Quantitation of ultraviolet radiation-induced cyclobutyl pyrimidine dimers in DNA by video and photographic densitometry

We have compared video and photographic methods for calculating the number of ultraviolet radiation (uv)-induced pyrimidine dimers in DNA from the bacteriophage T7 exposed to uv (0 to 800 J/m2) from an FS40 sunlamp. DNA was incubated with a pyrimidine dimer-specific Micrococcus luteus uv endonuclease, subjected to alkaline agarose gel electrophoresis, neutralized, and stained with ethidium bromide, and the DNA fluorescence was recorded either with a video camera or on photographic film. The slopes of the dose-response curves for the number of uv-endonuclease-sensitive sites per 10(3) bases (pyrimidine dimers) was 1.2 (+/- 0.1) X 10(-4) uv-endonuclease-sensitive sites per J/m2 for the video analysis and 1.3 (+/- 0.04) X 10(-4) uv-endonuclease-sensitive sites per J/m2 for the photographic analysis. Results for pyrimidine dimer determination by either method were statistically comparable.     

Dose response, wavelength dependence and rate of excision of ultraviolet radiation-induced pyrimidine dimers in mouse skin DNA

The yield of thymine-containing dimers produced in mouse skin DNA in vivo by 290 nm ultraviolet radiation was shown to increase with dose up to around 2000 J/m2 and subsequently at a much slower rate up to 8000 J/m2. The study of wavelength dependence of dimer formation in skin indicated that 290 nm was the most effective wavelength of those investigated, followed by 300, 280 and 260 nm, with 310 nm being by far the least effective. A reduction in the number of dimers present in skin DNA was shown to occur by 24 h post-irradiation in a dose-dependent manner. A significant percentage of the dimers was, however, found to persist in the skin until at least 72 h post-irradiation.     

The excision of pyrimidine dimers from DNA of ultraviolet irradiated yeast

Summary It is shown that pyrimidine dimers formed by ultraviolet light in the DNA of haploid Saccharomyces cerevisae are removed under the influence of photoreactivating light and also in the dark under growth conditions. The integrity of the rad 1 locus is necessary for the dark-removal of dimers.     

Photoreactivation and dark repair of ultraviolet light-induced pyrimidine dimers in chloroplast DNA.

A UV-specific endonuclease was used to detect ultraviolet light-induced pyrimidine dimers in chloroplast DNA of Chlamydomonas reinhardi that was specifically labeled with tritiated thymidine. All of the dimers induced by 100 J/m2 of 254 nm light are removed by photoreaction. Wild-type cells exposed to 50 J/m2 of UF light removed over 80% of the dimers from chloroplast DNA after 24 h of incubation in growth medium in the dark. A UV- sensitive mutant, UVS1, defective in the excision of pyrimidine dimers from nuclear DNA is capable of removing pyrimidine dimers from chloroplast DNA nearly as well as wild-type, suggesting that nuclear and chloroplast DNA dark-repair systems are under separate genetic control.     

Ultraviolet radiation-induced lethality and repair of pyrimidine dimers in fish embryos

Pimephales promelas (fathead minnow) embryos were used to show a correlation between induction of pyrimidine dimers in DNA and embryo death. Embryo killing was measured by a lack of heart-beat and blood circulation at 48 h post-ultraviolet radiation (UVR). When the embryos were exposed to various doses of UVR from a FS-40 sunlamp followed by exposure to photoreactivating light (PRL) (320-400 nm), the number of pyrimidine dimers decreased significantly. The photorepair of dimers was accompanied by a substantial increase in embryo survival. When embryo killing was examined as a function of the number of dimers present, dimers were identified as a major lesion involved in UVR-induced killing in these fish embryos. This in vivo study on photoreactivation treatment of fish embryos shows a direct association between UVR-induced pyrimidine dimers and embryo killing. In addition, when embryos were held in the dark for 9 h after UVR, 50% of the dimers were removed by excision repair.     

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.     

