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Literature DB >> 14576314

Repair of oxidative DNA damage by amino acids.

J R Milligan¹, J A Aguilera, A Ly, N Q Tran, O Hoang, J F Ward.

Abstract

Guanyl radicals, the product of the removal of a single electron from guanine, are produced in DNA by the direct effect of ionizing radiation. We have produced guanyl radicals in DNA by using the single electron oxidizing agent (SCN)2-, itself derived from the indirect effect of ionizing radiation via thiocyanate scavenging of OH. We have examined the reactivity of guanyl radicals in plasmid DNA with the six most easily oxidized amino acids cysteine, cystine, histidine, methionine, tryptophan and tyrosine and also simple ester and amide derivatives of them. Cystine and histidine derivatives are unreactive. Cysteine, methionine, tyrosine and particularly tryptophan derivatives react to repair guanyl radicals in plasmid DNA with rate constants in the region of approximately 10(5), 10(5), 10(6) and 10(7) dm3 mol(-1) s(-1), respectively. The implication is that amino acid residues in DNA binding proteins such as histones might be able to repair by an electron transfer reaction the DNA damage produced by the direct effect of ionizing radiation or by other oxidative insults.

Entities: Chemical Gene

Mesh：

Substances：

Year: 2003 PMID： 14576314 PMCID： PMC275458 DOI： 10.1093/nar/gkg816

Source DB: PubMed Journal: Nucleic Acids Res ISSN： 0305-1048 Impact factor: 16.971

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1. De novo proteins as models of radical enzymes.

Authors: C Tommos; J J Skalicky; D L Pilloud; A J Wand; P L Dutton
Journal: Biochemistry Date: 1999-07-20 Impact factor: 3.162

2. The reaction of triplet 2-methyl-1,4-naphthoquinone (menadione) with DNA and polynucleotides.

Authors: T Melvin; E Bothe; D Schulte-Frohlinde
Journal: Photochem Photobiol Date: 1996-11 Impact factor: 3.421

3. Radiation-induced DNA damage as a function of hydration. II. Base damage from electron-loss centers.

Authors: S G Swarts; D Becker; M Sevilla; K T Wheeler
Journal: Radiat Res Date: 1996-03 Impact factor: 2.841

Review 4. Oxidative damage to DNA: formation, measurement, and biological significance.

Authors: J Cadet; M Berger; T Douki; J L Ravanat
Journal: Rev Physiol Biochem Pharmacol Date: 1997 Impact factor: 5.545

5. Intraprotein radical transfer during photoactivation of DNA photolyase.

Authors: C Aubert; M H Vos; P Mathis; A P Eker; K Brettel
Journal: Nature Date: 2000-06-01 Impact factor: 49.962

6. Redox equilibrium between guanyl radicals and thiocyanate influences base damage yields in gamma irradiated plasmid DNA. Estimation of the reduction potential of guanyl radicals in plasmid DNA in aqueous solution at physiological ionic strength.

Authors: J R Milligan; J A Aguilera; J F Ward
Journal: Int J Radiat Biol Date: 2001-12 Impact factor: 2.694

7. A kinetic study on the interaction of deprotonated purine radical cations with amino acids and model peptides.

Authors: J Pan; W Lin; W Wang; Z Han; C Lu; S Yao; N Lin; D Zhu
Journal: Biophys Chem Date: 2001-02-15 Impact factor: 2.352

Review 8. Electron paramagnetic resonance and nuclear magnetic resonance studies of class I ribonucleotide reductase.

Authors: A Gräslund; M Sahlin
Journal: Annu Rev Biophys Biomol Struct Date: 1996

9. Induction of strand breaks in polyribonucleotides and DNA by the sulphate radical anion: role of electron loss centres as precursors of strand breakage.

Authors: P Wolf; G D Jones; L P Candeias; P O'Neill
Journal: Int J Radiat Biol Date: 1993-07 Impact factor: 2.694

10. ESR spectra of radicals of single-stranded and double-stranded DNA in aqueous solution. Implications for .OH-induced strand breakage.

Authors: K Hildenbrand; D Schulte-Frohlinde
Journal: Free Radic Res Commun Date: 1990

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Review 3. Targeted and Off-Target (Bystander and Abscopal) Effects of Radiation Therapy: Redox Mechanisms and Risk/Benefit Analysis.

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4. Chemical and Colloidal Dynamics of MnO₂ Nanosheets in Biological Media Relevant for Nanosafety Assessment.

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5. Irradiation of the porphyrin causes unfolding of the protein in the protoporphyrin IX/beta-lactoglobulin noncovalent complex.

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