The role of inflammation, oxidative stress, and proliferation in silica-induced lung disease: a species comparison.

To gain a better understanding of the complex mechanisms at work in silica-induced lung disease, we conducted studies comparing the rat and hamster response to silica (alpha-quartz). It has been hypothesized that the rat lung response to low-solubility particles, such as silica, may be due to the recruitment, activation, and subsequent release of damaging mediators by the inflammatory cells. Studies have suggested that hamsters and mice may be less sensitive to the inflammatory and tumorigenic effects of these low-solubility particles than rats. Differences in defense mechanisms, such as antioxidant levels or repair mechanisms, may play a key role in how different species respond to these particles. To investigate species differences in silica-induced lung response, this study compared the effects of alpha-quartz on rats and hamsters. Briefly, rats and hamsters were intratracheally instilled with saline or 0.2, 2, or 20 mg of alpha-quartz. Seven days after exposure, bronchoalveolar lavage (BAL) was performed, and the BAL fluid was evaluated for cell number, type, and LDH. In addition, lung tissue was evaluated for the expression of various pro- and anti-inflammatory mediators. Both species showed dose-related increases in neutrophils and LDH after alpha-quartz exposure; however, the changes were significantly greater in the rat, and rats showed greater expression of several pro-inflammatory mediators and lower levels of the anti-inflammatory mediators. These differences in pro- and anti-inflammatory mediators may contribute to the apparent species differences in tumor response. A basic understanding of the different responses of various species to these inhaled toxins will contribute to our understanding of the mechanisms involved in human disease.

Mitochondrial-derived oxidants and quartz activation of chemokine gene expression.

Macrophage inflammatory protein 2 (MIP-2) is a chemotactic cytokine which mediates neutrophil recruitment in the lung and other tissues. Pneumotoxic particles such as quartz increase MIP-2 expression in rat lung and rat alveolar type II epithelial cells. Deletion mutant analysis of the rat MIP-2 promoter demonstrated quartz-induction depended on a single NFkappaB consensus binding site. Quartz activation of NFkappaB and MIP-2 gene expression in RLE-6TN cells was inhibited by anti-oxidants suggesting the responses were dependent on oxidative stress. Consistent with anti-oxidant effects, quartz was demonstrated to increase RLE-6TN cell production of hydrogen peroxide. Rotenone treatment of RLE-6TN cells attenuated hydrogen peroxide production, NFkappaB activation and MIP-2 gene expression induced by quartz indicating that mitochondria-derived oxidants were contributing to these responses. Collectively, these findings indicate that quartz and crocidolite induction of MIP-2 gene expression in rat alveolar type II cells results from stimulation of an intracellular signaling pathway involving increased generation of hydrogen peroxide by mitochondria and subsequent activation of NFkappaB.

Pulmonary chemokine and mutagenic responses in rats after subchronic inhalation of amorphous and crystalline silica.

