Ronald E. Allen

Skeletal muscle satellite cell proliferation in response to members of the fibroblast growth factor family and hepatocyte growth factor

Fibroblast growth factors (FGF) have the ability to regulate satellite cell proliferation in culture and in muscle tissue, but the specific FGF receptors (FGFR) expressed by adult rat muscle satellite cells and the action of members of the FGF family have not been assessed. Therefore, the expression of FGF receptors 1–4 was examined in proliferating satellite cells in culture, and the effects of eight members of the fibroblast growth factor family (FGFs1, 2, 4, 5, 6, 7, 8, and 9) on adult rat muscle satellite cells were evaluated. In addition, the interactions of FGFs with hepatocyte growth factor (HGF) were described. Of the eight FGFs evaluated, 1, 2, 4, 6, and 9 significantly (P < 0.05) stimulated proliferation above control. FGFs5, 7, and 8 displayed no mitogenic activity. Furthermore, combinations of HGF with FGFs2, 4, 6, or 9 stimulated satellite cell proliferation above that of optimal concentrations of HGF alone. Expression of four FGFR genes was detected in satellite cell cultures by reverse‐transcription‐polymerase chain reaction (RT‐PCR). FGFR1 and FGFR4 were the most prominent forms expressed, and FGFR2 was only expressed at low levels. FGFR3 was difficult to detect. FGFR1 and FGFR2 were also expressed in muscle‐derived fibroblasts, but FGFR4 and FGFR3 were not. In proliferating cultures of satellite cells, HGF, insulin‐like growth factor I (IGF‐I) and FGF1 stimulated significantly (P < 0.05) higher levels of FGFR1 message content, relative to control conditions, and platelet‐derived growth factor‐BB (PDGF‐BB) and insulin‐like growth factor (IGF‐II) significantly (P < 0.05) depressed FGFR1 expression. During the activation period of satellite cell growth in culture (0–48 h), FGFR1 message content significantly (P < 0.05) increased from less than 1,000 copies per cell to approximately 5,000 copies per cell between 18 and 48 h, and HGF treatment significantly (P < 0.05) accelerated the accumulation of FGFR1 message during this period. J. Cell. Physiol. 181:499–506, 1999.

SKELETAL MUSCLE SATELLITE CELL CULTURES

Publisher Summary Skeletal muscle satellite cell culture techniques have provided a means for coupling muscle structural and physiological observations to cellular and molecular explanations. Intrinsic properties of these myogenic cells have been studied in vitro , and it has become apparent that the satellite cell has properties that are distinctly different from those of embryonic or fetal myogenic cells. This chapter describes two types of satellite cell culture procedures—(1) monolayer mass cultures of dissociated satellite cells and (2) single muscle fiber cultures with their associated satellite cells—and discusses their application. In both cases, cells and fibers are isolated directly from experimental subjects. The general cellular processes that have been studied in satellite cell culture systems include activation from the quiescent state, migration, proliferation, and differentiation or return to quiescence. There are advantages and disadvantages to each of the culture systems and one single culture system may not be adequate for addressing all experimental questions.

HGF is an autocrine growth factor for skeletal muscle satellite cells in vitro

Muscle satellite cell activation following injury is essential for muscle repair, and hepatocyte growth factor/scatter factor (HGF) was the first growth factor shown to be able to stimulate activation and early division of adult satellite cells in culture and in muscle tissue. In addition, HGF was shown to be present in uninjured and injured skeletal muscle. Experiments in this report demonstrate that cultured satellite cells also synthesize and secrete HGF. Reverse transcription‐polymerase chain reaction (RT‐PCR) was used to demonstrate the presence of HGF mRNA in cultured adult satellite cells as early as 12 h from the time of plating. Message content was detectable at early times in culture and appeared to increase between 36 and 48 h. HGF protein expression was demonstrated during this time period by immunofluorescence localization; HGF was localized to mononucleated cells and multinucleated myotubes. HGF message was not detectable in muscle‐derived fibroblast clones, and fibroblast‐like cells in satellite cell cultures were negative for HGF by immunofluorescence analysis. Furthermore, Western blot analysis revealed the presence of HGF in satellite cell culture conditioned medium, associated with the cell surface and inside cells. Finally, the addition of neutralizing HGF antibodies during the proliferation phase in culture (42–90 h) significantly reduced cell proliferation. These experiments indicate that HGF is expressed by cultured satellite cells and that endogenous HGF from satellite cells can act in an autocrine fashion. Because HGF plays a central role in satellite cell activation, it is likely that direct administration of HGF into damaged muscle may represent a potentially useful approach for stimulating muscle repair. This approach may also be useful in enhancing the efficiency of myoblast transplantation in vivo.

