Investigating the biochemical impact of DNA damage with structure-based probes: abasic sites, photodimers, alkylation adducts, and oxidative lesions

Impact of Polyphenols on Inflammatory and Oxidative Stress Factors in Diabetes Mellitus: Nutritional Antioxidants and Their Application in Improving Antidiabetic Therapy

Diabetes mellitus is a chronic metabolic disorder characterized by hyperglycaemia and oxidative stress. Oxidative stress plays a crucial role in the development and progression of diabetes and its complications. Nutritional antioxidants derived from dietary sources have gained significant attention due to their potential to improve antidiabetic therapy. This review will delve into the world of polyphenols, investigating their origins in plants, metabolism in the human body, and relevance to the antioxidant mechanism in the context of improving antidiabetic therapy by attenuating oxidative stress, improving insulin sensitivity, and preserving β-cell function. The potential mechanisms of, clinical evidence for, and future perspectives on nutritional antioxidants as adjuvant therapy in diabetes management are discussed.

Selectivity and efficiency in the ligation of the pyrene:abasic base pair by T4 and PBCV-1 DNA ligases

Remarkable selectivity was observed in the ligation of 5'-phosphate 1-pyrene nucleotide terminated strands across from an abasic lesion in a DNA-templated ligation reaction by two different ligases suggesting that pyrene-terminated strands could be used in abasic site detection. Increasing ATP concentration was critical to enhancing the selectivity for this base pair with T4 DNA ligase.

DNA damage by Withanone as a potential cause of liver toxicity observed for herbal products of Withania somnifera (Ashwagandha)

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The widely used medicinal herb Withania somnifera (Ashwagandha) has been recently reported to cause liver damage.

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Withanone is a major metabolite of Ashwagandha.

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Withanone was found to cause DNA damage.

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Withanone forms adducts with amines and thiols.

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Withanone-mediated DNA damage has serious biological consequences.

Withania somnifera, commonly known as Ashwagandha, is a medicinal plant used for thousands of years for various remedies. Extracts of Ashwagandha contain more than 200 metabolites, with withanone (win) being one of the major ones responsible for many of its medicinal properties. Recently, several cases of liver toxicity resulting from commercially available Ashwagandha products have been reported. The first report of Ashwagandha-related liver damage was from Japan, which was quickly resolved after drug-withdrawal. Later, similar cases of liver toxicity due to Ashwagandha consumption were reported from the USA and Iceland. Towards understanding the liver toxicity of Ashwagandha extracts, we studied win, a representative withanolide having toxicophores or structural alerts that are commonly associated with adverse drug reactions. We found that win can form non-labile adducts with the nucleosides dG, dA, and dC. Using various biochemical assays, we showed that win forms adducts in DNA and interfere with its biological property. Win also forms adducts with amines and this process is reversible. Based on the data presented here we concluded that win is detoxified by GSH but under limiting GSH levels it can cause DNA damage. The work presented here provides a potential mechanism for the reported Ashwagandha-mediated liver damage.

Mass Spectrometric Quantitation of Apurinic/Apyrimidinic Sites in Tissue DNA of Rats Exposed to Tobacco-Specific Nitrosamines and in Lung and Leukocyte DNA of Cigarette Smokers and Nonsmokers

Metabolic activation of the carcinogenic tobacco-specific nitrosamines 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and N'-nitrosonornicotine (NNN) results in formation of reactive electrophiles that modify DNA to produce a variety of products including methyl, 4-(3-pyridyl)-4-oxobutyl (POB)-, and 4-(3-pyridyl)-4-hydroxybutyl adducts. Among these are adducts such as 7-POB-deoxyguanosine (N7POBdG) which can lead to apurinic/apyrimidinic (AP) sites by facile hydrolysis of the base-deoxyribonucleoside bond. In this study, we used a recently developed highly sensitive mass spectrometric method to quantitate AP sites by derivatization with O-(pyridin-3-yl-methyl)hydroxylamine (PMOA) (detection limit, 2 AP sites per 108 nucleotides). AP sites were quantified in DNA isolated from tissues of rats treated with NNN and NNK and from human lung tissue and leukocytes of cigarette smokers and nonsmokers. Rats treated with 5 or 21 mg/kg bw NNK for 4 days by s.c. injection had 2-6 and 2-17 times more AP sites than controls in liver and lung DNA (p < 0.05). Increases in AP sites were also found in liver DNA of rats exposed for 10 and 30 weeks (p < 0.05) but not for 50 and 70 weeks to 5 ppm of NNK in their drinking water. Levels of N7POBG were significantly correlated with AP sites in rats treated with NNK. In rats treated with 14 ppm (S)-NNN in their drinking water for 10 weeks, increased AP site formation compared to controls was observed in oral and nasal respiratory mucosa DNA (p < 0.05). No significant increase in AP sites was found in human lung and leukocyte DNA of cigarette smokers compared to nonsmokers, although AP sites in leukocyte DNA were significantly correlated with urinary levels of the NNK metabolite 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL). This is the first study to use mass spectrometry based methods to examine AP site formation by carcinogenic tobacco-specific nitrosamines in laboratory animals and to evaluate AP sites in DNA of smokers and nonsmokers.