Chronic inhalation of crystalline silica can produce lung tumors in rats whereas this has not been shown for amorphous silica. At present the mechanisms underlying this rat lung tumor response are unknown, although a significant role for chronic inflammation and cell proliferation has been postulated. To examine the processes that may contribute to the development of rat lung tumors after silica exposure, we characterized the effects of subchronic inhalation of amorphous and crystalline silica in rats. Rats were exposed for 6 h/day, on 5 days/week, for up to 13 weeks to 3 mg/m(3) crystalline or 50 mg/m(3) amorphous silica. The effects on the lung were characterized after 6.5 and 13 weeks of exposure as well as after 3 and 8 months of recovery. Exposure concentrations were selected to induce high pulmonary inflammatory-cell responses by both compounds. Endpoints characterized after silica exposure included mutation in the HPRT gene of isolated alveolar cells in an ex vivo assay, changes in bronchoalveolar lavage fluid markers of cellular and biochemical lung injury and inflammation, expression of mRNA for the chemokine MIP-2, and detection of oxidative DNA damage. Lung burdens of silica were also determined. After 13 weeks of exposure, lavage neutrophils were increased from 0.26% (controls) to 47 and 55% of total lavaged cells for crystalline and amorphous silica, with significantly greater lavage neutrophil numbers after amorphous silica (9.3 x 10(7) PMNs) compared to crystalline silica (6.5 x 10(7) PMNs). Lung burdens were 819 and 882 microg for crystalline and amorphous silica, respectively. BAL fluid levels of LDH as an indicator of cytotoxicity were twice as high for amorphous silica compared to those of crystalline silica, at the end of exposure. All parameters remained increased for crystalline silica and decreased rapidly for amorphous silica in the 8-month recovery period. Increased MIP-2 expression was observed at the end of the exposure period for both amorphous and crystalline silica. After 8 months of recovery, those markers remained elevated in crystalline silica-exposed rats, whereas amorphous silica-exposed rats were not significantly different from controls. A significant increase in HPRT mutation frequency in alveolar epithelial cells was detected immediately after 13 weeks of exposure to crystalline, but not to amorphous silica. A significant increase in TUNEL staining was detected in macrophages and terminal bronchiolar epithelial cells of amorphous silica-exposed rats at the end of the exposure period; however, crystalline silica produced far less staining. The observation that genotoxic effects in alveolar epithelial cells occurred only after crystalline but not amorphous silica exposure, despite a high degree of inflammatory-cell response after subchronic exposure to both types of silica, suggests that in addition to an inflammatory response, particle biopersistence, solubility, and direct or indirect epithelial cell cytotoxicity may be key factors for the induction of either mutagenic events or target cell death.

Intratracheal instillation as an exposure technique for the evaluation of respiratory tract toxicity: uses and limitations.

The evaluation of respiratory tract toxicity from airborne materials frequently involves exposure of animals via inhalation. This provides a natural route of entry into the host and, as such, is the preferred method for the introduction of toxicants into the lungs. However, for various reasons, this technique cannot always be used, and the direct instillation of a test material into the lungs via the trachea has been employed in many studies as an alternative exposure procedure. Intratracheal instillation has become sufficiently widely used that the Inhalation Specialty Section of the Society of Toxicology elected to develop this document to summarize some key issues concerning the use of this exposure procedure. Although there are distinct differences in the distribution, clearance, and retention of materials when administered by instillation compared to inhalation, the former can be a useful and cost-effective procedure for addressing specific questions regarding the respiratory toxicity of chemicals, as long as certain caveats are clearly understood and certain guidelines are carefully followed.

TNFalpha and MIP-2: role in particle-induced inflammation and regulation by oxidative stress.

The cytokine tumor necrosis factor alpha (TNFalpha) plays a critical role in particle-induced inflammation in the lung. TNFalpha production by macrophage can be stimulated by a variety of noxious particles and initiate a cascade of responses involving adhesion molecule expression and production of chemotactic cytokines which ultimately result in the infiltration of inflammatory cells to site of infection or tissue injury in the respiratory tract. Regarding chemotactic cytokines, TNFalpha is a potent agonist of chemokine expression in both immune and non-immune cells (e.g. epithelial cells, fibroblasts). The chemokine macrophage inflammatory protein-2 (MIP-2) plays a major role in mediating the neutrophilic inflammatory response of the rodent lung to particles such as quartz, crocidolite asbestos, as well as high doses of other relative innocuous dusts such as titanium dioxide. The documented sources of MIP-2 in the rodent lung after particle exposure include macrophages as well as epithelial cells. Recent studies indicate that expression of the MIP-2 gene in rat lung epithelial cells is dependent on the transcription factor NFkappaB and is regulated, in part, by oxidative stress induced by particle exposure.

Inhibition of pulmonary neutrophil trafficking during endotoxemia is dependent on the stimulus for migration.

