Photochemical reactions on the synthetic polymers containing thymine bases

Photodimerizations of N-2-isobutyloxyethyl thymine (T-M), bis[2-(5-methyl-1-pyrimidinyl)ethyl]glutarate (T-T), poly-N-2-methacryloyloxethyl thymine (P-MAOT) and poly-N-2-acryloyloxyethyl thymine (P-AOT) were studied in dimethylformamide solution. Quantum efficiencies of intramolecular photodimerizations were determined to be 0.0012 for T-T, 0.0084 for P-MAOT and 0.010 for P-AOT. In the case of T-M, however, intermolecular photodimerization did not occur under the reaction condition used. Quenching studies by using isoprene suggest that the photodimerization of T-T occurs predominantly through an excited triplet state, while that of P-MAOT and P-AOT occur through both singlet and triplet states. For the effect of adding model compounds containing adenine bases on this reaction, adenine derivatives acts as an inhibitor against this reaction by quenching the excited singlet state of thymine. The photodimers of T-T, P-MAOT and P-AOT were concluded to be two syn-fused cyclobutane- type dimers (cis-syn and trans-syn).     

The structure of d(CGCGAAT[]TCGCG) . d(CGCGAATTCGCG); the incorporation of a thymine photodimer into a B-DNA helix

In the light of the biological significance of thymine photodimers , studies of the energetics of the dodecanucleotide fragment d( CGCGAATTCGCG )2 have been carried out using the methods of molecular mechanics, with and without incorporation of a thymine dimer in the cis-syn configuration. The results of the calculations suggest that the thymine dimerized structures show no gross distortion in the double helix with the conformational changes relative to the normal B-DNA double helix restricted largely to the dimer region. The energetics of dTp[]dT reveal a number of conformers which are energetically almost equally favorable and are, as a group, qualitatively consistent with NMR studies on this molecule. The biological implications of the results of the conformational studies, reported here, have been examined vis-a-vis the currently available models for the recognition of DNA "damage" by repair enzymes.     

Ultraviolet light-induction and photoreactivation of thymine dimers in a cyanobacterium,Anacystis nidulans

Partially photoreactivable mutant of Anacystis nidulans demonstrates partial photorepair of thymine dimers. The wild type which is completely photoreactivable at the conditions studied shows higher level of thymine dimer photolysis.Abbreviations UV ultraviolet light, peak intensity at 254 nm - PR photoreactivation - Dm D medium of Kratz and Myers modified by van Baalen - WT wild type     

A sensitive radioimmuno assay for thymine dimers

Summary A sensitive radioimmuno assay (RIA) method for detection of the UV photoproduct, thymine dimers has been developed. The limit of detection of this method is 6×10^-14 mol or 15 pg thymine dimer. It is highly specific: A structurally similar compound such as uridine dimer interferes with the detection of thymine dimers only when it is 53,000-fold or more in molar excess. Since this RIA method does not require the use of labeled DNA, it represents a considerable improvement for repair studies with radiation-sensitive cells.     

Nucleosomal distribution of thymine photodimers following far- and near-ultraviolet irradiation

The nucleosomal distribution of cis-syn cyclobutyl-type thymine photodimers was determined in normal human skin fibroblasts following irradiation with low doses of far-ultraviolet light at 254 nm and nearultraviolet light at 313 nm. The thymine photodimer concentrations were determined by high pressure liquid chromatography in acid hydrolysates of total cellular DNA and of nucleosomal core- and chromatosomal-DNA. The lesion concentrations in linker-DNA were calculated from these data. While thymine photodimers were distributed uniformely following 254 nm irradiation they were enriched by a factor of 2.4 – 4.2 in nucleosomal linker DNA after exposure to 313 nm light.     

