The photochemistry of d(T-A) in aqueous solution and in ice.

When d(T-A) is irradiated at 254 nm in aqueous solution an internal photoadduct is formed between its constituent adenine and thymine bases. The resultant photoproduct, designated TA*, arises from a singlet excited state precursor; a similar photoreaction is not observed with d(C-A) or d(T-G). In contradistinction, irradiation of d(T-A) in frozen aqueous solution yields a dimeric photoproduct in which two d(T-A) molecules are coupled together by a (6-4) photoadduct linkage between their respective thymine bases. Both photoproducts have been extensively characterised by a combination of electron impact and fast atom bombardment mass spectrometry, UV, CD, 1H NMR and fluorescence spectroscopy. Acid treatment of TA* gives 6-methylimidazo[4,5-b]pyridin-5-one whose identity was established by an independent chemical synthesis involving photorearrangement of 6-methyl-imidazo[4,5-b]pyridine N(4)-oxide. A tentative mechanism is presented to account for the acid degradation of TA*. The structure of the dimeric ice photoproduct follows from its cleavage, by snake venom phosphodiesterase, to 5'-dAMP and the (6-4) bimolecular photoadduct of thymidine; on acid hydrolysis it gives adenine and 6-(5'-methyl-2'-oxopyrimidin-4'-yl) thymine.     

Thymidine photoproducts of non-cyclobutane type as a crucial event in the conformation of UV-irradiated DNA

The UV-light induced conformational effects in deoxyoligonucleotides and polynucleotides have been analyzed by CD measurements and isolation of the photoproducts. The results demonstrate that the essential photoproduct formed on irradiation of thymidylyl-thymidine at 254 nm is of non-cyclobutane type and may be correlated to the primary photoproduct formed in DNAs at low doses Formation of thymine dimers of cyclobutane-type structure appears to be a secondary product generated by treatment with formic acid.     

Extensive photodimerization of non-adjacent pyrimidines

In a prior study we found that non-adjacent thymidyl residues in the single-stranded alternating copolymer poly[d(G-T)] are subject to photodimerization by germicidal lamp irradiation (lambda max 254 nm). The maximum yield of this photoproduct was 1% of the total thymine of poly[d(G-T)]. We now report that dimer formation in this polymer is increased to 10 to 40% thymine as dimer between non-adjacent pyrimidines, using near-ultraviolet irradiation (lambda max 310 nm) with or without acetone triplet-sensitization. As previously observed for 254 nm irradiation, dimer formation was nearly absent in double-stranded poly[d(G-T).d(C-A)]. These observations extend prior findings by demonstrating high-yield dimerization between non-adjacent pyrimidines via direct irradiation at environmentally relevant wavelengths (greater than or equal to 280 nm), and are potentially relevant to the mechanism of the ultraviolet light-induced targeted -1 frameshift mutation.     

Establishment of a monoclonal antibody recognizing ultraviolet light-induced (6-4) photoproducts

We obtained a monoclonal antibody directed against UV-induced DNA damage. Analysis of the antigenic determinant in UV-irradiated DNA recognized by this antibody, 64M-1, revealed that it bound UV-irradiated oligo- or poly-nucleotides containing thymine-thymine or thymine-cytosine sequences. The antibody failed to bind DNA irradiated with 313 nm UV in the presence of acetophenone, which contained predominantly thymine dimers as DNA damage. The binding activity of this antibody to 254-nm UV-irradiated DNA decreased with 313-nm UV irradiation, and the decrease of this binding activity correlated with the decrease of fluorescence corresponding to (6-4) photoproducts. These results suggest that the antigenic determinant recognized by this monoclonal antibody is a (6-4) photoproduct. Using autoradiography with 3H-antibody, we could detect the formation of the (6-4) photoproduct in individual human cells irradiated with 254-nm UV doses as low as 20 J/m2.     

Search for an adenine photoproduct in DNA.

