Abstract
Mononuclear phagocytes, located throughout all tissues of the body, serve a multitude of major defensive and homeostatic functions [1]. One of the most important functions is the pivotal role macrophages can play in host protection against the development and spread of neoplasia [2]. Yet, the consistent and successful immunotherapy of human cancer remains an elusive goal [3]. Understanding the complex mechanisms regulating macrophage-mediated tumor cell destruction may ultimately lead to a rational basis for immunomodulation and, hence, successful immunologically based therapy of neoplastic diseases.
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References
Nathan, C.F., Cohn, Z.A. 1985. Cellular components of inflammation: monocytes and macrophages. In: Textbook Rheumatology, (Kelly, W., Harris, E., Ruddy, S., Hedge, R., eds.), W.B. Saunders, New York 2nd ed. p. 144.
Adams, D.O., Snyderman, R. 1979. Do macrophages destroy nascent tumors? J. Natl. Cancer Inst. 16: 1341.
Baldwin, R.W. 1982. Manipulation of host resistance in cancer therapy. Springer Sem. Immunopathol. 5: 113.
Nathan, C.F. 1983. Secretory products in cytotoxicity. In: Biological Response Mediators and Modifiers. Academic Press, New York, p. 221.
Mosser, D.M., Edelson, P.J. 1984. Mechanisms of microbial entry and endocytosis by mononuclear phagocytes. Contemp. Topics Immunobiol. 13: 71.
Silverstein, S.C., Steinman, R.M., Cohn, Z.A. 1977. Endocytosis. Annual Rev. Biochem. 46: 669.
Steinman, R.M., Mellman, I.S., Muller, W.A., Cohn, Z.A. 1983. Endocytosis and recycling of plasma membrane. J. Cell. Biol. 96: 1.
Adams, D.O., Hamilton, T.A. 1984. The cell biology of macrophage activation. Ann. Review of Immunol. 2: 293.
Adams, D.O., Marino, P.A. 1981. Evidence for a multistep mechanism of cytolysis by BCG-activated macrophages: the interrelationship between capacity for cytolysis, target binding, and secretion of cytolytic factor. J. Immunol. 126: 981.
Mauel, J. 1982. Effector and escape mechanisms in host-parasite relationships. Prog. Allergy 31: 1.
Marino, P.A., Adams, D.O. 1980. Interaction of bacillus calmette-guerin-activated macrophages and neoplastic cells in vitro. II. The relationship of selective binding to cytolysis. Cell. Immunol. 54: 26.
Marino, P.A., Adams, D.O. 1982. The capacity for activated murine macrophages for augmented binding of neoplastic cells: analysis of induction by lymphokine containing MAF and kinetics of the reaction. J. Immunol. 128: 2816.
Adams, D.O., Lewis, J.G., Joihnson, W.J. 1984. Multiple modes of cellular injury by macrophages: requirement for different forms of effector activation. In: Progress in Immunology V. Academic Press Japan, Inc., pp. 1009–1118.
Adams, D.O., Lewis, J.G., Johnson, W.J. 1984. Analysis of interactions between immunomodulators and mononuclear phagocytes: different modes of tumor cell injury require different forms of macrophage activation. Behring Inst. Research Communications. 74: 132–139.
Hamilton, T.A., Fishman, M. Grawfod, G., Look, A.T. 1982. Macrophage-mediated cytostatic activity blocks lymphoblast cell cycle progression independently in both G 1 phase and S phase. Cell. Immunol. 77: 233.
Keller, R. 1973. Cytostatic elimination of syngeneic rat tumor cells in vitroby nonspecifically-activated macrophages. J. Exp. Med. 138: 625.
Keller, R. 1976. Susceptibility of normal and transformed cell lines to cytostatic and cytocidal effects exerted by macrophages. J. Natl. Cancer Inst. 56: 369.
Evans, R. 1982. Macrophages and neoplasms: new insights and their implication in tumor immunobiology. Can. Metastasis Rev. 1: 227.
Nathan, C.F., Brukner, L.H., Kaplan, G., Unkeless, J., Cohn, Z.A. 1980. Role of activated macrophages in antibody-dependent lysis of tumor cells. J. Exp. Med. 152: 183.
Walker, W. 1977. Mediation of macrophage cytolytic and phagocytic activities by antibodies of different classes and class-specific Fc receptors. J. Immunol. 119: 367.
Kurisu, M., Dohi, N., Yamazaki, M., Mizuno, D. 1980. Macrophage-tumor interaction induced by antibody in antibody-dependent, macrophage-mediated tumor lysis. J. Reticuloendothel. Soc. 28: 237.
Evans, R., Alexander, P. 1976. Mechanisms of extracellular killing of nucleated mammalian cells by macrophages. In: Immunobiology of the Macrophage ( D.S. Nelson, ed.), Academic Press, New York, p. 536.
Meltzer, M.S., Tucker, R.W., Sanford, K.K., Leonard, E.J. 1975. Interaction of BCG-activated macrophages with neoplastic and nonneoplastic cell lines in vitro: Quantitation of the cytotoxic reaction by release of tritiated thymidine from pre-labeled target cells. J. Natl. Cancer Inst. 54: 1177.
Bongrard, P., Capo, C., Depieds, R. 1982. Physics of cell adhesion. Progress in Surface Science 12: 217.
Bell, G.I. 1978. Models for the specific adhesion of cells to cells. Science 200: 618.
Edelman, G.M. 1983. Cell adhesion molecules, Science 219: 450.
Frazier, W.A., Glaser, L., Gottlieb, G. (Eds.) 1982. Cellular Recognition. Alan R. Liss, Inc., New York.
Umbrect, J., Roseman, S. 1976. A requirement for reversible binding between aggregating embkryonic cells before stable adhesion. J. Biol. Chem. 250: 9360.
Segal, D.M., Stephany, D.A. 1984. The mechanism of intercellular aggregation. I. The kinetics of the Fc1 receptor-mediated aggregation of P388D1 cells with antibody-coated lymphocytes at 4 °C. J. Immunol. 132: 1924.
McClay, D.R., Wessel, G.M., Marchase, R.B. 1981. Intercellular recognition: quantitation of initial binding events. Proc. Natl. Acad. Sci. U.S.A. 78: 4976.
Guarnaccia, S.P., Schnaar, R.L. 1982. Hepatocyte adhesion to immobilized carbohydrates. I. Sugar recognition is followed by energy-dependent strengthening. J. Biol. Chem. 257: 14288.
Guarnaccia, S.P., Kuhlenschmidt, M.S., Slife, S.W., Schnaar, R.L. 1982. Hepatocyte adhesion to immobilized carbohydrates. II. Cellular modification of the carbohydrate surface. J. Biol. Chem. 257: 14293.
Bell, G.I., Dembo, M., Bongrand, P. 1984. Cell adhesion. Competition between nonspecific repulsion and specific bonding. Biophys. J. 45: 1051.
