Evidence for structural deformation of the DNA helix by a psoralen diadduct but not by a monoadduct.

We have investigated the structural change in a double-stranded DNA helix caused by covalent addition of a psoralen. A synthetic double-stranded DNA was constructed to contain either a psoralen furan-side monoadduct or an interstrand diadduct at a specific site. When the unmodified and psoralen modified DNAs were examined by electron microscopy in the presence of distamycin, which stiffens the DNA helix, the DNA containing the psoralen interstrand diadduct appeared bent (or kinked), whereas the furan-side monoadducted DNA appeared similar to the unmodified DNA. RecA protein from E. coli has been shown to preferentially bind UV (ultra violet) irradiated DNA presumably due to alterations in the normal DNA helical structure. Using a nitrocellulose filter binding assay, we have found that the psoralen interstrand diadduct enhances the binding of recA protein to the double-stranded DNA, whereas a furan-side monoadduct has little effect. Thus both the recA protein binding and the electron microscopic data suggest that a psoralen diadduct causes deformation of a DNA helix, most likely by kinking the helix, and that a monoadduct has little effect on the DNA helix structure.     

Wavelength dependence for the photoreactions of DNA-psoralen monoadducts. 2. Photo-cross-linking of monoadducts

The photoreactions of HMT [4'-(hydroxymethyl)-4,5',8-trimethylpsoralen] monoadducts in double-stranded DNA have been studied with complementary oligonucleotides. The HMT was first attached to the thymidine residue in the oligonucleotide 5'-GAAGCTACGAGC-3' as either a furan-side monoadduct or a pyrone-side monoadduct. The HMT-monoadducted oligonucleotide was then hybridized to the complementary oligonucleotide 5'-GCTCGTAGCTTC-3' and irradiated with monochromatic light. In the case of the pyrone-side monoadducted oligonucleotide, photoreversal was the predominant reaction, and very little cross-link was formed at all wavelengths. The course of the photoreaction of the double-stranded furan-side monoadducted oligonucleotide was dependent on the irradiation wavelength. At wavelengths below 313 nm, both photoreversal and photo-cross-linking occurred. At wavelengths above 313 nm, photoreversal of the monoadduct could not be detected, and photo-cross-linking occurred efficiently with a quantum yield of 2.4 X 10(-2).     

Wavelength dependence for the photoreactions of DNA-psoralen monoadducts. 1. Photoreversal of monoadducts

We have studied the wavelength dependence for the photoreversal of a monoadducted psoralen derivative, HMT [4'-(hydroxymethyl)-4,5',8-trimethylpsoralen], in a single-stranded deoxyoligonucleotide (5'-GAAGCTACGAGC-3'). The psoralen was covalently attached to the thymidine residue in the oligonucleotide as either a furan-side monoadduct, which is formed through the cycloaddition between the 4',5' double bond of the psoralen and the 5,6 double bond of the thymidine, or a pyrone-side monoadduct, which is formed through the cycloaddition between the 3,4 double bond of the psoralen and the 5,6 double bond of the thymidine. As a comparison, we have also investigated the wavelength-dependent photoreversal of the isolated thymidine-HMT monoadducts. All photoreversal action spectra correlate with the extinction spectra of the isolated monoadducts. In the case of the pyrone-side monoadduct, two absorption bands contribute to the photoreversal with a quantum yield of 2 X 10(-2) at wavelengths below 250 nm and 7 X 10(-3) at wavelengths from 287 to 314 nm. The incorporation of the monoadduct into the DNA oligomer had little effect upon the photoreversal rate. For the furan-side monoadduct at least three absorption bands contribute to the photoreversal. The quantum yield varied from 5 X 10(-2) at wavelengths below 250 nm to 7 X 10(-4) at wavelengths between 295 and 365 nm. In contrast to the case of the pyrone-side monoadduct, the incorporation of the furan-side monoadduct into the DNA oligomer reduced the photoreversal rate constant at wavelengths above 285 nm.     

Monoclonal antibodies to DNA modified by 8-methoxypsoralen and ultraviolet A light.

