Electrochemical study of thymine dimer based on DNA charge transfer

Differential pulse voltammetry was used to study the formation and level of thymine dimer in DNA duplex modified on a gold electrode. The electrochemical signal of methylene blue coupled with ferricyanide can be obtained via DNA mediated electron transfer, which would be blocked during the formation of thymine dimer. DNA duplexes with different sequences differ in the level of thymine dimer under the same UV irradiation. Futhermore, the presence of guanine base directly preceding -TT- can effectively decrease the level of thymine dimer, possibly due to the self-repair process in which guanine participates. The proposed method can be further applied to DNA self-repair analysis.     

FORMATION OF CYCLOBUTANE THYMINE DIMERS PHOTOSENSITIZED BY PYRIDOPSORALENS: A TRIPLET-TRIPLET ENERGY TRANSFER MECHANISM

The 365 nm irradiation of thymine thin films in the presence of pyridopsoralens is shown to induce the formation of cyclobutane thymine dimers, in contrast to other compounds such as 8- and 5-methoxypsoralen. In order to elucidate the mechanism of such a photosensitized reaction, we have determined the energy of the lowest triplet state (T1) of these compounds, using phosphorescence spectroscopy and CNDO/S quantum chemistry calculations. The T1 energy values were found to be significantly higher for pyridopsoralens--up to 0.3 eV--than for 8- and 5-methoxypsoralen (approximately 2.8 eV), which are not able to photoinduce cyclobutane thymine dimers. The determination of the relative efficiency of cyclobutane thymine dimer formation was performed using chromatographic analysis. A good correlation was found between the energy of the T1 state of the psoralen derivatives and the related cyclobutane thymine dimer formation. Moreover, the photosensitized cyclobutane thymine dimer formation appeared to be temperature-dependent. Our results are consistent with a mechanism involving a triplet energy transfer from the pyridopsoralen to thymine.     

DNA-protein cross-linking: model systems for pyrimidine-aromatic amino acid cross-linking

[reaction: see text] We have synthesized simple model systems to explore the possibility of photo-cross-linking between the pyrimidine bases and the side chains of the aromatic amino acids. Thymine/phenylalanine and thymine/tyrosine models gave cross-links, and thymine/tryptophan models gave complex mixtures; the cytosine/phenylalanine model was unreactive. The quantum yields for the model cross-linking reactions were 18-46 times smaller than those for thymine dimer formation. Biphotonic excitation contributes little to the yield of these reactions.     

Functional monomers and polymers. XCIV. Photochemical reactions on the synthetic polymers containing thymine bases in the presence of adenine derivatives

Photodimerization reactions of polyacrylate and polymethacrylate derivatives and the dimer model compound containing thymine bases were studied in the presence of adenine derivatives in dimethyl sulfoxide; N,N-dimethylformamide; and dimethyl sulfoxide–ethylene glycol solutions. The photodimerization of thymine bases both in the polymers and in the dimer model compound was found to be quenched by the addition of adenine derivatives. Base-base interaction in the ground state was also studied by ultraviolet (UV) spectroscopy in the three solvents. The quenching of the photodimerizationof thymine bases in the presence of adenine derivatives was discussed in terms of the specific interaction between adenine and thymine bases both in ground and excited states.     

酶蛋白直接修复嘧啶二聚体机理的模型研究

去辅基的DNA光解酶在280 nm光辐照下, 能高效修复底物嘧啶二聚体(Φ＝0.56). 为了模拟酶蛋白的这一修复过程, 合成了色氨酸(Trp)和/或酪氨酸(Tyr)与胸腺嘧啶二聚体(D)共价连接的化合物, 作为酶-底物复合物的模型, 研究了它们在295 nm光照射下氨基酸残基光敏化二聚体裂解的性质, 测定了二聚体裂解量子产率(Φ), 获得一些新的结果并对其进行了分析.     

PHOTOPRODUCT FORMATION IN DNA AT LOW TEMPERATURes.

