Recovery of the ability to synthesize DNA in segments of normal size at long times after ultraviolet irradiation of human cells

Warsaw breakage syndrome DDX11 helicase acts jointly with RAD17 in the repair of bulky lesions and replication through abasic sites

Warsaw breakage syndrome, a developmental disorder caused by mutations in the conserved DDX11/ChlR1 DNA helicase, shows features of genome instability partly overlapping with those of Fanconi anemia (FA). Here, using avian cellular models of DDX11 deficiency, we find that DDX11 functions as backup to the FA pathway and facilitates, jointly with the checkpoint clamp 9-1-1, a homologous recombination pathway of DNA bulky-lesion repair that does not affect replication fork speed and stalled fork stability. DDX11 also promotes diversification of the immunoglobulin-variable gene locus by facilitating hypermutation and gene conversion at programmed abasic sites that constitute endogenous replication blocks. The results suggest commonality between postreplicative gap filling and replication through abasic sites and pinpoint DDX11 as a critical player in both these processes.

Warsaw breakage syndrome, a developmental disorder caused by mutations in the DDX11/ChlR1 helicase, shows cellular features of genome instability similar to Fanconi anemia (FA). Here we report that DDX11-deficient avian DT40 cells exhibit interstrand crosslink (ICL)-induced chromatid breakage, with DDX11 functioning as backup for the FA pathway in regard to ICL repair. Importantly, we establish that DDX11 acts jointly with the 9-1-1 checkpoint clamp and its loader, RAD17, primarily in a postreplicative fashion, to promote homologous recombination repair of bulky lesions, but is not required for intra-S checkpoint activation or efficient fork progression. Notably, we find that DDX11 also promotes diversification of the chicken Ig-variable gene, a process triggered by programmed abasic sites, by facilitating both hypermutation and homeologous recombination-mediated gene conversion. Altogether, our results uncover that DDX11 orchestrates jointly with 9-1-1 and its loader, RAD17, DNA damage tolerance at sites of bulky lesions, and endogenous abasic sites. These functions may explain the essential roles of DDX11 and its similarity with 9-1-1 during development.

Eukaryotic Translesion DNA Synthesis on the Leading and Lagging Strands: Unique Detours around the Same Obstacle

During S-phase, minor DNA damage may be overcome by DNA damage tolerance (DDT) pathways that bypass such obstacles, postponing repair of the offending damage to complete the cell cycle and maintain cell survival. In translesion DNA synthesis (TLS), specialized DNA polymerases replicate the damaged DNA, allowing stringent DNA synthesis by a replicative polymerase to resume beyond the offending damage. Dysregulation of this DDT pathway in human cells leads to increased mutation rates that may contribute to the onset of cancer. Furthermore, TLS affords human cancer cells the ability to counteract chemotherapeutic agents that elicit cell death by damaging DNA in actively replicating cells. Currently, it is unclear how this critical pathway unfolds, in particular, where and when TLS occurs on each template strand. Given the semidiscontinuous nature of DNA replication, it is likely that TLS on the leading and lagging strand templates is unique for each strand. Since the discovery of DDT in the late 1960s, most studies on TLS in eukaryotes have focused on DNA lesions resulting from ultraviolet (UV) radiation exposure. In this review, we revisit these and other related studies to dissect the step-by-step intricacies of this complex process, provide our current understanding of TLS on leading and lagging strand templates, and propose testable hypotheses to gain further insights.