Switch-on effect on conformation-specific arylamine-DNA adduct by cyclometalated Ir(III) complexes

Arylamines are known to form covalent-DNA adducts upon metabolic activation. These covalent adducts adopt different conformational attributes, viz., major groove (B), stacked (S), and minor groove (W), and lead to different types of mutations. The conformation depends on the flanking and next flanking bases at the 3' position of the adduct. Early detection of these conformations by simple probes is an ideal and challenging task. Here, we have reported two Ir(III)-based cyclometalated complexes, viz., [Ir(ppy)₂(imiphen)]⁺ (1) (ppy: 2-phenylpyridine; imiphen: 2-(1H-imidazol-2-yl)-1H-imidazo[4,5-f][1,10]phenanthroline) and [Ir(ppy)₂(furphen)]⁺ (2) (furphen: 2-(furan-2-yl)-1H-imidazo[4,5-f][1,10]phenanthroline) and its interaction with N-acetyl-2-aminofluorene-dG (AAF-dG). The sequences used in this work are NarI sequence (-CG₁G₂CG₃CX-) in which Gs are modified with AAF and X is either C or T. Luminescence studies reveal that the Ir(III) complexes bind to AAF-dG adduct with high specificity toward G₁ and G₃ compared to G₂ and unmodified control. The selectivity also depends on the next flanking base as cytosine favors G₃^AAF, while thymine favors G₁^AAF in complex 1 and vice versa for complex 2. The quenching studies confirm that Ir(III) complexes bind with AAF-dG sequences through the minor groove. The outcome of this work reveals that the switch-on effect by the complexes can be utilized for determining the conformational heterogeneity of the adduct and also for similar covalent-DNA adducts.

Determining Steady-State Kinetics of DNA Polymerase Nucleotide Incorporation

Polymerase enzymes catalyze the replication of DNA by incorporating deoxynucleoside monophosphates (dNMPs) into a primer strand in a 5' to 3' direction. Monitoring kinetic aspects of this catalytic process provides mechanistic information regarding polymerase-mediated DNA synthesis and the influences of nucleobase structure. For example, a range of polymerases have different capacities to synthesize DNA depending on the structure of the inserted dNMP (natural or synthetic) and also depending on the templating DNA base (modified vs. unmodified). Under steady-state conditions, relative rates depend on the deoxynucleoside triphosphate (dNTP) residence times in the ternary (polymerase-DNA-dNTP) complex. This chapter describes a method to measure steady-state incorporation efficiencies by which polymerase enzymes insert dNMPs into primer-template (P/T) oligonucleotides. The method described involves the use of a primer oligonucleotide 5' radiolabeled with [γ-³²P]ATP. Significant established applications of this experiment include studies regarding mechanisms of nucleotide misincorporation as a basis of chemically induced DNA mutation. Further, it can provide information important in various contexts ranging from biophysical to medical-based studies.

Selective recognition of DNA defects by cyclometalated Ir(iii) complexes

Three different cyclometalated Ir(iii) complexes selectively bind to DNA defects.

The Base Pairing Partner Modulates Alkylguanine Alkyltransferase

O⁶-Alkylguanine DNA adducts are repaired by the suicide enzyme alkylguanine alkyltransferase (AGT). AGT facilitates repair by binding DNA in the minor groove, flipping out the damaged base, and transferring the O⁶-alkyl group to a cysteine residue in the enzyme's active site. Despite there being significant knowledge concerning the mechanism of AGT repair, there is limited insight regarding how altered interactions of the adduct with its complementary base in the DNA duplex influence its recognition and repair. In this study, the relationship of base pairing interactions and repair by human AGT (hAGT) was tested in the frequently mutated codon 12 of the KRAS gene with complementary sequences containing each canonical DNA base. The rate of O⁶-MeG repair decreased 2-fold when O⁶-MeG was paired with G, whereas all other canonical bases had no impact on the repair rate. We used a combination of biochemical studies, molecular modeling, and artificial nucleobases to elucidate the mechanism accounting for the 2-fold decrease. Our results suggest that the reduced rate of repair is due to O⁶-MeG adopting a syn conformation about the glycosidic bond precluding the formation of a repair-active complex. These data provide a novel chemical basis for how direct reversion repair may be impeded through modification of the base pair partner and support the use of artificial nucleobases as tools to probe the biochemistry of damage repair processes.

Configurational and Conformational Equilibria of N6-(2-Deoxy-d-erythro-pentofuranosyl)-2,6-diamino-3,4-dihydro-4-oxo-5- N-methylformamidopyrimidine (MeFapy-dG) Lesion in DNA

The most common lesion in DNA occurring due to clinical treatment with Temozolomide or cellular exposures to other methylating agents is 7-methylguanine (N7-Me-dG). It can undergo a secondary reaction to form N⁶-(2-deoxy-d-erythro-pentofuranosyl)-2,6-diamino-3,4-dihydro-4-oxo-5- N-methylformamidopyrimidine (MeFapy-dG). MeFapy-dG undergoes epimerization in DNA to produce either α or β deoxyribose anomers. Additionally, conformational rotation around the formyl bond, C5- N⁵ bond, and glycosidic bond may occur. To characterize and quantitate the mixture of these isomers in DNA, a ¹³C-MeFapy-dG lesion, in which the CH₃ group of the MeFapy-dG was isotopically labeled, was incorporated into the trimer 5'-TXT-3' and the dodecamer 5'-CATXATGACGCT-3' (X = ¹³C-MeFapy-dG). NMR spectroscopy of both the trimer and dodecamer revealed that the MeFapy-dG lesion exists in single strand DNA as ten configurationally and conformationally discrete species, eight of which may be unequivocally assigned. In the duplex dodecamer, the MeFapy-dG lesion exists as six configurationally and conformationally discrete species. Analyses of NMR data in the single strand trimer confirm that for each deoxyribose anomer, atropisomerism occurs around the C5- N⁵ bond to produce R _a and S _a atropisomers. Each atropisomer exhibits geometrical isomerism about the formyl bond yielding E and Z conformations. ¹H NMR experiments allow the relative abundances of the species to be determined. For the single strand trimer, the α and β anomers exist in a 3:7 ratio, favoring the β anomer. For the β anomer, with respect to the C5- N⁵ bond, the R _a and S _a atropisomers are equally populated. However, the Z geometrical isomer of the formyl moiety is preferred. For the α anomer, the E- S _a isomer is present at 12%, whereas all other isomers are present at 5-7%. DNA processing enzymes may differentially recognize different isomers of the MeFapy-dG lesion. Moreover, DNA sequence-specific differences in the populations of configurational and conformational species may modulate biological responses to the MeFapy-dG lesion.