Edelman, G.M. 1984. Cell adhesion and morphogenesis: the regulatory hypothesis. Proc. Natl. Acad. Sci. 81: 1460.
Edelman, G.M. 1984. Cell-adhesion molecules: a molecular basis for animal form. Sci. Am. 250: 118.
Frazier, W., Glaser, L. 1979. Surface components and cell recognition. Ann. Rev. Biochem. 48: 491.
Rauvala, H., Prieels, J.-P., Finne, J. 1983. Cell adhesion mediated by a purified fucosyltransferase. Proc. Natl. Acad. Sci. 80: 3991.
Hynes, R.O., Yamada, K. 1982. Fibronectins: multifunctional modular glycoproteins. J. Cell Biol. 95: 369.
Grunnell, F. 1979. Cellular adhesiveness and extracellar substrates. Inter. Rev. Cytol. 53: 65.
Ellenberger, A., Nussenzwieg, V. 1977. The role of membrane receptors for C3b and C3d in phagocytosis. J. Exp. Med. 145: 357.
Unkeless, J.C. 1977. The presence of two Fc receptors on mouse macrophages: evidence from a variant cell line and differential trypsin sensitivity. J. Exp. Med. 145: 931.
Unkeless, J.C. 1969. Characterization of a monoclonal antibody directed against mouse macrophage and lymphocyte Fc receptors. J. Exp. Med. 150: 580.
Unkeless, J.C., Fleit, H., Mellman, I.S. 1981. Structural aspects and heterogeneity of immunoglobulin Fc receptors. Adv. Immunol. 31: 247.
Diamond, B., Scharff, M.D. 1980. IgG1 and IgG2b share the Fc receptor on mouse macrophages. J. Immunol. 125: 631.
Ralph, P., Nakoinz, I., Diamond, B., Yelten, D. 1980. All classes of murine IgG antibody mediate macrophage phagocytosis and lysis of erythrocytes. J. Immunol. 125: 1885.
Ralph, P., Nakoinz, I. 1983. Cell-mediated lysis of tumor targets directed by murine monoclonal antibodies of IgM and all IgG isotypes. J. Immunol. 131: 1028.
Ralph, P. 1983. Immunoglobulin class of antibody effective in macrophage ADCC. In: Macrophage-mediated Antibody-dependent Cellular Cytotoxicity ( H.S. Koren, ed.), Marcell Dekker, New York, p. 71.
Matthews, J.J., Collins, J.J., Roloson, G.J., Thiel, H.-J., Bolognesi, D.P. 1981. Immuno-logic control of the ascites form of murine adenocarcinoma 755. IV. Characterization of the protective antibody in hyperimmune serum. J. Immunol. 126: 2332.
Langlois, A.J., Matthews, T.J., Roloson, G.J., Thiel, H.-J., Collins, J.J., Bolognesi, D.P. 1981. Immunologic control of the ascites form of murine adenocarcinoma 755. V. Antibody-directed macrophages mediate tumor cell destruction. J. Immunol. 126: 2337.
Herlyn, D., Koprowski, H. 1982. Ig2a monoclonal antibody inhibits human tumor cell growth through interaction with effector cells. Proc. Nat. Acad. Sci. USA 79: 4761.
Steplewski, Z., Lubeck, M.O., Koprowski, H. 1983. Human macrophages armed with murine immunoglobulin G2a antibodies to tumors destroy human cancer cells. Science 221: 865.
Kipps, T.J., Parham, P., Pont, J., Herzenberg, L.A. 1985. Importance of immunoglobulin isotype in human antibody-dependent, cell-mediated cytotoxicity directed by murine monoclonal antibodies. J. Exp. Med. 161: 1.
Vogel, S.N., Finbloom, D.S., English, K.E., Rosenstreich, D.L., Langreth, S.G. 1983. Interferon-induced enhancement of macrophage Fc receptor expression [3-interferon treatment of C3H/HeJ macrophages results in increased numbers and density of Fc receptor. J. Immunol. 130: 1210.
Rhodes, J. 1975. Macrophage heterogeneity in receptor activity: the activation of macrophage Fc receptor function in vivoand in vitro. J. Immunol. 114: 976.
Rhodes, J., Jones, D.H., Bleehen, N.M. 1983. Increased expression of human monocyte HLA-DR antigens and Fcy receptors in response to human interferon in vivo. Clin. Exp. Immunol. 53: 739.
Ezekowitz, R.A.B., Gordon, S. 1984. Alterations of surface properties by macrophage activation: expression of receptors for Fc and mannose-terminal glycoproteins and differentiator antigens. Contemp. Top. Immunobiol. 14: 33.
Nitta, T., Suzuki, T. 1982. Biochemical signals transmitted by Fcy receptors triggering mechanisms of the increased synthesis of adenosine-3’,5’-cyclic monophosphate mediated by Fcy2a and Fc2b receptors of a murine macrophage-like cell line (P388 D1). J. Immunol. 129: 2708.
Young, J.D.-E., Unkeless, J.C., Kaback, R., Cohn, Z.A. 1983. Mouse macrophage Fc receptor for IgGy2b yi in artificial and plasma membrane vesicles functions as a ligand-dependent inophore. Proc. Natl. Acad. Sci. 80: 1636.
Johnston, P.A., Adams, D.O., Hamilton, T.A. 1984. Fe-receptor mediated protein phosphorylation in murine peritoneal macrophages. Biochem. Biophys. Res. Commun. 124: 197.
Humes, J.L., Sadowski, S., Galavage, M., Goldenberg, M., Subers, E., Bonney, R.J., Kuehl, F.A., Jr. 1982. Evidence for two sources of arachidonic acid for oxidative metabolism by mouse peritoneal macrophages. J. Biol. Chem. 257: 1591.
Gordon, S., Unkeless, J.C., Cohn, Z.A. 1974. Induction of macrophage plasminogen activator by endotoxin stimulation and phagocytosis: evidence for a 2 stage process, J. Exp. Med. 140: 995.
Melewicz, F.M., Spiegelberg, H.L. 1980. Fc receptors for IgG on a subpopulation of human peripheral blood monocytes. J. Immunol. 125: 1026.
Dessaint, J.P.L., Capron, A., Joseph, M., Aurrault, C., Pestel, J. 1983. Macrophage-mediated IgE ADCC to helminth parasites and IgE-dependent macrophage activation. In: Macrophage-mediated Antibody-dependent Cellular Cytotoxicity ( H.S. Koren, ed.), Marcell Dekker, New York, p. 315.
Diamond, B., Yelton, D.E. 1981. A new Fc receptor on mouse macrophages binding IgG3. J. Exp. Med. 153: 514.
Rabellino, E.M., Ross, G.D., Polley, M.J. 1978. Membrane receptors of mouse leukocytes. I. Two types of complement receptors for different regions of C3. J. Immunol. 120: 871.