Poly(d[14C]A), p(dA)2, and [14C]adenosine-labeled DNA were irradiated at 254 nm with fluences up to 50 J/m2, and then following formic acid hydrolysis at 170 degrees C WERE SUBJECTED TO PAPER CHROMAtography using a butanol:water:acetic acid (80:30:12) solvent system. For poly(dA), up to 25% of the radioactivity appeared as fluorescent material located in the Rf 0.21-0.29 region. The hydrolysate of the purified photoproduct, p(dA)2, isolated from irradiated p(dA)2 by DEAE chromatography also had an Rf of 0.29 as well as an absorbance maximum at 310 nm. In all cases studied, however, the photoproduct yield in the Rf 0.29 region for native DNA was less than 2%. Denaturation of the DNA appeared to enhance the yield slightly, although no pronounced peak in this region of the chromatogram was discerned. Mechanistic studies indicate that the yield of the adenine photoproduct in poly(dA) is favored by base stacking, has a singlet excimer as a precursor, and is quenched by hydrogen bonding to a pyrimidine. It is concluded that the yield of the adenine photoproduct in both native and denatured DNA is considerably less than in poly (dA) and in all probability does not represent a biologically significant product.     

Photochemical properties of Yt base in aqueous solution.

Photoreactivity of Yt base [I] has been studied in aqueous solution [pH approximately 6] saturated with oxygen. Two photoproducts (II,III], resulting from irradiation at lambda = 253.7 nm and lambda greater than or equal to 290 nm, were isolated and their structures determined. The quantum yield for Yt base disappearance [zeta dis] is 0.002 [lambda = 313 nm]. It was shown that dye-sensitized photooxidation of Yt base in aqueous solution occurs according to a Type I mechanism, as well as with participation of singlet state oxygen. Quantum yields, fluorescence decay times and phosphorescence of Yt base have been also determined.     

Use of a combined enzymatic digestion/ESI mass spectrometry assay to study the effect of TATA-binding protein on photoproduct formation in a TATA box

Recently, it was reported that TATA-binding protein (TBP) enhances (6-4) photoproduct formation in a TATA box under UVC irradiation [Aboussekhra and Thoma (1999) EMBO J. 18, 433-443]. The conclusions of that study were based on an indirect enzymatic assay that was not specific for (6-4) photoproducts. Herein we report the use of a recently developed coupled enzymatic digestion/mass spectrometry assay [Wang et al. (1999) Chem. Res. Toxicol. 12, 1077-1082] to identify unambiguously and quantify the photoproducts formed in a TATA box-containing dodecamer duplex sequence in the presence or absence of TBP binding. Exposure of the adenovirus major late promoter TATA box to a high dose of UVC irradiation in the absence of the C-terminal domain of yeast TBP leads to predominant formation of the cis-syn dimer within the T(4) tract, whereas exposure in the presence of TBP leads to almost exclusive formation of the (6-4) photoproduct. In contrast, the (6-4) product is not detected at high doses of UVB irradiation in the absence of TBP but is detected in the presence of TBP, although the cis-syn product predominates. When the products of UVB irradiation were subsequently exposed to a high dose of UVC irradiation in the presence of TBP, the (6-4) photoproduct again becomes nearly the exclusive photoproduct, indicating that the cis-syn dimer is being reversed to TT by UVC light. Both cis-syn and (6-4) photoproducts are formed in approximately equal amounts upon irradiation with small doses of UVC in the presence of TBP, but the fraction of (6-4) photoproduct increases with dose. Through the use of a TATA box containing a site-specifically deuterated thymine, it was found that (6-4) photoproducts formed most selectively at the second and third positions of the T(4) tract upon either UVB or UVC irradiation in the presence of TBP. By using the same substrate, it was found that UVC-induced TA formation was inhibited by TBP binding and that TA formation was greatest at the 5' end of the TATA sequence.     

Determination of the spectrum of mutations induced by defined-wavelength solar UVB (313-nm) radiation in mammalian cells by use of a shuttle vector.