In rat models of Gram-negative pneumonia, pulmonary emigration of neutrophils (polymorphonuclear leukocytes [PMNs]) is blocked when rats are made endotoxemic by an intravenous administration of endotoxin (lipopolysaccharide [LPS]). To test whether dysfunctional PMN migratory responses in the endotoxemic rat are specific for airway endotoxin, we gave rats intrapulmonary stimuli known to elicit different adhesion pathways for pulmonary PMN migration. Sprague-Dawley rats were treated intravenously with either saline or LPS and then instilled intratracheally with either sterile saline, LPS from Escherichia coli, interleukin (IL)-1, hydrochloric acid (HCl), zymosan-activated serum (ZAS), or lipoteichoic acid (LTA). Three hours later, accumulation of PMNs and protein in bronchoalveolar lavage fluid (BALF) were assessed. BALF PMN accumulation in response to intratracheal treatment with LPS (100%), IL-1 (100%), ZAS (40%), and LTA (58%) was inhibited by endotoxemia. In rats given intratracheal HCl, BALF PMN numbers were unaffected by intravenous LPS. The pattern of inhibition of migration suggests that intravenous LPS only inhibits migration in response to stimuli for which migration is CD18-dependent. In contrast to PMN migration, BALF protein accumulation was inhibited by intravenous LPS only when IL-1 or LPS was used as the intratracheal stimulus. To characterize further the differential responses to the various airway stimuli, the appearance in BALF of tumor necrosis factor-alpha (TNF-alpha) and the PMN chemokine macrophage inflammatory protein (MIP)-2 was measured. Accumulation of PMNs in BALF correlated with the BALF concentrations of MIP-2 (r = 0.846, P < 0.05) and TNF (r = 0.911; P < 0.05). The ability of intravenous LPS to inhibit pulmonary PMN migration correlated weakly with MIP-2 (r = 0.659; P < 0.05) and with TNF (r = 0.413; P > 0.05) concentrations in BALF. However, this correlation was strengthened for TNF (r = 0.752; P < 0.05) when data from IL-1-treated animals were excluded. Thus, the presence in BALF of inflammatory mediators that are known to promote CD18-mediated migration correlates with endotoxemia-related inhibition of PMN migration. Furthermore, the pattern of inhibition of pulmonary PMN migration during endotoxemia is consistent with the CD18 requirement of each migratory stimulus.

Interleukin-10 regulates quartz-induced pulmonary inflammation in rats.

Interleukin-10 (IL-10) can downregulate expression of several proinflammatory cytokines including chemokines. This study investigated the role of IL-10 in the acute response of the rat lung to quartz particles. Intratracheal instillation of rats with 1 mg of quartz produced an inflammatory and cytotoxic response demonstrated by increased bronchoalveolar lavage (BAL) fluid neutrophils, lactate dehydrogenase, and protein. IL-10 was detected in rat lung, but IL-10 levels were not altered by quartz. In contrast, quartz increased lung levels of the chemokine macrophage inflammatory protein-2 (MIP-2). Treatment with recombinant murine IL-10 (rmIL-10) attenuated quartz-induced pulmonary inflammation and injury. Pretreatment with anti-IL-10 antiserum enhanced inflammatory responses to quartz. Consistent with effects on quartz-induced inflammation, rmIL-10 and anti-IL-10 serum decreased and increased, respectively, lung MIP-2 mRNA and protein in response to quartz. Additionally, rmIL-10 reduced production of hydrogen peroxide, superoxide anion, and nitric oxide by BAL cells from quartz-exposed and control rats. These results demonstrate that IL-10 is expressed in rat lung and downregulates quartz-induced inflammation and cell activation. The mechanism of the anti-inflammatory action of IL-10 after quartz administration involves, at least in part, attenuation of MIP-2 expression.

Crocidolite activates NF-kappa B and MIP-2 gene expression in rat alveolar epithelial cells. Role of mitochondrial-derived oxidants.

