cell contact and cell branching, enabling detailed study of myocyte-matrix adhesion. A micropipette was used to pull back one end of a quasi-cylindrical cell while observing in detail the non-equilibrium detachment process. Peeling velocities fluctuated as focal roughness, microm in scale, was encountered along the detachment front. Nonetheless, mean peeling velocity (microm/second) generally increased with detachment force (nN), consistent with forced disruption of adhesion bonds. Immunofluorescence of beta1-integrins correlated with the focal roughness and appeared to be clustered in axially extended focal contacts. In addition, the peeling forces and rates were found to be moderately well described by a dynamical peeling model for receptor-based adhesion (Dembo, M., Torney, D. C., Saxman, K. and Hammer, D. (1988). Proc. R. Soc. Lond. B 234, 55–83). Estimates were thereby obtained for the spontaneous, molecular off-rate (kooff, (less than or equal to)10/seconds) and the receptor complex stiffness (kappa, approx. 10(−5)-10(−6) N/m) of adherent myocytes. Interestingly, the local stiffness is within the range of flexible proteins of the spectrin superfamily. The overall approach lends itself to elucidating the developing function of other structural and adhesive components of cells, particularly skeletal muscle cells with specialized components, such as the spectrin-homolog dystrophin and its membrane-linked receptor dystroglycan.

Preferential adhesion to and survival on patterned laminin organizes myogenesis in vitro

We have examined a potential role for differential adhesiveness in muscle development using an in vitro model 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 microm). 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.

Myelin proteins and collagen in the spinal roots and sciatic nerves of muscular dystrophic mice

Proteins of lumbosacral spinal roots and sciatic nerves of adult dystrophic mice (Bar Harbor 129REJ dydy) were analyzed by SDS gel electrophoresis to determine if identifiable proteins were affected. All peripheral nerve myelin proteins (P0 glycoprotein, P1 and Pr basic proteins, X protein and a high-molecular-weight protein) were decreased in the roots but not in the sciatic nerves. Central nervous system myelin proteins were not increased in either roots or sciatic nerves. Although dystrophic spinal roots and sciatic nerves contained less collagen, Type I, III and V collagens were present.

In vitro differentiation in the absence of nerve of avian myoblasts derived from slow and fast muscle rudiments

Slow anterior latissimus dorsi (ALD) and fast posterior latissimus dorsi (PLD) muscles of 9-day-old quail embryos were cultured in vitro without neurons for 1 to 12 weeks. Several differences could be observed between ALD- and PLD-derived cells. PLD cultures proliferated less rapidly than ALD cultures. ALD-derived muscle fibres exhibited wide Z lines, numerous mitochondria, and a poorly developed sarcotubular system, while PLD-derived muscle fibres exhibited narrow Z lines, few mitochondria, and an abundant sarcotubular system. Staining for myofibrillar ATPase revealed that all well-differentiated ALD-derived muscle fibres were of the beta' type, while PLD-derived fibres were of beta and beta R types. These results show that myoblasts from slow and fast muscle rudiments can express in vitro some of the characteristic features of slow and fast muscle fibres, independently of motor innervation.

Guidance of myogenic cell migration by oriented deposits of fibronectin

Fibronectin mediates myoblast-substratum attachment; one region of the molecule binds directly to the cell surface, while others bind to collagen, glycosaminoglycans, and other fibronectin molecules. There is evidence to suggest that fibronectin-containing extracellular matrices guide cell migration in vivo. We describe a method for producing regular deposits of fibronectin in vitro that can serve as a model system for studying cell-substrate interactions, cell orientation, and contact guidance. The novel culture substrate is prepared by allowing an aqueous solution of fibronectin and urea to dry in a culture dish and then washing away the urea crystals. Myogenic cells in vitro adhere to, align with, and migrate along, parallel streaks of fibronectin. This leads to the formation of myotubes that are long and thin, with little branching. Myogenic clones are highly elongated in the direction of the deposits, in contrast with the roughly circular clones seen in conventional cultures. Fibroblasts and limb bud mesenchymal cells align with fibronectin deposits, assuming a bipolar shape.