Predicting thymine dimerization yields from molecular dynamics simulations

It was recently shown that thymine dimers in the all-thymine oligonucleotide (dT)₁₈ are fully formed in <1 ps after ultraviolet excitation. The speed and low quantum yield of this reaction suggest that only a small fraction of the conformers of this structurally disordered oligonucleotide are in a position to react at the instant of photon absorption. In this work, we explore the hypothesis that conventional molecular dynamics simulations can be used to predict the yield of cyclobutane pyrimidine dimers in DNA. Conformations obtained from simulations of thymidylyl-(3′-5′)-thymidine in various cosolvents were classified as dimerizable or nondimerizable depending on the distance between the C5-C6 double bonds of the adjacent thymine bases and the torsion angle between them. The quantum yield of cyclobutane pyrimidine dimer formation was calculated as the number of dimerizable conformations divided by the total number of conformations. The experimental quantum yields measured in the different solvents were satisfactorily reproduced using physically reasonable values for the two parameters. The mean dimerizable structure computed by averaging all of the dimerizable cis-syn conformations is structurally similar to the actual cis-syn dimer. Compared to the canonical B-form TT step, the most important structural property of a dimerizable conformation is its reduced helical twist angle of 22°.     

Repair effect of thymine radical anion by echinocoside using pulse radiolysis

Repair activities of thymine radical anion by echinocoside, isolated from Pedicularis plicata. were studied using pulse radiolysis technique. The thymine radical anion was produced by the reaction of hydrated electron with thymine. Echinocoside. one of the polyphenols of phenylpropanoid glycoside, was added to the thymine aqueous solution saturated with N2. Kinetic analysis by transient absorption spectrum showed that thymine radical anion was formed at first, and then after several decades of microseconds of pulse radiolysis. the spectrum of thymine radical anion was changed to that of echinocoside radical anion. The evidence indicated that thymine radical anion was repaired through one-electron-transfer between the DNA base radical anion and echinocoside. The rate constant of electron transfer by echinocoside was 1.45× 109 dm3 · mol1 · s 1.     

Affinity of single- or double-stranded oligodeoxyribonucleotides containing a thymine photodimer for T4 endonuclease V

A gene for T4 endonuclease V was constructed by joining chemically synthesized oligodeoxyribonucleotides and expressed efficiently in Escherichia coli under the control of the E. coli tryptophan promoter. Overproduced T4 endonuclease V, which can cleave thymine photodimers as well as the corresponding phosphodiester linkage of DNA, was used to investigate the precise mode of the reaction with single- or double-stranded synthetic DNA fragments containing a thymine photodimer. The substrates, three oligodeoxyribonucleotides, d(GCGGTTGGCG) (10-mer), d(CGAAGGTTGGAAGC) (14-mer), and d(CACGAAGGTTGGAAGCAC) (18-mer), were prepared by UV irradiation of the nascent oligonucleotides. These single-stranded oligonucleotides were cleaved by the enzyme with a concentration 100 times higher than that required for the corresponding duplexes. The Km values for the TT duplex (14- and 18-mer) were found to be on the order of 10(-8) M. Dissociation constants for the 14- and 18-mer duplexes were measured by a binding assay on a nitrocellulose filter and found to be 10(-9).     

Photoaffinity labeling of T4 endonuclease V with a substrate containing a phenyldiazirine derivative.

T4 endonuclease V recognizes thymine photodimers in DNA duplexes and, in a two-step reaction, cleaves the glycosyl linkage of the 5'-side thymidine and the phosphodiester linkage. To determine the amino acid residues responsible for binding thymine photodimers, a photoaffinity reagent, 4-(1-azi-2,2,2-trifluoroethyl)-benzoate, was linked to the aminoalkylphosphonate of a thymine photodimer in a 14-mer duplex. The reactive substrate was treated with the enzyme under UV light (365 nm). The nascent enzyme and the modified enzyme were treated with lysyl endopeptidase, and the peptide maps were compared. Three peptides from the C terminus were found to interact with the reactive oligonucleotide to various extents. The three modified peptides were isolated and analyzed by Edman degradation. The amino acid residues Gly-133, Tyr-129, and Thr-89 were partially linked with the reactive substrate and may be involved in the binding of thymine photodimers.     

