Molecular analysis of TNF sensitivity in normal and Ha-{\it ras\/} transformed murine fibroblasts

Tumor necrosis factor (TNF) is known to have antiproliferative effects on a wide variety of tumor cells but proliferative effects on normal cells. However, the molecular basis for such differences in the action of TNF are unknown. The overall objectives of my research are to investigate the role of oncogenes in TNF sensitivity and delineate some of the molecular mechanisms involved in TNF sensitivity and resistance. To accomplish these objectives, I transfected TNF-resistant C3H mouse embryo fibroblasts (10T1/2) with an activated Ha-ras oncogene and determined whether these cells exhibit altered sensitivity to TNF. The results indicated that 10T1/2 cells transfected with an activated Ha-ras oncogene (10T-EJ) not only produced tumors in nude mice but also exhibited extreme sensitivity to cytolysis by TNF. In contrast, 10T1/2 cells transfected with the pSV2-neo gene alone were resistant to the cytotoxic effects of TNF. I also found that TNF-induced cell death was mediated through apoptosis. The differential sensitivity of 10T1/2 and 10T-EJ cell lines to TNF was not due to differences in the number of TNF receptors on their cell surface. In addition, TNF-resistant revertants isolated from Ha-ras-transformed, TNF-sensitive cells still expressed the same amount of p21 as TNF-sensitive cells and were still tumorigenic, suggesting that Ha-ras-induced transformation and TNF sensitivity may follow different pathways. Interestingly, TNF-resistant but not sensitive cells expressed higher levels of bcl-2, c-myc, and manganese superoxide dismutase (MnSOD) mRNA following exposure to TNF. However, TNF treatment resulted in a marginal induction of p53 mRNA in both TNF-sensitive and resistant cells. Based on these results I can conclude that (i) Ha-ras oncogene induces both transformation and TNF sensitivity, (ii) TNF-induced cytotoxicity involves apoptosis, and (iii) TNF-induced upregulation of bcl-2, c-myc, and MnSOD genes is associated with TNF resistance in C3H mouse embryo fibroblasts. ^

INHIBITION OF THE MITOCHONDRIAL RESPIRATION OF TUMOR CELLS BY SOLUBLE FACTORS RELEASED BY ACTIVATED MACROPHAGES (CYTOTOXICITY, ELECTRON TRANSPORT, MONOCYTE)

Particular interest has been directed towards the macrophage as a primary antineoplastic cell due to its tumoricidal properties in vitro and the observation that an inverse relationship exists between the number of macrophages infiltrating a tumor and metastatic potential. The mechanism of macrophage-mediated injury of tumor cells remains unknown. Recently, it has been shown that injured tumor cells have defective mitochondrial respiration. Our studies have shown that activated macrophages can release soluble factors which can alter tumor cell respiration.^ The effects of a conditioned supernatant (CS) from cultures of activated macrophages on tumor cell (TC) mitochondrial respiration was studied. CS was obtained by incubation of BCG-elicited, murine peritoneal macrophage with RPMI-1640 supplemented with 10% FCS and 50 ng/ml bacterial endotoxin. This CS was used to treat cultures of EMT-6 TC for 24 hours. Mitochondrial respiration was measured polarigraphically using a Clark-type oxygen electrode. Cell growth rate was assessed by ('3)H-Thymidine incorporation. Exposure of EMT-6 TC to CS resulted in the inhibition of malate and succinate oxidation 76.6% and 72.9%, respectively. While cytochrome oxidase activity was decreased 61.1%. This inhibition was accompanied by a 98.8% inhibition of DNA synthesis (('3)H-Thymidine incorporation). Inhibition was dose-related with a 21.3% inhibition of succinate oxidase from a 0.3 ml dose of CS and a 50% inhibition with 1.0 mls. Chromatography of CS on Sephacryl S-200 resulted in isolation of an 80,000 and a 55,000 dalton component which contained the respiration inhibiting activity (RIF). These factors were distinct from a 120,000 dalton cytolytic factor determined by bioassay on Actinomycin-D treated L929 cells. RIF activity was also distinct from several other cytostatic factors but was itself associated with 2 peaks of cytostatic activity. Characterization of the RIF activity showed that it was destroyed by trypsin and heat (100(DEGREES)C, 5 min). It was stable over a broad range of pH (4-9) and its production was inhibited by cycloheximide. The RIF did not have a direct effect on isolated mitochondria of TC nor did it induce the formation of a stable intracellular toxin for mitochondria.^ In conclusion, activated macrophages synthesize and secrete an 80,000 and a 55,000 dalton protein which inhibits the mitochondrial metabolism of TC. These factors induce a cytostatic but not a cytolytic effect on TC.^ The macrophage plays a role in the control of normal and tumor cell growth and in tissue involution. Inhibition of respiration may be one mechanism used by macrophages to control cell growth.^

DEVELOPMENT AND APPLICATION OF SHORT-TERM MUTAGENICITY AND CYTOTOXICITY BIOASSAYS FOR INTEGRATED HEALTH ASSESSMENT STUDIES OF COAL FLY ASH EMISSIONS

Two respirable coal fly ash samples ((LESSTHEQ) 3(mu)m), one from a pressurized fluidized-bed combustion miniplant and one from a conventional combustion power plant, were investigated for physical properties, chemical composition and biological activity. Electron microscopy illustrated irregularity in fluidized-bed combustion fly ash and sphericity in conventional combustion fly ash. Elemental analysis of these samples showed differences in trace elements. Both fly ash samples were toxic in rabbit alveolar macrophage and Chinese hamster ovary cell systems in vitro. The macrophages were more sensitive to toxicity of fly ash than the ovary cells. For measuring the cytotoxicity of fly ash, the most sensitive parameters were adenosine triphosphate in the alveolar macrophage system and viability index in the hamster ovary system. Intact fluidized-bed combustion fly-ash particles showed mutagenicity only in strains TA98 and TA1538 without metabolic activation in the Ames Salmonella assay. No mutagenicity was detected in bioassay of conventional combustion fly ash particles. Solvent extraction yielded more mass from fluidized-bed combustion fly ash than from conventional combustion fly ash. The extracts of fluidized-bed combustion fly ash showed higher mutagenic activity than conventional combustion fly ash. These samples contained direct-acting, frameshift mutagens.^ Fly ash samples collected from the same fluidized-bed source by cyclones, a fabric filter, and a electrostatic precipitator at various temperatures were compared for particle size, toxicity, and mutagenicity. Results demonstrated that the biological activity of coal fly ash were affected by the collection site, device, and temperature.^ Coal fly ash vapor-coated with 1-nitropyrene was developed as a model system to study the bioavailability and recovery of nitroaromatic compounds in fly ash. The effects of vapor deposition on toxicity and mutagenicity of fly ash were examined. The nitropyrene coating did not significantly alter the ash's cytotoxicity. Nitropyrene was bioavailable in the biological media, and a significant percentage was not recovered after the coated fly ash was cultured with alveolar macrophages. 1-Nitropyrene loss increased as the number of macrophages was increased, suggesting that the macrophages are capable of metabolizing or binding 1-nitropyrene present in coal fly ash. ^