Abstract— The temperature dependence of thy mine photoproduct formation in Escherichia culi DNA dissolved either in water or in a 50 per cent ethylene glycol solution was studied at temperatures between + 25 and — 196°C. At low temperatures, the formation of thymine dimer was strongly inhibited. A dose of 1 × 10⁴ ergs/mm² at 280 nm converted 2 per cent of the thymine to dimer at 25°C as compared with 0.2 per cent at — 196°C. In addition, a new thymine photo-product which was both nonphotoreversible and nonphotoreactivable was found at low temperatures. On the basis of its chromatographic mobility, this new photoproduct was assumed to be the same as that isolated from irradiated spores of Bacillus megaterium . Extensive irradiation at 254 nrn of DNA at — 120°C resulted in a yield of > 23 per cent for the 'spore-type' photoproduct as compared with 6 per cent for the thymine dimer. In poly d(AT), irradiated at low temperature, no spore-type photoproduct was found; this suggests that adjacent thymine residues are necessary for the formation of the spore-type photoproduct.     

An ab initio MO study on the thymine dimer and its radical cation

Ab initio SCF calculations with the 6-31G basis set for the thymine dimer (cys-syn form) and the thymine dimer radical cation are reported. The fusion of the thymine bases at the C5 and C6 positions involves the formation of a cyclobutane ring with puckering. The puckering causes a notable difference in the electronic structures of the two bases of the thymine dimer. The density of the HOMO orbital of the thymine dimer is localized on the O2, N1, and C6 atoms of both thymine rings, with the higher density on one of the rings. The HOMO orbital has a bonding character on the C6(SINGLEBOND)C6 bond. In the thymine dimer radical cation, the unpaired electron is localized mainly on the lengthened C6(SINGLEBOND)C6 bond with the higher density on one of the C6 atoms and to a lesser extent on the N1 atoms of both rings. © 1996 John Wiley & Sons, Inc.     

PHOTOCHEMICAL REACTIONS OF THYMINE WITH CARBOXYLIC ACIDS. A MODEL FOR NUCLEIC ACID-PROTEIN PHOTOCROSSLINKING

When nucleic acid bases are UV-irradiated in the presence of carboxylic acids or carboxylate anions new photoproducts are formed as compared to the bases irradiated in the absence of carboxylic acids. The behavior of thymine and thymidine has been examined in detail. At least four photoproducts are formed in the presence of propionic acid and three in the presence of butyric acid. None of them appears to be a cyclobutyl dimer. From the concentration dependence of the rate of photoproduct formation it is concluded that the reactive excited species is the first excited singlet state of thymine. When ¹⁴C-labelled thymine is irradiated in the presence of polyglutamic acid an important part of the radioactive material is covalently linked to the polymer. Photochemical reaction of thymine with glutamic (or aspartic) acid could thus induce crosslinks between proteins and nucleic acids. It is also shown that these photoproducts are stable under usual conditions of acidic hydrolysis of UV-irradiated DNA.     

SENSITIZED PHOTOINACTIVATION OF BACTERIOPHAGE T4

Abstract— The photoinactivation of an osmotic shock resistant mutant of the bacteriophage T 4 can be sensitized by two cationic derivatives of acetophenone. At least part of the sensitized inactivation appears to be due to the formation of thymine dimers in phage DNA by a mechanism which involves triplet excitation transfer from the sensitizer to thymine in the DNA. The photoreactivable sector of the phage inactivated by sensitized irradiation is about 0.6, almost twice as large as the sector for u.v. irradiated phage.     

Structural factors controlling the action of UV light in nucleic acids

Abstract— UV light induced conformational effects of different deoxyoligonucleotides and deoxypolynucleotides containing thymine and adenine residues are investigated by means of CD measurements and quantum yield calculations. UV-irradiation at the wavelengths 254 , 280 and 313 nm indicate that unsensitized irradiation at low doses leads to thymine photoproduct formation of non-cyclobutane type. In contrast to that irradiation at 313 nm in the presence of acetophenone causes different changes in the CD spectra due to the formation of thymine dimers of the cyclobutane type structure. Quantum yield calculations demonstrate a pronounced dependence of the photoproduct formation on the nucleotide sequence of the oligomers. Thus, clustering of thymine dimer formation can be neglected. Adenine photoproducts in the (A.T) containing oligomers are only formed at higher fluences. > 1.5 × 10⁴ J/m² and are biological less important events.     