A panel of monoclonal antibodies have been developed which specifically recognize DNA modified by 8-methoxypsoralen (8-MOP) and ultraviolet A light (320-400 nm) (UVA). These antibodies have been characterized as to sensitivity and specificity by an enzyme linked immunosorbent assay (ELISA). In a competitive ELISA with the most sensitive antibody, 50% inhibition of antibody binding occurred at 17 fmole 8-MOP-DNA photo adducts. One adduct per 10(7) bases could be reliably detected. There was also some antibody cross-reactivity with DNAs modified by 4' aminomethyl-4, 5, 8-trimethylpsoralen and 4', 5-dimethylangelicin as well as DNA isolated from cells treated with 8-MOP and UVA. The primary specificity of one of the antibodies was shown to be the 4', 5' thymine monoadduct by competitive inhibition studies using HPLC fractions of an enzymatic digest of 8-MOP poly(dA-dT) . poly(dA-dT). These antibodies should allow the quantitation of adduct levels in various in vitro systems as well as humans exposed clinically to 8-MOP and UVA.     

Thermostability of double-stranded deoxyribonucleic acids: effects of covalent additions of a psoralen

We have carried out a thermodynamic study on the effects of covalent additions of the psoralen derivative HMT, 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen, on the stability of double-stranded deoxyoligonucleotides. This was done with two systems. The first was a double-stranded DNA formed by two non-self-complementary oligonucleotides, 5'-GAAGCTACGAGC-3' and 5'-GCTCGTAGCTTC-3', where we site specifically placed an HMT molecule on the thymidine residue in oligonucleotide 5'-GAAGCTACGAGC-3' as either a furan-side monoadduct or a pyrone-side monoadduct. The second was a double-stranded DNA formed by a self-complementary oligonucleotide, 5'-GGGTACCC-3', where we placed an HMT molecule on the thymidine residue of each strand as a furan-side monoadduct or cross-linked the two strands with an HMT molecule linked to the two thymidines. We found that HMT cross-linking of the two strands stabilizes the double helix formed by 5'-GGGTACCC-3', as one might expect. Less predictable results were that the monoaddition of a psoralen stabilizes the double helix formed by the two non-self-complementary oligonucleotides by as much as 1.3 kcal/mol as a furan-side monoadduct and 0.7 kcal/mol as a pyrone-side monoadduct at 25 degrees C in 50 mM NaCl. In contrast, the monoaddition of a psoralen on each of the two thymidines in the double helix formed by 5'-GGGTACCC-3' destabilizes the helix by 1.8 kcal/mol at 25 degrees C in 1 M NaCl. This destabilization arises from an unfavorable enthalpy change (8.6 kcal/mol) and a favorable entropy change (23 cal/K X mol) due to the two HMT molecules at the centers of each strand.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alkali reversal of psoralen cross-link for the targeted delivery of psoralen monoadduct lesion

Psoralen intercalates into double-stranded DNA and photoreacts mainly with thymines to form monoadducts and interstrand cross-links. We used an oligonucleotide model to demonstrate a novel mechanism: the reversal of psoralen cross-links by base-catalyzed rearrangement at 90 degrees C (BCR). The BCR reaction is more efficient than the photoreversal reaction. We show that the BCR occurs predominantly on the furan side of a psoralen cross-link. The cleavage does not result in the breaking of the DNA backbone, and the thymine base freed from the cross-link by the cleavage reaction appears to be unmodified. Similarly, BCR of the furan-side monoadduct of psoralen removed the psoralen molecule and regenerated the unaltered native oligonucleotide. The pyrone-side psoralen monoadduct is relatively resistant to BCR. One can use BCR to perform efficient oligonucleotide-directed, site-specific delivery of a psoralen monoadduct. As a demonstration of this approach, we have hybridized a 19 base long oligonucleotide vehicle containing a furan-side psoralen monoadduct to a 56 base long complementary oligonucleotide target strand and formed a specific cross-link at the target site with 365-nm UV. Subsequent BCR released the oligonucleotide vehicle and deposited the psoralen at the target site.     

