Nasal secretion of the ozone scavenger uric acid.

Uric acid, an important scavenger of ozone, has been identified as the major low molecular weight antioxidant in baseline and cholinergically induced nasal secretions. The purpose of this study was to determine the specific tissue source of uric acid in airway secretions. The secretion of uric acid is increased by cholinergic stimulation and correlates closely with the secretion of lactoferrin (a nasal glandular protein), suggesting that submucosal glands are involved. Indeed, nasal turbinate tissue was found to contain uric acid. However, careful analysis of nasal turbinate tissue failed to reveal the presence of xanthine oxidase, the enzyme responsible for uric acid synthesis. These data suggest that uric acid might be taken up secondarily by glands from plasma. This possibility was strengthened by the observation that lowering the plasma urate level with probenecid concomitantly lowered urate secretion. These findings are consistent with the hypotheses that the principal source of uric acid in nasal secretions is plasma and that uric acid is taken up, concentrated, and secreted by nasal glands.

Assessment of chemokinetic behavior of inflammatory lung macrophages in a linear under-agarose assay.

Migration of cells in response to a chemoattractant gradient is influenced by directed migration (chemotaxis) and stimulated random motility (chemokinesis). The present study quantitated the chemokinetic motility of normal and inflammatory lung macrophages by performing the linear under-agarose assay in the presence of uniform concentrations of chemoattractant. Under these conditions, cell motility can be likened to a molecular diffusion process. Mathematical analyses which describe molecular diffusion were then applied, allowing the quantitation of the parameter, mu, the cellular equivalent to the molecular diffusivity constant. Determination of changes in mu as a function of chemoattractant concentration revealed that the chemokinetic motility of alveolar macrophages recovered during the early stages of acute pulmonary inflammation was greater than that of normal alveolar macrophages and macrophages recovered later in the inflammatory response. The correlation of differences in macrophage chemokinesis with macrophage maturation and the relevance of these differences to macrophage accumulation during inflammation are discussed.