Nuclear factor kappa B (NF-kappa B) is a transcription factor that regulates expression of several genes coding for inflammatory and immunoregulatory proteins including the neutrophil chemotactic cytokine MIP-2. In previous studies we found that crocidolite asbestos activates the nuclear translocation of NF-kappa B as well as MIP-2 gene expression in rat alveolar type II cells. Here we report that both crocidolite-induced NF-kappa B activation of MIP-2 gene expression can be attenuated by the antioxidant tetramethylthiourea, suggesting the dependence of these responses on oxidative stress. Crocidolite exposure of RLE-TN cells also increased production of H2O2, a response that was inhibited by the mitochondrial respiratory chain inhibitor thenoyltrifluoroacetone (TTFA). TTFA treatment of RLE-6TN cells also inhibited crocidolite-induced nuclear translocation of NF-kappa B and MIP-2 gene expression. These results indicate crocidolite exposure of rat alveolar type II cells results in increased production of mitochondrial-derived hydrogen peroxide and that mitochondrial-derived oxidants contribute to crocidolite activation of NF-kappa B and increases in MIP-2 gene expression.

Modulation of mitochondrial gene expression in pulmonary epithelial cells exposed to oxidants.

Oxidants are important in the regulation of signal transduction and gene expression. Multiple classes of genes are transcriptionally activated by oxidants and are implicated in different phenotypic responses. In the present study, we performed differential mRNA display to elucidate genes that are induced or repressed after exposure of rat lung epithelial (RLE) cells to H2O2 or crocidolite asbestos, a pathogenic mineral that generates oxidants. After 8 or 24 hr of exposure, RNA was extracted, reverse transcribed, and amplified by polymerase chain reaction with degenerate primers to visualize alterations in gene expression. The seven clones obtained were sequenced and encoded the mitochondrial genes, NADH dehydrogenase subunits ND5 and ND6, and 16S ribosomal RNA. Evaluation of their expression by Northern blot analysis revealed increased expression of 16S rRNA after 1 or 2 hr of exposure to H2O2. At later time periods (4 and 24 hr), mRNA levels of 16S rRNA and NADH dehydrogenase were decreased in H2O2-treated RLE cells when compared to sham controls. Crocidolite asbestos caused increases in 16S rRNA levels after 8 hr of exposure, whereas after 24 hr of exposure to asbestos, 16S rRNA levels were decreased in comparison to sham controls. In addition to these oxidants, the nitric oxide generator spermine NONOate caused similar decreases in NADH dehydrogenase mRNA levels after 4 hr of exposure. The present data and previous studies demonstrated that all oxidants examined resulted in apoptosis in RLE cells during the time frame where alterations of mitochondrial gene expression were observed. As the mitochondrion is a major organelle that controls apoptosis, alterations in expression of mitochondrial genes may be involved in the regulation of apoptosis.

Chemokine regulation of ozone-induced neutrophil and monocyte inflammation.

Pulmonary inflammation has been observed in humans and in many animal species after ozone exposure. Inflammatory cell accumulation involves local synthesis of chemokines, including neutrophil chemoattractants such as macrophage inflammatory protein-2 (MIP-2), and monocyte chemoattractants, such as monocyte chemoattractant protein-1 (MCP-1). To better understand the mechanism of ozone-induced inflammation, we exposed mice and rats to ozone for 3 h and measured MIP-2 and MCP-1 gene expression. In C57BL/6 mice, steady-state mRNA levels for MCP-1 in the lung increased at 0.6 parts/million (ppm) ozone and were maximal at 2.0 ppm ozone. After exposure to 2 ppm ozone, MIP-2 mRNA levels peaked at 4 h postexposure, whereas MCP-1 mRNA levels peaked at 24 h postexposure. Neutrophils and monocytes recovered in bronchoalveolar lavage fluid peaked at 24 and 72 h, respectively. The accumulation of monocytes was thus delayed relative to that of neutrophils, consistent with the sequential expression of the corresponding chemokines. The role of MCP-1 in monocyte accumulation was evaluated in greater detail in rats. Ozone caused an increase in monocyte chemotactic activity in bronchoalveolar fluid that was inhibited by an antibody directed against MCP-1. Ozone-induced MCP-1 mRNA levels were higher in lavage cells than in whole lung tissue, indicating that lavage cells are an important source of MCP-1. In these cells, nuclear factor-kappa B, a nuclear transcription factor implicated in MCP-1 gene regulation, was also activated 20-24 h after ozone exposure. These findings indicate that monocyte accumulation subsequent to acute lung injury can be mediated through MCP-1 and that nuclear factor-kappa B may play a role in ozone-induced MCP-1 gene expression.