Rabellino, E.M., Ross, G.D., Trang, H.T.K., Williams, N., Metcalf, D. 1978. Membrane receptors of mouse leukocytes. II. Subsequential expression of membrane receptors and phagocytic capacity during leukocyte differentiation. J. Exp. Med. 147: 434.
Springer, T.A., Unkeless, J.C. 1984. Analysis of macrophage differentiation and function with monoclonal antibodies. Contemp. Top. Immunobiol. 14: I.
Hartung, H.P., Hadding, U. 1983. Synthesis of complement by macrophages and modulation of their functions through complement activation. Springer Semin. Immunopathol. 6: 283.
Ross, G.D., Medof, M.E. 1985. Membrane complement receptors specific for bound fragments of C3. Adv. Immunol. 37: 217.
Beller, D.I., Springer, T.A., Schreiber, R.D. 1982. Anti-Mac-1 selectively inhibits the mouse and human type three complement receptor. J. Exp. Med. 156: 1000.
Aderem, A.A., Wright, S.D., Silverstein, S.C., Cohn, Z.A. 1985. Ligated C1 receptors do not activate the arachidonic acid cascade in resident peritoneal macrophages. J. Exp. Med. 161: 617.
Yamamoto, K., Johnston, R.B. 1984. Dissociation of phagocytosis from stimulation of the oxidative metabolic burst in macrophages. J. Exp. Med. 159: 405.
Griffin, F.M., Jr., and Mullinex, P.J. 1981. Augmantation of macrophage-complement receptor function in vitro. III. C3b receptors that promote phagocytosis migrate within the plane of the macrophage plasma membrane. J. Exp. Med. 154: 291.
Griffin, F.M. 1984. Activation of macrophage complement receptors for phagocytosis. Contemp. Top. Immunobiol. 14: 57.
Wright, S.D., Silverstein, S.C. 1982. Tumor-promoting phorbol esters stimulate C3b and C3bi receptor-mediated phagocytosis in cultured human monocyte. J. Exp. Med. 156: 1149.
Stahl, P., Schlesinger, P., Rodman, J.S., Doebber, T. 1976. Recognition of lysosomal glycosidases in vivoinhibited by modified glycoproteins. Nature 264: 86.
Imber, M., Pizzo, S.V., Johnson, W.J., Adams, D.O. 1982. Selective diminution of the binding of mannose by murine macrophages in the latter activation. J. Biol. Chem. 257: 5129.
Stahl, P., Gordon, S. 1982. Expression of a mannose-fucosyl receptor for endocytosis on cultured primary macrophages and then hybrids. J. Cell. Biol. 93: 49.
Sung, S-S.T., Nelson, R.S., Silverstein, S.C. 1983. Yeast mannans inhibit binding and phagocytosis of zymosan bymouse peritoneal macrophages. J. Cell Biol. 95: 160.
Ezekowitz, R.A.B., Gordon, S. 1982. Down-regulation of mannosyl receptor-mediated endocytosis and antigen F4/80 in bacillus calmette-guerin activated mouse macrophages. Role of T lymphocytes and lymphokines. J. Exp. Med. 155: 1623.
Kolb-Bachofen, V., Schlepper-Schafer, J., Vogell, W., Kolb, H. 1982. Electron microscopic evidence for an asialoglycoprotein receptor on Kupffer cells: localization of lectinmediated endocytosis. Cell 29: 859.
Benacerraf, B., Germain; R.N. 1978. The immune response genes of the major histocompatibility complex. Immunol. Rev. 38: 70.
Zeigler, K., Unanue, E.R. 1979. The specific binding of Listeria monocytogenes immune T lymphocytes to macrophages. I. Quantitation and role of H-2 gene products. J. Exp. Med. 150: 1143.
Rosenthal, A.S. 1978. Selection and macrophage function in genetic control of the immune response. Immunol. Rev. 40: 136.
Actuo, O., Reinherz, F.L. 1984. The human T cell receptor-structure and function. N. Eng. J. Med. 312: 1100.
Beller, D.I., Kiely, J.M., Unanue, E.R. 1980. Regulation of macrophage populations. I. Preferential induction of Ia rich peritoneal exudatie by immunologic stimuli. J. Immunol. 124: 1426.
Beller, D.I., Unanue, E.R. 1981. Regulation of macrophage populations. II. Synthesis and expression of la antigens by peritoneal exudate macrophages is a transient event. J. Immunol. 126: 263.
Beller, D.I., Unanue, E.R. 1982. Reciprocal regulation of macrophage and T cell function by way of soluble mediators. Lymphokines 6: 25.
Cowing, C., Schwartz, B.D., Dickler, H.B. 1978. Macrophage Ia antigens: I. Macrophage populations differ in their expression of Ia antigens. J. Immunol. 120: 378.
Marino, P.A., Adams, D.O. 1980. Interaction of bacillus calmette-guerin-activated macrophages and neoplastic cells in vitro. I. Conditions of binding and its selectivity. Cell Immunol. 54: 11.
Somers, S.D., Mastin, P.A., Adams, D.O. 1983. The binding of tumor cells by murine mononuclear phagocytes can be divided into two, qualitatively distinct types, J. Immunol. 131: 2086.
Marino, P.A., Whisnant, C.C., Adams, D.O. 1981. The binding of BCG-activated macrophages to tumor targets: selective inhibition by membrane preparations from homologous and heterologous neoplastic cells. J. Exp. Med. 154: 77.
Johnson, W.J., Whisnant, C., Adams, D.O. 1981. The binding of BCG-activated macrophages to tumor targets stimulates secretion of cytolytic factor. J. Immunol. 127: 1787.
Brown, M.S., Goldstein, J.L. 1983. Lipoprotein metabolism in the macrophage: implications for cholesterol deposition in altherosclerosis. Ann. Rev. Biochem. 52: 223.
Johnson, W.J., Pizzo, S.V., Imber, M.J., Adams, D.O. 1982. Receptors for maleylated proteins regulate the secretion of neutral proteases by murine macrophages. Science 218: 574.
Fogelman, A.M., Haverland, M.E., Edwards, P.A. 1984. Low density lipoprotein receptor and scavenger receptors on monocytes and macrophages-modulation by lymphokine. Lymphokines 9: 363.
Nathan, C.F., Silverstein, S.C., Brukner, L.H., Cohn, Z.A. 1979. Extracellular cytolysis by activated macrophages and granulocytes. II. Hydrogen peroxide as a mediator of cytotoxicity. J. Exp. Med. 149: 100.
Adams, D.O., Johnson, W.J., Fiorito, E., Nathan, C.F. 1981. H2O2 and CF can interact synergistically in effecting cytolysis of neoplastic targets. J. Immunol. 127: 1973.
Schlager, S.I., Ohanian, S.H., Boros, T. 1978. Correlation between the ability of tumor cells to resist humoral immune attack and their ability to synthesize lipid. J. Immunol. 120: 463.
