Respective roles of pyrimidine dimer and pyrimidine (6-4) pyrimidone photoproducts in UV mutagenesis of simian virus 40 DNA in mammalian cells

Viral inactivation by light

Nowadays, viral infections are one of the greatest challenges for medical sciences and human society. While antiviral compounds and chemical inactivation remain inadequate, physical approaches based on irradiation provide new potentials for prevention and treatment of viral infections, without the risk of drug resistance and other unwanted side effects. Light across the electromagnetic spectrum can inactivate the virions using ionizing and non-ionizing radiations. This review highlights the anti-viral utility of radiant methods from the aspects of ionizing radiation, including high energy ultraviolet, gamma ray, X-ray, and neutron, and non-ionizing photo-inactivation, including lasers and blue light.

Detection and analysis of UV-induced mutations in the chromosomal DNA of Arabidopsis

Under natural conditions, plants are exposed to solar ultraviolet (UV) radiation, which damages chromosomal DNA. Although plant responses to UV-induced DNA damage have recently been elucidated in detail, revealing a set of DNA repair mechanisms and translesion synthesis (TLS), limited information is currently available on UV-induced mutations in plants. We previously reported the development of a supF-based system for the detection of a broad spectrum of mutations in the chromosomal DNA of Arabidopsis. In the present study, we used this system to investigate UV-induced mutations in plants. The irradiation of supF-transgenic plants with UV-C (500 and 1000 J/m²) significantly increased mutation frequencies (26- and 45-fold, respectively). G:C to A:T transitions (43-67% of base substitutions) dominated in the mutation spectrum and were distributed throughout single, tandem, and multiple base substitutions. Most of these mutations became undetectable with the subsequent illumination of UV-irradiated plants with white light for photoreactivation (PR). These results indicated that not only G:C to A:T single base substitutions, but also tandem and multiple base substitutions were caused by two major UV-induced photoproducts, cyclobutane-type pyrimidine dimers (CPDs) and pyrimidine (6-4) pyrimidone photoproducts (6-4 PPs). In contrast, a high proportion of A:T to T:A transversions (56% of base substitutions) was a characteristic feature of the mutation spectrum obtained from photoreactivated plants. These results define the presence of the characteristic feature of UV-induced mutations, and provide insights into DNA repair mechanisms in plants.

Evaluating ultraviolet sensitivity of adventitious agents in biopharmaceutical manufacturing

Incidents of contamination in biopharmaceutical production have highlighted the need to apply alternative or supplementary disinfection techniques. Ultraviolet (UV) irradiation is a well-established method for inactivating a broad range of microorganisms, and is therefore a good candidate as an orthogonal technique for disinfection. To apply UV as a safeguard against adventitious agents, the UV sensitivity of these target agents must be known so that the appropriate dose of UV may be applied to achieve the desired level of inactivation. This document compiles and reviews experimentally derived 254 nm sensitivities of organisms relevant to biopharmaceutical production. In general, different researchers have found similar sensitivity values despite a lack of uniformity in experimental design or standardized quantification techniques. Still, the lack of consistent methodologies has led to suspicious UV susceptibilities in certain instances, justifying the need to create a robust collection of sensitivity values that can be used in the design and sizing of UV systems for the inactivation of adventitious agents.

A novel single-stranded DNA-specific 3'-5' exonuclease, Thermus thermophilus exonuclease I, is involved in several DNA repair pathways