Detection of thymine [2+2] photodimer repair in DNA: selective reaction of KMnO4.

The specific reaction of potassium permanganate with thymine in single-stranded DNA was employed to analyze thymine [2+2] dimer repair in DNA and in DNA/peptide nucleic acid hybrid duplexes. This simple and highly sensitive chemical assay is convenient for monitoring repair of thymine dimers in oligonucleotides.     

Designing of MIP based QCM sensor having thymine recognition sites based on biomimicking DNA approach

Quartz crystal microbalance (QCM) sensors coated with molecular imprinted polymers (MIP) have been developed for the determination of thymine. In this method, methacryloylamidoadenine (MA-Ade) have used as a new monomer and thymine template for inspiration of DNA nucleobases interaction. The thymine can be simultaneously hydrogen binding to MA-Ade and fit into the shape-selective cavities. Thus, the interaction between nucleobases has an effect on the binding ability of the QCM sensors. The binding affinity of the thymine imprinted sensors has investigated by using the Langmuir isotherm. The thymine imprinted QCM electrodes have shown homogeneous binding sites for thymine (K_a: 1.0 × 10⁵ M⁻¹) while heterogeneous binding sites for uracil. On the other hand, recognition selectivity of the QCM sensor based on thymine imprinted polymer toward to uracil, ssDNA and ssRNA has been reported in this work.     

UV-Absorbing Substance in the Red Alga <Emphasis Type="Italic">Porphyra yezoensis</Emphasis> (Bangiales,Rhodophyta) Block Thymine Photodimer Production

The effect of the water-soluble UV-absorbing substance (UVAS) extracted from the marine red alga Porphyra yezoensis Ueda on UV-dependent thymine photodimer production was investigated. The T<>T pyrimidine-pyrimidone 6-4 dimer and the cyclobutane cis-syn T<>T 5-6 dimer produced by UV irradiation with a xenon lamp were analyzed by reverse-phase high-performance liquid chromatography. Although the dimer production was reduced when the irradiation was filtered through a UVAS solution, it decreased more when thymine was mixed with UVAS. Furthermore, UVAS inhibited the degradation of UV-irradiated thymine. The inhibitory effect of UVAS was significantly greater than that of exogenously added adenine or guanine, which forms complementary base pairs with thymine. These data suggest that in addition to its filtering effect against UV radiation, UVAS also protects thymine by a direct molecule-to-molecule energy transfer process. The protective function of UVAS against UV irradiation is advantageous for this alga under strong UV irradiation.     

Synthesis of a trans-syn thymine dimer building block. Solid phase synthesis of CGTAT[t,s]TATGC.

The synthesis of a building block for the sequence specific introduction of the trans-syn thymine dimer into oligonucleotides via solid phase DNA synthesis technology is described. CGTAT[t,s]TATGC was synthesized in 48% overall yield by a partially automated procedure. The stepwise coupling yield for addition of the trans-syn thymine dimer building block was 58%. The dimer containing oligonucleotide was characterized by 500 MHz 1H COSY and NOESY spectroscopy and 202.5 MHz 31P NMR. The 1H chemical shifts for the trans-syn thymine dimer unit of the decamer were found to be quite similar to those found for the trans-syn thymine dimer of TpT. Upon photolysis at 254 nm, CGTAT[t,s]TATGC was converted to a major product which coeluted with authentic CGTATTATGC and a minor product which coeluted with authentic CGTAT[c,s]TATGC, further supporting the presence of an intact trans-syn thymine dimer unit.     

