The catalytic role of carbon dioxide in the decomposition of peroxynitrite.

The fast reaction of peroxynitrite with CO2 and the high concentration of dissolved CO2 in vivo (ca. 1 mM) suggest that CO2 modulates most of the reactions of peroxynitrite in biological systems. The addition of peroxynitrite to CO2 produces of the adduct ONOO-CO2- (1). The production of 1 greatly accelerates the decomposition of peroxynitrite to give nitrate. We now show that the formation of 1 is followed by reformation of CO2 (rather than another carbonate species such as CO3 = or HCO3-). To show this, it is necessary to study systems with limiting concentrations of CO2. (When CO2 is present in excess, its concentration remains nearly constant during the decomposition of peroxynitrite, and the recycling of CO2, although it occurs, can not be detected kinetically). We find that CO2 is a true catalyst of the decomposition of peroxynitrite, and this fundamental insight into its action must be rationalized by any in vivo or in vitro reaction mechanism that is proposed. When the concentration of CO2 is lower than that of peroxynitrite, the reformation of CO2 amplifies the fraction of peroxynitrite that reacts with CO2. Even low concentrations of CO2 that result from the dissolution of ambient CO2 can have pronounced catalytic effects. These effects can cause deviations from predicted kinetic behavior in studies of peroxynitrite in noncarbonate buffers in vitro, and since 1 and other intermediates derived from it are oxidants and/or nitrating agents, some of the reactions attributed to peroxynitrite may depend on the availability of CO2.