Cytokines and particle-induced inflammatory cell recruitment.

The inflammatory response is a key component of host defense. However, excessive or persistent inflammation can contribute to the pathogenesis of disease. Inflammation is regulated, in part, by cytokines, which are small, typically glycosylated proteins that interact with membrane receptors to regulate cellular processes such as proliferation, differentiation, and secretion. During the past 10 years studies in humans and experimental animals have demonstrated that a cytokine called tumor necrosis factor alpha (TNF-alpha) plays a key role in the initiation of inflammatory responses in the lung and other tissues, including inflammation resulting from inhalation of noxious particles. There is now compelling evidence that one of the pathways by which inhaled particles stimulate the recruitment and subsequent activation of inflammatory cells is through the activation of lung macrophages to release TNF-alpha. TNF-alpha then acts via paracrine and autocrine pathways to stimulate cells to release other cytokines known as chemokines, which are directly chemotactic to leukocytes and other cells that participate in inflammatory and wound healing responses. In addition to a TNF-alpha-mediated pathway, there is growing evidence that some particles such as quartz and crocidolite can directly activate lung epithelial cells to release chemokines such as macrophage inflammatory protein-2, cytokine-induced neutrophil chemoattractant, and interleukin-8. A direct stimulatory effect of particles on lung epithelium may represent an additional or alternate pathway by which inhaled particles may elicit inflammation in the lung. Recent studies have suggested that oxidative stress may be a component of the mechanism by which particles activate cytokine production in cells such as macrophages and epithelial cells. The contribution of oxidative stress to particle-induced cytokine gene expression appears to be mediated, at least in part, through activation of the transcription factor nuclear factor kappa B.

Asbestos causes translocation of p65 protein and increases NF-kappa B DNA binding activity in rat lung epithelial and pleural mesothelial cells.

The mechanisms of cell signaling and altered gene expression by asbestos, a potent inflammatory, fibrogenic, and carcinogenic agent, are unclear. Activation of the transcription factor, nuclear factor (NF)-kappa B, is critical in up-regulating the expression of many genes linked to inflammation and proliferation. Inhalation models of crocidolite- and chrysotile-induced inflammation and asbestosis were used to study the localization of p65, a protein subunit of the NF-kappa B transcription factor, in sham control rats and those exposed to asbestos. In addition, we investigated, using electrophoretic mobility shift analysis, whether in vitro exposure of rat lung epithelial cells and rat pleural mesothelial cells to asbestos increased binding of nuclear proteins, including p65, to the NF-kappa B DNA response element. Furthermore, translocation of p65 into the nucleus was determined by confocal microscopy. In comparison with sham animals, striking increases in p65 immunofluorescence were observed in airway epithelial cells of rats at 5 days after inhalation of asbestos. These increases were diminished by 20 days, the time period necessary for development of fibrotic lesions. In contrast, although inter-animal variability was observed, immunoreactivity for p65 was more dramatic in the interstitial compartment of asbestos-exposed rat lungs at both 5 and 20 days. Changes in p65 expression in pleural mesothelial cells exposed to asbestos in inhalation experiments were unremarkable. Exposure to asbestos also caused significant increases in nuclear protein complexes that bind the NF-kappa B consensus DNA sequence in both rat lung epithelial and rat pleural mesothelial cells. Using confocal microscopy, we observed partial nuclear translocation of p65 in rat pleural mesothelial cells exposed to asbestos. This partial response contrasted with the effects of lipopolysaccharide, which caused rapid and complete translocation of p65 from cytoplasm to nucleus. Our studies are the first to show the presence of the NF-kappa B system in lung tissue and evidence of activation in vitro and in vivo after exposure to a potent inflammatory, fibrinogenic, and carcinogenic environmental agent.