DNA damage in a liver tissue of metal exposed Clethrionomys glareolus

It is widely known that some toxic agents may act on DNA strand resulting in its damages. One of the possible impairments is formation of abasic sites in DNA. The aim of this study was to indicate a presence of these DNA sites in the liver tissue of bank voles inhabiting the vicinity of zinc/lead smelters. Samples that were used originated from animals collected from unpolluted (Niepołomice, Teleśnica Oszwarowa, Mikołajki) and polluted (Miasteczko Śląskie, Katowice, Olkusz) populations. They significantly differed in terms of tissue lead concentrations in the kidney and liver. The means of detected AP sites per 10⁵ bp ranged between 3.39 (Teleśnica Oszwarowa) to 5.13 (Miasteczko Śląskie). Statistical analysis (ANOVA) showed no difference in terms of number of the AP sites between single populations. However, t-test showed significant difference between the unpolluted and polluted populations. Factorial ANOVA indicated that sex is not a factor influencing the number of AP sites. The analyses revealed statistically significant relationships between the number of AP sites and Cu concentrations in the liver, and also Pb and Cd concentrations in the kidney.

Theoretical characterization of the conformational features of unnatural oligonucleotides containing a six nucleotide genetic alphabet

The addition of the unnatural P:Z base pair to the four naturally occurring DNA bases expands the genetic alphabet and yields an artificially expanded genetic information system (AEGIS). Herein, the structural feature of oligonucleotides containing a novel unnatural P:Z base pair is characterized using both molecular dynamics and quantum chemistry. The results show that the incorporation of the novel artificial base pair (P:Z) preserves the global conformational feature of duplex DNA except for some local structures. The Z-nitro group imparts new properties to the groove width, which widens the major groove. The unnatural oligonucleotides containing mismatched base pairs exhibit low stability. This ensures efficient and high-fidelity replication. In general, the incorporation of the P:Z pair strengthens the stability of the corresponding DNA duplex. The calculated results also show that the thermostability originates from both hydrogen interaction and stacking interaction. The Z-nitro group plays an important role in enhancing the stability of the H-bonds and stacking strength of the P:Z pair. Overall, the present results provide theoretical insights in the exploration of artificially expanded genetic information systems.

Reverse Transcription Past Products of Guanine Oxidation in RNA Leads to Insertion of A and C opposite 8-Oxo-7,8-dihydroguanine and A and G opposite 5-Guanidinohydantoin and Spiroiminodihydantoin Diastereomers

Reactive oxygen species, both endogenous and exogenous, can damage nucleobases of RNA and DNA. Among the nucleobases, guanine has the lowest redox potential, making it a major target of oxidation. Although RNA is more prone to oxidation than DNA is, oxidation of guanine in RNA has been studied to a significantly lesser extent. One of the reasons for this is that many tools that were previously developed to study oxidation of DNA cannot be used on RNA. In the study presented here, the lack of a method for seeking sites of modification in RNA where oxidation occurs is addressed. For this purpose, reverse transcription of RNA containing major products of guanine oxidation was used. Extension of a DNA primer annealed to an RNA template containing 8-oxo-7,8-dihydroguanine (OG), 5-guanidinohydantoin (Gh), or the R and S diastereomers of spiroiminodihydantoin (Sp) was studied under standing start conditions. SuperScript III reverse transcriptase is capable of bypassing these lesions in RNA inserting predominantly A opposite OG, predominantly G opposite Gh, and almost an equal mixture of A and G opposite the Sp diastereomers. These data should allow RNA sequencing of guanine oxidation products by following characteristic mutation signatures formed by the reverse transcriptase during primer elongation past G oxidation sites in the template RNA strand.

Recognition of DNA abasic site nanocavity by fluorophore-switched probe: Suitable for all sequence environments

Removal of a damaged base in DNA produces an abasic site (AP site) nanocavity. If left un-repaired in vivo by the specific enzyme, this nanocavity will result in nucleotide mutation in the following DNA replication. Therefore, selective recognition of AP site nanocavity by small molecules is important for identification of such DNA damage and development of genetic drugs. In this work, we investigate the fluorescence behavior of isoquinoline alkaloids including palmatine (PAL), berberine (BER), epiberberine (EPI), jatrorrhizine (JAT), coptisine (COP), coralyne (COR), worenine (WOR), berberrubine (BEU), sanguinarine (SAN), chelerythrine (CHE), and nitidine (NIT) upon binding with the AP nanocavity. PAL is screened out as the most efficient fluorophore-switched probe to recognize the AP nanocavity over the fully matched DNA. Its fluorescence enhancement occurs for all of the AP nanocavity sequence environments, which has not been achieved by the previously used probes. The bridged π conjugation effect should partially contribute to the AP nanocavity-specific fluorescence, as opposed to the solvent effect. Due to the strong binding with the AP nanocavity, PAL will find wide applications in the DNA damage recognition and sensor development.

