Effect of circulating neutrophil depletion on lung injury induced by inhaled silica particles.

Polymorphonuclear leukocytes (PMNs) recruited into the alveolar region during inflammation may injure the lung parenchyma by releasing cytotoxic oxygen radicals and proteases. Because brief exposures to crystalline silica elicit recruitment of PMNs into the alveolar region, which is strongly correlated with parameters of cytotoxicity, increased alveolar epithelial permeability, and lysosomal enzyme release, we sought to evaluate the potential role of PMNs in silica-induced lung injury. Rats were depleted of PMNs by administration of an anti-rat PMN antiserum prior to exposure to silica. Pulmonary inflammatory responses to silica in this group were compared to responses in normal silica-exposed rats as well as sham-exposed normal or PMN-depleted rats. Bronchoalveolar lavage fluids from normal, silica-exposed rats contained 9.7 x 10(6) PMNs immediately after exposure for 3 days, compared to 0.01 x 10(6) PMNs for both normal or PMN-depleted, sham-exposed rats. Bronchoalveolar lavage fluids from successfully PMN-depleted, exposed rats contained significantly fewer (0.7 x 10(6)) PMNs compared to normal silica-exposed rats. In both groups of silica-exposed rats, a variety of biochemical indicators of lung injury were increased significantly compared to measurements from both sham-exposed groups, but there were no differences between PMN-depleted and normal silica-exposed groups. The results suggest that recruitment of PMNs into the alveolar region is not a necessary prerequisite for the observed increases in biochemical indicators of silica-induced acute lung injury.

Chlorobenzene degradation by bacteria isolated from contaminated groundwater.

Bacterial isolates were obtained from groundwater and soils contaminated with chlorobenzene (CB). The isolates were tested to determine whether the natural community could remove the groundwater contaminants. These isolates were identified and characterized as to their ability to grow on CB and related aromatic compounds. The complete consortium could mineralize approximately 54% of the CB within 7 days, with no accumulation of 3-chlorocatechol. Metabolic pathways were evaluated for several isolates. One phenotype was characterized by the ability to degrade CB by the modified ortho pathway. One strain also degraded p-dichlorobenzene by using the same pathway. Isolates exhibiting a second phenotype degraded p-cresol, benzene, and phenol by the classical ortho pathway and accumulated 3-chlorocatechol when grown in the presence of CB. Strains of the third phenotype grew on complex media in the presence of CB but did not transform any of the aromatic compounds tested. The results suggest that the indigenous microbial community at the contaminated site would be able to degrade CB if provided with the appropriate conditions.