FGF5 stimulates expansion of connective tissue fibroblasts and inhibits skeletal muscle development in the limb.

FGF5 is expressed in the mesenchyme and skeletal muscle of developing and adult mouse limbs. However, the function of FGF5 during development of the limb and limb musculature is unknown. To elucidate the inherent participation of FGF5 during limb organogenesis, a retroviral delivery system (RCAS) was used to overexpress human FGF5 throughout developing hind limb of chicken embryos. Misexpression of the soluble growth factor severely inhibited the formation of mature myocytes. Limbs infected with RCAS-FGF5 contained smaller presumptive muscle masses as evidenced by a decrease in MyoD and myosin heavy chain expressing cells. In contrast, ectopic expression of FGF5 significantly stimulated proliferation and expansion of the tenascin-expressing, connective-tissue fibroblast lineage throughout the developing limb. Histological analysis demonstrated that the increase in tenascin immunostaining surrounding the femur, ileum, and pubis in the FGF5 infected limbs corresponded to the fibroblasts forming the stacked-cell perichondrium. Furthermore, pulse labeling experiments with the thymidine analog, BrdU, revealed that the increased size of the perichondrium was attributable to enhanced cell proliferation. These results support a model whereby FGF5 acts as a mitogen to stimulate the proliferation of mesenchymal fibroblasts that contribute to the formation of connective tissues such as the perichondrium, and inhibits the development of differentiated skeletal muscle. These results also contend that FGF5 is a candidate mediator of the exclusive spatial patterning of the hind limb connective tissue and skeletal muscle.

Determination of queuosine modification system deficiencies in cultured human cells.

Queuosine-deficient tRNAs are often observed in neoplastic cells. In order to determine possible sites for malfunction of the multistep queuosine modification system, comprehensive studies were performed on two human neoplastic cell lines, the HxGC(3) colon adenocarcinoma and the MCF-7 breast adenocarcinoma, which are 100 and 50-60% queuosine deficient, respectively. These results were compared with data obtained from normal human fibroblast (HFF) cultures which maintain 100% queuosine-modified tRNA populations. Queuine uptake in all three cell types was similar and each demonstrated activation by protein kinase C (PKC). However, incorporation of queuine into tRNA by tRNA:guanine ribosyltransferase (TGRase; E.C. 2.4.2.24) and PKC-catalyzed activation of this enzyme occurred only in HFF and MCF-7 cells. The HxGC(3) cell line exhibited no TGRase activity as was expected. Treatment with 5-azacytidine (5-azaC) induced TGRase activity to a level 20% of that in HFF and MCF-7 cells; however, this 5-azaC-induced TGRase activity was not regulated by PKC. Salvage of the queuine base from tRNA degradation products has been shown in mammalian cells and was measured in the HFF cells. However, salvage activity in the MCF-7 cell line was deficient. Therefore, it was shown by direct measurements that the HxGC(3) cell line is completely lacking in queuosine-modified tRNA due to loss of functional TGRase, while the MCF-7 cell line has an inefficient queuine salvage mechanism resulting in a significant deficiency of queuosine-modified tRNA. These techniques can be applied to any cultured cell types to determine specific lesions of the queuosine modification system, which have been suggested to be associated with neoplastic progression.

The FGF receptor-1 tyrosine kinase domain regulates myogenesis but is not sufficient to stimulate proliferation.

Ligand-stimulated activation of FGF receptors (FGFRs) in skeletal muscle cells represses terminal myogenic differentiation. Skeletal muscle cell lines and subsets of primary cells are dependent on FGFs to repress myogenesis and maintain growth. To understand the intracellular events that transduce these signals, MM14 skeletal muscle cells were transfected with expression vectors encoding chimeric receptors. The chimeras are comprised of the PDGF beta receptor (PDGFbetaR) extracellular domain, the FGFR-1 intracellular domain, and either the PDGFbetaR or FGFR-1 transmembrane domain. The chimeric receptors were autophosphorylated upon PDGF-BB stimulation and are capable of stimulating mitogen-activated protein kinase activity. Activation of the tyrosine kinase domain of either chimera repressed myogenesis, suggesting intracellular responses regulating skeletal muscle differentiation are transduced by activation of the FGFR-1 tyrosine kinase. Unexpectedly, we found that activation of either chimeric receptor failed to stimulate cellular proliferation. Thus, it appears that regulation of skeletal muscle differentiation by FGFs requires only activation of the FGFR tyrosine kinase. In contrast, stimulation of proliferation may require additional, as yet unidentified, signals involving the receptor ectodomain, the FGF ligand, and heparan sulfate either alone, or in combination.

Differentially expressed fibroblast growth factors regulate skeletal muscle development through autocrine and paracrine mechanisms.

Several FGF family members are expressed in skeletal muscle; however, the roles of these factors in skeletal muscle development are unclear. We examined the RNA expression, protein levels, and biological activities of the FGF family in the MM14 mouse skeletal muscle cell line. Proliferating skeletal muscle cells express FGF-1, FGF-2, FGF-6, and FGF-7 mRNA. Differentiated myofibers express FGF-5, FGF-7, and reduced levels of FGF-6 mRNA. FGF-3, FGF-4, and FGF-8 were not detectable by RT-PCR in either proliferating or differentiated skeletal muscle cells. FGF-I and FGF-2 proteins were present in proliferating skeletal muscle cells, but undetectable after terminal differentiation. We show that transfection of expression constructs encoding FGF-1 or FGF-2 mimics the effects of exogenously applied FGFs, inhibiting skeletal muscle cell differentiation and stimulating DNA synthesis. These effects require activation of an FGF tyrosine kinase receptor as they are blocked by transfection of a dominant negative mutant FGF receptor. Transient transfection of cells with FGF-1 or FGF-2 expression constructs exerted a global effect on myoblast DNA synthesis, as greater than 50% of the nontransfected cells responded by initiating DNA synthesis. The global effect of cultures transfected with FGF-2 expression vectors was blocked by an anti-FGF-2 monoclonal antibody, suggesting that FGF-2 was exported from the transfected cells. Despite the fact that both FGF-l and FGF-2 lack secretory signal sequences, when expressed intracellularly, they regulate skeletal muscle development. Thus, production of FGF-1 and FGF-2 by skeletal muscle cells may act as a paracrine and autocrine regulator of skeletal muscle development in vivo.