Oxidation of urate and tyrosine by peroxynitrite implications for the development of sequesters and peroxynitrite biomarkers

Peroxynitrite (ONOO- + ONOOH), which is formed by the fast reaction between nitric oxide and superoxide anion, has been receiving increasing attention as a mediator of the deleterious effects associated with an overproduction of •NO. The compound is a strong oxidant that is able to oxidize and nitrate a variety of biotargets by mechanisms that this work has contributed to establish. Specifically, we studied the oxidation of urate and tyrosine by peroxynitrite. Urate oxidation produced allantoin, alloxan and the amiocarbonyl radical. Since the rate constant of the direct reaction between urate and peroxynitrite (k= 4,8 x 102 M-1.s-1) is low in comparison with those of other biotargets, we proposed that urate is an efficient scavenger of peroxynitrite-derived radicals (•NO2 and CO3•- in most biological environments; at acid pH, the •OH radical may also become relevant). ln the case of tyrosine, we confirmed that it does not react directly with peroxynitrite but, instead, with the radicals derived form it. As anticipated, the relative yield of the products (3-nitrotyrosine, 3,3-bityrosine and 3-hydroxytyrosine (DOPA)) varied with the pH and CO2 presence. These results led us to propose that co-localization of nitrated and hydroxylated proteins could be a peroxynitrite biomarker. To test this hypothesis, a monoclonal anti-DOPA antibody was developed and tested in Leishamnia amazonensis infection models (macrophages (J774), and resistant (C56Bl/6) and susceptible mice (BALB/c). It was possible to evidence co-localization of hydroxylated and nitrated proteins in all tested models in a time when •NO synthesis was maximum. Unfortunetly, we were unable to confirm these results due to antibody inactvation; new antibody baches are being obtained. (AU)