Oxidation of Guanine in G, GG, and GGG Sequence Contexts by Aromatic Pyrenyl Radical Cations and Carbonate Radical Anions:  Relationship between Kinetics and Distribution of Alkali-Labile Lesions

Lee, Young Ae; Durandin, Alexander; Dedon, Peter C.; Geacintov, Nicholas E.; Shafirovich, Vladimir

doi:10.1021/jp076777x

Cited by 50 publications

(49 citation statements)

References 56 publications

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“…DNA oxidation usually occurs at guanine dimers or trimers and is associated with lesions of the DNA strand [80]. It interferes with binding of transcription factors, including the specificity protein (SP) family [55,81], although it does not appear to reduce nuclear factor B (NF-B) binding [55].…”

Section: Learn Pathway and Oxidative Damage Vs Admentioning

confidence: 99%

Applying Epigenetics to Alzheimer’s Disease via the Latent Early–life Associated Regulation (LEARn) Model

Maloney

Sambamurti

Zawia

et al. 2012

CAR

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Alzheimer's disease (AD) is a leading cause of aging related dementia and has been extensively studied by several groups around the world. A general consensus, based on neuropathology, genetics and cellular and animal models, is that the 4 kDa amyloid β protein (Aβ) triggers a toxic cascade that induces microtubule-associated protein τ (MAPT) hyperphosphorylation and deposition. Together, these lesions lead to neuronal dysfunction and neurodegeneration, modeled in animals, that ultimately causes dementia. Genetic studies show that a simple duplication of the Aβ precursor (APP) gene, as occurs in Down syndrome (trisomy 21), with a 1.5-fold increase in expression, can cause dementia with the complete AD associated neuropathology. The most fully characterized form of AD is early onset familial AD (FAD). Unfortunately, by far the most common form of AD is late onset AD (LOAD). FAD has well-identified autosomally dominant genetic causes, absent in LOAD. It is reasonable to hypothesize that environmental influences play a much stronger role in etiology of LOAD than of FAD. Since AD pathology in LOAD closely resembles FAD with accumulation of both Aβ and MAPT, it is likely that the environmental factors foster accumulation of these proteins in a manner similar to FAD mutations. Therefore, it is important to identify environmentally driven changes that "phenocopy" FAD in order to find ways to prevent LOAD. Epigenetic changes in expression are complex but stable determinants of many complex traits. Some aspects are regulated by prenatal and early post-natal development, others punctuate specific periods of maturation, and still others occur throughout life, mediating predictable changes that take place during various developmental stages. Environmental agents such as mercury, lead, and pesticides can disrupt the natural epigenetic program and lead to developmental deficits, mental retardation, feminization, and other complex syndromes. In this review we discuss latent early- life associated regulation (LEARn), where apparently temporary changes, induced by environmental agents, become latent and present themselves again at maturity or senescence to increase production of Aβ that may cause AD. The model provides us with a novel direction for identifying potentially harmful agents that may induce neurodegeneration and dementia later in life and provides hope that we may be able to prevent age-related neurodegenerative disease by "detoxifying" our environment.

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Section: Learn Pathway and Oxidative Damage Vs Admentioning

confidence: 99%

Applying Epigenetics to Alzheimer’s Disease via the Latent Early–life Associated Regulation (LEARn) Model

Maloney

Sambamurti

Zawia

et al. 2012

CAR

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“…, GG, GGG, are ultimately the most stable hole localization sites after long range hole transfer and these G stacks form loci for DNA base damage. 2 – 6, 12 – 16 …”

Section: Introductionmentioning

confidence: 99%

Prototropic equilibria in DNA containing one-electron oxidized GC: intra-duplex vs. duplex to solvent deprotonation

Adhikary

Kumar

Munafo

et al. 2010

Phys. Chem. Chem. Phys.

182

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By use of ESR and UV-vis spectral studies, this work identifies the protonation states of one-electron oxidized G:C (viz. G•+:C, G(N1-H)•:C(+H+), G(N1-H)•:C, and G(N2-H)•:C) in a DNA oligomer d[TGCGCGCA]2. Benchmark ESR and UV-vis spectra from one electron oxidized 1-Me-dGuo are employed to analyze the spectral data obtained in one-electron oxidized d[TGCGCGCA]2 at various pHs. At pH ≥7, the initial site of deprotonation of one-electron oxidized d[TGCGCGCA]2 to the surrounding solvent is found to be at N1 forming G(N1-H)•:C at 155 K. However, upon annealing to 175 K, the site of deprotonation to the solvent shifts to an equilibrium mixture of G(N1-H)•:C and G(N2-H)•:C. For the first time, the presence of G(N2-H)•:C in a ds DNA-oligomer is shown to be easily distinguished from the other prototropic forms, owing to its readily observable nitrogen hyperfine coupling (Azz(N2)= 16 G). In addition, for the oligomer in H2O, an additional 8 G N2-H proton HFCC is found. This ESR identification is supported by a UV-vis absorption at 630 nm which is characteristic for G(N2-H)• in model compounds and oligomers. We find that the extent of photo-conversion to the C1′ sugar radical (C1′•) in the one-electron oxidized d[TGCGCGCA]2 allows for a clear distinction among the various G:C protonation states which can not be easily distinguished by ESR or UV-vis spectroscopies with this order for the extent of photo-conversion: G•+:C > G(N1-H)•:C(+H+) >> G(N1-H)•:C. We propose that it is the G•+:C form that undergoes deprotonation at the sugar and this requires reprotonation of G within the lifetime of exited state.

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“…The most basic reaction is one-electron oxidation, the result of which is essentially independent of the process by which it is oxidized [110]. The loss of an electron converts DNA to its radical cation (an electron "hole"), which migrates reversibly through duplex DNA by hopping until it is trapped in an irreversible chemical reaction to form a structurally modified base [95].…”

Section: Oxidation Of Dnamentioning

confidence: 99%

Oxidative Processes and Antioxidative Metaloenzymes

Vašková¹,

Vaško²,

Kron³

2012

Antioxidant Enzyme

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Oxidation of Guanine in G, GG, and GGG Sequence Contexts by Aromatic Pyrenyl Radical Cations and Carbonate Radical Anions: Relationship between Kinetics and Distribution of Alkali-Labile Lesions

Cited by 50 publications

References 56 publications

Applying Epigenetics to Alzheimer’s Disease via the Latent Early–life Associated Regulation (LEARn) Model

Applying Epigenetics to Alzheimer’s Disease via the Latent Early–life Associated Regulation (LEARn) Model

Prototropic equilibria in DNA containing one-electron oxidized GC: intra-duplex vs. duplex to solvent deprotonation

Oxidative Processes and Antioxidative Metaloenzymes

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