The Effect of Diagnostic Absorbed Doses from 131I on Human Thyrocytes in Vitro

Background: Administration of diagnostic activities of ¹³¹I, performed in order to detect thyroid remnants after surgery and/or thyroid cancer recurrence/metastases, may lead to reduction of iodine uptake. This phenomenon is called “thyroid stunning”. We estimated radiation absorbed dose-dependent changes in genetic material, in particular in sodium iodide symporter (NIS) gene promoter, and NIS protein level in human thyrocytes (HT). Materials and Methods: We used unmodified HT isolated from patients subjected to thyroidectomy exposed to ¹³¹I in culture. The different ¹³¹I activities applied were calculated to result in absorbed doses of 5, 10, and 20 Gy. Results: According to flow cytometry analysis and comet assay, ¹³¹I did not influence the HT viability in culture. Temporary increase of 8-oxo-dG concentration in HT directly after 24 h (p < 0.05) and increase in the number of AP-sites 72 h after termination of exposition to 20 Gy dose (p < 0.0001) were observed. The signs of dose-dependent DNA damage were not associated with essential changes in the NIS expression on mRNA and protein levels. Conclusions: Our observation constitutes a first attempt to evaluate the effect of the absorbed dose of ¹³¹I on HT. The results have not confirmed the theory that the “thyroid stunning” reduces the NIS protein synthesis.

Interactions of Ru(ii) polypyridyl complexes with DNA mismatches and abasic sites

Ru(ii) polypyridyl complexes bind to CC mismatch DNA with high selectivity.

O6-alkylguanine postlesion DNA synthesis is correct with the right complement of hydrogen bonding

The ability of a DNA polymerase to replicate DNA beyond a mismatch containing a DNA lesion during postlesion DNA synthesis (PLS) can be a contributing factor to mutagenesis. In this study, we investigate the ability of Dpo4, a Y-family DNA polymerase from Sulfolobus solfataricus, to perform PLS beyond the pro-mutagenic DNA adducts O(6)-benzylguanine (O(6)-BnG) and O(6)-methylguanine (O(6)-MeG). Here, O(6)-BnG and O(6)-MeG were paired opposite artificial nucleosides that were structurally altered to systematically test the influence of hydrogen bonding and base pair size and shape on O(6)-alkylguanine PLS. Dpo4-mediated PLS was more efficient past pairs containing Benzi than pairs containing the other artificial nucleoside probes. Based on steady-state kinetic analysis, frequencies of mismatch extension were 7.4 × 10(-3) and 1.5 × 10(-3) for Benzi:O(6)-MeG and Benzi:O(6)-BnG pairs, respectively. Correct extension was observed when O(6)-BnG and O(6)-MeG were paired opposite the smaller nucleoside probes Benzi and BIM; conversely, Dpo4 did not extend past the larger nucleoside probes, Peri and Per, placed opposite O(6)-BnG and O(6)-MeG. Interestingly, Benzi was extended with high fidelity by Dpo4 when it was paired opposite O(6)-BnG and O(6)-MeG but not opposite G. These results indicate that hydrogen bonding is an important noncovalent interaction that influences the fidelity and efficiency of Dpo4 to perform high-fidelity O(6)-alkylguanine PLS.

Plant DNA-damage repair/toleration 100 protein repairs UV-B-induced DNA damage

We report the characterization of VvDRT100-L, a grape DNA-damage repair/toleration 100 protein. VvDRT100-L has nine leucine-rich repeats and belongs to the plant DRT100 protein family. VvDRT100-L is expressed abundantly in green organs of grapevines, including tendrils, leaves, and green berry skins. The overexpression of VvDRT100-L in Arabidopsis plants decreased the number of abasic sites and the frequency of DNA single-strand breaks in the DNA damaged by UV-B irradiation, whereas UV-B irradiation markedly increased the number of abasic sites and the frequency of DNA single-strand breaks in T-DNA insertion mutant drt100 plants. VvDRT100-L-overexpressing plants remained viable and noticeably healthy under lethal UV doses, suggesting that VvDRT100-L may enhance UV tolerance in plant. Taken together, we concluded that VvDRT100-L might play an important role in the repair and toleration of UV-B-induced DNA damage. These findings would help us better understand how plants acquire UV stress acclimation, tolerance and DNA repair.

Metal-mediated DNA damage and cell death: mechanisms, detection methods, and cellular consequences

Metal ions cause various types of DNA damage by multiple mechanisms, and this damage is a primary cause of cell death and disease.

Targeting abasic site-containing DNA with annelated quinolizinium derivatives: the influence of size, shape and substituents

A comparative analysis showed that the type and degree of annelation as well as methyl or chloro-substitution are relevant structural features that determine the interactions of quinolizinium derivatives with abasic site-containing DNA.

Evidence for endogenous formation of the hepatocarcinogen N-nitrosodihydrouracil in rats treated with dihydrouracil and sodium nitrite: a potential source of human hepatic DNA carboxyethylation

An earlier study demonstrated that hydrolysates of all human liver DNA samples analyzed contain the DNA adduct 7-(2'-carboxyethyl)guanine (7-CEGua) with an average level of 74.6 adducts per 10(9) nucleotides. One possible source of this DNA adduct would be endogenous nitrosation of the normal pyrimidine metabolites dihydrouracil (DHU) and β-ureidopropionic acid (β-UPA), yielding the corresponding nitroso compounds N-nitrosodihydrouracil, a potent hepatocarcinogen, and N-nitroso-β-ureidopropionic acid. Another potential source would be reaction of endogenously formed acrylic acid with DNA. We tested these hypotheses in a study in which rats were treated with NaNO2 in the drinking water, alone, or in combination with dietary DHU or β-UPA, or with acrylic acid in the drinking water, for either 2 or 4 weeks. Hepatic DNA from these rats was analyzed for 7-CEGua, using liquid chromatography-tandem mass spectrometry-selected reaction monitoring with confirmation by high resolution mass spectrometry. The results demonstrated consistent statistically significant increases of 7-CEGua in hepatic DNA of the rats treated with the combination of NaNO2 and DHU compared to the corresponding controls, while the other treatments gave variable results. These results support the hypothesis that endogenous nitrosation of DHU could be a major source of 7-CEGua in human hepatic DNA. Development of methodology for analysis of 7-CEGua in human leukocyte DNA is also reported, which will allow testing of this hypothesis in epidemiologic and clinical studies.

