Membrane perturbations and mediation of gap junction formation in response to taurine treatment in normal and injured alveolar epithelia.

Nitrogen dioxide is an air pollutant that causes pulmonary alterations. Employing light and transmission electron microscopy, we examined plastic sections and freeze-fracture replicas of alveolar epithelium of groups of hamsters exposed to nitrogen for 24 h to determine taurine-induced changes in intercellular junctions. Prior to exposure, one group of hamsters was given 0.5% taurine in their drinking water for 2 weeks. A second group of hamsters was given taurine-free water. The taurine-treated group was divided into three subgroups. The first subgroup was exposed to nitrogen dioxide at a concentration of 7 ppm for 24 h, the second subgroup was exposed to nitrogen dioxide at a concentration of 30 ppm for 24 h, and the third subgroup was exposed to normal room air for 24 h. The nontaurine-treated animals were similarly divided into three subgroups and treated as described above. The lungs of the hamsters exposed to nitrogen dioxide without the taurine pretreatment exhibited extensive inflammatory cell infiltration in the walls of the terminal bronchioles, alveolar ducts, and peribronchiolar alveoli. The degree of infiltration was proportional to the degree of nitrogen dioxide concentration. The taurine-treated animals exposed to nitrogen dioxide and the nontaurine-treated animals exposed to room aid did not show any inflammatory infiltrate. Freeze-fracture replicas of the tight junctional regions of the type I and type II pneumocytes revealed significant fragmentation in the nitrogen dioxide-exposed lungs. It was also observed that the tight junctions between the type I pneumocytes of the taurine-treated groups, whether exposed or not, revealed gap junction-like aggregates among the tight junction fibrils. The 30-ppm nitrogen dioxide exposed group exhibited larger and more frequent gap junctions between the pneumocytes than those observed in the 7-ppm nitrogen dioxide exposed group. The evidence suggests that taurine may have an effect on plasma membranes and intercellular communications. Changes in intercellular communication may contribute to decreased susceptibility to injury and increased pneumocyte survival.