PHOTOCHEMICAL REACTIONS OF THYMINE, URACIL, URIDINE, CYTOSINE AND BROMOURACIL IN FROZEN SOLUTION AND IN DRIED FILMS*

Abstract— The photochemistry of uracil, uridine, cytosine, thymine and broinouracil has been investigated in frozen aqueous solution and in dried films. Essentially the same photoproducts were obtained in the two conditions; however, the yield of photoproducts was considerably greater in frozen solution. Uracil forms a dimer which can exist in two forms. Some kinetic data are presented for the interconversion of these two forms, The mixed dimer of thymine and uracil can also exist in two forms. Uridine forms only one acid stable photoproduct and does not appear to form mixed photoproducts under the conditions used. Two new photoproducts of thymine other than the dimer are described. Cytosine was at first considered to be completely inert hut using more sensitive detecting equipment it has recently been found to form uracil dinier as a result of dinierization and deamination. The most remarkable response was shown by bromouracil. When irradiated by itself it formed no photoproducts but when irradiated in the presence of uracil, uridine, cytosine or NaOH it formed many photoproducts. Most of these products were devoid of bromide, but two still contained bromine. One of these has been identified as the mixed dimer of uracil and bromouracil while the other has been tentatively identified as the dimer of bromouracil. Dimers of thymine or bromouracil were not formed by X-rays.     

THYMINE DIMERIZATION IN L-STRAIN MAMMALIAN CELLS AFTER IRRADIATION WITH ULTRAVIOLET LIGHT AND THE SEARCH FOR REPAIR MECHANISMS

Abstract— The formation of thymine dimers in the DNA of L -strain mammalian cells after irradiation with ultraviolet light has been demonstrated. The amount of dimer formed rises with the dose of u.v. light.
In the course of post-irradiation incubation the thymine dimers remain in the TCA insoluble fraction and diminish as did the other thymidine-H³ derivatives with increasing incubation time. The dimer is not found in the soluble fraction. Thus, dimer excision (i.e. its liberation into the soluble fraction) as an expression of repair of radiation damage analogous to dark repair in E. coli was not found in these experiments.     

Photoreactivation of the thymine dimer containing DNA octamer d(GCGTTGCG).d(CGCAACGC) by the photoreactivating enzyme from Anacystis nidulans

Irradiation of the double-stranded octamer d(GCGTTGCG).d(CGCAACGC) with UV light causes dimerization of the two central thymine residues. Proton NMR data reveal that this photodimer has the same chemical structure as the photodimer, which is formed upon UV irradiation of the single strand d(GCGTTGCG), a cis-syn-cyclobutane-type thymine dimer. Irradiation of the purified thymine dimer double-stranded octamer d(GCGTTGCG).d(CGCAACGC) with visible light in the presence of photoreactivating enzyme isolated from Anacystis nidulans leads to an increase in absorbance at 260 nm, which is characteristic for the repair of thymine dimers. The NMR spectrum recorded after the photoreactivating treatment indeed shows that a complete conversion to the starting octamer has occurred.     

Epidermal reconstructs: a new tool to study topical and systemic photoprotective molecules

In this study, we compared the effects of sunscreens and antioxidants on reconstructed epidermis made with or without melanocytes 24 h after UVB, UVA or UVA+B irradiation. For this purpose, we studied sunburn cells and cyclobutane pyrimidine dimer formation, protein and lipid oxidation, catalase and superoxide dismutase activities and vitamin E levels. Topical sunscreens protected against direct cell death and thymine dimer formation whereas their protective effect against protein and lipid oxidation and antioxidant depletion was less marked partly due to the difficulty of spreading the cream. Antioxidant molecules protected against direct cell death and protein oxidation but not against thymine dimer formation. Since topical sunscreens and systemic antioxidant protected the skin differently, we speculate that their association might protect more efficiently against UV-induced damage. This model is relevant to study systemic molecules but is less practical, due to the technical limitations of studying topical molecules.     