From "Click" to "Fenton" chemistry for 5-bromo-2'-deoxyuridine determination

Ascorbic acid (AA) and copper have been increasingly employed in flow cytometry (FCM) and high content analysis (HCA) since the introduction of "click chemistry" as a non-destructive alternative to classical 5-bromo-2'-deoxyuridine (BrdU) immunodetection for DNA synthesis and proliferation assays. Mixtures of ascorbate and catalytic copper, under certain experimental conditions, act as oxidizing agent, catalyzing the formation of reactive hydroxyl radicals through hydrogen peroxides decomposition via Fenton reaction. We developed a procedure for BrdU incorporation detection based on the use of AA and cupric ions as DNA damaging agents. Optimal DNA damaging conditions were identified and found to provide results comparable with "click" 5-ethynyl-deoxyuridine (EdU) cycloaddition approach and classical BrdU immunodetection. Scavenger agents were found to prevent hydroxyl-induced DNA damages, providing the proof-of-concept for the use of this procedure for DNA denaturation prior to BrdU detection. We demonstrated hydroxyl radicals' reaction to be readily applicable to HCA and FCM assays, for both classical BrdU immunostaining and EdU cycloaddition procedure. This technique was successfully employed for BrdU pulse-chase experiments and in multiparametric immunofluorescence assays for the simultaneous detection of labile phosphoproteins in intact cells. The use of AA/Cu prior to immunodetection for BrdU incorporation assays is a viable alternative to chemical/physical DNA denaturing agents (acids or heat), since it allows preservation of labile epitopes such as phosphoproteins, and over enzymatic agents (digestion with DNases) for its lower cost.

Recognition of O6-benzyl-2'-deoxyguanosine by a perimidinone-derived synthetic nucleoside: a DNA interstrand stacking interaction

The 2'-deoxynucleoside containing the synthetic base 1-[(2R,4S,5R)-4-hydroxy-5-(hydroxymethyl)-tetrahydrofuran-2-yl)-1H-perimidin-2(3H)-one] (dPer) recognizes in DNA the O(6)-benzyl-2'-deoxyguanosine nucleoside (O(6)-Bn-dG), formed by exposure to N-benzylmethylnitrosamine. Herein, we show how dPer distinguishes between O(6)-Bn-dG and dG in DNA. The structure of the modified Dickerson-Drew dodecamer (DDD) in which guanine at position G(4) has been replaced by O(6)-Bn-dG and cytosine C(9) has been replaced with dPer to form the modified O(6)-Bn-dG:dPer (DDD-XY) duplex [5'-d(C(1)G(2)C(3)X(4)A(5)A(6)T(7)T(8)Y(9)G(10)C(11)G(12))-3']2 (X = O(6)-Bn-dG, Y = dPer) reveals that dPer intercalates into the duplex and adopts the syn conformation about the glycosyl bond. This provides a binding pocket that allows the benzyl group of O(6)-Bn-dG to intercalate between Per and thymine of the 3'-neighbor A:T base pair. Nuclear magnetic resonance data suggest that a similar intercalative recognition mechanism applies in this sequence in solution. However, in solution, the benzyl ring of O(6)-Bn-dG undergoes rotation on the nuclear magnetic resonance time scale. In contrast, the structure of the modified DDD in which cytosine at position C(9) is replaced with dPer to form the dG:dPer (DDD-GY) [5'-d(C(1)G(2)C(3)G(4)A(5)A(6)T(7)T(8)Y(9)G(10)C(11)G(12))-3']2 duplex (Y = dPer) reveals that dPer adopts the anti conformation about the glycosyl bond and forms a less stable wobble pairing interaction with guanine.

Oligonucleotide probes containing pyrimidine analogs reveal diminished hydrogen bonding capacity of the DNA adduct O⁶-methyl-G in DNA duplexes

Oligonucleotide hybridization probes containing nucleoside analogs offer a potential strategy for binding specific DNA sequences that bear pro-mutagenic O(6)-G alkylation adducts. To optimize O(6)-Me-G-targeting probes, an understanding of how base pairs with O(6)-Me-G are stabilized is needed. In this study, we compared the ability of O(6)-Me-G and G to hydrogen bond with three pyrimidine-like nucleobases (Z, 4-thio-U, and 3-deaza-C) bearing varied hydrogen bond donor and acceptor groups. We found that duplexes containing the pyrimidine analog nucleoside:G pairs were more thermodynamically stable than those containing pyrimidine analog nucleoside:O(6)-alkyl-G pairs. Thus, hydrogen bonding alone was not sufficient to impart selectivity to probes that target O(6)-G alkylation adducts in DNA.

Mutagenic spectra arising from replication bypass of the 2,6-diamino-4-hydroxy-N(5)-methyl formamidopyrimidine adduct in primate cells

DNA exposures to electrophilic methylating agents that are commonly used during chemotherapeutic treatments cause diverse chemical modifications of nucleobases, with reaction at N7-dG being the most abundant. Although this base modification frequently results in destabilization of the glycosyl bond and spontaneous depurination, the adduct can react with hydroxide ion to yield a stable, ring-opened MeFapy-dG, and this lesion has been reported to persist in animal tissues. Results from prior in vitro replication bypass investigations of the MeFapy-dG adduct had revealed complex spectra of replication errors that differed depending on the identity of DNA polymerase and the local sequence context. In this study, a series of nine site-specifically modified MeFapy-dG-containing oligodeoxynucleotides were engineered into a shuttle vector and subjected to replication in primate cells. In all nine sequence contexts examined, MeFapy-dG was shown to be associated with a strong mutator phenotype, predominantly causing base substitutions, with G to T transversions being most common. Single and dinucleotide deletions were also found in a subset of the sequence contexts. Interestingly, single-nucleotide deletions occurred at not only the adducted site, but also one nucleotide downstream of the adduct. Standard models for primer-template misalignment could account for some but not all mutations observed. These data demonstrate that in addition to mutagenesis predicted from replication of DNAs containing O(6)-Me-dG and O(4)-Me-dT, the MeFapy-dG adduct likely contributes to mutagenic events following chemotherapeutic treatments.