Single-stranded DNA (ssDNA)-specific exonucleases (ssExos) are expected to be involved in a variety of DNA repair pathways corresponding to their cleavage polarities; however, the relationship between the cleavage polarity and the respective DNA repair pathways is only partially understood. To understand the cellular function of ssExos in DNA repair better, genes encoding ssExos were disrupted in Thermus thermophilus HB8 that seems to have only a single set of 5'-3' and 3'-5' ssExos unlike other model organisms. Disruption of the tthb178 gene, which was expected to encode a 3'-5' ssExo, resulted in significant increase in the sensitivity to H(2)O(2) and frequency of the spontaneous mutation rate, but scarcely affected the sensitivity to ultraviolet (UV) irradiation. In contrast, disruption of the recJ gene, which encodes a 5'-3' ssExo, showed little effect on the sensitivity to H(2)O(2), but caused increased sensitivity to UV irradiation. In vitro characterization revealed that TTHB178 possessed 3'-5' ssExo activity that degraded ssDNAs containing deaminated and methylated bases, but not those containing oxidized bases or abasic sites. Consequently, we concluded that TTHB178 is a novel 3'-5' ssExo that functions in various DNA repair systems in cooperation with or independently of RecJ. We named TTHB178 as T. thermophilus exonuclease I.

Sequence and time-dependent deamination of cytosine bases in UVB-induced cyclobutane pyrimidine dimers in vivo

The mutational specificity of UV-light is characterized by an abundance of C to T transition mutations at dipyrimidines containing cytosine or 5-methylcytosine. A significant percentage of these mutations are CC to TT double transitions. Of the major types of UV-induced DNA lesions, the cis-syn cyclobutane pyrimidine dimers (CPDs) are thought to be the most mutagenic lesions, at least in mammalian cells. It has been proposed that the CPDs become mutagenic perhaps only after cytosine bases within these dimers deaminate to uracil and the resulting U-containing photolesions are correctly bypassed by DNA polymerases. In order to assess the significance of this proposed mutagenic mechanism, we have developed two methods to specifically measure deaminated CPDs in UV-irradiated human cells or DNA. The first method is based on enzymatic photoreversal of CPDs, followed by cleavage of the DNA with uracil DNA glycosylase, an AP lyase activity, and ligation-mediated PCR to map the resulting strand breaks. The second method, which can be used to detect double deamination events (CC to UU), is PCR amplification of photolyase-treated DNA using primers complemetary to the deaminated sequences. We have measured deamination events in the human p53 gene, which contains a large percentage of C to T transitions in skin cancers. The deamination reactions are specific for cytosine within CPDs, are negligible immediately after irradiation, and are time-dependent and DNA sequence context-dependent. Twenty four hours after irradiation of human fibroblasts with UVB light, between 10 and 60% of most CPD signals are converted to the deaminated form, depending on the sequence. Significant deamination occurs at skin cancer mutation sites in the p53 gene. Double deamination also occurs and this reaction can involve dimers containing 5-methylcytosine or cytosine. These double events are expected to occur more frequently in cells with a DNA repair defect because there is more time for deamination in unrepaired lesions. This may explain the relatively high frequency of CC to TT mutations in skin cancers from xeroderma pigmentosum patients. In summary, these novel detection techniques demonstrate that deamination of cytosine in pyrimidine dimers is a significant event that most likely contributes to the mutational specificity of UVB irradiation in human cells.

Mutation spectra resulting from carcinogenic exposure: from model systems to cancer-related genes

The events leading to cancer are complex and interactive. Alteration of cancer genes, such as the tumor suppressor gene p53, plays a central role in this process. Analysis of the frequency, type and site of mutations in important cancer-related genes may provide clues to the identification of etiological factors and sources of exposure. In this chapter we have selected a few examples of environmental human carcinogens and have attempted to use the knowledge of their mechanisms of mutagenesis, as derived from in vitro cell systems, as a key to understanding the complexity of p53 mutation spectra in tumors arising at the putative target organ. The analysis will focus on environmental exposure to UV radiation. The examples of tobacco smoke, dietary aflatoxin and vinyl chloride will be also briefly discussed.

Formation and processing of UV photoproducts: effects of DNA sequence and chromatin environment

Cyclobutane pyrimidine dimers and (6-4) photoproducts are the two major classes of lesions produced in DNA by UVB and UVC irradiation. Their distribution along genes is nucleotide sequence-dependent. In vivo, the frequency of these lesions at specific sites is modulated by nucleosomes and other DNA binding proteins. Repair of UV photoproducts is dependent on the transcriptional status of the sequences to be repaired and on the chromatin environment. The formation of DNA photolesions by UV light is responsible for the induction of mutations and the development of skin cancer. To understand the mechanisms of UV mutagenesis, it is important to know how these lesions are formed, by which cellular pathways they are repaired and how they are dealt with by DNA polymerases.