VARIATION IN THE PHOTOCHEMICAL REACTIVITY OF THYMINE IN THE DNA OF B. SUBTILIS SPORES, VEGETATIVE CELLS AND SPORES GERMINATED IN CHLORAMPHENICOL*,†

Abstract— The chief photoproduct of thymine produced in u.v. irradiated (2537Å) vegetative cells of B. subtilis is the cyclobutane-type dimer while in spores very little of this dimer is produced (maximum yield 2·6 per cent of thymine) but a new photoproduct is produced in high yield (maximum of 28·4 per cent of thymine). This difference in photochemical response appears to be due, at least in part, to a difference in uydration of the DNA. The photochemistry of thymine in isolated DNA irradiated in solution is similar to that of DNA in irradiated vegetative cells, but differs markedly from that of isolated DNA irradiated dry. The yield of cyclobutane-type thymine dimer is much reduced in isolated DNA irradiated dry but a new photoproduct of thymine. is produced which is chromatographically similar to the spore photoproduct. The yield of this photoproduct, however, is never as great as that obtained in irradiated spores. The photochemistry of the DNA thymine of spores germinated in the presence of chloramphenicol is very similar to that of normal vegetative cells. Except for hydration, the physical state of the DNA is probably not otherwise altered by germination in the presence of chloramphenicol since DNA replication is prevented by the presence of chloramphenicol. These results are also consistent with the hypothesis that the unique photochemistry of spores is due, at least in part, to the hydration state of the DNA. The acid stability of the spore photoproduct is indicated by the fact that it is isolated from irradiated spores after hydrolysis in trifluoroacetic acid at 155°C for 60 min. It still contains the methyl group of thymine as judged by the fact that for a given dose of u.v. the same yield of photoproduct was obtained whether the spores were labeled with thymine-2–C-14 or -methyl-C-14. This photoproduct is stable to reirradiation (2537Å) in solution under condiditions where thymine dimers of the cyclobutane-type are completely converted back to monomeric thymine. On a column of molecular sieve material (Sephadex-G10), the spore photoproduct elutes in a region intermediate between the cyclobutanetype thymine dimers and monomeric thymine. Of the numerous compounds tested by paper chromatography, the spore photoproduct is most similar (but not identical) in several solvents to 5–hydroxyuracil and 5–hydroxymethyluracil. Our data do not allow us to decide if the product is a monomer or a dimer. Although the photochemistry of thymine in the DNA of spores differs markedly from that for vegetative cells, several lines of evidence make it seem doubtful that the enhanced resistance of spores to u.v. relative to that of vegetative cells can be explained solely on the basis of this difference in the photochemistry of DNA thymine.     

Interaction between thymine dimer and flavin-adenine dinucleotide: a DFT and direct ab initio molecular dynamics study

The interaction between the fully reduced flavin-adenine dinucleotide (FADH (-)) and thymine dimer (T) 2 has been investigated by means of density functional theory (DFT) calculations. The charges of FADH (-) and (T) 2 were calculated to be -0.9 and -0.1, respectively, at the ground state. By photoirradiation, an electron transfer occurred from FADH (-) to (T) 2 at the first excited state. Next, the reaction dynamics of electron capture of (T) 2 have been investigated by means of the direct ab initio molecular dynamics (MD) method (HF/3-21G(d) and B3LYP/6-31G(d) levels) in order to elucidate the mechanism of the repair process of thymine dimer caused by the photoenzyme. The thymine dimer has two C-C single bonds between thymine rings (C 5-C 5' and C 6-C 6' bonds) at the neutral state, which is expressed by (T) 2. After the electron capture of (T) 2, the C 5-C 5' bond was gradually elongated and then it was preferentially broken. The time scale of the C-C bond breaking and formation of the intermediate with a single bond (T) 2 (-) was estimated to be 100-150 fs. The present calculations confirmed that the repair reaction of thymine dimer takes place efficiently via an electron-transfer process from the FADH (-) enzyme.     