Evaluation of 2-iminoimidazolidin-4-one and thymine as respective internal standards for normal-phase and reversed-phase high-performance liquid chromatographic determination of creatinine in human serum

We evaluated two internal standards for HPLC determination of creatinine in human serum after ultrafiltration: 2-iminoimidazolidin-4-one for normal-phase HPLC on aluminium oxide, and thymine for C₁₈ reversed-phase HPLC. Detection of 2-iminoimidazolidin-4-one was done at the same wavelength as that used for creatinine, i.e. 240 nm. For thymine, the wavelength was switched to 280 nm. The suitability of the selected compounds to serve as an internal standard in the described measurement procedures, including ultrafiltration of serum, was evaluated from the precision and accuracy obtained. The method based on normal-phase HPLC with 2-iminoimidazolidin-4-one showed an imprecision expressed as R.S.D. ranging from 0.8 to 3.4% (mean: 2.1%) and an inaccuracy, calculated from the deviations from target values determined by isotope-dilution gas chromatography-mass spectrometry, ranging from −1.3 to +1.8% (mean: +0.4%). For the reversed-phase HPLC procedure with thymine, the imprecision ranged from 0.3 to 1.3% (mean: 1.0%) and the inaccuracy from +0.1 to 3.9% (mean: +1.7%). The occasional observation of interferences with 2-iminoimidazolidin-4-one limited the application of the normal-phase method to a certain extent.     

Mechanisms of targeted frameshift mutations: Insertions arising during error-prone or SOS synthesis of DNA containing cis-syn cyclobutane thymine dimers

It is still unclear how frameshift mutations arise at cyclobutane pyrimidine dimers. The polymerase model is commonly used to explain the mechanisms of various mutations. An alternative polymerase-tautomer model was developed for UV-induced mutagenesis. A mechanism was proposed for targeted insertions caused by cis-syn cyclobutane thymine dimers. Targeted insertions are frameshift mutations due to addition of one or more nucleotides in a DNA sequence opposite to a lesion capable of stopping DNA synthesis. Among other factors, cyclobutane pyrimidine dimers can cause targeted insertions. UV irradiation can change the tautomeric form of DNA bases. Five rare tautomeric forms are possible for thymine, and they are stable when the thymine is a component of a cyclobutane dimer. A structural analysis showed that none of the canonical nucleotides can be added opposite to a specific rare thymine tautomer so that hydrogen bonds form between the two bases. A single nucleotide gap is consequently left in the corresponding site of the nascent strand when a specialized or modified DNA polymerase drives SOS or error-prone DNA synthesis on a template containing cis-syn cyclobutane thymine dimers with a base occurring in the rare tautomeric form. If the DNA composition is homogenous within the region, the end of the growing DNA strand may slip to form a complementary pair with the nucleotide adjacent to the dimer according to the Streisinger model, thus producing a loop. A targeted insertion is thereby generated to make the daughter strand longer. Targeted insertions were for the first time assumed to result from the cis-syn cyclobutane thymine dimers wherein one or both of the bases occur in the specific tautomeric form that does not allow the addition and hydrogen bonding of any canonical nucleotide in the opposite position. A model was developed to explain how targeted insertions of one or more nucleotides are caused by cis-syn cyclobutane thymine dimers. Thus, the polymerase-tautomer model can explain the nature and formation of targeted frameshift mutations in addition to hot and cold spots or targeted or untargeted nucleotide substitutions.     

Discrimination between translesion synthesis and template switching during bypass replication of thymine dimers in duplex DNA

The goal of this study was to determine whether bypass replication occurs by translesion synthesis or template switching (copy choice) when a duplex molecule carrying a single cis,syn-cyclobutane thymine dimer is replicated in vitro by human cell extracts. Circular heteroduplex DNA molecules were constructed to contain the SV40 origin of replication and a mismatch opposite to or nearby the dimer. Control molecules with only the mismatch were also prepared. Heteroduplexes were methylated at CpG islands and replicated in vitro (30 min). Following bisulfite treatment, the nascent DNA complementary to the dimer-containing template was distinguished from the other three strands by methylation-specific polymerase chain reaction. Cloning and sequencing of polymerase chain reaction products revealed that 80-98% carried the sequence predicted for translesion synthesis, with two adenines incorporated opposite the dimer. The fraction of clones with sequence predictive of template switching was reduced when extracts deficient in mismatch repair or nucleotide excision repair activities were used to replicate the heteroduplex molecules. These results support the conclusion that lesion bypass during in vitro replication of duplex DNA containing thymine dimers occurs by translesion synthesis.     

