Metabolism of anti-inflammatory OXE (oxoeicosanoid) receptor antagonists by nonhuman primates

Abstract

5-Oxo-6,8,11,14-eicosatetraenoic acid (5-oxo-ETE) is the only product of the proinflammatory 5-lipoxygenase pathway with potent chemoattractant effects for human eosinophils, suggesting an important role in eosinophilic diseases such as asthma. 5-Oxo-ETE, acting through its selective OXE receptor, induces dermal eosinophilia in both humans and monkeys. To block its effects, we designed selective indole-based OXE antagonists containing hexyl (S-230) or phenylhexyl (S-C025 and S-Y048) side chains, which inhibit allergen-induced dermal and pulmonary inflammation in monkeys, suggesting that they may be useful therapeutic agents in humans. In this study we identified two metabolic pathways for the phenylhexyl-containing antagonists in liver microsomes: benzylic and N-methyl hydroxylation, resulting in ω-hydroxy, ω-oxo, and NH-containing products with reduced potencies that were identified by mass spectrometry and comparison with synthetic standards. Products of both pathways were also identified in monkey plasma following oral administration of S-C025 and S-Y025, but were less abundant than the α-hydroxy metabolites that we previously identified. Interestingly, the α-hydroxy compounds were not detected in microsomal incubations, suggesting a different origin. The relative rates of metabolism of these antagonists were S-230 >> S-C025 > S-Y048, which may help to explain the differences in their plasma half-lives (S-230 < S-C025 < S-Y048). In conclusion, S-C025 and S-Y048 are metabolized by liver microsomes by benzylic and N-methyl hydroxylation but not by α-hydroxylation, whereas all three pathways exist in vivo. Addition of a phenyl group to the hexyl side chain of these antagonists dramatically reduced their rates of metabolism, which would explain their prolonged in vivo half-lives.