THE PHOTOSENSITIZED OXIDATION OF TYROSINE REACTION UNDER HOMOGENEOUS CONDITIONS DERIVATIVES IN THE PRESENCE OF ALGINATE-I

Abstract —The rates of dye-sensitized photooxidation of tyrosine and tyramine to brown products were compared in the presence and the absence of the anionic polysaccharide, alginate. The polyelectrolyte did not affect the reaction when it was sensitized by monochromatic light absorbed mainly by the monomeric form of the dye. In white light, the rate of oxidation sensitized by thionine or phenosafranine was increased in the presence of alginate for tyramine, but not for tyrosine. In the thionine sensitized reaction, the ratio of brown product formation to tyramine consumption increased with decreasing wavelength of monochromatic excitation. These and other phenomena are believed related to the formation of complexes between the dyes and some of the oxidation products, and to association between some of the oxidation products and alginate. A mechanism for oxidation of phenols is proposed, based on the addition of O₂ (¹Δ9) across a double bond ortho to the phenolate oxygen. Dyes bind to alginate in monomeric and in aggregated forms; only the monomeric forms of thiazine dyes are photochemically active, but both the monomeric and the aggregated forms of crystal violet are active.     

PHOTOSENSITIZED SPLITTING OF PYRIMIDINE DIMERS IN DNA BY INDOLE DERIVATIVES AND TRYPTOPHAN-CONTAINING PEPTIDES

Abstract —Indole derivatives, such as serotonin or the oligopeptide Lys-Trp-Lys, are able to photosensitize the splitting of thymine dimers in DNA. These indole derivatives have to be bound to DNA in order to efficiently photosensitize the splitting reaction. Serotonin may also induce the photosensitized formation of thymine-containing dimers in native DNA. In this case, an equilibrium is reached when 5 per cent of the total thymines are dimerized. In both cases (splitting and dimer formation), the formation of electron donor-acceptor complexes between either dimers or two adjacent thymine monomers, and excited indole rings, could be an intermediate step in the reactions. Thymine-dimer splitting would then result from an electron transfer reaction involving the indole ring as the electron donor. These results are discussed with respect to the mechanism of action of the photoreactivating enzyme.     

紫外线光照产物——胸腺嘧啶二聚体物理化学性质的研究

本文分离和鉴定了紫外线光照胸腺嘧啶冰冻水溶液时迅速形成的低吸收的胸腺嘧啶二聚体,研究了和光化学与光生物学有关的胸腺嘧啶二聚体的一些性质。除了它的酸和热稳定性之外,实验表明,胸腺嘧啶二聚体的化学稳定性受加入的金属离子Ag⁺、Fe⁺⁺、Cu⁺⁺和EB染料的影响;而且胸腺嘧啶二聚体和胸腺嘧啶之间的相互转换依赖于金属离子的种类和浓度。     

THE EFFECT OF AROMATIC AMINO ACIDS ON THE PHOTOCHEMISTRY OF A DISULFIDE: ENERGY TRANSFER AND REACTION WITH HYDRATED ELECTRONS

Abstract —The decomposition of dithioglycolic acid in oxygen-free solutions illuminated by low-intensity 254 nm light at pH 1.5-4.7 is enhanced by light absorbed in tyrosine. This occurs through an interaction with excited tyrosine, leading to the formation of excited dithioglycolic acid. At pH 6-1 an additional pathway appears, through the formation of a hydrated electron from excited tyrosine.
In the presence of tryptophan at pH 1 -2–6-1 the pathway involving sensitized formation of excited dithioglycolic acid is much less important, and that due to hydrated-electron (or H ) formation from excited tryptophan of greater importance.