Hepatocyte growth factor/scatter factor (HGF/SF) is a multifunctional growth factor that promotes proliferation, motility, and morphogenesis in epithelial cells. Recently the HGF receptor, c-met protooncogene product, has been shown to be expressed in developing limb buds (Sonnenberg, E., D. Meyer, M. Weidner, and C. Birchmeiyer, 1993. J. Cell Biol. 123: 223-235), suggesting that some populations of mesenchymal cells in limb buds respond to HGF/SF. To test the possibility that HGF/SF is involved in regulation of cartilage development, we isolated chondrocytes from knee joints and costal cartilages of 23-d embryonic and 4-wk-old rabbits, and analyzed the effects of HGF/SF on migration and proliferation of these cells. We found that HGF/SF stimulated migration of cultured articular chondrocytes but did not scatter limb mesenchymal fibroblasts or synovial fibroblasts in culture. HGF/SF also stimulated proliferation of chondrocytes; a maximum three-fold stimulation in DNA synthesis was observed at the concentration of 3 ng/ml of HGF/SF. Moreover, HGF/SF had the ability to enhance proteoglycan synthesis in chondrocytes. The responsiveness of chondrocytes to HGF/SF was also supported by the observation that they expressed the HGF/SF receptor. Addition of the neutralizing antibody to rat HGF/SF affected neither DNA synthesis nor proteoglycan synthesis in rat chondrocytes, suggesting a paracine mechanism of action of HGF/SF on these cells. In situ hybridization analysis showed that HGF/SF mRNA was restrictively expressed in the areas of future joint regions in developing limb buds and in the intercostal spaces of developing costal cartilages. These findings suggest that HGF/SF plays important roles in cartilage development through its multiple activities.

Treatment of epithelial African green monkey kidney (BSC-1) cells with the potent tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) induces a rapid and reversible redistribution of actin and vinculin that is detectable after only 2 min of treatment. Within 20-40 min, stress fibers disappear, while at the same time large actin-containing ribbons resembling ruffles develop both at the cell periphery and in more central regions. Vinculin is associated with these actin ribbons or bands in a punctate or patchy staining pattern. Adhesion to the substratum is changed from predominantly focal contacts associated with stress fiber ends in untreated cells to broad zones of close contact after TPA treatment. High voltage electron microscopic observations disclose the ribbons to consist of highly cross-linked actin filament networks. Thus, association of vinculin with filament networks, rather than (the ends of) filament bundles, is demonstrated. The integrity of microtubules and vimentin filaments is not affected by TPA treatment, but their distribution is altered to conform with the highly distorted cell shape. The response to TPA is neither prevented nor modified by nocodazole-induced depolymerization or taxol-induced stabilization of microtubules. An intact intermediate filament network seems not required either since colcemid-induced collapse of vimentin filaments towards the nucleus does not affect the cell's response to TPA. Rapid redistribution of actin and vinculin also takes place in enucleated cells and in the presence of cycloheximide, but is prevented by dinitrophenol or oligomycin. TPA-induced cytoskeletal alterations are independent of fibronectin expression and not mimicked, modified, or prevented by calmodulin inhibitors or experimentally elevated levels of calcium and cyclic AMP. Thus the morphological response to TPA involves rapid redistribution of actin and vinculin independent of transcription and translation, fluctuations in the levels of calcium or cyclic AMP, or changes in the organization of microtubules, intermediate filaments, and fibronectin.