Inhibition of repair of UV-damaged DNA by caffeine and mutation induction in Chinese hamster cells

The effect of caffeine on UV-irradiated Chinese hamster cells in vitro was studied on the cellular and molecular levels. Caffeine (1 mM) was shown to decrease the colony-forming ability and the frequencies of spontaneous and UV-induced mutations in Chinese hamster cells. The effect of caffeine in reducing the frequency of UV-induced mutations was demonstrated only if caffeine was present in the culture medium during the first post-irradiation cell division. Using alkaline sucrose gradient centrifugation, both parental and newly synthesized DNA in UV-irradiated and unirradiated cells were studied in the presence and absence of caffeine. Caffeine affected the sedimentation profile of DNA synthesized in UV-irradiated cells but not in unirradiated cells. Caffeine had no apparent effect on the incorporation of [³H]-thymidine into DNA of control or UV-irradiated cells, nor on the small amount of excision of UV-induced pyrimidine dimers. These results may be interpreted by a hypothesis that caffeine inhibits a certain S-phase specific, post-replication, dark-repair mechanism. The hamster and perhaps other rodent cells exposed to low doses of UV are capable of DNA replication, by-passing the non-excised pyrimidine dimers. This postulated repair process probably involves de novo DNA synthesis to seal the gaps in the nascent strand. This repair may be also responsible for the enzymatic production of mutations.     

UV-induced immobilization of DNA repair protein XPA in different human cell line

XPA repair protein is absolutely needed for nucleotide excision repair (NER). It preferentially binds UV-irradiated DNA in vitro and possibly takes place in the recognition of pyrimidine dimers, the main type of UV-lesions in DNA. Using immunofluorescent microscopy and immunoblotting technique we have found that XPA protein is fully extractable by Triton X-100 solution from non-irradiated normal human fibroblasts, but after UV-irradiation its extractability decreases in UV-dose dependent manner. UV-induced XPA-immobilization was observed in human cell lines with different types of repair defects, but XPA-extractability from unirradiated cells of these lines was significantly lower in comparison with normal fibroblasts. These data do not permit to make conclusion concerning the distinct connection of this phenomenon with different pathways of NER. Histone deacetylase inhibitor, sodium butyrate, did not change the level of extractability in unirradiated and UV-irradiated normal human cells and CHO cells, defective in global genome repair, that indicated the independence of XPA-immobilization from the level of histone acetylation. It was established with the help of confocal microscopy that XPA-foci in detergent-treated UV-irradiated cell were partially colocalized with the focal sites of PCNA, an auxiliary protein of DNA polymerases delta and epsilon. It may mean that a part of detergent-resistant XPA foci correspond to DNA repair synthesis sites, but the major part of immobilized XPA reflects the early step of repair proteins assembly formation needed for the repair of the lesions.     

Gamma- and UV-induced DNA synthesis in neurons of the rat neocortex

Nuclear DNA synthesis in neocortex neurons of neonatal 14- and 60-day rats after in vitro irradiation of isolated sections was estimated by the incorporation of a labeled precursor into DNA. gamma- and UV-radiation increased the rate of DNA synthesis in the cells of animals of all studied age groups. However, the level of the UV-induced synthesis sharply dropped during the postnatal ontogenesis while gamma-radiation-induced synthesis decreased slightly. The peculiarities revealed in the repair DNA synthesis seem to be influenced by the process of postnatal differentiation of a neuron accompanied by the nucleosome length shortening and the decrease in the DNA-polymerase alpha content.     

Caffeine delays replication fork progression and enhances UV-induced homologous recombination in Chinese hamster cell lines

The ability to bypass DNA lesions encountered during replication is important in order to maintain cell viability and avoid genomic instability. Exposure of mammalian cells to UV-irradiation induces the formation of DNA lesions that stall replication forks. In order to restore replication, different bypass mechanisms are operating, previously named post-replication repair. Translesion DNA synthesis is performed by low-fidelity polymerases, which can replicate across damaged sites. The nature of lesions and of polymerases involved influences the resulting frequency of mutations. Homologous recombination represents an alternative pathway for the rescue of stalled replication forks. Caffeine has long been recognized to influence post-replication repair, although the mechanism is not identified. Here, we found that caffeine delays the progress of replication forks in UV-irradiated Chinese hamster cells. The length of this enhanced delay was similar in wild-type cells and in cell deficient in either homologous recombination or nucleotide excision repair. Furthermore, caffeine attenuated the frequency of UV-induced mutations in the hprt gene, whereas the frequency of recombination, monitored in this same gene, was enhanced. These observations indicate that in cells exposed to UV-light, caffeine inhibits the rescue of stalled replication forks by translesion DNA synthesis, thereby causing a switch to bypass via homologous recombination. The biological consequence of the former pathway is mutations, while the latter results in chromosomal aberrations.     

