Deamination of 5-methylcytosines within cyclobutane pyrimidine dimers is an important component of UVB mutagenesis

UVB mutagenesis is characterized by an abundance of C --> T and 5-methylcytosine --> T transitions at dipyrimidine sequences. It is not known how these mutations might arise. One hypothesis is that UV-induced mutations occur only after deamination of the cytosine or 5-methylcytosine within the pyrimidine dimer. It is not clear how methylation of cytosines at the 5-position influences deamination and how this affects mutagenesis. We have now conducted experiments with a CpG-methylated supF shuttle vector that was irradiated with UVB and then incubated at 37 degrees C to allow time for deamination before passage through a human cell line to establish mutations. This led to a significantly increased frequency of CC --> TT mutations and of transition mutations at 5'-PymCG-3' sequences. A spectrum of deaminated cis-syn cyclobutane pyrimidine dimers in the supF gene was determined using the mismatch glycosylase activities of MBD4 protein in combination with ligation-mediated PCR. Methylation at the C-5 position promoted the deamination of cytosines within cis-syn cyclobutane pyrimidine dimers, and these two events combined led to a significantly increased frequency of UVB-induced transition mutations at 5'-PymCG-3' sequences. Under these conditions, the majority of all supF mutations were transition mutations at 5'-PymCG-3', and they clustered at several mutational hot spots. Exactly these types of mutations are frequently observed in the p53 gene of nonmelanoma skin tumors. This particular mutagenic pathway may become prevalent under conditions of inefficient DNA repair and slow proliferation of cells in the human epidermis.     

Repair of cyclobutane pyrimidine dimers and 6-4 photoproducts in the fission yeast Schizosaccharomyces pombe

We have measured repair of both of the major lesions induced by ultraviolet irradiation (cyclobutane pyrimidine dimers and 6-4 photoproducts) in wild-type Schizosaccharomyces pombe and in selected rad mutants, including mutants with deletions in genes from the main phenotypic groups. We find that rad13Δ, rad15 and rad16Δ, which are the S. pombe homologues of the excision-defective Saccharomyces cerevisiae rad2, rad3 and rad1, respectively, repair lesions somewhat more slowly than the wild type, but still have considerable repair capacity. rad2Δ, also a presumed excision-defective mutant, behaves similarly. radS and rad9δ, which belong to different phenotypic groups, repair lesions at the same rate as wild-type cells. These findings provide new evidence that S. pombe has a second repair system for removing ultraviolet damage, which is absent in S. cerevisiae. Surprisingly, this second mechanism repairs lesions very efficiently; its possible nature is discussed.     

Photoreactivation of pyrimidine dimers in the DNA of normal and xeroderma pigmentosum cells.

Photoproducts formed in the DNA of human cells irradiated with ultraviolet light (uv) were identified as cyclobuytl pyrimidine dimers by their chromatographic mobility, reversibility to monomers upon short wavelength uv irradiation, and comparison of the kinetics of this monomerization with that of authentic cis-syn thymine-thymine dimers prepared by irradiation of thymine in ice. The level of cellular photoreactivation of these dimers reflects the level of photoreactivating enzyme measured in cell extracts. Action spectra for cellular dimer photoreactivation in the xeroderma pigmentosum line XP12BE agree in range (300 nm to at least 577 nm) and maximum (near 400 nm) with that for photoreactivation by purified human photoreactivating enzyme. Normal human cells can also photoreactivate dimers in their DNA. The action spectrum for the cellular monomerization of dimers is similar to that for photoreactivation by the photoreactivating enzyme in extracts of normal human fibroblasts.     

Subcellular distribution of proteasomes implicates a major location of protein degradation in the nuclear envelope-ER network in yeast.

26S proteasomes are the key enzyme complexes responsible for selective turnover of short-lived and misfolded proteins. Based on the assumption that they are dispersed over the nucleoplasm and cytoplasm in all eukaryotic cells, we wanted to determine the subcellular distribution of 26S proteasomes in living yeast cells. For this purpose, we generated yeast strains that express functional green fluorescent protein (GFP) fusions of proteasomal subunits. An alpha subunit of the proteolytically active 20S core complex of the 26S proteasome, Pre6/YOL038w, as well as an ATPase-type subunit of the regulatory 19S cap complex, Cim5/YOL145w, were tagged with GFP. Both chimeras were shown to be incorporated completely into active 26S proteasomes. Microscopic analysis revealed that GFP-labelled 20S as well as 19S subunits are accumulated mainly in the nuclear envelope (NE)-endoplasmic reticulum (ER) network in yeast. These findings were supported by the co-localization and co-enrichment of 26S proteasomes with NE-ER marker proteins. A major location of proteasomal peptide cleavage activity was visualized in the NE-ER network, indicating that proteasomal degradation takes place mainly in this subcellular compartment in yeast.     

