Inter-strand photoproducts are produced in high yield within A-DNA exposed to UVC radiation

Far-UV irradiation of DNA leads to the dimerization of pyrimidine bases, resulting in the formation of cyclobutane type dimers and (6–4) photoproducts. In the dry state, an additional thymine dimeric photolesion, the spore photoproduct, is also generated. While most photoproducts are expected to be produced between adjacent pyrimidines, little attention has been paid to lesions involving bases located on different DNA strands. Using HPLC– mass spectrometry analysis of enzymatically digested DNA, we observed that, in the dry state, inter-strand dimeric photoproducts represented 30% of the total yield of dimeric thymine lesions. The major inter-strand damage was found to be the spore photoproduct. Formation of inter-strand lesions in significant yield could be obtained in solution upon modification of the DNA conformation as the result of the addition of large amounts of ethanol. In both cases, DNA is in the A-form, which is characterized by a high compaction, likely to favor inter-strand photoreactions. Since the latter DNA conformation is also predominant in bacterial spores, the formation and repair of dimeric photoproducts involving thymine bases located on different DNA strands may thus be relevant in terms of deleterious effects of UV radiation to the latter microorganisms.     

Ultraviolet-induced dimerization of non-adjacent pyrimidines. A potential mechanism for the targeted -1 frameshift mutation

The DNA photoproduct responsible for the ultraviolet (u.v.)-induced targeted -1 frameshift mutation is unknown. Based on mutagenesis studies by others, we surmised that this lesion might be found in high abundance in single-stranded DNA. u.v. irradiation of the single-stranded alternating copolymer poly[d(G-T)] yielded a photoproduct that was characterized in detail. It consists of a thymine-thymine cyclobutane dimer of predominantly cis-syn configuration occurring between non-adjacent thymidyl residues on the same strand. Its formation is strongly inhibited in double-stranded DNA. A similar u.v. photoproduct was obtained in higher yield from the polypyrimidine alternating copolymer poly[d(C-T)] under conditions in which it is single-stranded. It is proposed that replication across the unrepaired photoproduct: (formula; see text) is the cause of the targeted u.v.-induced -1 frameshift mutation.     

Ultraviolet-induced dimerization of non-adjacent pyrimidines in poly[d(A-T)].

The DNA photoproduct responsible for the ultraviolet (UV) light-induced -1 frameshift mutation remains unknown. We recently identified a UV photoproduct consisting of a cyclobutane dimer occurring between non-adjacent thymine residues in the same strand, [sequence: see text] and proposed that replication across this unrepaired photoproduct might result in a -1 frameshift mutation since the intervening base is extrahelical. Until now this novel photoproduct has only been identified in single-stranded DNA polymers and does not occur in UV-irradiated double-stranded polymers due to conformational restraint. This observation suggested that this photoproduct could only occur in vivo in chromosomal sites that were single-stranded. In the current work the cis-syn dithymine cyclobutane dimer has been identified in the self-complementary polymer poly[d(A-T)] when UV irradiated in solution conditions (concentrated manganese chloride or 60% ethanol plus trace salts) wherein this polymer remains double-stranded but the double-helix is partially destabilized. Taken together, the current findings suggest that dipyrimidine photoproducts between non-adjacent residues on the same strand could occur in vivo in double-stranded, but partially destabilized, DNA.     

Photofootprint of nucleosome core DNA in intact chromatin having different structural states