Mutations induced by UVB (313-nm) radiation, a wavelength in the region of peak effectiveness for sunlight-induced skin cancer in humans, have been analyzed at the sequence level in simian cells by using a plasmid shuttle vector (pZ189). We find that significant differences exist between the types of mutations induced by this solar wavelength and those induced by nonsolar UVC (254-nm) radiation. Compared with 254-nm radiation, 313-nm radiation induces more deletions and insertions in the region sequenced. In addition, although the types of base substitutions induced by the two wavelengths are broadly similar (in both cases, the majority of changes occur at G-C base pairs and the G-C to A-T transition is predominant), an analysis of the distribution of these base changes within the supF gene following irradiation at 313 nm reveals additional hot spots for mutation not seen after irradiation at 254 nm. These hot spots are shown to arise predominantly at sites of mutations involving multiple base changes, a class of mutations which arises more frequently at the longer solar wavelength. Lastly, we observed that most of the sites at which mutational hot spots arise after both UVC and UVB irradiation of the shuttle vector are also sites at which mutations arise spontaneously. Thus, a common mechanism may be involved in determining the site specificity of mutations, in which the DNA structure may be a more important determinant than the positions of DNA photoproducts.     

UVB-Induced formation of intrastrand cross-link products of DNA in MCF-7 cells treated with 5-bromo-2'-deoxyuridine

Nucleoside 5-bromo-2'-deoxyuridine (BrdU), after being incorporated into cellular DNA, is well-known to sensitize cells to ionizing radiation and UV irradiation. We reported here, for the first time, the sequence-dependent formation of intrastrand cross-link products from the UVB irradiation of BrdU-treated MCF-7 human breast cancer cells. Our results showed that BrdU replaced more than 30% dT in genomic DNA after the cells were treated with 10 microM BrdU for 48 h. LC-MS/MS data revealed that more than 50% of the incorporated BrdU was consumed during UVB irradiation, of which more than half was dehalogenated to yield dU. Low-dose (5.0 kJ/m2) UVB irradiation of BrdU-treated cells yielded four intrastrand cross-link products, where the C5 of uracil is covalently bonded to the C8 of its neighboring 5' or 3' guanine to give G[8-5]U and U[5-8]G, respectively, and the C5 of uracil could couple with the C2 or C8 of its vicinal 5' adenine to give A[2-5]U and A[8-5]U, respectively. All the above cross-link products except A[2-5]U could also be induced in BrdU-treated cells upon UVB irradiation at a dose of 39 kJ/m2. We further demonstrated, by using LC-MS/MS, that the yield of G[8-5]U was much greater than the total yields of A[2-5]U and A[8-5]U. In addition, our results revealed that BrdU treatment stimulated considerably the UVB-induced formation of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxo-dG) in vivo. The formation of these intrastrand cross-link products and 8-oxo-dG in vivo underscores the importance of these products in the photosensitizing effect of BrdU.     

Evidence for a near UV-induced photoproduct of 5-hydroxymethylcytosine in bacteriophage T4 that can be recognized by endonuclease V

Summary Non-photoreactivable endonuclease V-sensitive sites have been detected in the DNA of wild type bacteriophage T4 irradiated with near UV light (320 nm). Such sites were not detected in the DNA of (a) wild type T4 irradiated with far UV (254 nm) or (b) in T4 mutants in which non-glucosylated 5-hydroxy-methylcytosine (5HMC) or cytosine replaces glucosylated 5HMC normally present in T4, irradiated with 320 nm or 254 nm light. Although the non-photoreactivable sites accounted for 50% of the endonuclease V-sensitive sites in the DNA of glucosylated T4 irradiated with near UV, there was very little difference in the sensitivities of T4 containing glucosylated 5HMC, non-glucosylated 5HMC and cytosine to near UV (313 nm). We propose that the photoproduct responsible for the non-photoreactivable, but endonuclease V-sensitive, sites in glucosylated DNA is formed from glucosylated 5HMC and that a similar photoproduct is formed from non-glucosylated 5HMC or cytosine in the appropriate phage strains. We further propose that the glucosylated 5HMC photoproduct is non-photoreactivable whereas the cytosine and non-glucosylated 5HMC photoproducts are photoreactivable and are therefore possibly cyclobutane dimers.AECL Refence No. 6370Communicated by B.A. Bridges     

