NO2 REACTIVE ABSORPTION SUBSTRATES IN RAT PULMONARY SURFACE LINING FLUIDS

Inhaled (NO2)-N-. is absorbed by a free radical-dependent reaction mechanism that localizes the initial oxidative events to the extracellular space of the pulmonary surface lining layer (SLL). Because (NO2)-N-. per se is eliminated upon absorption, most likely the SLL-derived reaction products are critical to the genesis of (NO2)-N-.-induced lung injury. We utilized analysis of the rate of (NO2)-N-. disappearance from the gas phase to determine the preferential absorption substrates within rat SLL. SLL was obtained via bronchoalveolar lavage and was used either as the cell-free composite or after constituent manipulation [(i) dialysis, treatment with (ii) N-ethylmaleimide, (iii) ascorbate oxidase, (iv) uricase, or (v) combined ii + iii]. Specific SLL constituents were studied in pure chemical systems. Exposures were conducted under conditions where (NO2)-N-. is the limiting reagent and disappears with first-order kinetics ([NO2](0) less than or equal to 10 ppm). Reduced glutathione and ascorbate were the principle rat SLL absorption substrates. Nonsulfhydryl amino acids and dipalmitoyl phosphatidylcholine exhibited negligible absorption activity. Whereas uric acid and vitamins A and E displayed rapid absorption kinetics, their low SLL concentrations preclude appreciable direct interaction, Unsaturated fatty acids may account for less than or equal to 20% of absorption. The results suggest that water soluble, low molecular weight antioxidants are the preferential substrates driving (NO2)-N-. absorption. Consequently, their free radicals, produced as a consequence of (NO2)-N-. exposure, may participate in initiating the (NO2)-N-.-induced cascade, which results in epithelial injury.