Recently, we reported that the distribution of ultraviolet light (u.v.) induced pyrimidine dimers in nucleosome core DNA has a striking 10.3(+/- 0.1) base periodicity and the regions of enhanced quantum yield map to positions where DNA strands are farthest from the core histone surface. Improvement of the mapping procedure has allowed us to analyze this distribution in more detail, and compare the distribution pattern for nucleosome cores from intact chromatin having different higher-order structures (from the 10 nm filament to the 30 nm fiber). At all levels of chromatin compaction, we observed the following. (1) The average periodicity in pyrimidine dimer yield is 10.3 bases. (2) The peak-to-peak spacing in this distribution is significantly different from 10.3 bases in the region covering three helix turns immediately 5' of the dyad axis. (3) There is a suppression of photoproduct formation in the region of the dyad axis, especially at position 84 from the 5' end. (4) The approximately 10 base ensembles have alternating peak intensities throughout core DNA. Furthermore, peak deconvolution analysis of the pyrimidine dimer pattern yielded a striking similarity in photoproduct yield for the different levels of chromatin compaction. Irradiation of isolated core DNA yields a much more random distribution of photoproducts, although a weak modulation pattern is observed (indicating that there is a non-random alignment of adjacent pyrimidines in our core DNA preparations). This pattern includes a depression in photoproduct yield near position 95, suggesting that the sequence in this region plays a role in nucleosome positioning. These results show that the u.v. photofootprint is a sensitive, diagnostic probe of core histone-DNA interactions in intact chromatin, and these interactions are not significantly altered by changes in the structural state of the chromatin fiber.     

Effects of organosulfurs, isothiocyanates and vitamin C towards hydrogen peroxide-induced oxidative DNA damage (strand breaks and oxidized purines/pyrimidines) in human hepatoma cells

The aim of this study was to evaluate the effects of organosulfurs, isothiocyanates and vitamin C towards hydrogen peroxide-induced DNA damage (DNA strand breaks and oxidized purines/pyrimidines) in human hepatoma cells (HepG2), using the Comet assay. Treatment with hydrogen peroxide (H(2)O(2)) increased the levels of DNA strand breaks and oxidized purine and pyrimidine bases, in a concentration and time dependent manner. Organosulfur compounds (OSCs) reduced DNA strand breaks induced by H(2)O(2). In addition, OSCs also decreased the levels of oxidized pyrimidines. However, none of the OSCs tested reduced the levels of oxidized purines. Isothiocyanates compounds (ITCs) and vitamin C showed protective effects towards H(2)O(2)-induced DNA strand breaks and oxidized purine and pyrimidine bases. The results indicate that removal of oxidized purine and pyrimidine bases by ITCs was more efficient than by OSCs and vitamin C. Our findings suggest that OSCs, ITCs and vitamin C could exert their protective effects towards H(2)O(2)-induced DNA strand breaks and oxidative DNA damage by the free radical-scavenging efficiency of these compounds.     

Effects of proflavin and photoactivated proflavin on the template function of single-stranded DNA

DNA context-specific effects of the association of proflavin, single-stranded DNA and DNA polymerase on DNA polymerization reactions were examined. Frameshift mutations induced by the presence of proflavin during in vitro DNA replication of a single-stranded DNA template by the Klenow fragment of Escherichia coli DNA polymerase I were sequenced. More than 80% of the frameshifts were one base-pair deletions opposite purine bases that were immediately 3' to pyrimidines. Purines (Pu) that were not adjacent to pyrimidines (Py) were not deletion sites. The remaining deletions were opposite template pyrimidines that were also immediately 3' to another pyrimidine. All pyrimidine site deletions occurred in the context 5' PyPyPu 3'. In additional experiments, the site-specific inhibition of processive DNA polymerization by proflavin was examined. A novel inhibition of polymerization was found opposite all pyrimidines in the template when proflavin-template complexes were exposed to ten seconds of white light. This inhibition of polymerization is reversible. Longer photoactivation led to an altered pattern of DNA sequence-specific inhibition that was not reversible. The role of DNA sequence-specific interactions of proflavin with DNA in proflavin mutagenesis is discussed.     