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.     

The cyclobutane dimers of 5-methylcytosine and their deamination products.

The photochemical reactions of 5-methylcytosine (m(5)C), a minor component of mammalian DNA, have been studied at a concentration of 2 mM in frozen 10 mM aqueous NaCl solution at dry ice temperature (194.5 K). For these studies, low-pressure lamps emitting mainly UVB radiation were used. We have isolated and characterized three cyclobutane dimers, namely the cis-anti(c,a) the cis-syn(c,s) and the trans-syn(t,s) forms. While the c,a and the t,s cyclobutane dimers are relatively stable towards deamination upon standing in solution at 277 K, the c,s isomer is gradually converted into the corresponding c,s m(5)C-thymine (Thy) mixed dimer; this latter reaction occurs considerably faster at 310 K. The t,s cyclobutane dimer is converted into the corresponding m(5)C-Thy mixed dimer upon incubation at 373 K, while the c,a dimer is converted into a mixture of m(5)C and c,a mixed dimer when incubated at 310 K. Irradiation of equimolar mixtures of Thy (1 mM) and m(5)C (1 mM) under similar conditions yields each of the three m(5)C cyclobutane dimers, as well as significant amounts of c,a, c,s and t,s m(5)C-Thy mixed cyclobutane dimers. These m(5)C-Thy dimers undergo decompositions similar in nature to the processes undergone by m(5)C cyclobutane dimers. Pseudo-first order rate constants for deamination of the c,s m(5)C homodimer and c,s m(5)C-Thy heterodimer at various temperatures and at pH 7.7 have been measured and the enthalpies and entropies of activation have been evaluated for the deamination processes for these two compounds. The two dimers have half-lives of about 14 and 22 h, respectively, at 310 K; however, at 273 K, the corresponding half-lives can be evaluated as being around 30 and 36 days, respectively.     

Inhibition of eukaryotic topoisomerase II by ultraviolet-induced cyclobutane pyrimidine dimers.

The effects of short wave ultraviolet (UV)-induced DNA lesions on the catalytic activity of Drosophila melanogaster topoisomerase II were investigated. The presence of these photoproducts impaired the enzyme's ability to relax negatively supercoiled pBR322 plasmid molecules. As determined by DNA photolyase-catalyzed photoreactivation experiments, enzyme inhibition was due to the presence of cyclobutane pyrimidine dimers in the DNA. When 10-20 cyclobutane dimers were present per plasmid, the initial velocity of topoisomerase II-catalyzed DNA relaxation was inhibited approximately 50%. Decreased relaxation activity correlated with an inhibition of the DNA strand passage step of the enzyme's catalytic cycle. In contrast, UV-induced photoproducts did not alter the prestrand passage DNA cleavage/religation equilibrium of topoisomerase II either in the absence or presence of antineoplastic agents. Results of the present study demonstrate that the repair of cyclobutane pyrimidine dimers is important for the efficient catalytic function of topoisomerase II.     

(6-4) photoproducts and not cyclobutane pyrimidine dimers are the main UV-induced mutagenic lesions in Chinese hamster cells.

A partial revertant (RH1-26) of the UV-sensitive Chinese hamster V79 cell mutant V-H1 (complementation group 2) was isolated and characterized. It was used to analyze the mutagenic potency of the 2 major UV-induced lesions, cyclobutane pyrimidine dimers and (6-4) photoproducts. Both V-H1 and RH1-26 did not repair pyrimidine dimers measured in the genome overall as well as in the active hprt gene. Repair of (6-4) photoproducts from the genome overall was slower in V-H1 than in wild-type V79 cells, but was restored to normal in RH1-26. Although V-H1 cells have a 7-fold enhanced mutagenicity, RH1-26 cells, despite the absence of pyrimidine dimer repair, have a slightly lower level of UV-induced mutagenesis than observed in wild-type V79 cells. The molecular nature of hprt mutations and the DNA-strand specificity were similar in V79 and RH1-26 cells but different from that of V-H1 cells. Since in RH1-26 as well as in V79 cells most hprt mutations were induced by lesions in the non-transcribed DNA strand, in contrast to the transcribed DNA strand in V-H1, the observed mutation-strand bias suggests that normally (6-4) photoproducts are preferentially repaired in the transcribed DNA strand. The dramatic influence of the impaired (6-4) photoproduct repair in V-H1 on UV-induced mutability and the molecular nature of hprt mutations indicate that the (6-4) photoproduct is the main UV-induced mutagenic lesion.     