Effects of particle exposure and particle-elicited inflammatory cells on mutation in rat alveolar epithelial cells.

To investigate mechanisms underlying development of lung adenomas and carcinomas in rats exposed to poorly soluble particles the relationships between particle exposure, inflammation and mutagenesis in rat alveolar type II cells were characterized. Rats were exposed to saline or saline suspensions of 10 and 100 mg/kg of alpha-quartz, carbon black or titanium dioxide by intratracheal instillation. Fifteen months after exposure, bronchoalveolar lavage (BAL) cells were characterized as to number and type and lung histopathology performed. The alveolar type II cells were isolated and cultured in 6 thioguanine (6TG) containing media to select for mutation in the hprt gene. The potential contribution of lung inflammatory cells to in vivo mutagenic responses, were evaluated by co-culturing BAL cells with the rat alveolar epithelial cell line, RLE-6TN for 24 h and the RLE-6TN cells selected for 6TG resistance. Neutrophilic inflammation was detected in all rats exposed to 10 and 100 mg/kg of alpha-quartz and carbon black and 100 mg/kg titanium dioxide; epithelial hyperplasia was observed in rats exposed to 10 and 100 mg/kg of alpha-quartz and 100 mg/kg carbon black. Hprt mutation frequency was increased in alveolar type II cells from rats exposed to 10 and 100 mg/kg of alpha-quartz, 100 mg/kg carbon black and 100 mg/kg titanium dioxide. In vitro exposure of RLE-6TN cells to BAL cells from rats treated with 10 and 100 mg/kg of alpha-quartz or 100 mg/kg carbon black increased hprt mutant frequency. Both macrophage and neutrophil enriched BAL cell populations were mutagenic to RLE-6TN cells, however, the mutagenic activity appeared greatest for neutrophils. Addition of catalase to BAL cell:RLE-6TN co-cultures inhibited the increase in hprt mutation frequency. These studies demonstrate exposure of rats to doses of particles producing significant neutrophilic inflammation is associated with increased mutation in rat alveolar type II cells. The ability of particle-elicited macrophages and neutrophils to exert a mutagenic effect on epithelial cells in vitro supports a role for these inflammatory cells in the in vivo mutagenic effects of particle exposure. The inhibition of BAL cell-induced mutations by catalase implies a role for cell-derived oxidants in this response.

Alpha-quartz-induced chemokine expression by rat lung epithelial cells: effects of in vivo and in vitro particle exposure.

Chemokines are chemotactic cytokines that can play a key role in leukocyte recruitment to sites of tissue injury or infection. Previous studies have demonstrated that exposure to alpha-quartz as well as other noxious particles increases chemokine gene expression in rat lung, although the cells responsible for chemokine expression and the mechanisms underlying this response have remained unclear. The present studies demonstrate that exposure of rats to alpha-quartz induced expression of mRNA for the chemokine macrophage-inflammatory protein (MIP)-2 in epithelial cells lining the terminal bronchioles and alveolar ducts as well as macrophages and alveolar type II cells in the more distal lung. Treatment of rats with an anti-MIP-2 antiserum before alpha-quartz exposure markedly attenuated neutrophilic infiltration of the lungs demonstrating an important role for MIP-2 in alpha-quartz-induced pulmonary inflammation. In vitro exposure of primary cultures of rat alveolar type II cells or the rat alveolar type II cell line RLE-6TN to tumor necrosis factor-alpha, endotoxin, or alpha-quartz increased mRNA for MIP-2 as well as the structurally and functionally similar chemokine cytokine-induced neutrophil chemoattractant but not the chemokine MIP-1 alpha. The alpha-quartz-induced increase in epithelial MIP-2 mRNA resulted, at least in part, from increased gene transcription and was associated with the release of active MIP-2 protein. Induction of RLE-6TN MIP-2 and cytokine-induced neutrophil chemoattractant mRNA expression was not unique to alpha-quartz, being also increased by crocidolite asbestus fibers but not by titanium dioxide or MMVF-10 glass fibers. These findings indicate that epithelial cells contribute to chemokine expression in rat lung after exposure to alpha-quartz and potentially other noxious particles and suggest that alpha-quartz-activated MIP-2 expression in vivo results, at least in part, from a direct action of the particles on the lung epithelium.