Schlager, Si, Ohanian, S.H., Boros, T. 1978. Identification of lipids synthesized and released by tumor cells under attack by antibody and complement. J. Immunol. 120: 1644.
Johnston, R.B., Godzik, C.A., Cohn, Z.A. 1978. Increased superoxide anion production by immunologically activated and chemically elicited macrophages. J. Exp. Med. 148: 115.
Nathan, C.F., Root, R.K. 1977. Hydrogen peroxide release from mouse peritoneal macrophages. Dependence on sequential activation and triggering. J. Exp. Med. 146: 1648.
Szuro-Sudol, A., Murray, H.W., Nathan, C.F. 1982. Suppression of macrophage antimicrobial activity by a tumor cell product. J. Immunol. 131: 384.
Suzo-Sudol, A., Nathan, C.F. 1982. Suppression of macrophage oxidative metabolism by products of malignant and non-malignant cells. J. Exp. Med. 156: 945.
Bonney, R.J., Davies, P. 1984. Possible autoregulatory functions of the secretory products of mononuclear phagocytes. Contemp. Top. Immunobiol. 14: 199.
Adams, D.O. 1980. Effector mechanisms of cytolytically activated macrophages. I. Secretion of neutral proteases and effect of protease inhibitors. J. Immunol. 124: 286.
Adams, D.O., Kao, K.-J., Farb, R., Pizzo, S.V. 1980. Effector mechanisms of cytolytically activated macrophages. II. Secretion of a tumor-selective cytolytic factor by activated macrophage and its relationship to secreted neutral proteases. J. Immunol. 124: 293.
Adams, D.O., Johnson, W., Marino, P.A. 1982. Mechanisms of target recognition and destruction in macrophage-mediated tumor cytotoxicity. Fed. Proc. 41: 115.
Wright, S.D., Silverstein, S.C. 1984. Phagocytosing macrophages exclude proteins from the zones of contact with opsonized targets. Nature 309: 359.
Podack, E.R. 1985. The molecular mechanism of lymphocyte-mediated tumor cell lysis. Immunol. Today 6: 21.
Henkart, P.A., Millard, P.J., Reynolds, G.W., Henkart, M.P. 1984. Cytolytic activity of purified cytoplasmic granules from cytotoxic rat large granular lymphocyte tumors. J. Exp. Med. 160: 75.
Adams, D.O., Nathan, C.F. 1983. Molecular mechanisms operative in cytolysis of tumor cells by activated macrophages. Immunol. Today 4: 166.
Granger, D.L., Taintor, R.R., Cook, J.L., Hibbs, J.B., Jr. 1980. Injury of neoplastic cells by murine macrophages leads to inhibition of mitochondiral respiration. J. Clin. Invest. 65: 357.
Kaplan, A.M., Brown, J., Collins, J.M., Morahan, P S, Snodgrass, M.J. 1978. Mechanism of macrophage-mediated tumor cell cytotoxicity. J. Immunol. 121: 1781.
Johnson, W.J., Somers, S.D., Adams, D.O. 1984. Activation of macrophages for tumor cytotoxicity. In: Contemporary Topics in Immunobiology, (Adams, D.O. and Hanna, M.G., eds.),`Plenum Press, New York, pp. 127–146.
Johnson, W.J., Weiel, J.E., Adams, D.O. 1982. The relationship between secretion of a novel cytolytic protease and macrophage-mediated tumor cytotoxicity. In: Natural Cell-Mediated Immunity. II., (Herberman, R., ed.), Academic Press, New York, pp. 949–954.
Johnson, W.J., Goldfarb, R.H., Van Dyke-Phillips, V., Adams, D.O. 1985. Secretion of a novel cytolytic protease by activated murine macrophages: its properties and role in tumor cytolysis. Lymphokines 11 (in press).
Currie, G.A., Basham, C. 1975. Activated macrophages release a factor which lyses malignant cells but not normal cells. J. Exp. Med. 142: 1600.
Sharma, S.D., Piessens, W.F., Middlebrook, G. 1980. In vitro killing of tumor cells by soluble products of activated guinea pig peritoneal macrophages. Cell. Immunol. 49: 379.
Reidarson, T., Levy, W., Klostergaard, J., Granger, G.A. 1982. Inducible macrophage cytotoxins. I. Biokinetics of activation and release in vitro. Tumor lysis mechanisms involving target cell-binding proteases. J. Natl. Cancer Inst. 69: 879.
Reidarson, T., Granger, G.A., Klostergaard, J. 1982. Inducible macrophage cytotoxins. II. J. Natl. Cancer Inst. 69: 889.
Klostergaard, J., Reidarson, T., Granger, G.A. 1984. Purification of murine macrophage cytotoxin. J. Leuko. Biol. 35: 229.
Destafano, J., Beck, G., Lane, B., Zucker, S. 1982. Role of tumor cell membrane-bound serine proteases in tumor-induced target cytolysis. Cancer Res. 42: 207.
Chapman, H.A., Vavrin, Z., Hibbs, J.B. 1982. Macrophage fibrinolytic activity: identification of two pathways of plasmin formation by intact cells and of a plasminogen activator inhibitor. Cell 28: 653.
Zucker-Franklin, D., Laurie, G., Franklein, E.C. 1981. Demonstration of membrane-bound proteolytic activity on the surface of mononuclear leukocytes. J. Histochem. Cytochem. 29: 451.
Kilborn, R.G., Klostergaard, J., Lopez-Brestein, G. 1984. Activated macrophages secrete a soluble factor that inhibits mitochondrial respiration of tumor cells. J. Immunol. 133: 2597.
Nathan, C.F. 1982. Secretion of oxygen intermediates: role in effector functions of activated macrophages. Fed. Proc. 41: 2206.
Nathan, C.F., Brukner, L.H., Silverstein, S.C., Cohn, Z.A. 1979. Extracellular cytolysis by activated macrophages and granulocytes. I. Pharmacological triggering of effector cells and the release of hydrogen peroxide. J. Exp. Med. 149: 84.
Johnston, P.A., Adams, D.O., Hamilton, T.A. 1985. Regulation of Fc-mediated respiratory burst: long term treatment of murine macrophages with LPS selectively inhibits immune-complex stimulated secretion of H2O2. J. Immunol. 135: 513.
Silverstein, S.C., Michl, J., Nathan, C.F., Horowitz, M. 1980. In: Basic and Clinical Aspects of Granulomatous Diseases, (Boros, D.L. and Yoshida, T., eds.), Elsevier, New York, p. 67.
Trol, W. Witz, G., Goldstein, B., Stone, D., Sugimura, T. 1982. The role of free oxygen radicals in tumor promotion and carcinogenesis. Carcinogenesis 7: 593.
