Enhanced Macrophage Anti-Microbial Activity Following Dimethylnitrosamine Exposurein Vivois Related to Augmented Production of Reactive Oxygen Metabolites

Abstract

Previous results demonstrated that mice exposed in vivo to DMN were more resistant to both bacterial and tumor challenges. Furthermore, macrophages (M phi) isolated from these animals demonstrated increased functional properties. As reactive oxygen intermediates (ROI) represent a key mechanism of anti-microbial action, it was important to determine whether ROI levels in M phi were related to augmented anti-microbial action in animals exposed to DMN in vivo. Peritoneal exudate M phi elicited with either thioglycollate (TG), Con A or C. parvum (CP) were examined for the production of ROIs. TG-M phi, Con A-M phi and CP-M phi obtained from animals exposed to DMN showed increased superoxide anion (O2-) production in vitro following stimulation with either phorbol myristate acetate (PMA) or opsonized zymosan (Op-zym) when compared to vehicle M phi. ROI production by bone marrow-derived macrophages (BMDM) produced by either GM-CSF or CSF-1 was also determined. BMDM from DMN-exposed animals obtained using either growth factor, had increased ROI production at 3, 5, 7 and 9 d of culture compared to vehicle BMDM. There was no shift in the kinetics of ROI production during differentiation of these BMDM. Analysis of extracellular anti-listericidal activity of TG- and CA-elicited M phi demonstrated that only TG-M phi obtained from DMN-exposed animals had enhanced killing capacity. There were no differences in intracellular anti-microbial activity in TG- and CA-elicited M phi obtained from either vehicle or DMN-exposed animals. TG-elicited M phi from either vehicle or DMN-exposed animals were examined for anti-microbial activity and H2O2 production following in vitro exposure to PMA. M phi from both vehicle and DMN treatment groups had enhanced killing and H2O2 production following PMA treatment, while PMA-stimulated TG-M phi from DMN-exposed animals demonstrated significantly higher levels of H2O2 production and cell killing as compared to all other treatment groups. These results suggest that previously observed increases in anti-microbial action by M phi from DMN-exposed animals are due in-part to enhanced ROI production.