Postreplication repair of ultraviolet damage to DNA, DNA-chain elongation, and effects of metabolic inhibitors in mouse L cells

Alkaline sucrose sedimentation studies of DNA from mouse L cells have demonstrated the following effects of several inhibitors of nucleic acid and protein synthesis on postreplication repair of ultraviolet (UV) damage to their DNA. The DNA newly synthesized by a 2 h [(3)H]thymidine (dThd) label following 254 nm UV irradiation of 20 J/m(2) is made in smaller segments of the number average mol wt (Mn) of approximately 10 x 10(6) than the control of approximately 40 x 10(6). The presence of caffeine at a concentration of 2 mM during the labeling of the irradiated cells reduces the Mn value to 5.8 x 10(6), which is nearly comparable to, but somewhat larger than the expected distance between dimers in parental DNA. Afterwards, such an interrupted DNA made in the irradiated cells is completely repaired to the present maximum Mn value of 40 x 10(6) in the consecutive 4 h chase in unlabeled dThd. The presence of the nucleic acid inhibitor, either 2 mM hydroxyurea, 50 microM arabinofuranosyl cytosine, 2 mM excess dThd or 5 microg/ml of actinomycin D (AMD) during 2- to 24-h chase periods after a 2 h postirradiation label prevents the repair to various extents, while 2 mM caffeine completely inhibits it. In the unirradiated cells, these agents except excess dThd and caffeine also interfere severely with normal elongation of nascent DNA made by a 3 min pulse label, but do not appreciably induce single chain breaks of either newly synthesized or parental DNA. The inhibition of the repair by AMD suggests that de novo elongation of DNA to close the gaps in new DNA made in the irradiated cells requires at least a template-dependent DNA polymerase. In contrast, 100 microg/ml of cycloheximide allows to complete the gap-filling repair, while it simply reduces the rates of chain growth for the repair and normal replication. Therefore, the similar sensitivity of gap-filling repair and normal replication towards the above inhibitors indicates that a preexisting DNA polymerizing system appears to be responsible and to play a common role without new protein synthesis, as far as the repair at early time after UV is concerned.

Search for DNA repair pathways in Drosophila melanogaster

The knowledge about the existence of different pathways for the repairing of DNA lesions has made possible a better understanding of mutation processes. The double mutant method has been shown to be useful for grouping rad mutants in yeast. Through this method, three different groups of repair mechanisms were found: (a) RAD3 group corresponding to the excision repair of UV lesions, (b) RAD6 group corresponding to the translesion type of post-replication repair and (c) RAD52 group corresponding to the recombination type of post-replication repair. In this work, a search for a classification of Drosophila mus mutants in groups analogous to yeast RAD groups is done. Information obtained by double mutant studies was integrated with that obtained by biochemical, recombination, DNA damaging agent sensitivity and mutation studies. The following groups were found: (a) group of mei9 and mus201, analogous to RAD3, (b) group of mei41 and mus302 analogous to RAD52 and, (c) group of mus104 and mus101 analogous to RAD6. In addition, there are mutants that belong to a group corresponding to pre-replication repair of MMS lesions such as mus103, mus306 and mus207. As a peculiarity of Drosophila, it was found that interaction between pre- and post-replication repair mechanisms is indifferent and not synergistic as was found in yeast. A possible explanation could be a weaker control of post-replication repair mechanisms in Drosophila than in yeast. It is expected that this research could help for a better understanding of repair mechanisms in complex organisms.

Inhibition of 80 kDa protein phosphorylation by short-wavelength UV light in NIH 3T3 cells

The exposure of NIH 3T3 fibroblast cells to 254 nm UV radiation resulted in a temporary depression of DNA synthesis and inhibition of 80 kDa protein phosphorylation. This inhibition of protein phosphorylation was correlated with decreased protein kinase C activity in the membrane fractions of UV-damaged cells. The inositol triphosphate contents measured, by the competitive binding assay using bovine adrenal binding protein, showed 80% reduction in the fibroblasts treated with 15 J/m2 of UV light. The intracellular diacylglycerol concentration was also markedly reduced in UV-damaged cells. The results suggest that UV light causes acute reductions of inositol triphosphate and diacylglycerol contents in cells along with decreases in membrane protein kinase C activity, which leads to the inhibition of phosphorylation of an acidic protein of 80 kDa.