Excision of pyrimidine dimers from the DNA of Neurospora

Summary Germinated conidia of Neurospora have been monitored for their ability to excise pyrimidine dimers. Dimer concentration was measured in DNA extracted immediately after UV treatment, and it was compared to that of DNA from cells which had a post-UV incubation before extraction. Two methods were used to assay dimer level in DNA: 1) measurement of the number of single-strand breaks (as revealed in alkaline sucrose gradients) produced by a dimer-specific endonuclease; 2) monitoring the ability to compete for binding to dimer-specific antibodies in a radioimmuno assay. Both methods showed efficient excision of dimers by wild-type and by uvs-2, even though an earlier study had reported that uvs-2 was unable to excise dimers.UV-induced mutation shows a dose-rate effect: acute UV yields several times as many mutations as does the same dose of chronic UV. There is a parallel effect on dimer accumulation. The concentration of dimers at the conclusion of the UV treatment shows a strong correlation with the resultant mutation frequency.     

A rapid and sensitive assay for pyrimidine dimers in DNA

We have developed a rapid, sensitive assay for pyrimidine dimers. The assay has greatly facilitated the purification and characterization of the photoreactivating enzyme. The procedure depends on (1) the resistance of the nucleotide phosphate bond in dimer-containing regions of DNA to attack by DNase I, venom phosphodiesterase and alkaline phosphatase and (2) selective adsorption to Norit of mononucleosides and ³²P-labeled, dimer containing oligonucleotides (but not ³²P₁) resulting from nuclease digestion of highly-purified, ³²P-labeled bacteriophage DNA. The method is sensitive and rapid. The presence of the usual nuclease activities found in cell extracts does not interfere with the assay. Thus photoreactivating enzyme activity can be detected even in the presence of non-specific or uv-specific nucleases. Neither photoreactivation nor the digestion reaction is affected by purification agents at concentrations commonly used in enzyme purification.     

Persistence of pyrimidine dimers during post-replication repair in ultraviolet light-irradiated Escherichia coli K12

We have used a new assay for pyrimidine dimers to obtain evidence regarding the mechanism of post-replication repair of ultraviolet light-induced damage in excision-deficient (uvr) mutants of Escherichia coli. Our data indicate that dimers are gradually removed from the irradiated DNA under conditions permitting post-replication repair. Concomitantly, dimers appear in daughter strands synthesized after irradiation. The daughter strands initially contain gaps. During post-replication repair the gaps are filled and the originally discontinuous DNA is joined into long molecules resembling those observed in unirradiated control cells. Density transfer experiments reported by other investigators have provided evidence that the gap-filling involves exchanges between irradiated parental DNA and unirradiated daughter strands. The results of our experiments are in accord with this possibility and suggest that some dimers are included in the exchanged regions. Our data imply that intact, dimer-free DNA molecules are not necessarily generated by gap-filling and may not appear in uvr cells until several hours after u.v. irradiation. Instead, dimers may be gradually diluted among successive generations of DNA molecules synthesized after irradiation.     

Mutability of bacteriophage M13 by ultraviolet light: Role of pyrimidine dimers

Summary The role of pyrimidine dimers in mutagenesis by ultraviolet light was examined by measuring the UV-induced reversion of six different bacteriophage M13 amber mutants for which the neighboring DNA sequences are known. The mutational response at amber (TAG) codons preceded by a guanine or adenine (where no pyrimidine dimer can be formed) were compared with those preceded by thymine or cytosine (where dimer formation is possible). Equivalent levels of UV-induced mutagenesis were observed at both kinds of sites. This observation demonstrates that there is no requirement for a pyrimidine dimer directly at the site of UV-induced mutation in this single-stranded DNA phage. UV irradiation of the phage was also performed in the presence of Ag⁺ ions, which specifically sensitize the DNA to dimer formation. The two methods of irradiation, when compared at equal survival levels (and presumably equal dimer frequencies), produced equivalent frequencies of reversion of the amber phage. We believe these results indicate that while the presence of pyrimidine dimers may be a prerequisite for UV mutagenesis, the actual mutagenic event can occur at a site some distance removed from a dimer.