The contribution of interstitial macrophages (IM) to lung defense, homeostasis, and pathophysiology is for the most part unknown. Studies on this cell type are difficult because they are not readily accessible in large numbers or in high purity. In the present work, various nonenzymatic and enzymatic methods were compared with the aim of isolating and characterizing pure populations of lung IM. The results of our studies demonstrate that most procedures currently used to isolate IM yield subpopulations of alveolar macrophages (AM) or IM highly contaminated by AM and granulocytes. We found that lavage of the lung yielded only one half of the total AM present in the tissue. The remainder of the AM could only be obtained by extensive washing of cut and disaggregated lung tissue, which is considered by some investigators to be an effective procedure for IM isolation. According to our results, cells recovered by lavage and washing of cut and disaggregated lung tissue were morphologically and histochemically identical, were strongly positive for nonspecific esterase, highly phagocytic, and appeared to represent subpopulations of AM with apparently varying degrees of adherence to the alveolar walls. We also found that IM could be obtained in high purity by sequential digestion of the remaining lung tissue with 60 and 175 IU/ml of collagenase followed by selective adherence. Digestion of the tissue with 60 IU/ml of collagenase resulted in a highly enriched population of granulocytes and also reduced their contamination in the IM population. The resulting IM were distinct from AM by morphology and histochemistry. Like AM, these cells displayed Fc receptor-mediated phagocytosis.(ABSTRACT TRUNCATED AT 250 WORDS)
The specific function of interstitial macrophages (IM) in the lung is poorly understood because of difficulties in isolating these cells in high purity or large number. In the present studies, a pure population of enzymatically isolated IM and lung macrophages obtained mechanically from the lung were compared functionally with alveolar macrophages recovered by lavage (AM). Macrophages isolated mechanically from the tissue and AM displayed similarly high levels of Fc-receptor mediated phagocytosis. In contrast, IM phagocytized significantly fewer opsonized sheep red blood cells per macrophage than AM. In addition, although some variations in the amounts of nitric oxide and superoxide anion produced by AM and macrophages obtained by mechanical tissue disruption were observed, these subpopulations released significantly more of these mediators than IM. These data support the concept that macrophages isolated by mechanical disruption of the tissue represent a subpopulation of AM. We also found that, in contrast to AM, IM did not respond synergistically to combinations of IFN-gamma and lipopolysaccharide (LPS) or tumor necrosis factor alpha in terms of nitric oxide production. Furthermore, regulation of superoxide anion release in AM and IM by LPS and/or IFN-gamma was distinct. Taken together, these studies demonstrate that IM are functionally different from other macrophage subpopulations which might reflect their unique location within the lung.
A characteristic reaction of the lung to inhaled ozone is an increase in the number of type II epithelial cells and alveolar macrophages (AMs). In the present study, we analyzed mechanisms regulating this response. Acute exposure of rats to ozone (2 parts/million, 3 h) induced expression of proliferating cell nuclear antigen, a marker of cellular proliferation, in both type II cells and AMs. This was maximum 48 h after ozone inhalation. Type II cells and AMs isolated from treated rats at this time also incorporated significantly more [3H]thymidine ([3H]TdR) than cells from control animals. When type II cells and AMs were cocultured, a synergistic increase in [3H]TdR uptake was observed. This appeared to be due to increased DNA synthesis by both cell types. Thus [3H]TdR incorporation by type II cells and AMs cocultured with mitomycin C-treated AMs and type II cells, respectively, was elevated compared with cells cultured alone. Type II cells and AMs plated onto tissue culture inserts, as well as culture supernatants from these cells, were found to stimulate DNA synthesis in AMs and type II cells, respectively. In addition, crude membrane preparations from these cells exhibited growth-promoting activity. Thus the mitogenic effects of both cell types appeared to be mediated by soluble factors and membrane-associated molecules. Ozone inhalation resulted in an increase in the mitogenic activity of AMs treated with mitomycin C and plated on tissue culture inserts toward type II cells and of type II cell culture supernatants toward AMs. These data suggest that type II cell and AM proliferation contributes to the regulation of the number of cells in the lung under normal homeostatic conditions and after ozone-induced injury. Moreover, type II cells and AMs produce paracrine mediators that contribute to cellular proliferative responses.
Abstract:Nitric oxide has been shown to contribute to cytotoxicity in mouse and rat tumor cells.
Nitric oxide has been implicated as an important effector molecule involved in tumor cell growth and cytotoxicity. In these studies we examined mechanisms regulating nitric oxide production by hamster tumor cells. Cocultures of hamster alveolar macrophages (HAM) and spontaneously transformed hamster embryonic fibroblasts (STHE cells) produced significant quantities of nitric oxide in response to lipopolysaccharide (LPS). Culture supernatants from HAM treated with LPS also stimulated nitric oxide production by STHE cells, whereas tumor cell culture supernatants had no effect on HAM. These data, together with the findings that paraformaldehyde treatment of STHE cells, but not macrophages, completely abrogated nitric oxide production in the cocultures demonstrate that the tumor cells were the source of this mediator. In contrast to STHE cells, STHE-83/20 cells, a highly malignant variant, did not produce nitric oxide in response to HAM or HAM culture supernatants even in the presence of LPS. Both anti-tumor necrosis factor-alpha (TNF-alpha) and anti-interleukin-1alpha (IL-1alpha) antibodies inhibited HAM-induced nitric oxide production by STHE cells. However, the kinetics of their effects were different. Moreover, although the nitric oxide stimulating activity in HAM culture supernatants was abrogated by anti-TNF-alpha antibody, it was only minimally reduced by anti-IL-1alpha antibody. These data demonstrate that TNF-alpha and IL-1alpha play distinct roles in induction of nitric oxide synthesis in STHE cells. HAM were also found to suppress proliferation of STHE cells, an effect that was inhibited by anti-TNF-alpha antibody, but not NG-monomethyl-L-arginine, which blocks nitric oxide synthase. Abrogation of macrophage-induced cytostasis in STHE cells by anti-TNF-alpha antibody was associated with decreased nitric oxide production. Thus TNF-alpha released by macrophages may indirectly activate STHE cells for nitric oxide synthesis by suppressing tumor cell proliferation.
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