Mass spectrometric analysis of leukotriene A4 and other chemically reactive metabolites of arachidonic acid

Abstract

The biosynthesis of prostaglandins and leukotrienes proceeds through the formation of chemically reactive intermediates leukotriene A₄ (LTA₄) and prostaglandin H₂ (PGH₂) which in aqueous solutions have chemical half-lives of 3 s and 3 min, respectively. Prostacyclin (PGI₂) is another chemically reactive prostanoid that has a chemical half-life of 3–4 min. The recent development of reversed phase HPLC stationary phases that are stable to elevated pH (pH 10–12) without significant column damage has permitted direct analysis of these acid-sensitive eicosanoids. Using electrospray ionization, molecular anions [M - H]⁻ of these compounds were observed at m/z 317 for LTA₄ and m/z 351 for both PGH₂ and PGI₂. The mechanism of formation of ions derived from collisional activation of LTA₄ was studied using stable isotope labeled and chemical analogs of LTA₄ and found to involve formation of highly conjugated anions at m/z 261 and 163. The collisional activation of the molecular anion of PGH₂ yielded a product ion spectrum identical to that observed for the isomeric prostaglandins PGE₂ and PGD₂. However, it was possible to baseline separate PGE₂, PDG₂, and PGH₂ by reversed phase HPLC using basic HPLC mobile phases. The collisional activation of PGI₂ led to a family of abundant ions including highly conjugated carbon-centered and oxygen-centered radical species (m/z 245 and 205) likely derived from the attack of the carboxylate anion on the cyclic enolether of PGI₂ as well as the most abundant product ion (m/z 215) which formed following loss of neutral hexanal and water. The structures of these product ions were consistent with high resolution measurements measured in a quadrupole time-of-flight mass spectrometer.