Biological properties associated with the enhanced lung-colonizing potential in a B16 murine melanoma line grown in a medium conditioned by syngeneic Corynebacterium parvum-elicited macrophages

Environmental control of invasiveness and metastatic dissemination of tumor cells: the role of tumor cell-host cell interactions

Recent advances in tumor biology led to the realization that, in order to understand the mechanisms involved in proliferation and invasion of tumor cells, an analysis of the complex interactions that tumor cells establish with host cells of tumor microenvironment is required. The bidirectional interactions between tumor cells and components of tumor microenvironment, in particular endothelial cells, cells of monocyte/macrophage lineage and fibroblasts/myofibroblasts, play a critical role in most of the events that characterize tumor progression and metastasis. Interactions between these "reactive" normal cells and the genetically altered tumor cells, by either cell-to-cell contacts or soluble mediators, control the most aspects of tumor formation and progression. This review addresses some of the experimental evidences documenting that tumor cells may influence host cells of their own microenvironment by triggering changes that facilitate their local as well as distant dissemination. Therefore, it focuses on macrophages and fibroblasts that, upon stimulation by tumor cells, change their state towards a tumor-promoting-like phenotype.

Tumoral and macrophage uPAR and MMP-9 contribute to the invasiveness of B16 murine melanoma cells

The aim of this study was to investigate whether tumor cells as well as tumor-associated macrophages (TAMs) contribute to the generation of protease activities essential to tumor cell invasiveness, such as matrix metalloproteinase 2 and 9 (MMP-2 and MMP-9), and the urokinase-type plasminogen activator (uPA) and uPA receptor (uPAR). We found that the enhanced invasiveness through Matrigel-coated filters of B16 murine melanoma cells stimulated with IFNgamma was associated with an higher expression of uPAR and MMP-9 in these cells. Moreover, treatment with anti-MMP-9 or anti-uPAR monoclonal antibodies abrogated the increase of invasiveness in IFNgamma-stimulated melanoma cells, suggesting a cooperation of uPA system and MMP-9 in cytokine-stimulated invasiveness. Invasiveness through Matrigel was also enhanced in B16 melanoma cells exposed to a medium conditioned by TAMs, represented in our experimental model by thioglycollate-elicited macrophages co-cultivated with melanoma cells. Macrophages isolated from these co-cultures were found to express higher levels of uPAR and MMP-9 compared to macrophage cultures alone, and the pro-invasive activity of the co-culture-conditioned medium was abrogated by anti-MMP-9 monoclonal antibodies, but not anti-uPAR monoclonal antibodies. Furthermore, the enhanced uPAR and MMP-9 expression in macrophages co-cultivated with tumor cells seems a rather specific phenomenon, generated through a cell-to-cell contact mechanism. On the whole, our data point to a cooperation between tumor cells and macrophages elicited by tumor cells themselves in generating key enzymes essential in the promotion of tumor invasiveness, such as uPAR and MMP-9.

Platelet-activating factor (PAF) is the effector of IFNγ-stimulated invasiveness and motility in a B16 melanoma line

In this study, we investigated whether PAF synthesized by F10-M3 cells (a clone of B16-F10 melanoma line) mediates the increased capacity of these cells to penetrate into Matrigel upon stimulation with IFN gamma. The determination of PAF synthesized by IFN gamma-stimulated tumor cells revealed that 70% of newly synthesized PAF was released into growth media, while the remaining 30% was associated with the cell bodies. An experimental protocol based on the use of WEB 2086, a PAF receptorial antagonist, was designed to explore which of the two fractions of PAF synthesized by IFN gamma-stimulated F10-M3 cells (released into the growth medium or associated with the cell bodies) is essential to their capacity to migrate through Matrigel. We found that the PAF secreted into growth medium is the fraction responsible for the enhanced invasiveness of melanoma cells stimulated with IFN gamma. We also investigated whether motility of melanoma cells is stimulated by IFN gamma, and, if so, whether PAF is involved in this effect. We found that WEB 2086 prevented the remodeling of stress fibers, examined as an index of cell motility, that we observed in F10-M3 cells stimulated with IFN gamma. Furthermore, the observation that PAF receptor is expressed in IFN gamma-stimulated melanoma cells suggests that the invasive phenotype (e.g. migration through a reconstituted basement membrane and motility) promoted by PAF is based on an autocrine mechanism. On the whole, these results might indicate that PAF contributes to the expression of properties typical of an invasive phenotype in tumor cells stimulated with cytokines.

Expression of a metastatic phenotype in IFNs-primed/TNFalpha-activated B16 murine melanoma cells: role of JAK1/PKCdelta signal transduction factors

In previous studies, we found that IFNgamma and TNFalpha generated by activated macrophages stimulate the metastatic potential in F10-M3 cells, a clone isolated from B16-F10 murine melanoma line. In this phenomenon, TNFalpha promoted the expression of a metastatic phenotype in tumor cells previously primed with IFNgamma. Here, we demonstrate that IFNalpha or IFNbeta may replace IFNgamma in priming tumor cells. We also noticed that an enhancement of the expression of p55TNFalpha receptor was associated with the preconditioning of tumor cells with IFNgamma and IFNbeta. By the use of an appropriate inhibitor, we observed that JAK1 signal transduction pathway was involved in the expression of a metastatic phenotype and of p55TNFalpha receptor shown in IFNgamma- and IFNbeta-primed melanoma cells stimulated with TNFalpha. Furthermore, the activity of the protein kinase C (PKC) was required for IFNgamma-primed melanoma cells to express a metastatic phenotype after stimulation with TNFalpha. In conclusion, our study shows that a metastatic phenotype was expressed in B16 murine melanoma cells stimulated with TNFalpha regardless of whether the cells were primed with IFNgamma IFNalpha or IFNbeta. The molecular events leading to the expression of a metastatic phenotype in F10-M3 melanoma cells are represented by: (a) an enhanced expression of p55TNFalpha receptor in IFNs-primed tumor cells dependent on JAK1 signal transduction pathway; and (b) an intact PKC activity during TNFalpha stimulation.