Enzymic in vitro repair and chemical nature of DNA chain breaks induced by incorporated phosphorus-32P decay.

In vitro repair of single strand breaks in T4 and phage DNA caused by 32p decay was studied. Zone centrifugation procedure showed that polynucleotide kinase, ligase enzyme system failed to repair 32P-damages. It was found that damaged DNA contained gaps and could be repaired by DNA-polymerase I, polynucleotide ligase treatment.     

The study of DNA-repair defects using [125I]iododeoxycytidine incorporation as an assay for the growth of herpes simplex virus

[125I]Iododeoxycytidine incorporation was used to measure herpes virus (HSV-1) DNA synthesis following specific DNA damage. Xeroderma pigmentosum fibroblasts were less able to replicate UV-irradiated viral DNA than were normal fibroblasts, indicating the necessity for excision repair for the survival of UV-irradiated virus. Because of its rapidity and ease of quantitation, this assay had advantages over standard viral mediated assays of DNA excision repair. It was possible to monitor viral replication as a function of the cellular cell cycle. Other genetic defects which have been proposed to reflect deficiencies in DNA-repair capacity were not detected by this assay. DNA-repair inhibitors, caffeine and 3-aminobenzamide, also did not show synergistic lethal effects on the replication of damaged viral DNA.     

Physiological and genetic effects of puromycin aminonucleoside on ultraviolet-irradiated Escherichia coli strains.

Puromycin aminonucleoside (PAN) increased significantly the mutation rate of Escherichia coli B/r strains when used in conjunction with certain ultraviolet dosages. PAN (2.5 mM) when added to the post-irradiation medium of hcr+ cells slowed down RNA synthesis to 65%, protein to 76% and DNA to 48% of the control rate. Purine ribosides such as adenosine decreased the inhibitory action of PAN on DNA, RNA and protein synthesis. Quantitatively quite different results were obtained with the hcr- strains. PAN did not increase killing of UV, but decreased the frequency of UV-induced mutations. Antimutagenic purine ribosides decreased the synergistic mutagenic activity of PAN. Increases in DNA synthesis in the presence of antimutagens correspond to reductions in the rate of mutation to streptomycin resistance. The excision of UV-induced pyrimidine dimers was investigated in the presence and absence of PAN. The pattern of repair-inhibition reversion of pre-mutagenic lesions by adenosine suggests that PAN behaves as a feedback inhibitor of purine biosynthesis in UV-irradiated cells. It is probable that this inhibition results in an impairment of repair which produces the increase in mutant numbers.     

Induction and repair of DNA strand breaks in Bacteroides fragilis

Alkaline sucrose gradient sedimentation was used to establish whether strand breakage and repair take place in the DNA of UV-irradiated Bacteroides fragilis during the removal of pyrimidine dimers. A B. fragilis wild-type strain and two of its repair mutants, a mitomycin C sensitive mutant (MTC25) having wild-type levels of UV survival, and a UV-sensitive, mitomycin C sensitive mutant (UVS9), were investigated. Under anaerobic conditions, far-UV irradiation induced metabolically regulated strand breakage and resynthesis in the wild-type strain, but this was markedly reduced in both the MTC25 and UVS9 mutants. Approximately half of the strand breaks generated by the various strains were rejoined during further holding in buffer. Under replicating conditions, complete repair of strand breaks in the wild type was observed. Caffeine treatment under anaerobic conditions caused direct DNA strand breakage in B. fragilis cells but did not inhibit UV-induced breakage or repair.     

Effect of UV radiation on the DNA-membrane complex of Bacillus subtilis]

The influence of UV-light on DNA-membrane complex (DMC) of Bacillus subtilis was studied. An increased DNA content in DMC for strains 168 and rec A-, and a degradation of DMC for strain polA- have been registrated. The increase in DNA in DMC of the two former strains is inhibited by caffeine to be correlated with changes in protein content in DMC, determined by a radioactive label, but not with lipid content. Thus, the association of DNA with the membrane is mediated by proteins. DNA increasing capacity seen in DMC after UV-irradiation and after the following incubation of bacteria in the complete medium is correlated with a relative sensitivity of strains. To explain these data, it is supposed that the reparative synthesis is accomplished in cell on their membranes and that for the normal completion of DNA repair the association between DNA and the membrane is necessary.     