Spragg, R.G., Hyshop, P.A., Schraufstatter, LU., Hinshaw, D.B., Cochrane, C.G. 1985. Oxidant injury of cultured cells results in rapid decreases in intracellular ATP. Fed. Proc. (Abstr.) 44: 1125.
Schraufstatter, I., Hinshaw, D., Hyslop, P., Spragg, R., Cochrane, C. 1985. ADP-ribosylation in cellular oxidant injury. Fed. Proc. (Abstr.) 44: 1125.
Lewis, J.G., Adams, D.O. 1984. Induction of 5,6 saturated thymine bases in NIH-3T3 cells by TPA-stimulated macrophages: role of reactive oxygen intermediates. Manuscript submitted.
Carswell, E.A., Old, L.J., Kassel, L. 1975. An endotoxin-induced serum factor that causes necrosis of tumors. Proc. Natl. Acad. Sci. 72: 3666.
Green, S., Dobijansky, A., Carswell, E.A., Kassel, R.L., Oed, L.J., Fiore, N., Schwartz, M.K. 1976. Partial purification of a serum factor that causes necrosis of tumors. Proc. Natl. Acad. Sci. 73: 381.
Ruff, M.R., Gifford, G.E. 1980. Purification and physio-chemical characterization of rabbit tumor necrosis factor. J. Immunol. 125: 1671.
Matthews, N., Ryley, H.C., Neale, M.L. 1980. Tumor necrosis factor from the rabbit. IV. Purification and chemical characterization. Br. J. Cancer 42: 416.
Kull, F.C., Cuatrecasas, P. 1981. Preliminary characterization of the tumor cell cytotoxin in tumor necrosis serum. J. Immunol. 126: 1279
Pennica, D., Nedwin, G.E., Hayflich, J.S., Seeberg, P.H., Derynch, R., Palladino, M.A., Kohr, W.J., Aggarwal, B.B., Goeddel, D.V. 1984. Human tumor necrosis factor: percursor structure, expression and homology to lymphotoxin. Nature 312: 724.
Heise, E.R., Weiser, R.S. 1969. Factors in delayed sensitivity: lymphocyte and macrophage cytotoxins in the tuberculin reaction. J. Immunol. 103: 570.
Kramer, J.J., Granger, G.A. 1972. The in vitroinduction and release of a cell toxin by immune C57BL/6 mouse peritoneal macrophages. Cell. Immunol. 3: 88.
Reed, W.P., Lucas, Z.J. 1975. Cytotoxic activity of lymphocytes. V. Role of soluble toxin in macrophage-inhibited cultures of tumor cells. J. Immunol. 115: 395.
Matthews, N. 1981. Production of an anti-tumor cytotoxin by human monocytes. Immunol. 44: 135.
Drysdale, B.-E., Zacharchutz, C.M., Shin, H.S. 1983. Mechanism of macrophage-mediated cytotoxicity: production of a soluble factor. J. Immunol. 131: 2362.
Kull, F.C., Cuatrecasas, P. 1984. Necrosin: purification and properties of a cytoxin derived from murine macrophage-like cell line. Proc. Natl. Acad. Sci. 81: 7932.
Mannel, D.N., Falk, W., Meltzer, M.S. 1981. Inhibition of non-specific tumoricidal activity by activated macrophages with antisera against a soluble cytotoxic factor. Infect. Immun. 33: 156.
Matthews, N. 1983. Effect on human monocyte killing of tumor cells of antibody raised against an extracellular monocyte cytotoxin. Immunol. 48: 321.
Gray, P.W., Aggarwal, B.B., Benton, L.V., Bringman, T.S., Hinzel, W.J., Jarrett, J.A., Leung, D.W., Moffat, B., Ng, P., Svedersky, L.P., Palladino, M.A., Nedwin, G.E. 1984. Cloning and expression of cDNA for human lymphotoxin, a lymphokine with tumor necrosis activity. Nature 312: 721.
Currie, G.A. 1978. Activated macrophages kill tumor cells by releasing arginase. Nature 273: 758.
Currie, G.A., Basham, C. 1978. Differential anginase dependence and the selective cytotoxic effecfs of activated macrophages for malignant cells in vitro. Br. J. Cancer 38: 653.
Kung, J.T., Brooks, S.B., Jakway, J.P., Leonard, L.L., Talmage, D.W. 1977. Suppression of in vitrocytotoxic response by macrophages due to induced arginase. J. Exp. Med. 146: 665.
Fishman, M. 1980. Functional heterogeneity among peritoneal macrophages. III. No evidence for the role of arginase in the inhibition of tumor cell growth by supernatant from macrophages or macrophage subpopulation cultures. Cell. Immunol. 55: 174.
Stadecker, M.J., Calderon, J., Karnovsky, M.L., Unanue, E.R. 1977. Synthesis and release of thymidine by macrophages J. Immunol. 119: 1738.
Stadecker, M.J., Unanue, E.R. 1979. The regulation of thymidine secretion by macrophages. J. Immunol. 123: 568.
Mackaness, G.B. 1969. The influence of immunologically committed lymphoid cells of macrophage activity in vivo. J. Exp. Med. 129: 973.
Mackaness, G.B. 1972. The mechanism of macrophage activation. In: Infectious Agents and Host Reactions, ( Mudd, S., ed.), Saunders, Philadelphia, Pa., p. 61.
Hibbs, J.B., Lambert, L.H., Remington, J.S. 1971. Resistance to murine tumor conferred by chronic infection with intracellular protozoa Toxoplasma gondii and Besnoctia jellisoni. J. Infect. Dis. 124: 587.
Hibbs, J.B., Lambvert, L.H., Remington, J.S. 1972. Adjunant induced resistance to tumor development in mice. Proc. Soc. Exp. Bio. Med. 139: 1053.
Alexander, P., Evans, R. 1971. Endotoxin and double stranded RNA render macrophages cytotoxic. Nature New Biology 232: 75.
Cleveland, R.P., Meltzer, M.S., Zbar, B. 1974. Tumor cytotoxicity in vitroby macrophages from mice infected with Mycobacterium bovis strain BCG. J. Natl. Cancer Inst. 52: 1887.
Hibbs, J.B. 1974. Disvrimination between neoplastic and non-neoplastic cells in vitroby activated macrophages. J. Natl. Cancer Inst. 53: 1487.
Hibbs, J.B., Jr. 1974. Heterocytolysis by macrophages activated by bacillus calmette-guerin: lysosome exocytosis into tumor cells. Science 184: 468.
Hibbs, J.B., Jr., Chapman, H.A., Jr., Weinberg, J.B. 1978. The macrophage as an antineoplastic surveillance cell: biological perspectives. J. Reticuloendothel. Soc. 24: 549.
Meltzer, M.S., Stevenson, M.M. 1977. Macrophage function in tumor-bearing mice: tumoricidal function and chemotactic responses of macrophages activated by infection with Mycobacterium Bovis, strain BCG. J. Immunol. 118: 2176.
