Abstract
The chemistry underlying superoxide toxicity is not fully understood. A potential mechanism for superoxide-mediated injury involves addition to tyrosyl radicals, to give peptide or protein hydroperoxides. The rate constant for the reaction of tyrosyl radicals with superoxide is higher than for dimerization, but the efficiency of superoxide addition to peptides depends on the position of the Tyr residue. We have examined the requirements for superoxide addition and structurally characterized the products for a range of tyrosyl peptides exposed to a peroxidase/O(2)(.) system. These included enkephalins as examples of the numerous proteins and physiological peptides with N-terminal tyrosines. The importance of amino groups in promoting hydroperoxide formation and effect of methionine residues on the reaction were investigated. When tyrosine was N-terminal, the major products were hydroperoxides that had undergone cyclization through conjugate addition of the terminal amine. With non-N-terminal tyrosine, electron transfer from O(2)(.) to the peptide radical prevailed. Peptides containing methionine revealed a novel and efficient intramolecular oxygen transfer mechanism from an initial tyrosine hydroperoxide to give a dioxygenated derivative with one oxygen on the tyrosine and the other forming methionine sulfoxide. Exogenous amines promoted hydroperoxide formation on tyrosyl peptides lacking a terminal amine, without forming an adduct. These findings, plus the high hydroperoxide yields with N-terminal tyrosine, can be explained by a mechanism in which hydrogen bonding of O(2)(.) to the amine increases is oxidizing potential and alters its reactivity. If this amine effect occurred more generally, it could increase the biological reactivity of O(2)(.) and have major implications.
Highlights
Tyrosyl radicals are generated in many physiological situations and proteins are major targets for reactive oxidants [9]
Reactions of Superoxide with Peptide Radicals. It has been observed [5, 26, 27] that radicals generated on Tyr and tyrosyl dipeptides react with O2. to form hydroperoxides [5, 26, 27]. This occurs in competition with dimerization of the radicals, and with Tyr and the xanthine oxidase (XO)/horseradish peroxidase (HRP) system as in Fig. 1a, more hydroperoxide than dityrosine was formed [5]
We extended these observations to the enkephalins and related peptides, and found that they were all oxidized by HRP and H2O2
Summary
Radical Targets for Superoxide group to the phenol ring (HOHICA, designated I and named in full in Fig. 1b, proposed to arise from reactions 5 and 6). It has been postulated that the repair mechanism involves singlet oxygen release from an intermediate (reaction 4) rather than electron transfer (reaction 2) [18], but this has not been studied experimentally The objectives of this investigation were to determine the structures of the hydroperoxide and any other superoxide addition products, and to understand the mechanism of formation, using a range of synthetic and physiological tyrosyl peptides. These include the opioids Leu- and Met-Enkephalin (Leu-Enk, YGGFL; and Met-Enk, YGGFM, respectively) and Endomorphin 2 (Endo, YPFF). We have obtained structural information on the hydroperoxides, identified a mechanism of rapid intramolecular oxidation of Met residues via a hydroperoxide intermediate, and provide an explanation for why amino groups facilitate the addition of O2. to the tyrosyl radical
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