Further characterization of the epa gene cluster and Epa polysaccharides of Enterococcus faecalis.

We previously identified a gene cluster, epa (for enterocococcal polysaccharide antigen), involved in polysaccharide biosynthesis of Enterococcus faecalis and showed that disruption of epaB and epaE resulted in attenuation in translocation, biofilm formation, resistance to polymorphonuclear leukocyte (PMN) killing, and virulence in a mouse peritonitis model. Using five additional mutant disruptions in the 26-kb region between orfde2 and OG1RF_0163, we defined the epa locus as the area from epaA to epaR. Disruption of epaA, epaM, and epaN, like prior disruption of epaB and epaE, resulted in alteration in Epa polysaccharide content, more round cells versus oval cells with OG1RF, decreased biofilm formation, attenuation in a mouse peritonitis model, and resistance to lysis by the phage NPV-1 (known to lyse OG1RF), while mutants disrupted in orfde2 and OG1RF_163 (the epa locus flanking genes) behaved like OG1RF in those assays. Analysis of the purified Epa polysaccharide from OG1RF revealed the presence of rhamnose, glucose, galactose, GalNAc, and GlcNAc in this polysaccharide, while carbohydrate preparation from the epaB mutant did not contain rhamnose, suggesting that one or more of the glycosyl transferases encoded by the epaBCD operon are necessary to transfer rhamnose to the polysaccharide. In conclusion, the epa genes, uniformly present in E. faecalis strains and involved in biosynthesis of polysaccharide in OG1RF, are also important for OG1RF shape determination, biofilm formation, and NPV-1 replication/lysis, as well as for E. faecalis virulence in a mouse peritonitis model.

Host factors in metastasis: Direct lysis of bloodborne metastatic tumor cells by murine vascular endothelial cells

During the process of cancer metastasis, the majority of circulating tumor cells arrest in microcapillary beds and then rapidly die. To study whether vascular endothelial cells can directly lyse tumor cells, we isolated vascular endothelial cells by perfusion of lungs from immunocompetent or nude mice. The cells were grown in culture, and then cloned and characterized. Cloned endothelial cells were incubated with several lymphokines and cytokines. Cells incubated with IFN-$\gamma$ and TNF lysed a variety of tumor cells with different metastatic potential. Mouse skin and lung fibroblasts treated with the same cytokines did not. Endothelial cell mediated tumor cell lysis was not due to different binding ability of tumor cells to cytokine treated and untreated endothelial monolayers. Kinetic studies demonstrated that the continuous presence of cytokines in the tumor-endothelial cocultures was necessary to produce maximal lysis of tumor cells. Target cell lysis was not due to the direct effects of IFN-$\gamma$ or TNF, since vascular endothelial cells isolated from the lung of nude mice lysed human melanoma cells that are sensitive or resistant to TNF. Cytokine treated endothelial cells produced a high level of nitric oxide, which is known to be cytotoxic to a variety of target cells. The level of nitric oxide production was directly correlated with the degree of tumor cell lysis. A specific inhibitor of nitric oxide synthesis(N$\sp{\rm G}$-monomethyl-L-arginine), completely inhibited production of nitric oxide and tumor cell lysis. Treatment of cytokine activated endothelial cells with dexamethasone also inhibited tumor cell lysis. This inhibition was independent of tumor-endothelial adhesion but correlated with inhibition of nitric oxide production. Collectively, these results suggest that vascular endothelial cells can directly destory tumor emboli and thus play an active role in the pathogenesis of cancer metastasis. ^