Meltzer, M.S. 1981. Macrophage activation for tumor cytotoxicity: characterization of priming and trigger signals during lymphokine activation. J. Immunol. 127: 179.
Meltzer, M.S. 1981. Tumoricidal cytotoxicity by lymphokine-activated macrophages: development of macrophage tumoricidal activity requires a sequence of reaction. Lymphokines 3: 319.
Meltzer, M.S., Ruco, L.P., Boraschi, D., Nacy, C.A. 1979. Macrophage activation for tumor cytotoxicity: analysis of intermediary reactions. J. Reticuloendothel. Soc. 26: 403.
Hibbs, J.B., Lambert, L.H., Remington, J.S. 1972. Possible role of macrophage-mediated nonspecific cytotoxicity in tumor resistance. Nature New Biol. 235: 48.
Doe, W.F., Yang, S.T., Morrison, D.C., Betz, S.J., Henson, P.M. 1979. Macrophage stimulation by bacterial lipopolysaccharides. II. Evidence for differentiation signals delivered by Lipid A and by a protein-rich fraction of lipopolysaccharides. J. Exp. Med. 148: 557.
Johnson, W.J., Marino, P.A., Schreiber, R.D., Adams, D.O. 1983. Sequential activation of murine mononuclear phagocytes for tumor cytolysis: differential expression of markers by macrophages in the several stages of development. J. Immunol. 131: 1038.
Ruco, L.P., Meltzer, M.S. 1978. Macrophage activation for tumor cytotoxicity: develop-ment of macrophage cytotoxic activity requires completion of a sequence of short-lived intermediary reactions. J. Immunol. 121: 2035.
Soberman, R.J., Karnovsky, M.L. 1981. Biochemical properties of activated macrophages. Lymphokines 3; 11.
Cohn, Z.A. 1978. The activation of mononuclear phagocytes: fact, fancy, and future. J. Immunol. 121: 813.
Schreiber, R.D., Pace, J.L., Russell, S.W., Altman, A., Katz, D.H. 1983. Macrophage activating factor produced by a T cell hybridoma: physicochemical and biosynthetic resemblance to 7-interferon. J. Immunol. 131: 826.
Adams, D.O., Marino, P. 1984. Activation of mononuclear phagocytes for destruction of tumor cells as a model for study of macrophage development. In: Contemporary Topics in Hematology-Oncology, Vol. III, ( Gordon, A.S., Silber, R., LoBue, J., eds.), Plenum Publishing Corp., NY, pp. 69–136.
Hibbs, J.B. 1973. Activated macrophage nonimmunologic recognition: target cell factors related to contact inhibition. Science 180: 868.
Meltzer, M.S., Tucker, R.W., Breuer, A.C. 1975. Interaction of BCG-activated macrophages with neoplastic and non-neoplastic cell lines in vitro: cine-micrographic analysis. Cell. Immunol. 17: 30.
Piessens, W.F. 1978. Increased binding of tumor cells by macrophages activated in vitrowith lymphocyte mediators. Cell. Immunol. 35: 303.
Hamilton, T.A., Fishman, M. 1981. Characterization of the recognition of target cells sensitive or resistant to cytolysis by activated rat peritoneal macrophages. J. Immunol. 127: 1702.
Somers, S.D., Whisnant, C.C., Adams, D.O. 1985. Manuscript in preparation.
Hamilton, T.A., Becton, D.A., Somers, S.D., Gray, P.W., Adams, D.O. 1985. Interferon gamma modulates protein kinase C activity in murine peritoneal macrophages. J. Biol. Chem. 260: 1378.
Blumberg, P.M. 1980. In vitro studies on the mode of action of the phorbol esters, potent tumor,promoters. CRC Crit. Reviews Toxicol. 8: 153.
Somers, S.D., Adams, D.O. 1985. Manuscript in preparation.
Straussman, G., Springer, T., Adams, D.O. 1985. Manuscript in preparation.
Straussman, G., Springer, T.A., Somers, S.D., Adams, D.O. 1985. Unpublished observations.
Springer, T.A., Davignon, D., Ho, M.K., Kurzinger, K., Mantz, E., Sanchez-Madrid, F. 1982. LFA-1 and LY + 2,3, molecules associated with T-lymphocyte-mediated killing; and Mac-1, and LFA-1 homologue associated with complement receptor functions. Immunol. Rev. 68: 111.
Adams, D.O., Johnson, W.J., Marino, P.A., Dean, J.H. 1983. Pyran copolymer induces incomplete activation of murine macrophages: analysis by use of objective markers that characterize the stages of activation. Cancer Research 43: 3633.
Adams, D.O., Marino, P.A., Meltzer, M.S. 1981. Characterization of genetic deficits in macrophage tumoricidal capacity: identification of murine strains with abnormalities in secretion of cytolytic factor and ability to bind neoplastic targets. J. Immunol. 126: 1843.
Sorrell, T.C., Lehrer, R.I., Cline, M.J. 1978. Mechanism of nonspecific macrophage-mediated cytotocity: evidence for lack of dependence on oxygen. J. Immunol. 120: 347.
Freedman, V.H., Gorrell, T.E., Nathan, C.F., Copeland, C.S., Silverstein, S.C. 1984. Bacillus calmette-guerin-activated murine macrophage kill syngeneic melanoma cells under strict anaerobic conditions. J. Exp. Med. 160: 94.
Nathan, C.F., Murray, H.W., Wiebe, M.E., Rubin, B.Y. 1983. Identification of interferon 7 as the lymphokine that activates human macrophage oxidative metabolism and antimicrobial activity. J. Exp. Med. 158: 670.
Takemura, R., Werb, S. 1984. Secretory products of macrophages and their physiological functions. Am. J. Physiol. 15: 1.
Rinehart, J.J., Vesalla, R., Lange, P., Kaplan, M.E., Gormus, B.J. 1979. Characterization and comparison of human monocyte-and macrophage-induced tumor cytotoxicity. J. Lab. Clin. Med. 93: 361.
Horwitz, D.A., Knight, N., Temple, A., Allison, A.C. 1979. Spontaneous and induced cytotoxic properties of human adherent mononuclear cells: killing of non-sensitized and antibody-coated non-erythroid cells. Immunology 36: 221.
Mantovani, A., Jerrells, T.R., Dean, J.H., Herberman, R.B. 1978. Cytolytic and cytostatic activity on tumor cells by circulating human monocytes. Int. J. Cancer 23: 18.
Kleinerman, E., Herberman, R.B. 1984. Tumoricidal activity of human monocytes: evidence for cytolytic function distinct from that of NK cells. J. Immunol. 133: 4.
Weinberg, J.B., Haney, A.F. 1983. Spontaneous tumor cell killing by human blood monocytes and human peritoneal macrophages: lack of alteration by endotoxin or quenchers of reactive oxygen species. J. Natl. Cancer Inst. 70: 1005.