Inhibition by hyperthermia of repair synthesis and chromatin reassembly of ultraviolet-induced damage to DNA

We have investigated the effects of hyperthermia treatment on sequential steps of the repair of UV-induced DNA damage in HeLa cells. DNA repair synthesis was inhibited by 40% after 15 min of hyperthermia treatment at 45 degrees C; greater inhibition of repair synthesis occurred with prolonged incubation at 45 degrees C. Enzymatic digestion of repair-labeled DNA with Exonuclease III indicated that once DNA repair was initiated, the DNA repair patch was synthesized to completion and that ligation of the DNA repair patch occurred. Thus the observed inhibition of UV-induced DNA repair synthesis by hyperthermia treatment may be the result of inhibition of enzymes involved in the initiating step(s) of DNA repair. DNA repair patches synthesized in UV-irradiated cells labeled at 37 degrees C with [3H]Thd were 2.2-fold more sensitive to micrococcal nuclease digestion than was parental DNA; if the length of the labeling period was prolonged, the nuclease sensitivity of the repair patch synthesized approached that of the parental DNA. DNA repair patches synthesized at 45 degrees C, however, remained sensitive to micrococcal nuclease digestion even after long labeling periods, indicating that heat treatment inhibits the reassembly of the DNA repair patch into nucleosomal structures.     

Xeroderma pigmentosum group A correcting protein from calf thymus.

A proteinous factor was purified from calf thymus and HeLa cells, which specifically corrects the excision repair defect of xeroderma pigmentosum complementation group A (XP-A) cells. Recovery of UV-induced unscheduled DNA synthesis after microinjection of XP-A cells was used as a quantitative assay for the correcting activity of protein preparations. XP-A correcting protein appears to be very stable as it withstands heating to 100 degrees C and treatment with SDS or 6 M urea. A molecular weight of 40-45 kD was found both under native (gel filtration) and denaturing (SDS-PAGE) conditions. Calf XP-A protein binds to single-stranded DNA more strongly than to double-stranded DNA, but shows no clear preference for UV-irradiated DNA. Polyclonal antibodies raised against human recombinant XP-A protein, which strongly inhibit UV-induced unscheduled DNA synthesis of normal human cells, completely abolished XP-A correcting activity when mixed with calf thymus preparations. This indicates a close relationship between human gene product and the calf protein. In the final preparation two main protein bands were present. Only one band at approx. 41 kD showed both DNA binding activity in Southwestern blots and immune reaction with human XP-A antibody, suggesting that this is the active calf XP-A correcting factor.     

DNA polymerase I acts in translesion synthesis mediated by the Y-polymerases in Bacillus subtilis

Translesion synthesis (TLS) across damaged DNA bases is most often carried out by the ubiquitous error-prone DNA polymerases of the Y-family. Bacillus subtilis encodes two Y-polymerases, Pol Y1 and Pol Y2, that mediate TLS resulting in spontaneous and ultraviolet light (UV)-induced mutagenesis respectively. Here we show that TLS is a bipartite dual polymerase process in B. subtilis, involving not only the Y-polymerases but also the A-family polymerase, DNA polymerase I (Pol I). Both the spontaneous and the UV-induced mutagenesis are abolished in Pol I mutants affected solely in the polymerase catalytic site. Physical interactions between Pol I and either of the Pol Y polymerases, as well as formation of a ternary complex between Pol Y1, Pol I and the beta-clamp, were detected by yeast two- and three-hybrid assays, supporting the model of a functional coupling between the A- and Y-family polymerases in TLS. We suggest that the Pol Y carries the synthesis across the lesion, and Pol I takes over to extend the synthesis until the functional replisome resumes replication. This key role of Pol I in TLS uncovers a new function of the A-family DNA polymerases.     

Manifestation of antimutagenic activity of "dark" repair under alternative levels of aeration of UV-irradiated bacteria]

The cease of aeration of UV-irradiated bacteria incubated in glucose-salt medium does not affect antimutagenic activity of excision repair in Escherichia coli cells but strongly inhibits that in Bacillus subtilis cells. It has been suggested that these differences are connected with various possibilities for energy (ATP) production in facultative anaerobe, which is E. coli, and obligate anaerobe, Bac. subtilis. The absence of noticeable influence of the aerobiosis----anaerobiosis shift on the kinetics of disappearance of potential mutations in E. coli cells is interpreted in terms of existence of a mechanism regulating the expenditure of cell energy reserve upon repair process. It is suggested that the low rate of disappearance of potential mutations observed in post-irradiation conditions favourable for protein synthesis is a consequence of limited supply of energy to repair process at some sites of cellular DNA, due to great expense of energy for protein synthesis.     