Pyrimidine dimers as pre-mutational lesions in Escherichia coli WP2 Hcr

Summary Mutation to prototrophy in E. coli WP2 Hcr^- induced by far-UV radiation (F-UV) in an intermediate dose range follows dose-squared kinetics. In a comparable dose-range with near-UV radiation in the presence of acetophenone (N-UV+Acph) mutation induction follows kinetics which are linearly related to dose. The difference in response to the two types of irradiation is a more general one in that it is the same for true revertants, for suppressor mutants, and for several markers.Double-irradiation experiments together with treatment by photoreactivating light (PR) after the first irradiation (i.e. F-UVPRF-UV; N-UV+AcphPRN-UV+Acph; N-UV+AcphF-UV; N-UV+AcphPRF-UV) seem to indicate the following: a) the dose-squared kinetics for F-UV are due to the necessary co-operation of at least two types of pre-mutational lesions, only one of which is photoreversible; b) N-UV+Acph also produces these photoreversible lesions in addition to such photoreversible ones which do not require the co-operation of other types; the production of the former is not indicated by the appearance of visible mutants because the non-photoreversible type, whose co-operation is required to give rise to such mutants, is not produced.     

Photoreactivation of U.V.-induced cytoplasmatic lesions in eggs of Sciara ocellaris

Photoreactivation of Sciara eggs inactivated by U.V. at 254 or 300 nm wave-lengths was observed regardless of whether the lesions were induced in nuclear or cytoplasmic targets. Photoreactivation of cytoplasmic injury caused by U.V. at 254 nm seems to be a special property of Sciara eggs since this mechanism is practically absent in other insect eggs. The cause of this differential behaviour is not known.     

Photoreactivation of damage induced by ionizing radiation in yeast cells

Summary Experimental data on photoreactivation of damage induced by ionizing radiation in yeast cells are presented. The value of photoreactivation was found to be the highest for the following conditions predicted by us as optimum ones: large volume of irradiated suspension, hypoxia and high energy sparsely ionizing radiation. A comparison of data for yeast and bacterial cells shows that Cerenkov emission from ionizing radiation may produce photoreactivated pyrimidine dimers in both prokaryotic and eukaryotic cell systems.     

Photoreactivation of thymine dimers in UV-irradiated human cells: Unique dependence on culture conditions

UV-irradiated human fibroblasts in tissue culture were exposed to photoreactivating light in an attempt to demonstrate a light-dependent loss of thymine dimers from the acid-insoluble fraction of the DNA. The only experimental conditions in which this phenomenon was observed was if the cells were grown for at least 10 days in Dulbecco's modified Eagle's minimum essential medium. Such cells lost a maximum of between 10–30% of the thymine dimers from their DNA during illumination for 1 h. When cells were grown in a variety of other media the phenomenon was not observed. The present experiments do not discriminate between true enzymatic photoreactivation and a medium-dependent photosensitization phenomenon that is not enzymatic in nature.     

Rapid immunoassays for detection of UV-induced cyclobutane pyrimidine dimers in whole bacterial cells

Immunoassays were developed to measure DNA damage retained by UV-irradiated whole bacterial cells. Active Mycobacterium parafortuitum and Serratia marcescens cells were fixed and incubated with cyclobutane pyrimidine dimer-binding antibodies after being exposed to known UV doses (254 nm). When both fluorescent (Alexa Fluor 488) and radiolabeled ((125)I) secondary antibodies were used as reporters, indirect whole-cell assays were sensitive enough to measure intracellular UV photoproducts in M. parafortuitum and S. marcescens cells as well as photoenzymatic repair responses in S. marcescens cells. For the same UV dose, fluorescent DNA photoproduct detection limits in whole-cell assays (immunofluorescent microscopy) were similar to those in fluorescent assays performed on membrane-bound DNA extracts (immunoslot blot). With either fluorescent or radiolabeled reporters, the intracellular cyclobutane pyrimidine dimer content of UV-irradiated whole bacterial cells could be reliably quantified after undergoing a <0.5-order-of-magnitude decrease in culturability. Immunofluorescent microscopy results showed that photoenzymatic repair competence is not uniformly distributed among exponential-growth UV-irradiated pure cultures.