Freundlich, B., Trinchieri, G., Perussia, B., Zurier, R.B. 1983. Cytotoxic effector cells from human peripheral blood adherent cells. Fed. Proc. 42: 3884.
Horwitz, D.A., Linker-Israeli, A.M., Bakke, A.C., Nishiya, K. 1983. Interferon enhances NK cell activity but not spntaneous cytotoxicity by monocytes. Fed. Proc. 42: 5424.
Kaplan, G. 1983. In vitrodifferentiation of human monocytes. J. Exp. Med. 156: 2063.
Becker, S., Reilly, M. 1984. Tumor cytotoxic and growth stimulatory activities mediated by monocytes and peritoneal macrophages. J. Leuko. Biol. 36: 664 (Abst.).
Fidler, I.J., Kleinerman, E. 1984. Lymphokine-activated human blood monocytes destroy tumor cells but not normal cells under co-cultivation conditons. J. Clin. Incol. 2: 937.
Fischer, D.G., Golightly, M.G., Koren, H.S. 1983. Potentiation of the cytolytic activity of peripheral blood monocytes by lymphokine and interferon. J. Immunol. 130: 1220.
Dean, R.T., Virelizier, J.-L. 1983. Interferon as a macrophage activating factor. I. Enhancement of cytotoxicity by fresh and matured human monocytes in the absence of other soluble signals. Clin. Exp. Immunol. 51: 501.
Le,J., Prensky, W., Yip, Y.K., Chang, Z., Hoffman, T., Stevenson, H.C., Balays, I., Sadlik, J.R., Vilcek, J. 1983. Activation of human monocyte cytotoxicity by natural and recombinant immune interferon. J. Immunol. 131: 2821.
Sone, S., Mutsuuna, S., Ogawara, M., Tsubura, E. 1984. Potentiating effect of muramyl dipeptide and its lipophilic analog encapsulated in liposomes on tumor cell killing by human monocytes. J. Immunol. 132: 2105.
Golightly, M.G., Fischer, D.G., Ohlander, C., Koren, H.S. 1983. Characreristics and requirements of the interaction between human monocytes and tumor cells on the single cell level. Blood 61: 390.
Koren, H.S., Ohlander, C., Muse, K.E. 1982. Spontaneous killing by human monocytes: a functional and morphological analysis. In: Human Cancer Immunology, ( Serrow B., ed.), Elsevier, North Holland Biomedical, Amsterdam.
Sore, S., Lopez-Berestein, G., Fidler, I. 1985. Kinetics and function of tumor cytotoxic factor(s) produced by human blood monocytes activated to the tumoricidal state. J. Natl. Cancer Inst. 74: 583.
Argov, S., Chen, A.R., McKinnon, K.P., Koren, H.S. 1984. Cytolytic cell free supernatants from human monocytes. J. Leuk. Biol. 36: 670 (Abst.).
Mavier, P., Edgington, T.S. 1984. Human monocyte mediated tumor cytotoxicity. I. Demonstration of an oxygen-dependent myeloperoxidase-independent mechanism. J. Immunol. 132: 1980.
Bersani, L., Colotta, F., Poli, G., Mantovani, A. 1984. Mechanism of killing of actinomycin D treated WEHI 164 tumor cells by human peripheral blood monocytes. J. Leuk. Biol. 36: 671 (Abst.).
Andreesen, R., Osterholz, J., Bross, K.J., Schulz, A., Luckenbach, G.A., Löhn, G.W. 1983. Cytotoxic effector cell function at different stages of human monocyte-macrophage maturation. Cancer Res. 43: 5931.
Jett, J.R., Mantovani, A., Herberman, R.B. 1980. Augmentation of human monocyte-mediated cytolysis by interferon. Cell. Immunol. 54: 425.
Biondi, A., Peri, G., Lorenzet, R., Fumarola, D., Mantovani, A. 1983. Role of endotoxin in the expression of human monocyte cytotoxicity. J.R.E.S. 33: 315.
Cameron, D.J., Churchill, W.H. 1980. Cytotoxicity of human macrophages for tumor cells: enhancement by bacterial lipopolysaccharides. J. Immunol. 124: 708.
Koff, W.C., Fidler, I.J., Showalter, S.D., Chakrabarty, M.K., Hamper, B., Ceccorulli, L.M., Kleinerman, E.S. 1984. Human monocytes activated by immunomodulators in liposomes lyse herpesvirus-infected cells but not normal cells. Sci. 224: 1007.
Pabst, M.J., Johnston, R.B. 1980. Increased production of superoxide anion by macrophages exposed in vitroto muramyl dipeptide or lipopolysaccharide. J. Exp. Med. 151: 101.
Pabst, M.J., Hedegard, H.B., Johnston, R.B. 1982. Cultured human monocytes require exposure to bacterial products to maintain an optimal oxygen radial response. J. Immunol. 128: 123.
Seto, M., Takahashi, T., Nakamura, S., Matsudaira, Y., Nishizuka, Y. 1983. In vivo antitumor effects of monoclonal antibodies with different immunoglobulin classes. Cancer Res. 43:4768.
Steplewski, Z., Herlyn, D., Maul, G., Koprowski, H. 1982. Hypothesis: macrophages as effector cells or human tumor destruction mediated by monoclonal antibodies. Hybridoma 2: 1.
Adams, D.O., Hall, T., Steplewski, Z., Koprowski, H. 1984. Tumors undergoing rejection induced by monoclonal antibodies of the IgG2a isotype contain increased numbers of macrophages activated for a distinctive form of antibody-dependent cytolysis. Proc. Nat. Acad. Sci. USA 81: 3506.
Nathan, C., Cohn, Z.A. 1980. Role of oxygen-dependent mechanisms in antibody-induced lysis of tumor cells by activated macrophages. J. Exp. Med. 152: 198.
Koren, H.S., Anderson, S.J., Adams, D.O. 1981. Studies on the antibody-dependent cell-mediated cytotoxicity (ADCC) of thioglycollatge-stimulated and BCG-activated peritoneal macrophages. Cell Immunol. 57: 51.
Koren, H.S., Meltzer, M.S., Adams, D.O. 1981. The ADCC capcity of macrophages from C3H/HEJ and A/J mice can be augmented by BCG. J. Immunol. 126: 1013.
Johnson, W.J., Bolognesi, D., Adams, D.O. 1984. Antibody dependent cytolysis (ADCC) of tumlor cells by activated murine macrophages is a two step process: quantification of target binding and subsequent target lysis. Cell. Immunol. 83: 170.
Shaw, D.R., Griffin, F.M., Jr. 1982. Thioglycollate-elicited mouse peritoneal macrophages are less efficient than resident macrophages in antibody-dependent cell-mediated cytolysis. J. Immunol. 128: 433.