Formation of Meta III during the decay of activated rhodopsin proceeds via Meta I and not via Meta II

Thermal isomerization of the retinal Schiff base C=N double bond is known to trigger the decay of rhodopsin's Meta I/Meta II photoproduct equilibrium to the inactive Meta III state [Vogel, R., Siebert, F., Mathias, G., Tavan, P., Fan, G., and Sheves, M. (2003) Biochemistry 42, 9863-9874]. Previous studies have indicated that the transition to Meta III does not occur under conditions that strongly favor the active state Meta II but requires a residual amount of Meta I in the initial photoproduct equilibrium. In this study we show that the triggering event, the thermal isomerization of the protonated Schiff base, is independent of the presence of Meta II and occurs even under conditions where the transition to Meta II is completely prevented. We have examined two examples in which the transitions from Lumi to Meta I or from Meta I to Meta II are blocked. This was achieved using dry films of rhodopsin and rhodopsin reconstituted into rather rigid lipid bilayers. In both cases, the resulting fully inactive room temperature photoproducts decay specifically by thermal isomerization of the protonated Schiff base C=N double bond to an all-trans 15-syn chromophore isomer, corresponding to that of Meta III. This thermal isomerization becomes less efficient as the conformation of the respective photoproduct approaches that of Meta II and is fully absent in a pure Meta II state. These results indicate that the decay of the Meta I/Meta II photoproduct equilibrium to Meta III proceeds via Meta I and not via Meta II.     

Sequence effect on alkali-sensitive sites in UV-irradiated SV40 DNA.

Ultraviolet light at 254 nm induces various kinds of DNA damage. We have located and quantified the pyrimidine (6-4) pyrimidone photoproducts along three hundred and forty two nucleotides of SV40 DNA. The level of photoproduct induction varies greatly according to the position on the DNA, but unlike what happens with pyrimidine dimers, the very adjacent nucleotides do not play a major role in the frequency of formation. A new alkali-sensitive site has been found on the ACA sequence after UV irradiation. This complex lesion is insensitive to the T4 endonuclease V and the E. coli photolyase, and may be involved with mutagenesis.     

Bipyrimidine photoproducts rather than oxidative lesions are the main type of DNA damage involved in the genotoxic effect of solar UVA radiation

Exposure to solar UV radiation gives rise to mutations that may lead to skin cancer. UVA (320-340 nm) constitutes the large majority of solar UV radiation but is less effective than UVB (290-320 nm) at damaging DNA. Although UVA has been implicated in photocarcinogenesis, its contribution to sunlight mutagenesis has not been elucidated, and DNA damage produced by UVA remains poorly characterized. We employed HPLC-MS/MS and alkaline agarose gel electrophoresis in conjunction with the use of specific DNA repair proteins to determine the distribution of the various classes and types of DNA lesions, including bipyrimidine photoproducts, in Chinese hamster ovary cells exposed to pure UVA radiation, as well as UVB and simulated sunlight (lambda > 295 nm) for comparison. At UVA doses compatible with human exposure, oxidative DNA lesions are not the major type of damage induced by UVA. Indeed, single-strand breaks, oxidized pyrimidines, oxidized purines (essentially 8-oxo-7,8-dihydroguanine), and cyclobutane pyrimidine dimers (CPDs) are formed in a 1:1:3:10 ratio. In addition, we demonstrate that, in contrast to UVB and sunlight, UVA generates CPDs with a large predominance of TT CPDs, which strongly suggests that they are formed via a photosensitized triplet energy transfer. Moreover, UVA induces neither (6-4) photoproducts nor their Dewar isomers via direct absorption. We also show that UVA photons contained in sunlight, rather than UVB, are implicated in the photoisomerization of (6-4) photoproducts, a quickly repaired damage, into poorly repaired and highly mutagenic Dewar photoproducts. Altogether, our data shed new light on the deleterious effect of UVA.     