Sequence analysis of ultraviolet-induced mutations in M13lacZ hybrid phage DNA

We have studied the specificity of ultraviolet (u.v.) mutagenesis in single-stranded DNA phage by analyzing u.v.-induced forward mutations in the lac insert of M13mp2 hybrid phage. Sequence analysis of 114 lac mutants derived from u.v.-irradiated phage grown in u.v.-irradiated cells showed that ultraviolet induces mainly single-nucleotide substitutions and deletions in progeny phage DNA. A total of 74% of the single-base substitution mutations occurred at sites of adjacent pyrimidines in the single-stranded DNA, with both T----C and C----T transitions predominating in the u.v. spectrum. Single-nucleotide deletion mutations occurred preferentially in tracts of repeated pyrimidine nucleotides. Tandem, double-base substitutions did not represent a major class of u.v.-induced mutations, but nearly 10% of mutant clones contained multiple, non-tandem nucleotide changes.     

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.     

Pyrimidine dimer dependent cleavage of single-stranded DNA by T4 UV endonuclease

T4 UV endonuclease cleaves double- and single-stranded DNA with equal specificity for photo-pyrimidine dimers. Thus, the enzyme can be used for mapping and quantifying pyrimidine dimers in single-stranded DNA as well as in double-stranded DNA. Mapping of pyrimidine dimers shows that rates of UV-dimerization are not only affected by 5', 3' adjacent bases, but also by position within pyrimidine tracts. Di-pyrimidines at 3' ends of tracts are more photoreactive than those at 5' ends.     

Molecular mechanisms of stress-induced hereditary variability

The molecular mechanisms of generation of stress-induced genetic recombinations and point mutations are considered. Due to the oxidative, temperature, radiation and other forms of stress, intensive modification of DNA bases occurs. Excision of the modified bases (hypoxanthine, uracil, pyrimidine photoproducts, methylated purines) leads to the formation of single-stranded gaps in DNA. If one DNA strand is damaged, there is high probability of its primary structure being completely restored. When the rate of lesions increases, the DNA can be damaged in the gap-related opposite sites of both strands. It is shown that in this case, the excision repair leads to a burst of recombinations and point mutations which may be concerned with the mispairings, double-stranded breaks, induction of SOS-response. With the increase in the rate of lesions, the possibility of the damage in self-complementary DNA sequences is also enhanced. This leads to formation of hairpin structures in the single-stranded DNA stretches. It is demonstrated that in these cases the repair results in development of deletions, insertions and clusters of point mutations predetermined by the primary DNA structure. Independent means of stress-induced mutations' occurrence seem to be the transposable elements. The stress-induced outbreaks of recombinations provide conceivably new variants of genotypes to be selected for the adaptation to new extreme conditions.     

An oligopurine sequence bias occurs in eukaryotic viruses.

Twenty four DNA and RNA viral nucleotide sequences, comprising over 346 kilobases, have been analyzed for the occurrence of strings of contiguous purine or pyrimidine residues. On average strings greater than or equal to 10 contiguous purines or pyrimidines are found three and a half times more frequently than would be expected for a random distribution of bases. Detailed analysis of the 172 kilobase Epstein-Barr viral sequence shows that the bias in favor of contiguous purine residues increases with the length of the purine string. These findings are similar to those seen for genomic DNA from higher eukaryotes. In contrast no overrepresentation of oligopurine or oligopyrimidine strings is observed in 52 kilobases from eight bacteriophage and E. coli DNA sequences.     

Detection of UV purine photoproducts in a defined sequence of human DNA.

The UV-irradiated, 3'-end-labeled, 92-base-pair terminus of the human alphoid sequence was incubated with purified endonuclease v. Previously unreported photoproducts were incised at purine loci. These were not pyrimidine photodimers, 6-4'-(pyrimidin-2'-one)-pyrimidines, base loss sites, or ring-opened purines. Therefore, purine-containing photoproducts, possibly dimers, were incised by the enzyme preparation.     