Isolation and biological characterization of morphological transformation-sensitive Syrian hamster embryo cells.

Investigations were carried out designed to isolate and biologically characterize the subpopulation of cells within the Syrian hamster embryo (SHE) cell population which are sensitive to morphological transformation (MT). Biological cloning of MT-sensitive cells demonstrated that within the complex SHE cell population, MT-sensitive cells comprise approximately 27% of the clonally plateable cellular population. Importantly, MT-sensitive cells display MT rates of approximately 7% following benzo[a]pyrene exposure, a rate which falls to <1% with additional passage of the cells, indicating that the ability to undergo MT is a transient phenomenon. Biological characterization of the clonal MT-sensitive cells indicates that these cells are relatively undifferentiated, since they express both cytokeratins and vimentin and respond to a variety of stem cell growth and differentiation factors, although the majority appear to be committed progenitor cells, since they express either mesenchymal or epithelial cell characteristics. Together these data demonstrate that MT-sensitive cells comprise a subpopulation of the cells within the complex SHE cell population, that the ability to undergo MT is a transient phenomenon and that MT-sensitive cells are relatively undifferentiated committed progenitor stem-like cells, all of which gives rise to the hypothesis that MT is an alteration in the cellular differentiation state.

Pulmonary inflammatory, chemokine, and mutagenic responses in rats after subchronic inhalation of carbon black.

Chronic inhalation of carbon black can produce carcinomas in rat lungs. At present the mechanisms underlying the rat lung tumor response to carbon black are unknown, although a significant role for inflammation and cell proliferation has been postulated. To investigate the processes which may contribute to development of rat lung tumors after carbon black exposure, we characterized the effects of subchronic inhalation of carbon black by rats on mutagenesis in alveolar epithelial cells, pulmonary inflammation, inflammatory cytokine/growth factor expression, and lung histopathology. Briefly, rats were exposed for 6 hr/day, 5 days/week for up to 13 weeks to 1.1, 7.1, and 52.8 mg/m3 carbon black and the effects on the lung were characterized after 6.5 and 13 weeks of exposure and 3 and 8 months of recovery. Endpoints characterized after carbon black exposure included mutation in the hprt gene of alveolar epithelial cells, changes in bronchoalveolar lavage fluid markers of lung injury and inflammation, expression of mRNA for the chemokines, MIP-2 and MCP-1, and lung histopathology. Lung burdens of carbon black were also determined. After 13 weeks of exposure to 1.1, 7.1, and 52.8 mg/m3 carbon black, lung burdens were 354, 1826, and 7861 micrograms carbon black, respectively. The lung clearance of carbon black appeared impaired after exposure to 7.1 and 52.8 mg/m3 carbon black, with the effects being more pronounced at the higher exposure level. Subchronic inhalation of 1.1 mg/m3 carbon black did not elicit any detectable adverse lung effects. A significant increase in hprt mutation frequency in alveolar epithelial cells was detected immediately after 13 weeks of exposure to 7.1 and 52.8 mg/m3 carbon black as well as after 3- and 8-month recovery periods for the group exposed to 52.8 mg/m3. No increase in hprt mutation frequency was observed for epithelial cells obtained from rats exposed to 1.1 mg/m3 carbon black. The observation that genotoxic effects (i.e., mutations) on alveolar epithelial cells occurred only after carbon black exposures which resulted in significant inflammation and epithelial hyperplasia supports the hypothesis that inflammatory cell-derives oxidants and increased cell proliferation play a role in the pathogenesis of rat lung tumors in response to carbon black.