Cell cycle progression in denV-transfected murine fibroblasts exposed to ultraviolet radiation

Repair-proficient murine fibroblasts transfected with the denV gene of bacteriophage T4 repaired 70-80% of pyrimidine dimers within 24 h after exposure to 150 J/m2 ultraviolet radiation (UVR) from an FS-40 sunlamp. Under the same conditions, control cells repaired only about 20% of UVR-induced pyrimidine dimers. After UVR exposure, both control and denV-transfected cells exhibited some degree of DNA-synthesis inhibition, as determined by flow cytometric analysis of cell-cycle kinetics in propidium iodide-stained cells. DenV-transfected cells had a longer and more profound S phase arrest than control cells, but both control and denV-transfected cells had largely recovered from UVR effects on cell-cycle kinetics by 48 h after UVR exposure. Inhibition of DNA synthesis by UVR was also measured by determining post-UVR incorporation of bromodeoxyuridine (BrdU). The amount of BrdU incorporated was quantitated by determining with flow cytometry the quenching of Hoechst dye 33342 by BrdU incorporated in cellular DNA. DenV-transfected cells showed more marked inhibition of BrdU incorporation after low fluences of UVR than control cells. Differences between denV-transfected and control cells in cell-cycle kinetics following UVR exposure may be related to differences in mechanisms of repair when excision repair of pyrimidine dimers is initiated by endonuclease V instead of cellular repair enzymes.

Pyrimidine dimers in Drosophila chromatin become increasingly accessible after irradiation

A prokaryotic DNA-repair enzyme has been utilized as a probe for changes in the accessibility of pyrimidine dimers in Drosophila chromatin following UV irradiation. The results demonstrate a rapid cellular response to physiologically relevant doses of radiation which results in at least a 40% increase in accessible dimers. This increase occurs in two incision-deficient mutants which indicates that the excision-repair process, at or beyond the incision step, is not required or responsible for the increase. In the absence of excision the increase in accessibility persists for at least 2 days following irradiation. The observed increase in accessibility is inhibited by both novobiocin and coumermycin. These inhibitors do not inhibit the initial rate of incision, but do reduce dimer excision measured over more extended periods. A pre-incision process is proposed which actively exposes DNA lesions to excision repair. A fraction of the genome is postulated to be accessible without the intervention of that process.

Inhibition and recovery of DNA synthesis in human cells after exposure to ultraviolet light

The inhibition of DNA synthesis in normal human cells by UV is a complex function of fluence because it has several causes. At low fluences, inhibition of replicon initiation is most important. This is made clear by the fact that it occurs to a lesser degree in cells from patients with ataxia telangiectasia (AT). Assuming that only leading strand synthesis is blocked by UV-induced lesions, single lesions between replicons in parental strands for leading strand synthesis inhibit DNA synthesis by acting as temporary blocks until they are replicated by extension of the lagging strand of the adjacent replicon. A more severe inhibition occurs when two lesions are induced between adjacent growing replicons, because one in four possible configurations may result in a long-lived unreplicated region (LLUR). In the absence of excision repair, these may eventually be replicated by activation of an otherwise unused origin within the LLUR. The frequency of LLURs increases steeply with fluence. Activation of normally unused origins to replicate LLURs may facilitate recovery from inhibition of DNA synthesis, but repair of lesions is probably more important. In excision-repair-defective cells, an LLUR without an origin to initiate its replication may be a lethal lesion.

DNA of Chinese hamster V79 cells newly synthesized after ultraviolet irradiation contains alkali-labile sites

Pulse-labeled daughter DNA of UV-irradiated Chinese hamster V79 cells was denatured in alkaline or neutral conditions and analysed by sucrose gradient centrifugation. A comparison of the sedimentation profiles of DNA treated in alkaline or neutral conditions has shown that in UV-irradiated cells some alkali-labile sites are produced during replication of damaged templates.