Bistranded oxidized purine damage clusters: induced in DNA by long-wavelength ultraviolet (290-400 nm) radiation?

Bistranded clustered DNA damages involving oxidized bases, abasic sites, and strand breaks are produced by ionizing radiation and radiomimetic drugs, but it was not known whether they can be formed by other agents, e.g., nonionizing radiation. UV radiation produces clusters of cyclobutyl pyrimidine dimers, photoproducts that occur individually in high yield. Since long-wavelength UV (290-400 nm) radiation induces oxidized bases, abasic sites, and strand breaks at low yields, we tested whether it also produces clusters containing these lesions. We exposed supercoiled pUC18 DNA to UV radiation with wavelengths of >290 nm (UVB plus UVA radiation), and assessed the induction of bistranded clustered oxidized purine and abasic clusters, as recognized by Escherichia coli Fpg protein and E. coli Nfo protein (endonuclease IV), respectively, as well as double-strand breaks. These three classes of bistranded clusters were detected, albeit at very low yields (37 Fpg-OxyPurine clusters Gbp(-1) kJ(-1) m(2), 8.1 double-strand breaks Gbp(-1) kJ(-1) m(2), and 3.4 Nfo-abasic clusters Gbp(-1) kJ(-1) m(2)). Thus, these bistranded OxyPurine clusters, abasic clusters, and double-strand breaks are not uniquely induced by ionizing radiation and radiomimetic drugs, but their level of production by UVB and UVA radiation is negligible compared to the levels of frequent photoproducts such as pyrimidine dimers.     

Sequence specificity of cyclobutane pyrimidine dimers in DNA treated with solar (ultraviolet B) radiation.

Cyclobutane pyrimidine dimers were quantified at the sequence level after irradiation with solar ultraviolet (UVB) and nonsolar ultraviolet (UVC) light sources. The yield of photoproducts at specific sites was dependent on the nucleotide composition in and around the potential lesion as well as on the wavelength of ultraviolet light used to induce the damage. Induction was greater in the presence of 5' flanking pyrimidines than purines; 5' guanine inhibited induction more than adenine. UVB irradiation increased the induction of cyclobutane dimers containing cytosine relative to thymine homodimers. At the single UVC and UVB fluences used, the ratio of thymine homodimers (T mean value of T) to dimers containing cytosine (C mean value of T, T mean value of C, C mean value of C) was greater after UVC compared to UVB irradiation.     

Some acute effects of monochromatic ultraviolet B irradiation on mouse epidermis measured by the tetrazolium-reduction test and determination of DT-diaphorase activity, with reference to carcinogenesis

Some acute epidermal effects of monochromatic ultraviolet B (UVB) irradiation on hairless mouse skin were measured by the tetrazolium test (TZT), and by determining the DT-diaphorase activity in epidermal cells. Dose response and time course studies were carried out after UVB irradiation at 280, 290, 297 and 302 nm. Appropriate UV doses at all the wavelengths increased the cellular deposition of formazan (TZT). At higher doses the epidermal cells became too injured to react. Wavelengths at 280 and 290 nm seemed more injurious than those at 297 and 302 nm. There was, however, no increase in DT-diaphorase activity after UVB irradiation. This indicates that the increased formazan deposition (TZT) after UVB is more likely to be caused mainly by membrane effects. Detoxification mechanisms which activate DT-diaphorase, as often seen after cellular contact with chemical carcinogens, are not involved.     

Photoreactivation implicates cyclobutane dimers as the major promutagenic UVB lesions in yeast.