A Theoretical Study of the cis-syn Pyrimidine Dimers in the Gas Phase and Water Cluster and a Tautomer-Bypass Mechanism for the Origin of UV-induced Mutations

Abstract

A quantum mechanical study of all cis-syn cyclobutane pyrimidine photodimers including the normal and rare tautomeric forms of bases has been performed using the ab initio method at HF/6–31G(d,p), MP2(fc)//HF/6–31G(d,p) and MP2(fc)/6–31G(d,p) levels. A puckering angle of the cyclobutyl ring and twist angle of pyrimidine rings with respect to each other is well described by these calculations. It is predicted that in the gas phase all photodimers containing the rare imino form of cytosine are more stable than those containing its normal form. The Monte Carlo simulations show that the dimer containing the imino form of cytosine is more stabilized by water cluster than that containing its amino forms. The possible biological significance stems from the fact that the cytosine in the dimer directs the incorporation of adenine in the complementary strand during replicative bypass. Data obtained point to the cytosine tautomerism as a possible mechanism for the origin of UV-induced mutation.     

Proton magnetic resonance study of nucleosides,nucleotides, and dideoxynucleoside monophosphates containing a syn pyrimidine base

Proton magnetic resonance data have been obtained for 6-methyl-2′-deoxyuridine (dT*), its 3′- and 5′-monophosphates, and its 3′,5′-diphosphate, as well as for the corresponding thymine derivatives. The synthesis of the dideoxynucleoside monophosphates—d(TpT), d(T*pT), d(TpT*), and d(T*pT*)—was accomplished, and spectral data were obtained for these four dimers. The data show that the 6-methyluracil base prefers the syn conformation about the N-glycosyl bond at the monomer and dimer levels. The presence of the syn base leads to increases in the cis couplings of the sugar ring, J_1′2″ and J_2′3′, which indicate a trend towards eclipsing of the substituents on the C1′-C2′ and C2′-C3′ fragments. This trend is discussed in terms of changes in the pseudorotational parameters which describe the pucker of the ring. The syn base destabilizes the g⁺ conformer about the C4′-C5′ bond, leading to a preference for the t conformer in all dT* residues at the monomer and dimer levels. Preliminary work on the formation of cyclobutane-type photodimers in d(T*pT) and d(T*pT*) is discussed and presented as evidence for the capability of the syn 6-methyluracil base to form base-stacked complexes.     

The interplay of supercoiling and thymine dimers in DNA

Thymine dimers are a major mutagenic photoproduct induced by UV radiation. While they have been the subject of extensive theoretical and experimental investigations, questions of how DNA supercoiling affects local defect properties, or, conversely, how the presence of such defects changes global supercoiled structure, are largely unexplored. Here, we introduce a model of thymine dimers in the oxDNA forcefield, parametrized by comparison to melting experiments and structural measurements of the thymine dimer induced bend angle. We performed extensive molecular dynamics simulations of double-stranded DNA as a function of external twist and force. Compared to undamaged DNA, the presence of a thymine dimer lowers the supercoiling densities at which plectonemes and bubbles occur. For biologically relevant supercoiling densities and forces, thymine dimers can preferentially segregate to the tips of the plectonemes, where they enhance the probability of a localized tip-bubble. This mechanism increases the probability of highly bent and denatured states at the thymine dimer site, which may facilitate repair enzyme binding. Thymine dimer-induced tip-bubbles also pin plectonemes, which may help repair enzymes to locate damage. We hypothesize that the interplay of supercoiling and local defects plays an important role for a wider set of DNA damage repair systems.