Wavelength dependence for the photoreversal of a psoralen-DNA cross-link

We report an action spectrum for the photoreversal of a psoralen cross-link joining two self-complementary DNA oligonucleotides. The cross-link was formed between two thymines (T) on opposite strands of the DNA oligomers and 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen (HMT). For comparison, we also present an action spectrum for the photoreversal of the isolated diadduct T-HMT-T. The wavelength dependence for the diadduct photoreversal parallels its absorption spectrum. Both the diadduct and the cross-linked DNA can be photoreversed by exposure to light with wavelengths between 240 and 313 nm. We did not observe photoreversal at 334 nm or above. At least two distinct absorption bands appear to contribute to photoreversal. We measured a quantum yield of 0.16 for photoreversal of the isolated diadduct at wavelengths between 240 and 266 nm. For wavelengths above 280 nm, the quantum yield is 0.30. We also observed a preferential photoreversal at the furan end of the psoralen in the T-HMT-T diadduct. In contrast, the cross-linked DNA oligonucleotides preferentially photoreversed at the pyrone end of the psoralen adduct. The rate constant for photoreversal of the cross-linked DNA is larger than that for the isolated diadduct at wavelengths below 300 nm.     

Repair of 8-methoxypsoralen monoadducts in mouse lymphoma cells

Studies of the repair of DNA lesions at biologically important doses is extremely difficult for most mutagens. With 8-methoxypsoralen (8-MOP) plus longwave ultraviolet light (UVA) as the lesion-inducing agent, however, it is easy to manipulate the relative frequency of different DNA adducts by means of a special experimental protocol (the tap-and-test protocol) and this can be used to measure repair of DNA adducts. Three classes of photoadducts are produced by 8-MOP plus UVA treatment: 3,4-cyclobutane monoadducts, 4',5'-cyclobutane monoadducts, and 8-MOP-DNA interstrand crosslinks. A monoadduct is formed when a photoactivated 8-MOP molecule reacts with a pyrimidine base. An 8-MOP-DNA interstrand crosslink is formed when an existing monoadduct is photoactivated to react with another pyrimidine base on the opposite DNA strand. Thus monoadducts are formed by absorption of one photon of light and crosslinks by absorption of two. In the tap-and-test experiments, cells were exposed to UVA in the presence of 8-MOP and then re-exposed to UVA in the absence of free 8-MOP so that only crosslinks can be produced by the second UVA treatment. By means of this technique we have previously shown that DNA crosslinks are much more effective than monoadducts at producing chromosomal damage (sister-chromatid exchanges and micronuclei) but not mutations (Liu-Lee et al., 1984). If L5178Y mouse lymphoma cells were able to remove monoadducts, incubation prior to the second UVA treatment should lead to decreases in the effect of re-irradiation, because fewer monoadducts would be available for crosslink formation. In this way, we have found that psoralen monoadducts are repaired in these cells and that about 70% of those capable of crosslink formation are removed or otherwise made unavailable for crosslink formation in 6 h.     

Diepoxybutane forms a monoadduct with B-form (dG-dC)n.(dG-dC)n and a crosslinked diadduct with the left-handed Z-form.

The characteristics of the reactions of DL-diepoxybutane (DEB) with (dG-dC)n.(dG-dC)n in the right-handed B-form or the left-handed Z-form were investigated. DEB does react with right-handed B-DNA since less salt is required to convert the modified B-form to Z-form than for the unmodified DNA. However, the product appears to be a monoadduct rather than the crosslinked diadduct formed with the Z-form. The modified B-form can be isolated, converted to a Z-form with l mM MnCl2, and then this activated complex further reacts intramolecularly to give the crosslinked Z-product. This modified Z-form cannot be reverted to the B-form unless the crosslink is cleaved with periodate. Only MnCl2, and to a lesser extent ZnCl2, was effective in facilitating the intramolecular conversion of the B-DNA monoadduct to the Z-DNA diadduct; lmM MgCl2 and 4M NaCl were ineffective suggesting that somewhat different types of modified left-handed conformations were generated by the different salts. DEB also cleaves DNA under our reaction conditions thus precluding studies with supercoiled recombinant plasmids harboring segments that adopt Z-structures.     