DNA repair in Bacillus subtilis: excision repair capacity of competent cells.

Competent Bacillus subtilis were investigated for their ability to support the repair of UV-irradiated bacteriophage and bacteriophage DNA. UV-irradiated bacteriophage DNA cannot be repaired to the same level as UV-irradiated bacteriophage, suggesting a deficiency in the ability of competent cells to repair UV damage. However, competent cells were as repair proficient as noncompetent cells in their ability to repair irradiated bacteriophage in marker rescue experiments. The increased sensitivity of irradiated DNA is shown to be due to the inability of excision repair to function on transfecting DNA in competent bacteria. Furthermore, competent cells show no evidence of possessing an inducible BsuR restriction system to complement their inducible BsuR modification enzyme.     

The UV-damaged DNA binding protein mediates efficient targeting of the nucleotide excision repair complex to UV-induced photo lesions

Previous studies point to the XPC-hHR23B complex as the principal initiator of global genome nucleotide excision repair (NER) pathway, responsible for the repair of UV-induced cyclobutane pyrimidine dimers (CPD) and 6-4 photoproducts (6-4PP) in human cells. However, the UV-damaged DNA binding protein (UV-DDB) has also been proposed as a damage recognition factor involved in repair of UV-photoproducts, especially CPD. Here, we show in human XP-E cells (UV-DDB deficient) that the incision complex formation at UV-induced lesions was severely diminished in locally damaged nuclear spots. Repair kinetics of CPD and 6-4PP in locally and globally UV-irradiated normal human and XP-E cells demonstrate that UV-DDB can mediate efficient targeting of XPC-hHR23B and other NER factors to 6-4PP. The data is consistent with a mechanism in which UV-DDB forms a stable complex when bound to a 6-4PP, allowing subsequent repair proteins--starting with XPC-hHR23B--to accumulate, and verify the lesion, resulting in efficient 6-4PP repair. These findings suggest that (i) UV-DDB accelerates repair of 6-4PP, and at later time points also CPD, (ii) the fraction of 6-4PP that can be bound by UV-DDB is limited due to its low cellular quantity and fast UV dependent degradation, and (iii) in the absence of UV-DDB a slow XPC-hHR23B dependent pathway is capable to repair 6-4PP, and to some extent also CPD.     

Microinjection of Micrococcus luteus UV-endonuclease restores UV-induced unscheduled DNA synthesis in cells of 9 xeroderma pigmentosum complementation groups

The UV-induced unscheduled DNA synthesis (UDS) in cultured cells of excision-deficient xeroderma pigmentosum (XP) complementation groups A through I was assayed after injection of Micrococcus luteus UV-endonuclease using glass microneedles. In all complementation groups a restoration of the UV-induced UDS, in some cells to the repair-proficient human level, was observed. Another prokaryotic DNA-repair enzyme, T4 endonuclease V, restored the UV-induced UDS in a similar way after microinjection into XP cells. Since both enzymes specifically catalyse only the incision of UV-irradiated DNA, we conclude that this activity is impaired in cells of all 9 excision-deficient XP complemenation groups tested.     

Excision repair of DNA in nuclear extracts from the yeast Saccharomyces cerevisiae.

Excision repair of DNA is an important cellular response to DNA damage caused by a broad spectrum of physical and chemical agents. We have established a cell-free system in which damage-specific DNA repair synthesis can be demonstrated in vitro with nuclear extracts from the yeast Saccharomyces cerevisiae. Repair synthesis of UV-irradiated plasmid DNA was observed in a radiation dose-dependent manner and was unaffected by mutations in the RAD1, RAD2, RAD3, RAD4, RAD10, or APN1 genes. DNA damaged with cis-platin was not recognized as a substrate for repair synthesis. Further examination of the repair synthesis observed with UV-irradiated DNA revealed that it is dependent on the presence of endonuclease III-sensitive lesions in DNA, but not pyrimidine dimers. These observations suggest that the repair synthesis observed in yeast nuclear extracts reflects base excision repair of DNA. Our data indicate that the patch size of this repair synthesis is at least seven nucleotides. This system is expected to facilitate the identification of specific gene products which participate in base excision repair in yeast.