Ditryptophan Cross-Links as Novel Products of Protein Oxidation

Paviani, Verônica; Galdino, Gabriel T.; Prazeres, Janaina N. dos; Queiroz, Raphael Ferreira; Augusto, Ohára

doi:10.21577/0103-5053.20170239

Cited by 9 publications

(16 citation statements)

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“…It was shown that the hydroxylation of tryptophan by Fenton's reaction and photolysis oxidation occurs in different positions of the molecule yielding many possible isomers of hydroxytryptophans and monohydroxytryptophan dimers. 21,22 However, none of these studies have ever reported the formation of nanoparticles 21,22 . It is well known that sonication of an aqueous solution results in the formation of H and OH radicals due to acoustic cavitation 15 .…”

Section: Resultsmentioning

confidence: 99%

Sound-driven dissipative self-assembly of aromatic biomolecules into functional nanoparticles

et al. 2020

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Section: Resultsmentioning

confidence: 99%

Sound-driven dissipative self-assembly of aromatic biomolecules into functional nanoparticles

et al. 2020

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“…Notably, the ditryptophan dimer in superoxide dismutase or lysozyme can cleave under MS/MS conditions [ 47 ], suggesting that it is not as stable as a dityrosine link and thus is similar to the labile crosslinks we have detected in the current study. Paviani et al have suggested that the susceptibility to cleavage of ditryptophan is more consistent with a C–N bond than a C–C bond [ 47 ]. Accordingly, the crosslink that is reversed by ascorbate in the current study is likely a C–N bond.…”

Section: Discussionmentioning

confidence: 67%

Section: Discussionmentioning

confidence: 99%

“…The nature of ditryptophan bonds is not yet fully elucidated [ 47 ]. Available data suggest that C and N participate in ditryptophan crosslinking [ 47 ], giving the possibility of either C–C or C–N crosslinks. Notably, the ditryptophan dimer in superoxide dismutase or lysozyme can cleave under MS/MS conditions [ 47 ], suggesting that it is not as stable as a dityrosine link and thus is similar to the labile crosslinks we have detected in the current study.…”

Section: Discussionmentioning

confidence: 99%

“…Available data suggest that C and N participate in ditryptophan crosslinking [ 47 ], giving the possibility of either C–C or C–N crosslinks. Notably, the ditryptophan dimer in superoxide dismutase or lysozyme can cleave under MS/MS conditions [ 47 ], suggesting that it is not as stable as a dityrosine link and thus is similar to the labile crosslinks we have detected in the current study. Paviani et al have suggested that the susceptibility to cleavage of ditryptophan is more consistent with a C–N bond than a C–C bond [ 47 ].…”

Section: Discussionmentioning

confidence: 99%

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Reversible Oxidative Modifications in Myoglobin and Functional Implications

et al. 2020

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Myoglobin (Mb), an oxygen-binding heme protein highly expressed in heart and skeletal muscle, has been shown to undergo oxidative modifications on both an inter- and intramolecular level when exposed to hydrogen peroxide (H2O2) in vitro. Here, we show that exposure to H2O2 increases the peroxidase activity of Mb. Reaction of Mb with H2O2 causes covalent binding of heme to the Mb protein (Mb-X), corresponding to an increase in peroxidase activity when ascorbic acid is the reducing co-substrate. Treatment of H2O2-reacted Mb with ascorbic acid reverses the Mb-X crosslink. Reaction with H2O2 causes Mb to form dimers, trimers, and larger molecular weight Mb aggregates, and treatment with ascorbic acid regenerates Mb monomers. Reaction of Mb with H2O2 causes formation of dityrosine crosslinks, though the labile nature of the crosslinks broken by treatment with ascorbic acid suggests that the reversible aggregation of Mb is mediated by crosslinks other than dityrosine. Disappearance of a peptide containing a tryptophan residue when Mb is treated with H2O2 and the peptide’s reappearance after subsequent treatment with ascorbic acid suggest that tryptophan side chains might participate in the labile crosslinking. Taken together, these data suggest that while exposure to H2O2 causes Mb-X formation, increases Mb peroxidase activity, and causes Mb aggregation, these oxidative modifications are reversible by treatment with ascorbic acid. A caveat is that future studies should demonstrate that these and other in vitro findings regarding properties of Mb have relevance in the intracellular milieu, especially in regard to actual concentrations of metMb, H2O2, and ascorbate that would be found in vivo.

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