Measurement of translesion synthesis by fluorescent capillary electrophoresis: 7,8-dihydro-8-oxodeoxyguanosine bypass modulation by natural products

Translesion synthesis (TLS) relies on a series of specialized DNA polymerases able to insert a base either correctly or incorrectly opposite a lesion on a DNA template strand during replication or post-repair synthesis. To measure the correct or mutagenic outcome of 7,8-dihydro-8-oxodeoxyguanosine (8-oxodG) bypass by TLS DNA polymerases, a capillary electrophoresis (CE) method with fluorescent label has been developed. Two oligonucleotides were designed and hybridized: (i) a 72-mer oligonucleotide framing one 8-oxodG at position 40 and (ii) the 39-mer oligonucleotide complementary to the first strand from the 3' end to the lesion and labeled at the 5' end with a fluorochrome. After incubation with FHs 74 Int human intestinal epithelial cell nuclear proteins, in the presence of either deoxyadenosine triphosphate (dATP) or deoxycytidine triphosphate (dCTP), and denaturation, the resulting elongated oligomers were analyzed by fluorescent capillary electrophoresis. This primer extension assay was then validated in terms of linearity (linear range=0.5-2.5 nM), detectability (limits of detection and quantification=0.023 and 0.091 nM, respectively), and precision (total precisions=8.1% and 3.7% for dATP and dCTP, respectively, n=9). The addition of some natural phytochemicals to the reaction mix significantly influences the outcome of TLS either in an error-free way or in a mutagenic way.

Tolerance of base pair size and shape in postlesion DNA synthesis

The influence of base pair size and shape on the fidelity of DNA polymerase-mediated extension past lesion-containing mispairs was examined. Primer extension analysis was performed with synthetic nucleosides paired opposite the pro-mutagenic DNA lesion O(6)-benzylguanine (O(6)-BnG). These data indicate that the error-prone DNA polymerase IV (Dpo4) inefficiently extended past the larger Peri:O(6)-BnG base pair, and in contrast, error-free extension was observed for the smaller BIM:O(6)-BnG base pair. Steady-state kinetic analysis revealed that Dpo4 catalytic efficiency was strongly influenced by the primer:template base pair. Compared to the C:G pair, a 1.9- and 79,000-fold reduction in Dpo4 efficiency was observed for terminal C:O(6)-BnG and BIM:G base pairs respectively. These results demonstrate the impact of geometrical size and shape on polymerase-mediated mispair extension.

Synthesis and photophysical characterisation of a fluorescent nucleoside analogue that signals the presence of an abasic site in RNA

The synthesis and site-specific incorporation of an environment-sensitive fluorescent nucleoside analogue (2), based on a 5-(benzofuran-2-yl)pyrimidine core, into DNA oligonucleotides (ONs), and its photophysical properties within these ONs are described. Interestingly and unlike 2-aminopurine (a widely used nucleoside analogue probe), when incorporated into an ON and hybridised with a complementary ON, the emissive nucleoside 2 displays significantly higher emission intensity than the free nucleoside. Furthermore, photophysical characterisation shows that the fluorescence properties of the nucleoside analogue within ONs are significantly influenced by flanking bases, especially by guanosine. By utilising the responsiveness of the nucleoside to changes in base environment, a DNA ON reporter labelled with the emissive nucleoside 2 was constructed; this signalled the presence of an abasic site in a model depurinated sarcin/ricin RNA motif of a eukaryotic 28S rRNA.

Metabolic imbalance associated with methylation dysregulation and oxidative damage in children with autism

Oxidative stress and abnormal DNA methylation have been implicated in the pathophysiology of autism. We investigated the dynamics of an integrated metabolic pathway essential for cellular antioxidant and methylation capacity in 68 children with autism, 54 age-matched control children and 40 unaffected siblings. The metabolic profile of unaffected siblings differed significantly from case siblings but not from controls. Oxidative protein/DNA damage and DNA hypomethylation (epigenetic alteration) were found in autistic children but not paired siblings or controls. These data indicate that the deficit in antioxidant and methylation capacity is specific for autism and may promote cellular damage and altered epigenetic gene expression. Further, these results suggest a plausible mechanism by which pro-oxidant environmental stressors may modulate genetic predisposition to autism.

Synthesis and binding properties of new selective ligands for the nucleobase opposite the AP site

DNA is continuously damaged by endogenous and exogenous factors such as oxidative stress or DNA alkylating agents. These damaged nucleobases are removed by DNA N-glycosylase and form apurinic/apyrimidinic sites (AP sites) as intermediates in the base excision repair (BER) pathway. AP sites are also representative DNA damages formed by spontaneous hydrolysis. The AP sites block DNA polymerase and a mismatch nucleobase is inserted opposite the AP sites by polymerization to cause acute toxicities and mutations. Thus, AP site specific compounds have attracted much attention for therapeutic and diagnostic purposes. In this study, we have developed nucleobase-polyamine conjugates as the AP site binding ligand by expecting that the nucleobase part would play a role in the specific recognition of the nucleobase opposite the AP site by the Watson-Crick base pair formation and that the polyamine part should contribute to the access of the ligand to the AP site by a non-specific interaction to the DNA phosphate backbone. The nucleobase conjugated with 3,3'-diaminodipropylamine (A-ligand, G-ligand, C-ligand, T-ligand and U-ligand) showed a specific stabilization of the duplex containing the AP site depending on the complementary combination with the nucleobase opposite the AP site; that is A-ligand to T, G-ligand to C, C-ligand to G, T- and U-ligand to A. The thermodynamic binding parameters clearly indicated that the specific stabilization is due to specific binding of the ligands to the complementary AP site. These results have suggested that the complementary base pairs of the Watson-Crick type are formed at the AP site.

