To investigate the antigenic relationship between the macrophage and lymphocyte Fc receptors (FcR), a monoclonal antibody capable of blocking mouse macrophage Fc receptors was selected. Hybrids were formed by fusing the P3U1 mouse myeloma and spleen cells from a rat immunized with the mouse macrophage-like cell lines J774 and P388D1. The Fab fragment of the monoclonal IgG secreted by clone 2.4G2, inhibited the trypsin-resistant Fc receptor II (FcRII), which is specific for immune aggregates of mouse IgG1 and IgG2b, but had no inhibitory effect on the trypsin-sensitive Fc receptor I (FcRI), which binds monomeric IgG2a and erythrocytes coated with IgG2a. Thus, the monoclonal 2.4G2 IgG appeared to be specific for macrophage FcRII. Further evidence that the 2.4G2 IgG was directed against FcRII came from binding studies of the monoclonal antibody to J774 cells and a series of independently isolated variants which do not express FcRII. These variants of J774 bound 5% as much of the monoclonal antibody as the parent line, which bound 600,000 molecules of 2.4G2 IgG per cell. The antigenic relatedness of mouse lymphocyte FcR to mouse macrophage FcRII was demonstrated by the binding of 2.4G2 IgG to FcR-bearing lymphoid cell lines and the inhibition of the lymphocyte FcR by the monoclonal antibody. Preincubation of spleen cells and peritioneal cells with 2.3G2 IgG likewise inhibited rosette formation with ox erythrocytes coated with rabbit IgG. The ability of the hybridoma IgG to inhibit mouse FcRII was independent of the major histocompatibility complex. The 2.4G2 IgG antigenic determinant was not present on rat, guinea pig, rabbit, or human FcR-bearing cells.
Interferons are a family of proteins first identified by their ability to induce cellular resistance to infection by many viruses. In addition to the antiviral properties it shares with the alpha- and beta-interferons, gamma-interferon (IFN-gamma), a lymphokine secreted by activated T cells, activates macrophages, stimulates B cells, increases fibroblast and endothelial cell resistance to many nonviral intracellular parasites and modulates cell-surface proteins central to immune cell regulation. To identify molecules involved in the IFN-gamma response and characterize their modulation, we have isolated genes that are induced following recombinant IFN-gamma treatment of U937 cells, a histiocytic lymphoma cell line with monocytic characteristics. We report here the molecular cloning and characterization of a gene regulated by rIFN-gamma in U937 cells as well as in human mononuclear cells, fibroblasts and endothelial cells. Messenger RNA from this gene is induced within 30 min of rIFN-gamma treatment and demonstrates maximal (greater than 30-fold) accumulation within 5 h. Increased transcription is partly responsible for this accumulation. This gene encodes a protein of relative molecular mass (Mr) 12,378 which has significant amino-acid homology to platelet factor-4 and beta-thromboglobulin, two chemotatic proteins released by platelets on degranulation. This IFN-gamma-inducible protein may be a member of a family of proteins involved in the inflammatory process.
The signal pathways that trigger tumor cell escape from immune surveillance are incompletely understood. Toll-like receptors (TLRs), which activate innate and adaptive immune responses, are thought to be restricted to immune cells. We show here that TLRs, including TLR4, are expressed on tumor cells from a wide variety of tissues, suggesting that TLR activation may be an important event in tumor cell immune evasion. Activation of TLR4 signaling in tumor cells by lipopolysaccharide induces the synthesis of various soluble factors and proteins including interleukin-6, inducible nitric oxide synthase, interleukin-12, B7-H1, and B7-H2, and results in resistance of tumor cells to CTL attack. In addition, lipopolysaccharide-stimulated tumor cell supernatants inhibit both T cell proliferation and natural killer cell activity. Blockade of the TLR4 pathway by either TLR4 short interfering RNA or a cellpermeable TLR4 inhibitory peptide reverses tumor-mediated suppression of T cell proliferation and natural killer cell activity in vitro, and in vivo, delays tumor growth and thus prolongs the survival of tumor-bearing mice. These findings indicate that TLR signaling results in a cascade leading to tumor evasion from immune surveillance. These novel functions of TLRs in tumor biology suggest a new class of therapeutic targets for cancer therapy. (Cancer Res 2005; 65(12): 5009-14)
We have recently shown that, following transformation by oncogenic viruses or chemicals, avian and mammalian cells release an enzyme that functions as a plasminogen activator (1-3). The evidence obtained so far indicates that the increased activation of plasminogen determines, at least in part, several of the phenotypic properties of transformed cells; these include colony formation in semisolid media, and the characteristic changes in cell morphology and migration (4). Although the significance of plasminogen activation for cell growth remains to be determined, its association with transformation and neoplasia suggests that the formation of plasminogen activator may also occur during normal cellular proliferation, such as that in the lymphoid and hemopoietic systems.In view of the role of macrophages in lymphocyte activation by lectins and antigens (5, 6), in the production of factors regulating granulocyte differentiation (7), and in chronic inflammation, we have examined pure populations of peritoneal macrophages for production of plasminogen activator. Mononuclear phagocytes are a rich source of acid proteases, such as cathepsins (8), which are thought to play a role in intracellular digestion, but proteases capable of acting extracellularly, at neutral pH, have not been characterized.In this paper, we report that thioglycollate-stimulated mouse macrophages produce and secrete a plasminogen activator in vitro similar to that reported previously from transformed cells. Unstimulated peritoneal macrophages do not produce this enzyme. We have characterized the plasminogen activator secreted into the medium by thioglycollate-stimulated macrophages and have examined the production and release of the enzyme in culture. In addition, we have found that stimulated macrophages m a y also release a variety of proteases that are not formed by unstimulated cells. Materials and MethodsCell Cultures.--Female mice of the NCS (Rockefeller) strain, weighing 25-30 g, were used throughout. Peritoneal macrophages were always harvested without anticoagulants and cul-
The tumor cell signaling pathways that trigger the uncontrolled proliferation, resistance to apoptosis, metastasis and escape from immune surveillance are partially understood. Toll-like receptors (TLRs), which recognize a variety of pathogen-associated molecular patterns, are centrally involved in the initiation of the innate and adaptive immune responses. However, recent evidence shows that functional TLRs are also expressed on a wide variety of tumors suggesting that TLRs may play important roles in tumor biology. Activation of tumor cell TLRs not only promotes tumor cell proliferation and resistance to apoptosis, but also enhances tumor cell invasion and metastasis by regulating metalloproteinases and integrins. Moreover, the activation of TLR signaling in tumor cells induces the synthesis of proinflammatory factors and immunosuppressive molecules, which enhance the resistance of tumor cells to cytotoxic lymphocyte attack and lead to immune evasion. Thus, the neoplastic process may usurp TLR signaling pathways to advance cancer progression, which suggests that targeting tumor TLR signaling pathways may open novel therapeutic avenues.
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