Specific UV-induced mutation spectrum in the p53 gene of skin tumors from DNA-repair-deficient xeroderma pigmentosum patients

The UV component of sunlight is the major carcinogen involved in the etiology of skin cancers. We have studied the rare, hereditary syndrome xeroderma pigmentosum (XP), which is characterized by a very high incidence of cutaneous tumors on exposed skin at an early age, probably due to a deficiency in excision repair of UV-induced lesions. It is interesting to determine the UV mutation spectrum in XP skin tumors in order to correlate the absence of repair of specific DNA lesions and the initiation of skin tumors. The p53 gene is frequently mutated in human cancers and represents a good target for studying mutation spectra since there are > 100 potential sites for phenotypic mutations. Using reverse transcription-PCR and single-strand conformation polymorphism to analyze > 40 XP skin tumors (mainly basal and squamous cell carcinomas), we have found that 40% (17 out of 43) contained at least one point mutation on the p53 gene. All the mutations were located at dipyrimidine sites, essentially at CC sequences, which are hot spots for UV-induced DNA lesions. Sixty-one percent of these mutations were tandem CC-->TT mutations considered to be unique to UV-induced lesions; these mutations are not observed in internal human tumors. All the mutations, except two, must be due to translesion synthesis of unrepaired dipyrimidine lesions left on the nontranscribed strand. These results show the existence of preferential repair of UV lesions [either pyrimidine dimers or pyrimidine-pyrimidone (6-4) photoproducts] on the transcribed strand in human tissues.

The distribution of UV damage in the lacI gene of Escherichia coli: correlation with mutation spectrum

We have determined the UV (254 nm) damage distribution in the transcribed and non-transcribed strands of the i-d region of the Escherichia coli lacI gene. The locations of replication blocking lesions were revealed as termination sites of T7 DNA polymerase and/or T4 DNA polymerase 3'-5' exonuclease. Termination products, i.e. both cyclobutane pyrimidine dimers and 6-4 photoproducts, were resolved and analysed on an automated DNA sequencer. These two major photoproducts are not randomly distributed along the gene, but occur in clusters, in longer runs of pyrimidines. We also have compared the UV damage distribution with the previously reported UV-induced base substitutions in the same region. Mutational hotspots, in both repair-deficient and repair-proficient strains of E. coli, are all located in stretches of pyrimidines, and thus correlate well with the distribution of photolesions. One mutational hotspot in the wild-type strain may reflect the high frequency of closely opposed lesions. To explain the other mutational hotspots, we propose that the repair of UV lesions is impaired due to the local conformation of the DNA, which might deviate from the B-form. This hypothesis is supported by the excess of mutational hotspots in pyrimidine runs in the Uvr+ strain compared to Uvr-. Runs of pyrimidines thus represent both damage- and mutation-prone sequences following UV treatment.

(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.

Comparison of spontaneous and ultraviolet-induced mutagenesis on naked SV40 DNA and SV40 virus

Molecular aspects of mutagenesis in mammalian cells have been essentially analyzed using biological probes such as viruses and shuttle vectors. Although the main data concerning the specificity of carcinogen-induced mutations are similar, the observed spontaneous mutation frequencies are significantly different when using one or the other model. This frequency is considerably higher with shuttle vectors than with viruses. We have performed an analysis of mutagenesis in order to determine if the obligatory transfection step associated with shuttle vector technology was responsible for the high mutation frequency found with these molecules. For this purpose simian virus 40 (SV40) genome used as virus or as naked DNA was introduced into permissive cells by viral infection or DNA transfection respectively. Our results show that transfection alone does not induce a higher mutation frequency on SV40 DNA than virus infection. Moreover, we have shown that the ultraviolet-light induced mutation spectrum was similar on the SV40 VP1 gene after viral infection or DNA transfection.