Capillary monolithic bioreactor of immobilized snake venom phosphodiesterase for mass spectrometry based oligodeoxynucleotide sequencing

A capillary monolithic bioreactor of snake venom phosphodiesterase (SVP) was constructed to generate different single-nucleotide mass ladders of oligodeoxynucleotides for mass spectrometry (MS)-based sequencing by immobilization. The immobilization of SVP in the porous silica monolith significantly enhances its stability for prolonged and repeated applications. The constructed capillary bioreactor has the advantages of handling (sub)microliter DNA samples and having good permeability. Benefiting from its good permeability, DNA solutions can be directly injected into the sequential digestion bioreactor simply by hand pushing or a low-pressure microinjection pump. Moreover, the immobilization of SVP facilitates the elimination or repression of the metal adducts of oligodeoxynucleotides, improving the analytical performance of MS sequencing. By the application of capillary bioreactor of immobilized SVP, the sequence-specific modification of single-stranded oligodeoxynucleotide induced by a ubiquitous pollutant acrolein (Acr) was identified, demonstrating its promising applications in identification of sequence-specific damage, which may further our understanding of DNA damage caused mutagenesis.

Synthesis, characterization, thermal behavior, and DNA-cleaving studies of cyano-bridged nickel(II)-copper(II) complexes of 4-(pyridin-2-ylazenyl)resorcinol

We present here the syntheses of a mononuclear Cu(II) complex and two polynuclear Cu(II)-Ni(II) complexes of the azenyl ligand, 4-(pyridin-2-ylazenyl)resorcinol (HL; 1). The reaction of HL (1) and copper(II) perchlorate with KCN gave a mononuclear complex [CuL(CN)] (4). Using 4, one pentanuclear complex, [{CuL(NC)}(4) Ni](ClO(4))(2) (5) and one trinuclear complex, [{CuL(CN)}(2) NiL]ClO(4) (6), were prepared and characterized by elemental analyses, magnetic susceptibility, molar conductance, IR, and thermal analysis. Stoichiometric and spectral results of the mononuclear Cu(II) complex indicated that the metal/ligand/CN ratio was 1 : 1 : 1, and the ligand behaved as a tridentate ligand forming neutral metal chelates through the pyridinyl and azenyl N-, and resorcinol O-atom. The interaction between the compounds (the ligand 1, its Ni(II) and Cu(II) complexes without CN, i.e., 2 and 3, and its complexes with CN, 4-6) and DNA has also been investigated by agarose gel electrophoresis. The pentanuclear Cu(4) Ni complex (5) with H(2) O(2) as a co-oxidant exhibited the strongest DNA-cleaving activity.

Evolution of research on the DNA adduct chemistry of N-nitrosopyrrolidine and related aldehydes

This perspective reviews our work on the identification of DNA adducts of N-nitrosopyrrolidine and some related aldehydes. The research began as a focused project to investigate mechanisms of cyclic nitrosamine carcinogenesis but expanded into other areas, as aldehyde metabolites of NPYR were shown to have their own diverse DNA adduct chemistry. A total of 69 structurally distinct DNA adducts were identified, and some of these, found in human tissues, have provided intriguing leads for investigating carcinogenesis mechanisms in humans due to exposure to both endogenous and exogenous agents.

Tissue-specific distribution and dynamic changes of 5-hydroxymethylcytosine in mammalian genomes

Cytosine residues in the vertebrate genome are enzymatically modified to 5-methylcytosine, which participates in transcriptional repression of genes during development and disease progression. 5-Methylcytosine can be further enzymatically modified to 5-hydroxymethylcytosine by the TET family of methylcytosine dioxygenases. Analysis of 5-methylcytosine and 5-hydroxymethylcytosine is confounded, as these modifications are indistinguishable by traditional sequencing methods even when supplemented by bisulfite conversion. Here we demonstrate a simple enzymatic approach that involves cloning, identification, and quantification of 5-hydroxymethylcytosine in various CCGG loci within murine and human genomes. 5-Hydroxymethylcytosine was prevalent in human and murine brain and heart genomic DNAs at several regions. The cultured cell lines NIH3T3 and HeLa both displayed very low or undetectable amounts of 5-hydroxymethylcytosine at the examined loci. Interestingly, 5-hydroxymethylcytosine levels in mouse embryonic stem cell DNA first increased then slowly decreased upon differentiation to embryoid bodies, whereas 5-methylcytosine levels increased gradually over time. Finally, using a quantitative PCR approach, we established that a portion of VANGL1 and EGFR gene body methylation in human tissue DNA samples is indeed hydroxymethylation.

Synthesis of oxygen-linked 8-phenoxyl-deoxyguanosine nucleoside analogues

Nucleobase adducts, which form in vivo by the nucleophilic attack of nucleobases on exogenous electrophilic species, can impact conformation and biological influences of the adducted nucleoside. Contemporary studies aim to address the occurrence and relevance of O-linked 8-phenoxy-purine adducts; however, preparative techniques for synthesizing these nucleosides were not previously described. Reported herein is a relatively facile synthesis of O-linked 8-dG phenol adducts with a wide variety of electron-donating, electron-withdrawing, and sterically demanding phenols.