Genetic control of mitotic crossing-over in yeasts. III. Induction by 8-methoxypsoralen and long-wave UV irradiation (lambda=365 nm)

The lethal effect of 8-methoxypsoralen (8-MOP) plus 365 nm light has been studied in haploid radiosensitive strains of Saccharomyces cerevisiae. The diploid of wild type and the diploid homozygous for the rad2 mutation (this mutation blocks the excision of UV-induced pyrimidine dimers) were more resistant to the lethal effect of 8-MOP plus 365 nm light than the haploid of wild type and rad2 haploid, respectively. The diploid homozygous for rad54 mutation (the mutation blocks the repair of double-strand breaks in DNA) was more sensitive than haploid rad54. The method of repeated irradiation allowed to study the capacity of radiosensitive diploids to remove monoadducts induced by 8-MOP in DNA. This process was very effective in diploids of wild type and in the rad54 rad54 diploid, while the rad2 rad2 diploid was characterized by nearly complete absence of monoadduct excision. The study of mitotic crossing over and mitotic segregation in yeast diploids, containing a pair of complementing alleles of the ade2 gene (red/pink) has shown a very high recombinogenic effect of 8-MOP plus 365 nm light. The rad2 mutation slightly increased the frequency of mitotic segregation and mitotic crossing over. The rad54 mutation decreased the frequency of mitotic segregation and entirely suppressed mitotic crossing over. The method of repeated irradiation showed that the cross-links, but not monoadducts, are the main cause of high recombinogenic effect of 8-MOP plus 365 nm light. The possible participation of different repair systems in recombinational processes induced by 8-MOP in yeast cells is discussed.     

The repair of psoralen monoadducts by the Escherichia coli UvrABC endonuclease.

We have examined the interactions of UvrABC endonuclease with DNA containing the monoadducts of 8-methoxypsoralen (8-MOP) and 4,5',8-trimethylpsoralen (TMP). The UvrA and UvrB proteins were found to form a stable complex on DNA that contains the psoralen monoadducts. Subsequent binding of UvrC protein to this complex activates the UvrABC endonuclease activity. As in the case of incision at pyrimidine dimers, a stable protein-DNA complex was observed after the incision events. For both 8-MOP and TMP, the UvrABC endonuclease incised the monoadduct-containing strand of DNA on the two sides of the monoadduct with 12 bases included between the two cuts. One incision was at the 8th phosphodiester bond on the 5' side of the modified base. The other incision was at the 5th phosphodiester bond 3' to the modified base. The UvrABC endonuclease incision data revealed that the reactivity of psoralens is 5'TpA greater than 5'ApT greater than 5'TpG.     

Interaction of the UvrABC endonuclease with DNA containing a psoralen monoadduct or cross-link. Differential effects of superhelical density and comparison of preincision complexes.

The effect of negative supercoiling on UvrABC incision of covalently closed duplex DNA circles containing either a furan-side monoadduct or a cross-link of 4'-hydroxymethyl-4,5',8-trimethylpsoralen at a unique site was examined. The rate of UvrABC incision of these DNA substrates was measured as a function of superhelical density, sigma, for values of sigma between 0 and -0.050. The monoadducted DNA substrate was incised at close to the maximum rate at all superhelical densities, with only a slight stimulation of activity between sigma = 0 and -0.035. In contrast, efficient UvrABC incision of the cross-linked DNA substrate required the DNA to be underwound, and activity showed a linear dependence on superhelical density up to sigma = -0.035. DNase I protection studies show that in the presence of both UvrA and UvrB a protein complex binds to the site of a psoralen monoadduct or cross-link in linear DNA. This UvrA-UvrB-dependent complex binds with similar affinity to both the monoadducted and the cross-linked DNA helices. However, differences in the DNase I footprint on these two DNA substrates indicate that the interaction of this protein complex is different at these two lesions. The addition of UvrC to linear DNA molecules that are saturated at the site of the lesion with the UvrA-UvrB-dependent complex resulted in efficient nicking of the monoadducted DNA, but not the cross-linked DNA. Thus, the properties of a DNA lesion site that lead to UvrAB recognition and binding are not necessarily sufficient to allow incision when all three Uvr subunits are present. We propose that after recognition and binding of a lesion site by the UvrAB complex and prior to incision, the damaged DNA helix undergoes a conformational change such as unwinding or melting that is induced by the lesion-bound Uvr complex.     