Damage distribution and mutation spectrum: the case of 8-methoxypsoralen plus UVA in mammalian cells

We determined the distribution of monoadducts and biadducts induced in the supF tRNA gene carried by the shuttle vector pZ189, after exposure to 8-methoxypsoralen (8-MOP) plus a double UVA (365 nm) irradiation. These data were compared to our previously published 8-MOP-photoinduced mutation spectrum obtained after propagation of the damaged shuttle vector in mammalian cells. One mutational hot spot in an ATAT/TATA sequence is targeted at a hot spot of biaddition. A second hot spot is not related to the presence of photoadducts either at or near the site. Moreover, it is located in a sequence which can be defined as 'mutation-prone'. Mutations occurring at GC base pairs are not targeted at sites of photoaddition, and may result from a decrease in fidelity of DNA polymerase when copying the damaged vector.

In vivo mapping of a DNA adduct at nucleotide resolution: detection of pyrimidine (6-4) pyrimidone photoproducts by ligation-mediated polymerase chain reaction

DNA adducts in unique sequences along the mammalian genome are mapped in vivo at single-nucleotide resolution. Pyrimidine (6-4) pyrimidone photoproducts [(6-4) photoproducts] represent one of the two major adduct classes found after UV irradiation of DNA and were shown to play an important role in UV-induced mutagenesis. After UV light treatment of cells, DNA is prepared and chemically cleaved at (6-4) photoproducts with piperidine. Gene-specific fragments are then amplified from total genomic DNA by use of a ligation-mediated polymerase chain reaction. Analysis of the human chromosome X-linked phosphoglycerate kinase (PGK1) gene's promoter has shown that the frequency of (6-4) photoproducts expressed as piperidine-labile sites is (i) high at TpC and CpC dinucleotides, (ii) dependent on the nearest-neighbor bases, (iii) inhibited by the binding of a transcription factor, and (iv) different for DNA derived from the active and inactive X chromosome. This latter difference is mainly a consequence of the presence of 5-methylcytosine (m5C) in CpG dinucleotides on the inactive X chromosome. 5-Methylcytosine in the sequences Tm5CG and Cm5CG inhibits the formation of (6-4) photoproducts. Thus, in addition to in vivo mapping of a DNA adduct at nucleotide resolution, we also report another method for methylation analysis and photofootprinting.

Mechanisms and consequences of mutation induction in mammalian cells

Mutations have been studied for several decades in order to understand biological processes of great significance and the selection of better-adapted species. Our knowledge both of mutation spectra induced by genotoxic agents and the mechanisms involved in DNA damage processing is more advanced in bacteria than in animal cells. However, the use of new technologies such as shuttle vectors or the polymerase chain reaction will undoubtedly allow rapid progress in the next few years. Shuttle vectors consist of target sequences for monitoring mutagenic activity and additional sequences permitting DNA replication and selection, both in bacteria and in mammalian cells. These plasmids are very efficient in allowing the production of mutation spectra of a particular genotoxin in animal cells. In most cases, base substitutions occur predominantly at the sites of base damage and the type of substitution depends on the kind of damage. This has been well characterized using ultraviolet (UV) light as a mutagen. UV-induced mutations are targeted opposite pyrimidine-pyrimidine sites, where the two major UV lesions are produced. The direct relationships existing between mutation and cancer are exemplified by some hereditary diseases where deficiency in an enzymatic repair system is linked to a high incidence of tumours. Similarly, activation of some cellular proto-oncogenes occurs via specific point mutations. A correlation does exist between the mutation spectra found in model systems and the specific mutation found in the activated oncogene in tumours induced by a given genotoxin. This is particularly well illustrated in the DNA repair deficiency syndrome, xeroderma pigmentosum. The specific mutations found in activated ras oncogenes isolated from UV-stimulated skin tumours correlate well with the mutagenic properties of unrepaired UV-induced DNA lesions.