Regulation of satellite cells during skeletal muscle growth and development

Abstract Satellite cells are myogenic cells attributed with the role of postnatal growth and regeneration in skeletal muscle. Following proliferation and subsequent differentiation, these cells will fuse with one another or with the adjacent muscle fiber, thereby increasing myonuclei numbers for fiber growth and repair. The potential factors which could regulate this process are many, including exercise, trauma, passive stretch, innervation, and soluble growth factors. Three classes of growth factors in particular (fibroblast growth factor, insulin-like growth factor, and transforming growth factor-β) have been studied extensively with respect to their effects on satellite cell proliferation and differentiation in culture. Fibroblast growth factor has been shown to stimulate proliferation but depress differentiation. Insulin-like growth factor stimulates both proliferation and differentiation, although the latter to a much greater degree. Transforming growth factor-β slightly depresses proliferation but inhibits differentiation. When administered in combination, these factors can induce satellite cell activities in culture which mimic those typical of satellite cells found in vivo in growing, regenerating, or healthy mature muscle. Alterations in the concentrations of these growth factors in the muscle environment as well as alterations in the cells sensitivity or responsiveness to these factors represent potential mechanisms for regulating satellite cell activity in situ.

Regulation of skeletal muscle satellite cell proliferation by bovine pituitary fibroblast growth factor

Satellite cells in skeletal muscle have been implicated in muscle growth processes and regeneration. However, very little is known about the regulation of their proliferation and differentiation. The effect of fibroblast growth factor (FGF) on the proliferation of myogenic cells from adult rat skeletal muscle, presumably satellite cells, has been examined, and FGF has been found to be a potent mitogen for these cells. The mitogenic properties of serum were also documented and studied in conjunction with FGF. Even under conditions of maximal stimulation by serum, the addition of FGF caused a substantial increase in proliferation of satellite cells. The additive nature of the FGF and serum-stimulatory activity suggests that FGF-like molecules are not the active agents in serum and that more than one pathway may be involved in stimulating satellite cell proliferation.

Active hepatocyte growth factor is present in skeletal muscle extracellular matrix

When skeletal muscle is stretched or injured, satellite cells are activated to proliferate, and this process can be mediated by release of the active form of hepatocyte growth factor (HGF) from the extracellular matrix. The objective of these experiments was to determine whether the mechanism of release includes proteolytic activation of pro‐HGF. Extracellular HGF in uninjured adult rat extensor digitorum longus muscle was extracted by treatment with 1 M NaCl or heparinases I and III in the presence of a cocktail of serine protease inhibitors. Active HGF heterodimer was the predominant form present, but both pro‐HGF and active HGF were extracted when muscle was incubated with Triton X‐100 or crush‐injured. Incubation of exogenous pro‐HGF with uninjured or crush‐injured skeletal muscle resulted in cleavage to the active form, indicating that endogenous extracellular proteases are present and capable of rapidly converting pro‐HGF to active HGF. Finally, treatment with sodium nitroprusside, a nitric oxide (NO) donor, resulted in liberation of active HGF. These experiments indicate that the active form of HGF is present in the extracellular compartment of uninjured skeletal muscle; therefore, the mechanism of HGF release in response to stretch and NO does not require proteolytic activation of pro‐HGF. Muscle Nerve, 2004

Satellite cell-mediated angiogenesis in vitro coincides with a functional hypoxia-inducible factor pathway

Muscle regeneration involves the coordination of myogenesis and revascularization to restore proper muscle function. Myogenesis is driven by resident stem cells termed satellite cells (SC), whereas angiogenesis arises from endothelial cells and perivascular cells of preexisting vascular segments and the collateral vasculature. Communication between myogenic and angiogenic cells seems plausible, especially given the number of growth factors produced by SC. To characterize these interactions, we developed an in vitro coculture model composed of rat skeletal muscle SC and microvascular fragments (MVF). In this system, isolated epididymal MVF suspended in collagen gel are cultured over a rat SC monolayer culture. In the presence of SC, MVF exhibit greater indices of angiogenesis than MVF cultured alone. A positive dose-dependent effect of SC conditioned medium (CM) on MVF growth was observed, suggesting that SC secrete soluble-acting growth factor(s). Next, we specifically blocked VEGF action in SC CM, and this was sufficient to abolish satellite cell-induced angiogenesis. Finally, hypoxia-inducible factor-1alpha (HIF-1alpha), a transcriptional regulator of VEGF gene expression, was found to be expressed in cultured SC and in putative SC in sections of in vivo stretch-injured rat muscle. Hypoxic culture conditions increased SC HIF-1alpha activity, which was positively associated with SC VEGF gene expression and protein levels. Collectively, these initial observations suggest that a heretofore unexplored aspect of satellite cell physiology is the initiation of a proangiogenic program.