Construction of DNA substrates modified with psoralen at a unique site and study of the action mechanism of ABC excinuclease on these uniformly modified substrates

Psoralens bind to DNA noncovalently and upon exposure to near UV (320-400 nm) light produce covalent adducts. Thymidine residues in DNA, especially those at 5'-TpA-3' sequences, are most susceptible to the photochemical reaction. This property of the reaction and the recent advances in oligonucleotide synthesis and separation has enabled us to construct DNA fragments containing psoralen adducts at a specific site. The octanucleotide 5'-TCGTAGCT-3' was photoreacted (in the presence of the complementary strand) with the synthetic psoralen 4'-hydroxymethyl-4,5',8-trimethylpsoralen to obtain oligonucleotides adducted via the furan or pyrone ring at the internal thymine. These modified octanucleotides were ligated to nonmodified oligonucleotides to obtain a 40-base pair DNA fragment containing a psoralen adduct at a central location. The modified fragment having the thymine-furan side 4'-hydroxymethyl-4,5',8-trimethylpsoralen adduct was irradiated with 360 nm of light to produce an interstrand cross-link, and this cross-linked DNA was purified to homogeneity. These uniquely modified DNAs were used as substrates for Escherichia coli ABC excinuclease to determine its incision mechanism unambiguously and to determine the contact sites of the enzyme. ABC excinuclease mediates the cleavage of the 8th and 5th phosphodiester bonds 5' and 3', respectively, to psoralen monoadducts, and the 9th (5') and 3rd (3') phosphodiester bonds to the furan-side thymine of the cross-link. Preliminary DNaseI footprinting studies show that ABC excinuclease protects the whole 40-base pair fragment from DNaseI, and binding of the A and B subunits to the furan side-monoadducted substrate produces two hypersensitive phosphodiester bonds in the vicinity of the 5' incision site of ABC excinuclease.     

Photochemical production of psoralen - DNA monoadducts capable of subsequent photocrosslinking.

Irradiation of 4' -aminomethyl-4,5' ,8-trimethyl psoralen in the presence of DNA at wavelengths between 380 and 400nm leads to efficient production of monoadducts with no significant amount of crosslinking. The yield of monoadduct attainable is high (about 35 adducts per 1000 base pairs) and can be made still higher by repeated irradiation with fresh psoralen derivative. Subsequent irradiation at 350nm results in crosslinking of a almost half of the monoattached psoralen. Studies of the yield of nonoadduct and crosslink as function of irradiation wavelength show that the action spectrum for crosslink formation is blue-shifted relative to that for monoadduct formation.     

Oxidative DNA damage photo-induced by 3-carbethoxypsoralen and other furocoumarins. Mechanisms of photo-oxidation and recognition by repair enzymes

DNA photosensitization by several furocoumarins (including 3-carbethoxypsoralen (3-CPs), 8-methoxypsoralen (8-MOP), 5-methoxypsoralen (5-MOP) and angelicin was investigated by using DNA sequencing methodology. 3-CPs induces photo-oxidation of guanine residues leading to alkali-labile sites in DNA (revealed by hot piperidine), whereas 8-MOP, 5-MOP and angelicin do not. There is a preferential photo-oxidation of G when located on the 5' side of GG doublets, likely to reflect a better accessibility of the G moiety in such a context. Mechanisms operating via both radicals (type I) and singlet oxygen (type II) are involved in the photo-oxidation of G residues by 3-CPs. Photo-oxidized G residues are produced independently of the formation of photoadducts, and scavengers of singlet oxygen or radicals do not inhibit photobinding of 3-CPs to DNA. This leads us to propose that covalent photoadducts arise from the intercalated excited sensitizer molecules, whereas G photo-oxidations are produced either by electron transfer reactions involving bound 3-CPs or by energy transfer to molecular oxygen, thereby producing singlet oxygen that subsequently reacts with guanine bases. Quantification of both types of DNA lesions indicated that in vitro photo-oxidized G residues are produced in DNA by 3-CPs plus ultraviolet light at least to the same extent as photoadducts, under our conditions. A calf thymus redoxyendonuclease, equivalent to the endonuclease III of Escherichia coli, specific for oxidative DNA damages, recognizes and cleaves DNA at sites of photo-oxidized G residues. The extent of the cleavage by this enzyme was close to that observed by hot piperidine and followed the amount of photo-oxidized G residues produced when the lifetime of excited oxygen species is modified. The redoxyendonuclease did not incise DNA treated with 8-MOP, 5-MOP or angelicin plus ultraviolet light. The exonuclease III and endonuclease IV of E. coli also involved in the repair of oxidative DNA damage, convert the replicative form I of 3-CPs-treated DNA to replicative form II. This suggests that the lesions recognized by these enzymes are apurinic-like lesions. In view of the low toxicity and mutagenicity of 3-CPs, DNA photo-oxidation products induced by the photodynamic effect of 3-CPs are likely to be efficiently taken care of by the DNA repair system(s). It is clear that 3-CPs photo-induces several classes of DNA damage, including oxidative damage.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structure of a psoralen-thymine monoadduct formed in photoreaction with DNA

