Increased oxidant resistance of alveolar macrophages isolated from rats repeatedly exposed to cadmium aerosols.

This study investigated potential mechanisms of oxidant resistance in alveolar macrophages (AM) isolated from Lewis rats exposed repeatedly to cadmium aerosols. Macrophages from Cd-adapted animals significantly greater resistance to oxidant-induced cytotoxicity than control cells when challenged with hydrogen peroxide in vitro. Elevations in glutathione peroxidase and glutathione reductase activities were associated with increased oxidant tolerance but catalase activity was unchanged. Metallothionein (MT) expression (protein and mRNA) was dramatically up-regulated in response to in vivo Cd exposure. A study using immunocytochemistry and in situ hybridization techniques revealed significantly heterogeneity in the expression of metallothionein by AMs. The percentage of AMs positive for MT (protein and mRNA) and the degree of MT expression within individual cells increased in response to additional Cd exposures. A putative state of activation was suggested by differences in size and number of inclusion bodies in macrophages from Cd-adapted animals and by secretion of a cytokine with interleukin-1-like characteristics. In summary, AMs from Cd-adapted animals are distinguished from control cells with respect to: (1) increased oxidant resistance, (2) secretion of cytokines, (3) elevations in enzymes associated with glutathione metabolism, and (4) up-regulation in metallothionein expression.

Increased oxidant resistance of alveolar epithelial type II cells. Isolated from rats following repeated exposure to cadmium aerosols.

Alveolar epithelial type II cells (AEIIC) were isolated from male Lewis rats following repeated in vivo cadmium aerosol exposure and were subsequently evaluated for their oxidant resistance in vitro. AEIIC from Cd-adapted animals removed a greater proportion of hydrogen peroxide from the extracellular milieu and incurred less oxidant-induced cytotoxicity than AEIIC from air controls. This altered response to oxidants occurred coincident with changes in cellular resistance factors. A two-fold increase in glutathione peroxidase activity and a 1.5-fold increase in the activities of glutathione reductase and catalase were observed in Cd-adapted AEIIC compared to control cells. These cells also exhibited a dramatic induction of metallothionein (MT), a thiol-rich protein known to scavenge free radicals in vitro. MT concentration increased as a function of exposure number. MT was localized within the nucleus and cytoplasm of AEIIC by immunocytochemical techniques. MT positive cells showed a wide variation of MT content, particularly in the nucleus. The biochemical and physiological features of these AEIIC may explain, in part, why animals pretreated with Cd aerosols develop cross-tolerance to hyperoxia.

In vivo expression of metallothionein in rat alveolar macrophages and type II epithelial cells following repeated cadmium aerosol exposures.

This study examined the ability of alveolar macrophages and alveolar type II epithelial cells to accumulate cadmium (Cd) and to express metallothionein (MT). Lung cells were isolated from Lewis rats repeatedly exposed to a Cd aerosol (1.6 mg Cd/m3). Intracellular Cd concentration rose following Cd exposure and showed an increasing rend as a function of exposure number. Alveolar macrophages accrued approximately four times more Cd than type II epithelial cells similarly exposed. Macrophages and type II cells responded to the presence of intracellular Cd by increasing MT protein levels. MT concentration was highly correlated with intracellular Cd. Immunocytochemical studies revealed that not all macrophages and type II cells from Cd-exposed animals were immunopositive for MT and that the intensity of immunostaining varied within each cell population. Although a greater percentage of macrophages were immunopositive for MT than type II cells, a greater proportion of type II cells showed moderate and dark MT staining patterns. Oligonucleotide probes, shown to distinguish between MT-1 and MT-2 mRNA isoforms, were used to test for cell-specific differences in MT isoform gene expression. The basal level of MT-1 mRNA was greater in macrophages than in type II cells. Following Cd administration, the level of MT-1 mRNA and MT-2 mRNA increased in each cell class but the response to Cd was three times greater in alveolar macrophages. Neither macrophages nor type II cells expressed MT mRNA isoforms in equal proportions. Macrophages expressed more MT-1 mRNA when exposed to air and more MT-2 mRNA in response to Cd exposure. Type II cells, on the other hand, expressed more MT-2 mRNA than MT-1 mRNA regardless of whether the cells were exposed to air or Cd. In conclusion, the present study has demonstrated that (1) alveolar macrophages and type II cells respond to in vivo Cd exposure by increasing MT protein and mRNA levels; (2) MT expression is greater in macrophages than in type II cells and correlates well with intracellular Cd concentration; and (3) the MT-2 mRNA to MT-1 mRNA ratio is cell and treatment specific.

Oxidant resistance of cadmium-adapted human lung fibroblasts.

Metallothionein (MT) is a metal and thiol-rich protein readily induced by cadmium (Cd) exposure. In vitro experiments have demonstrated that MT is able to serve as a scavenger of hydroxyl radicals as well as superoxide anions, albeit to a lesser extent. The role of MT as a mediator in Cd induced oxidant resistance was investigated in a nontransformed human lung fibroblast cell line (IMR-90). Cells were passaged three times either in a Cd-containing medium (8.9 microM CdCl2) or in a medium which lacked Cd. Cellular MT content, as quantitated by a modification of the heme/109Cd binding assay, increased significantly with each passage in Cd. Immunocytochemistry studies revealed that all Cd-pretreated cells contained MT and that MT was localized in both cytoplasmic and nuclear compartments. Immunolabeling was more intense in some cells compared to others. Very slight immunolabeling was observed in physiological control cells, grown in the absence of Cd, and virtually no staining was observed in Cd-adapted or non-adapted cells when primary antibody was omitted. Using the xanthine/xanthine oxidase system as a generating system for active oxygen species, we found that the magnitude of cell injury for Cd-adapted and non-adapted fibroblasts was dependent upon oxidant concentration and duration of oxidant exposure. Cd-adapted fibroblasts, which were characterized by over-expression of MT, were significantly more resistant to injury by active oxygen species and also exhibited a greater ability to scavenge extracellular hydrogen peroxide compared to cells with no previous history of Cd exposure. Experiments with aminotriazole demonstrated that catalase was not a major contributor to the additional hydrogen peroxide scavenging capacity of Cd-adapted cells. The data presented in this report are consistent with involvement of MT in protecting critical cellular targets from reactive oxygen species.