Human alkyladenine DNA glycosylase uses acid-base catalysis for selective excision of damaged purines

Human alkyladenine DNA glycosylase (AAG) protects against alkylative and oxidative DNA damage, flipping damaged nucleotides out of double-stranded DNA and catalyzing the hydrolytic cleavage of the N-glycosidic bond to release the damaged nucleobase. The crystal structure of AAG bound to a DNA substrate reveals features of the active site that could discriminate between oxidatively damaged or alkylated purines and normal purines. A water molecule bound in the active site adjacent to the anomeric carbon of the N-glycosidic bond is suggestive of direct attack by water, with Glu125 acting as a general base. However, biochemical evidence for this proposed mechanism has been lacking. The structure also fails to explain why smaller pyrimidine nucleosides are excluded as substrates from this relatively permissive active site that catalyzes the excision of a structurally diverse group of damaged purine bases. We have used pH dependencies, site-directed mutagenesis, and a variety of substrates to investigate the catalytic mechanism of AAG. Single-turnover excision of hypoxanthine and 1,N(6)-ethenoadenine follows bell-shaped pH-rate profiles, indicating that AAG-catalyzed excision of these neutral lesions requires the action of both a general acid and a general base. In contrast, the pH-rate profile for the reaction of 7-methylguanine, a positively charged substrate, shows only a single ionization corresponding to a general base. These results suggest that AAG activates neutral lesions by protonation of the nucleobase leaving group. Glu125 must be deprotonated in the active form of the enzyme, consistent with a role as a general base that activates and positions a water nucleophile. Acid-base catalysis can account for much of the 10(8)-fold rate enhancement that is achieved by AAG in the excision of hypoxanthine. The prominent role of nucleobase protonation in catalysis by AAG provides a rationale for its specialization toward damaged purines while effectively excluding pyrimidines.     

15-mer DNA duplexes containing an abasic site are thermodynamically more stable with adjacent purines than with pyrimidines

Abasic site (AP)-containing duplexes, with flanking adenine (A) or cytosine (C) bases, were shown to be more stable with flanking A than with C bases [Sági, J., Hang, B., and Singer, B. (1999) Chem. Res. Toxicol. 12, 917-923]. We investigated whether the lower-magnitude destabilization by an AP site, with A neighbors, is a general effect of the purine versus the pyrimidine neighbors. Duplex stability, as compared to that of the corresponding control duplexes, was markedly decreased by the incorporation of the AP site (x) opposite any of the four bases. However, for the duplexes containing T, A, or C opposite the AP site, replacement of the symmetric doublet flanking pyrimidine bases with purines resulted in a smaller destabilization effect. The average stabilizing effect of the symmetric doublet purine neighbors of an AP site opposite T, A, or C bases was 3.2 degrees C (DeltaT(m)) and 1.3 kcal/mol (DeltaDeltaG degrees (37)) compared to those of pyrimidine neighbors. In contrast, a G.AP pair reduced or eliminated the differential effect of the neighbors. Using unrestrained molecular dynamics, it was shown that for the duplexes containing T opposite the AP site, with doublet pyrimidine neighbors, there was a larger magnitude of curvature around the lesion site than for the duplexes with the purines flanking the AP site. Purines flanking the AP site tend to shift toward each other, creating overlap, in contrast to the flanking pyrimidines. This indicates the possibility of stacking between purine bases at the AP site and can be the reason for the observed smaller thermodynamic destabilization of the duplexes with the AAxAA and GGxGG central sequences, as compared to those with TTxTT and CCxCC sequences. This work showed that for an AP site the GC content is not the only determinant of duplex stability, but rather is influenced more by whether purines or pyrimidines flank the AP site.     