Thiol-activated DNA damage by α-bromo-2-cyclopentenone

Some biologically active chemicals are relatively stable in the extracellular environment but, upon entering the cell, undergo biotransformation into reactive intermediates that covalently modify DNA. The diverse chemical reactions involved in the bioactivation of DNA-damaging agents are both fundamentally interesting and of practical importance in medicinal chemistry and toxicology. The work described here examines the bioactivation of α-haloacrolyl-containing molecules. The α-haloacrolyl moiety is found in a variety of cytotoxic natural products including clionastatin B, bromovulone III, discorahabdins A, B, and C, and trichodenone C, in mutagens such as 2-bromoacrolein and 3-chloro-4-(dichloromethyl)-5-hydroxy-2(5H)-furanone (MX), and in the anticancer drug candidates brostallicin and PNU-151807. Using α-bromo-2-cyclopentenone (1) as a model compound, the activation of α-haloacrolyl-containing molecules by biological thiols was explored. The results indicate that both low molecular weight and peptide thiols readily undergo conjugate addition to 1. The resulting products are consistent with a mechanism in which initial addition of thiols to 1 is followed by intramolecular displacement of bromide to yield a DNA-alkylating episulfonium ion intermediate. The reaction of thiol-activated 1 with DNA produces labile lesions at deoxyguanosine residues. The sequence specificity and salt dependence of this process is consistent with involvement of an episulfonium ion intermediate. The alkylated guanine residue resulting from the thiol-triggered reaction of 1 with duplex DNA was characterized using mass spectrometry. The results provide new insight regarding the mechanisms by which thiols can bioactivate small molecules and offer a more complete understanding of the molecular mechanisms underlying the biological activity of cytotoxic, mutagenic, and medicinal compounds containing the α-haloacrolyl group.

Superoxide anion and hydrogen peroxide-induced signaling and damage in angiotensin II and aldosterone action

The formation of reactive oxygen species (ROS) can be induced by xenobiotic substances, such as redox cycling molecules, but also by endogenous substances such as hormones and cytokines. Recent research shows the importance of ROS in cellular signaling. Here, the signaling pathways of the two blood pressure-regulating hormones angiotensin II and aldosterone are presented, focusing on both their physiological effects and the change of signaling owing to the action of increased concentrations or prolonged exposure. When present in high concentrations, both angiotensin II and aldosterone, as various other endogenous substances, activate NADPH oxidase, which produces superoxide. In this review the generation of superoxide anions and hydrogen peroxide in cells stimulated with angiotensin II or aldosterone, as well as the subsequently induced signaling processes and DNA damage is discussed.

Quantification of DNase type I ends, DNase type II ends, and modified bases using fluorescently labeled ddUTP, terminal deoxynucleotidyl transferase, and formamidopyrimidine-DNA glycosylase

Here we describe the substitution of fluorescently labeled ddUTP for dUTP in the TUNEL assay to allow quantification of generated fluorescence signals by epifluorescence microscopy. The capping of DNase type I 3'OH DNA ends using ddTUNEL was further combined with phosphatase treatment for detection of DNase type II 3'PO4 ends in the same sample using a second round of ddTUNEL. Levels of modified DNA bases in tissues and fixed cultured cells could be interrogated in the ddTUNEL assay with the base modification repair enzyme formamidopyrimidine DNA glycosylase. Using rat mammary gland, from days 1 and 7 of involution, we validate the methodology's ability to label apoptotic nuclei and apoptotic inclusion bodies. In addition, we examined the types of DNA damage and modification that occur in human glioblastoma, U87 cells, following exposure to reactive oxygen stressing agents, chemotherapeutic alkylating agents, and a topoisomerase I inhibitor, irinotecan.

Detection of 7-(2'-carboxyethyl)guanine but not 7-carboxymethylguanine in human liver DNA

7-Carboxymethylguanine (7-CMGua) and 7-(2'-carboxyethyl)guanine (7-CEGua) are DNA adducts that potentially could be formed upon the metabolism of the carcinogenic nitrosamines N-nitrososarcosine (NSAR) and 3-(methylnitrosamino)propionic acid (MNPA), respectively, or from other sources such as nitrosation of glycine (7-CMGua) or reaction of DNA with acrylic acid (7-CEGua). Since both NSAR and MNPA have been detected in human urine and there are plausible sources of exposure to other precursors to these adducts, we analyzed human liver DNA for 7-CMGua and 7-CEGua, using liquid chromatography-electrospray ionization-tandem mass spectrometry-selected reaction monitoring (LC-ESI-MS/MS-SRM). Human hepatic DNA was mixed with [15N5]7-CMGua and [15N5]7-CEGua as internal standards and enzymatically hydrolyzed. The hydrolysate was partially purified by solid-phase extraction, and the resulting fraction was treated with acetyl chloride in methanol to convert 7-CMGua and 7-CEGua to their methyl esters. After a second solid-phase extraction, LC-ESI-MS/MS-SRM analysis was carried out using the transitions m/z 224 [M + H](+) --> m/z 164 [(M + H)-HCOOCH3]+ and m/z 238 [M + H]+ --> m/z 152 [BH]+ for the methyl esters of 7-CMGua and 7-CEGua, respectively. The method was sensitive, accurate, precise, and apparently free from artifact formation. 7-CEGua, as its methyl ester, was detected in all 24 human liver samples analyzed, mean +/- SD, 373 +/- 320 fmol/mumol Gua (74.6 adducts per 10(9) nucleotides), range 17-1189 fmol/mumol Gua, but the methyl ester of 7-CMGua was not detected in any sample. These results demonstrate the ubiquitous presence of 7-CEGua in human liver DNA. Acrylic acid may be a likely endogenous precursor to 7-CEGua.