Johnson, W.J., Steplewski, Z., Matthews, T.J., Hamilton, T.A., Koprowski, H., Adams, D.O. 1985. Cytolytic interactions between murine macrophages, tumor cells and monoclonal antibodies: characterization of lytic conditions and requirements for effector activation. Submitted.
Johnson, W.J., Matthews, T.J., Bolognesi, D.P., Adams, D.O. 1985. Antibody-mediated rejection of a murine adenocarcinoma in vivo: quantification of the number and function of intratumoral macrophages. Submitted.
Klassen, D.K., Sagone, A.L. 1980. Evidence for both oxygen and non-oxygen dependent mechanisms of antibody sensitized target cell lysis by human monocytes. Blood 56: 985.
Koller, C.A., LoBuglio, A.F. 1981. Monocyte-meidated antibody dependent cell-mendiated cytotoxicity: the role of the metabolic burst. Blood 58: 293.
Nathan, C.F. 1983. Reactive oxygen intermediates in lysis of antibody-coated targets. In: Macrophage-Mediated Antibody-Dependent Cellular Cytotoxicity, ( Koren, H.S., ed.), Marcel Dekker, New York, p. 199.
Nathan, C.F., Arrick, B.A., Murray, H.W., DeSantis, N.M., Cohn, Z.A. 1981. Tumor cell anti-oxidant defenses inhibition of the glutathione redox cycle enhances macrophage-mediated cytolysis. J. Exp. Med. 153: 766.
Arrick, B.A., Nathan, C.F., Griffith, O.W., Cohn, Z.A. 1982. Glutathione depletion sensitizes tumor cells to oxidative cytolysis. J. Biol. Chem. 257: 1231.
Borregaard, N., Kragballe, K. 1980. Role of oxygen in antibody-dependent cytotoxicity mediated by monocytes and neutrophils. J. Clin. Invest. 66: 677.
Borregaard, N., Kragballe, K. 1980. Role of oxygen in antibody-dependent cytotoxicity mediated by monocytes and neutrophils. J. Clin. Invest. 66: 677.
Yamazaki, M., et al.1976. Two step mechanism of macrophage-mediated tumor lysis in vitro. Gann 67: 741.
Lohmann-Matthes, M.-L., Lang, H., Sun, D. 1982. Macrophages as effector cells. Immunobiol. 161: 401.
Shaw, G.M., Levy, P.C., Lobuglio, A.F. 1978. Human monocyte cytotoxicity to tumor cells. I. Antibody-dependent cytotoxicity. J. Immunol. 121: 573.
Conkling, P., Klassen, D.K., Sagore, A.L. 1982. Comparison of antibody-dependent cytotoxicity mediated by human polymorphonuclear cells, monocytes and alveolar macrophages. Blood 60: 1282.
Conkling, P., Papermaster-Bender, G., Whitcomb, M., Sagore, A.L. 1982. Oxygen dependence of human alveolar macrophage-mediated antibody-dependent cytotoxicity. Infect. Immun. 38: 114.
Sein, S., Esperik, T. 1983. Toxic oxygen species in monocyte-mediated antibody-dependent cytotoxicity. JRES 33: 417.
Esperik, T., Hammerstrom, J. 1983. Human monocyte-mediated antibody-dependent cytotoxicity to K-562 cells an elelctron microscopic study. Acta Path. Microbiol. Immunol. Scand. 91: 211.
Esperik, T. 1985. Human monocyte-mediated lysis of antibody-coated tumor cells: the role of the cytoskeleton in monocytes. J. Immunol. 131: 2017.
Sagone, A.L., Rinehart, J.J. 1984. Human monocyte to macrophage differentiation in vitro: characterization and mechanisms of the increased antibody-dependent cytotoxicity with differentiation. J. Leuko. Biol. 35: 217.
Stuttman, O. 1980. Immunological surveillance and cancer. In: Handbook of Cancer Immunology (H.A. Walters, Ed.) 7: 1.
Fidler, I.J., Poste, G. 1982. Macrophage-mediated destruction of malignant tumor cells and new strategies for the therapy of metastatic disease. Springer Sem. Immunopathol. 5: 161.
Oldham, R.K., Thurman, G.B., Talmadge, J.E., Stevenson, H.C., Foon, K.A. 1984. Lymphokines, monoclonal antibodies and other biological response modifiers in the treatment of cancer. Cancer 54 (Suppl.): 2795.
Celada, A., Gray, P.W., Rinderkrecht, E., Schreiber, R.D. 1984. Evidence for a gamma-interferon receptor that regulates macrophage tumoricidal activity. J. Exp. Med. 160: 55.
Weiel, J., Adams, D.O., Hamilton, T. 1985. Biochemical models of y-interferon activation: altered expression of transferrin receptors on murine peritoneal macrophages following treatment in vitrowith PMA or A23187. J. Immunol. 134: 293.
Somers, S.D., Weiel, J.E., Hamilton, T.A., Adams, D.O. 1985. Phorbol esters and calcium inophore act synergistically to prime murine macrophages for tumoricidal activity. Manuscript submitted.
Weiel, J.E., Hamilton, T.A., Adams, D.O. 1985. Stimulation of protein phosphorylation in murine macrophages by bacterial endotoxin. Manuscript submitted.
Hamilton, T.A., Jasen, M., Somers, S.D., Adams, D.O. 1985. Stimulation of protein synthesis by bacterial endotoxin in murine macrophages. Submitted.
Nishizuka, Y. 1984. The role of protein kinase C in cell surface signal transduction and tumor promotion. Nature 308: 693.
Davis, R.J., Ganong, B.R., Bell, R.M., Czech, M.P. 1985. Structural requirements for diacylglycerols to mimic tumor-promoting phorbol diester action can epidermal growth factor receptor. J. Biol. Chem. 260: 5315.
Schorlemmer, H.U., Allison, A.C. 1976. Effects of activated complement components or enzyme secretion by macrophages. Immunol. 31: 781.
Goodman, M.G., Weigle, W.O., Hugli, T.E. 1980. Inability of the C3a anaphylaxatoxin to promote cellular lysis. Nature 283: 78.
Osserman, E.F., Klockars, M., Halper, J., Fischel, R.C. 1973. Effects of lysozyme on normal and transformed mammalian cells. Nature 243: 331.
Stewart, W.E., Gresser, I., Tovey, M., Bandu, M.T., LeGoff, S. 1976. Identification of the cell multiplication inhibitor factors in interferon preparations as interferon. Nature 262: 300.
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Somers, S.D., Johnson, W.J., Adams, D.O. (1986). Destruction of Tumor Cells by Macrophages: Mechanisms of Recognition and Lysis and Their Regulation. In: Herberman, R.B. (eds) Cancer Immunology: Innovative Approaches to Therapy. Cancer Treatment and Research, vol 27. Springer, Boston, MA. https://doi.org/10.1007/978-1-4613-2629-8_3
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