Ultraviolet Sensitivity of the Biological Activity of ΦX174 Virus, Single-Stranded DNA, and RF DNA

Action spectra for inactivation of varphiX virus, free varphiX single-stranded DNA, and double-stranded varphiX DNA (RF) have been measured using light of wavelength 225-302 mmu. The sensitivity of RF has been determined using bacterial hosts both capable and incapable of reactivation of UV damage. The inactivation of varphiX virus is due, at all wavelengths, to damage to its DNA; it appears that, below 240 mmu, energy absorbed by viral structural protein may inactivate the viral DNA. The variation of the probability of inactivation by an absorbed quantum (quantum yield) with wavelength, in the case of free-single-stranded varphiX DNA, suggests that energy absorbed by pyrimidine residues is more likely to yield inactivation than absorption by purines. This implies that energy transfer is not so extensive as to make all absorbed energy available to pyrimidines.     

UV-induced photoproducts of 5-methylcytosine in a DNA sequence context.

In order to detect possible m5C photoproducts, highly purified rat liver DNA-cytosine methyltransferase was used to specifically generate m5C with a radioactive methyl group. When these DNAs were subjected to a large dose (10 kJ/m2) of 254 nm or 302 nm ultraviolet light (UVB) to enhance the yield, two labeled photoproducts were detected and isolated by reverse phase HPLC after formic acid hydrolysis. Further studies using acetone as a triplet state sensitizer and UVB irradiation suggested that photoproduct II was activated via a triplet state while the more polar photoproduct I was not. Photoreversion of the purified photoproducts with 10 kJ/m2 254 nm light demonstrated the following reactions: Photoproduct I regenerated m5C, while photoproduct II is split and regenerated m5C and photoproduct I. These results suggest that photoproduct I is monomeric while photoproduct II dimeric, and from the latter's elution position possibly a cyclobutyl type dimer arising from a reaction with an adjacent cytosine. Using d[TTG] and d[Cm5CG] as models of typical sequences, irradiation with 10 kJ/m2 254 nm or 302 nm, respectively, gave rise to a small component having altered mobility in sequencing gels. The altered mobility trinucleotides were resistant to degradation by PI and micrococcal nucleases as expected from photodimerization of the pyrimidine bases. Furthermore, oligonucleotide substrates containing m5C were synthesized and shown to be susceptible to T4 endonuclease v action at locations consistent with d[Cm5C] photodimer formation when irradiated in the UVB range.     

Optimization of separation of purine and pyrimidine compounds using ion-pair reversed-phase high performance chromatography (HPLC)

Utilization of ion-air reagents in a reversed-phase chromatographic system allows solving a number of problems related to the separation of purine and pyrimidine derivatives. Simultaneous analysis of nucleotides, nucleosides and their bases was carried out by acetonitrile gradient elution using tetrabutyl ammonium phosphate as a counterion in the mobile phase. Besides, optimal conditions were selected for isocratic separation of adenine nucleotides and their metabolites. Furthermore, isocratic separation of certain purines and pyrimidines was achieved by modifying the stationary C18-phase with pentane- and heptane sulphonic acids.     

Oligonucleotide-directed triple helix formation at adjacent oligopurine and oligopyrimidine DNA tracts by alternate strand recognition.

A significant limitation to the practical application of triplex DNA is its requirement for oligopurine tracts in target DNA sequences. The repertoire of triplex-forming sequences can potentially be expanded to adjacent blocks of purines and pyrimidines by allowing the third strand to pair with purines on alternate strands, while maintaining the required strand polarities by combining the two major classes of base triplets, Py.PuPy and Pu.PuPy. The formation of triplex DNA in this fashion requires no unusual bases or backbone linkages on the third strand. This approach has previously been demonstrated for target sequences of the type 5'-(Pu)n(Py)n-3' in intramolecular complexes. Using affinity cleaving and DNase I footprinting, we show here that intermolecular triplexes can also be formed at both 5'-(Pu)n(Py)n-3' and 5'-(Py)n(Pu)n-3' target sequences. However, triplex formation at a 5'-(Py)n(Pu)n-3' sequence occurs with lower yield. Triplex formation is disfavored, even at acid pH, when a number of contiguous C+.GC base triplets are required. These results suggest that triplex formation via alternate strand recognition at sequences made up of blocks of purines and pyrimidines may be generally feasible.