A photoreaction product between calf thymus DNA and 8-methoxypsoralen, a naturally occurring psoralen, was hydrolyzed with acid to isolate a major species of the reaction, 8-methoxypsoralen-thymine monoadduct. The crystal structure of the monoadduct has been determined. The structure confirms the results of other spectroscopic studies and allows one to conclude or suggest that: (1) the photoreaction occurs preferentially at both T-A and A-T sequences in natural DNA; (2) the photocrosslink introduces a substantial kink in the DNA structure; (3) the configuration of the photoproduct is “cis-syn” at both ends of the psoralen; (4) the thymine and psoralen moieties remain planar even after the photoreaction; and (5) the angle between psoralen and thymine in the photoproducts is not fixed but has a limited range of flexibility.     

Repair of plasmid DNA treated with 8-methoxypsoralen and long-wave UV light (lambda=365 nm) in wild type and mutant rad2 cells of Saccharomyces cerevisiae

The method of repeated irradiation has been used to study excision of 8-MOP monoadducts from plasmid and chromosomal DNA in cells of wild type and rad2 mutant of Saccharomyces cerevisiae. The measurement of kinetics of monoadduct removal from chromosomal DNA in intact and competent yeast cells showed that monoadducts were excised in both types of cells with normal repair, but this process was blocked in intact and competent cells of the rad2 mutant. The survival of pYF91 plasmid treated in vitro with 8-MOP plus near UV-light has been studied in the cells of the wild type and in incision-defective rad2 mutant by the measurement of cell transformation frequency. Episomic pYF91 plasmid used in these experiments contained the yeast nuclear LEU2 gene, a portion of 2 mkm DNA and DNA of bacterial plasmid pBR322 with resistance to ampicillin. The pYF91 plasmid was treated with 8-MOP plus near UV-light in vitro, then unbound 8-MOP was removed by dialysis. This DNA was used for transformation. The transformed yeast cells were irradiated repeatedly. The quantitative alteration of the yield of transformants, depending on the time of keeping these yeast cells in complete liquid medium at 30 degrees C, prior to repeated irradiation, allowed to measure the kinetics of monoadduct excision from plasmid DNA. It was shown that monoadducts were removed equally effectively from plasmid DNA introduced into cells of the wild type and rad2 mutant. Possibly, the repair system of both these strains provides excision of monoadducts from plasmid DNA, but this process is blocked in the rad2 mutant, relatively to monoadduct excision from chromosomal DNA.     

Sequence context effects on 8-methoxypsoralen photobinding to defined DNA fragments

The photoreaction of 8-methoxypsoralen (8-MOP) with DNA fragments of defined sequence was studied. We took advantage of the blockage by bulky adducts of the 3'-5'-exonuclease activity associated with the T4 DNA polymerase. The action of the exonuclease is stopped by biadducts as well as by monoadducts. The termination products were analyzed on sequencing gels. A strong sequence specificity was observed in the DNA photobinding of 8-MOP. The exonuclease terminates its digestion near thymine residues, mainly at potentially cross-linkable sites. There is an increasing reactivity of thymine residues in the order T less than TT much less than TTT in a GC environment. For thymine residues in cross-linkable sites, the reactivity follows the order AT much less than TA approximately TAT much less than ATA less than ATAT less than ATATAA. Repeated A-T sequences are hot spots for the photochemical reaction of 8-MOP with DNA. Both monoadducts and interstrand cross-links are formed preferentially in 5'-TpA sites. Our results highlight the role of the sequence and consequently of the conformation around a potential site in the photobinding of 8-MOP to DNA.