High concentrations of HGF inhibit skeletal muscle satellite cell proliferation in vitro by inducing expression of myostatin: a possible mechanism for reestablishing satellite cell quiescence in vivo

Skeletal muscle regeneration and work-induced hypertrophy rely on molecular events responsible for activation and quiescence of resident myogenic stem cells, satellite cells. Recent studies demonstrated that hepatocyte growth factor (HGF) triggers activation and entry into the cell cycle in response to mechanical perturbation, and that subsequent expression of myostatin may signal a return to cell quiescence. However, mechanisms responsible for coordinating expression of myostatin after an appropriate time lag following activation and proliferation are not clear. Here we address the possible role of HGF in quiescence through its concentration-dependent negative-feedback mechanism following satellite cell activation and proliferation. When activated/proliferating satellite cell cultures were treated for 24 h beginning 48-h postplating with 10-500 ng/ml HGF, the percentage of bromodeoxyuridine-incorporating cells decreased down to a baseline level comparable to 24-h control cultures in a HGF dose-dependent manner. The high level HGF treatment did not impair the cell viability and differentiation levels, and cells could be reactivated by lowering HGF concentrations to 2.5 ng/ml, a concentration that has been shown to optimally stimulate activation of satellite cells in culture. Coaddition of antimyostatin neutralizing antibody could prevent deactivation and abolish upregulation of cyclin-dependent kinase (Cdk) inhibitor p21. Myostatin mRNA expression was upregulated with high concentrations of HGF, as demonstrated by RT-PCR, and enhanced myostatin protein expression and secretion were revealed by Western blots of the cell lysates and conditioned media. These results indicate that HGF could induce satellite cell quiescence by stimulating myostatin expression. The HGF concentration required (over 10-50 ng/ml), however, is much higher than that for activation, which is initiated by rapid release of HGF from its extracellular association. Considering that HGF is produced by satellite cells and spleen and liver cells in response to muscle damage, local concentrations of HGF bathing satellite cells may reach a threshold sufficient to induce myostatin expression. This time lag may delay action of the quiescence signaling program in proliferating satellite cells during initial phases of muscle regeneration followed by induction of quiescence in a subset of cells during later phases.

Matrix metalloproteinases are involved in mechanical stretch-induced activation of skeletal muscle satellite cells.

When skeletal muscle is stretched or injured, myogenic satellite cells are activated to enter the cell cycle. This process depends on nitric oxide (NO) production, release of hepatocyte growth factor (HGF) from the extracellular matrix, and presentation of HGF to the c‐met receptor. Experiments reported herein provide new evidence that matrix metalloproteinases (MMPs) are involved in the NO‐dependent release of HGF in vitro. When rat satellite cells were treated with 10 ng/ml recombinant tissue inhibitor‐1 of MMPs (TIMP‐1) and subjected to treatments that induce activation in vitro, i.e., sodium nitroprusside (SNP) of an NO donor or mechanical cyclic stretch, the activation response was inhibited. In addition, conditioned medium generated by cultures treated with TIMP‐1 plus SNP or mechanical stretch failed to activate cultured satellite cells and did not contain HGF. Moreover, NOx assay demonstrated that TIMP‐1 does not impair NO synthase activity of stretched satellite cell cultures. Therefore, results from these experiments provide strong evidence that MMPs mediate HGF release from the matrix and that this step in the pathway is downstream from NO synthesis. Muscle Nerve, 2006

Matrix metalloproteinase-2 mediates stretch-induced activation of skeletal muscle satellite cells in a nitric oxide-dependent manner.

When skeletal muscle is stretched or injured, myogenic satellite cells are activated to enter the cell cycle. This process depends on nitric oxide (NO) production, release of hepatocyte growth factor (HGF) from the extracellular matrix, and presentation of HGF to the c-met receptor. Matrix metalloproteinases (MMPs), a large family of zinc-dependent endopeptidases, mediate HGF release from the matrix and this step in the pathway is downstream from NO synthesis [Yamada, M., Tatsumi, R., Kikuiri, T., Okamoto, S., Nonoshita, S., Mizunoya, W., et al. (2006). Matrix metalloproteinases are involved in mechanical stretch-induced activation of skeletal muscle satellite cells. Muscle Nerve, 34, 313-319]. Experiments reported herein provide evidence that MMP2 may be involved in the NO-dependent release of HGF in vitro. Whole lysate analyses of satellite cells demonstrated the presence of MMP2 mRNA and the protein. When rat satellite cells were treated with 30 microM sodium nitroprusside a NO donor or mechanical cyclic stretch for 2h period, inactive proMMP2 (72 kDa) was converted into 52-kDa form and this processing was abolished by adding a NO synthase inhibitor l-NAME (10 microM) to the stretch culture. The 52-kDa species was also generated by treatment of the recombinant MMP2 protein with 1 microM NOC-7 that can spontaneously release NO under physiological conditions without any cofactor, and its activating activity was demonstrated by applying the NOC-7-treated MMP2 to satellite cell culture. HGF release was detected in NOC-7-MMP2-conditioned media by western blotting; very little HGF was found in media that were generated from cultures receiving NOC-7-treated MMP2 (10 ng/ml) plus 250 ng/ml tissue inhibitor-1 of metalloproteinases. Therefore, results from these experiments provide evidence that NO-activated MMP2 may cause release of HGF from the extracellular matrix of satellite cells and contribute to satellite cell activation.