TNF alpha and increased chemokine expression in rat lung after particle exposure.

Macrophage inflammatory protein 2 (MIP-2) and CINC (Cytokine-Induced-Neutrophil-Chemoattractant) are members of the chemokine family of inflammatory and immunoregulatory cytokines. MIP-2 and CINC exhibit potent neutrophil chemotactic activity and are thought to be key mediators of inflammatory cell recruitment in response to tissue injury and infection. In the present studies, we examined the potential involvement of MIP-2 and CINC in particle-elicited inflammation in the rat lung and the role of TNF alpha in particle-induced chemokine expression. Acute intratracheal instillation exposure of F344 rats to alpha quartz or titanium dioxide was shown to markedly increase steady-state levels of MIP-2 and CINC mRNA in lung tissue; a response which was associated with a significant increase in neutrophils in the bronchoalveolar lavage fluid. Additional studies demonstrated that acute inhalation of crocidolite fibers by rats also induced increased MIP-2 and CINC expression. Since previous studies had demonstrated that TNF alpha stimulates MIP-2 and CINC expression in vitro and that particle exposure induces TNF alpha production in rat lung we examined the role of TNF alpha in alpha quartz-induced MIP-2 gene expression. We demonstrated that passive immunization of mice against TNF alpha markedly attenuated the increased lung MIP-2 mRNA seen in response to alpha quartz inhalation. Collectively, these findings suggest that the chemokines MIP-2 and CINC play a role in neutrophil recruitment to the rat lung after particle exposure and indicate that particle-induced expression of these chemokines is mediated, at least in part, by production of TNF alpha.

Characterizing mutagenesis in the hprt gene of rat alveolar epithelial cells.

A clonal selection assay was developed for mutation in the hypoxanthine-guanine phosphoribosyl transferase (hprt) gene of rat alveolar epithelial cells. Studies were conducted to establish methods for isolation and long-term culture of rat alveolar epithelial cells. When isolated by pronase digestion purified on a Nycodenz gradient and cultured in media containing 7.5% fetal bovine serum (FBS), pituitary extract, EGF, insulin, and IGF-1, rat alveolar epithelial cells could be maintained in culture for several weeks with cell doubling times of 2-4 days. The rat alveolar epithelial cell cultures were exposed in vitro to the mutagens ethylnitrosourea (ENU) and H2O2, and mutation in the hprt gene was selected for by culture in the presence of the toxic purine analog, 6-thioguanine (6TG). In vitro exposure to ENU or H2O2 produced a dose-dependent increase in hprt mutation frequency in the alveolar epithelial cells. To determine if the assay system could be used to evaluate mutagenesis in alveolar type II cells after in vivo mutagen or carcinogen exposure, cells were isolated from rats treated previously with ENU or alpha-quartz. A significant increase in hprt mutation frequency was detected in alveolar epithelial cells obtained from rats exposed to ENU or alpha-quartz; the latter observation is the first demonstration that crystalline silica exposure is mutagenic in vivo. In summary, these studies show that rat alveolar epithelial cells isolated by pronase digestion and Nycodenz separation techniques and cultured in a defined media can be used in a clonal selection assay for mutation in the hprt gene. This assay demonstrates that ENU and H2O2 in vitro and ENU and alpha-quartz in vivo are mutagenic for rat alveolar epithelial cells. This model should be useful for investigating the genotoxic effects of chemical and physical agents on an important lung cell target for neoplastic transformation.