Previously we compared the mutational specificities of polychromatic UVB (285-320 nm) and UVC (254 nm) light in the SUP4-o gene of the yeast Saccharomyces cerevisiae. Striking similarities in the types and distributions of induced SUP4-o mutations were consistent with roles for cyclobutane dimers and pyrimidine(6-4)pyrimidone photoproducts in mutation induction by UVB. To assess the relative importance of cyclobutane dimers, we have now examined the effect of photoreactivation (PR), which specifically reverses these lesions, on UVB and UVC induction of SUP4-o mutations. PR reduced the frequencies of both UVB and UVC mutagenesis by approximately 75%. Collections of 138 and 158 SUP4-o mutants induced by treatment with UVB plus PR or UVC plus PR, respectively, were characterized by DNA sequencing and the results were compared to those for 208 UVB and 211 UVC-induced mutants analyzed earlier. PR decreased the frequency of UVB-induced G.C----A.T transitions by 85%, diminished the substitution frequencies at individual sites by 64% on average, and reduced the mutation frequencies at the five UVB hotspots by 87%. A more detailed examination revealed that the transition frequencies at the 3' base of 5'-TC-3' and 5'-CC-3' sequences were decreased by 90% and 72%, respectively. Finally, PR appeared to occur to the same extent on both the transcribed and non-transcribed strands of SUP4-o. Similar results were obtained for PR following UVC irradiation. Our findings indicate that cyclobutane dimers are responsible for the majority of UVB mutagenesis in yeast.     

Repair and recombination of nonreplicating UV-irradiated phage DNA in E. coli II. Stimulation of RecF-dependent recombination by excision repair of cyclobutane pyrimidine dimers and of other photoproducts

Summary Three aspects of recombination of UV-irradiated nonreplicating lambda phage DNA were addressed: the photoproduct(s) responsible, the role of UvrABC-mediated excision repair, and the dependence on RecF function.Cyclobutane pyrimidine dimers appeared responsible for some recombination because photoreactivation reduced the frequency of 254-nm-stimulated recombination and because photosensitized 313-nm irradiation stimulated recombination. Other photoproducts seemed recombinogenic as well, because high fluences of 254-nm irradiation stimulated recombination considerably more, per cyclobutane dimer induced, than photosensitized 313-nm irradiation, and because photoreactivation did not eliminate 254-nm stimulated recombination. For both treatments, much, but not all, of the recombination was UvrABC-dependent. Recombination was mostly RecF-dependent, but was not affected by recB recC or recE mutationsThe first paper in this series is Hays et al., (1985)     

Reduced formation of bipyrimidine photoproducts in DNA UV irradiated at high intensity

DNA was irradiated using an excimer laser (248 nm) at low intensity (3.15 x 10(7) watts/m2) or high intensity (1.25 x 10(11) watts/m2). Fluences up to 30 kJ/m2 were delivered at either intensity. Following irradiation, DNA damage products were measured, yielding the following findings: 1) the rate of formation of thymine-thymine and thymine-cytosine cyclobutane dimers and the bipyrimidine photoadduct 6-4'-[pyrimidine-2'-one]thymine were reduced at high intensity by about 2-fold and 2) extensive release of free thymine and thymine decomposition fragments occurred at high intensity, but not at low intensity. The effects of high intensity UV are due to promotion of low-lying excited state(s) by absorption of a second photon, producing higher excited state(s) with consequent ionization and base loss. Possible excited state intermediates in this process are the lowest triplet state of DNA bases and prolonged singlet states associated with excimer formation. The depletion of these excited states via promotion may be the cause of the diminished yield of bimolecular pyrimidine photoproducts, suggesting that these photoproducts are formed at low UV intensity in part from long-lived excited states. Long-lived excited states present at conventional UV intensities may contribute to formation of some photoproducts that occur rarely, but are of potential biologic importance, such as dimers between nonadjacent pyrimidines on the same strand and interstrand dimers forming DNA cross-links.     

Photoproducts from DNA pyrimidine bases and polycyclic aromatic hydrocarbons

The major photoproduct formed between benzo[a]pyrene and thymine is identified as 1-(benzo[a]pyren-6-yl)-thymine by means of spectroscopic analysis and isotopic syntheses. Irradiation of 1-methylcytosine hydrochloride and anthracene gives two isolable photoproducts of which one is assigned the structure 5-(anthracen-9-yl)-1-methylcytosine.