Inhibition and recovery of the rate of DNA synthesis in V79 Chinese hamster cells following ultraviolet light irradiation. Variation in the rate of movement of the replication fork

Chinese hamster fibroblasts (V79 cell line) exhibit the phenomenon of recovery of DNA synthesis from the initial inhibition observed after ultraviolet light irradiation, in the absence of significant excision of pyrimidine dimers. In an attempt to determine whether the initial inhibition and subsequent recovery can be accounted for by parallel variations in the rate of movement of the replication fork, the cells were pulse-labeled with radioactive bromodeoxyuridine at different times following irradiation and their DNA centrifuged in neutral CsCl density gradients. When DNA synthesis inhibition was at a maximum, an accumulation of DNA, of density intermediate between hybrid and nonsubstituted DNA, was noticed in the density-distribution profiles. This intermediate-density DNA has been previously shown to correspond to fork structures, and thus it seems that inhibition of DNA synthesis after irradiation is to a great extent caused by the forks pausing at the lesions. Later on, when recovery in the rate of DNA synthesis occurs, the accumulation of intermediate-density DNA is no longer observed. The density distribution of DNA along the gradient can thus provide an estimate of the rate of movement of the replication fork, and the results indicate that most of the variation in the overall rate of DNA synthesis can be accounted for by a parallel variation in the rate of fork movement.

Replicon size and excision repair as factors in the inhibition and recovery of DNA synthesis from ultraviolet damage

Initiation of DNA replication and chain growth, analyzed by alkaline sucrose gradient sedimentation, was interrupted to different extents in different cell types by irradiation with ultraviolet light. Within the first hour of irradiation DNA replication was reduced in a manner that depended on the average number of lesions per replicating unit (replicon). At low numbers of lesions per replicon, inhibition of replicon initiation was the predominant response; at higher numbers of lesions per replicon, blockage of chain growth was also observed. After irradiation with a dose that initially blocked chain growth, the rate at which cells recovered their ability to synthesize increasingly more and larger size DNA was a function both of replicon size and of excision repair capacity. Cells with small replicons recovered more rapidly than cells with large replicons, and excision repair-deficient cells recovered less rapidly than excision-competent cells. These observations indicate that excision repair capacity and replicon size play major roles in the response of DNA replication to ultraviolet damage.

Effect of UV-irradiation on DNA replication of the parvovirus minute-virus-of-mice in mouse fibroblasts

The effect of UV-irradiation on the conversion of the single-stranded DNA of the parvovirus Minute-Virus-of-Mice (MVM) to duplex Replicative Forms (RF) was studied after infection of mouse A9 fibroblasts. UV-irradiation of the virus prior to infection of unirradiated cells resulted in a dose-dependent, single-hit, inhibition of RF formation. Restriction fragment analysis indicated that this inhibition could be ascribed to the introduction of absolute blocks which prevent elongation of the newly synthesized complementary strand. Cell exposure to UV-light prior to infection with UV-irradiated MVM enhanced the fraction of input viral DNA which was converted to RF. This enhancement required de novo protein synthesis during the interval between cell irradiation and virus infection. These results suggest that DNA replication constitutes a target in the viral life cycle that leads to the UV-enhanced Reactivation of virus survival, however, they do not permit us to identify the step of RF formation which is enhanced in UV-pretreated cells.

Identification of radiation-induced thymine derivatives in DNA

A methodology for the separation of radiation-induced thymine derivatives in DNA using high pressure liquid chromatography is presented. DNA was subjected to enzymatic hydrolysis yielding 2'-deoxyribonucleosides and the hydrolysate cochromatographed with marker compounds. Confirmation of the presence of derivatives was accomplished by chromatography on Sephadex LH-20 and microderivatization. The method separates free bases from nucleosides allowing for identification of spontaneously released bases or those released through the action of repair enzymes. The results indicate that most of the thymine derivatives formed in irradiated cellular DNA were the same as those found in DNA irradiated in solution. However, the major cellular derivative was not present in the latter. This derivative was identified as 5-hydroxymethyl-2'-deoxyuridine (HMdU). HMdU has previously been shown to be cytotoxic to cells in culture and caused diarrhea and bone marrow failure when administered to mice. Thus, the presence of this radiation-induced thymine derivative in cellular DNA correlates with the known effects of ionizing radiation on cells and animals.

Identification of the cis-thymine glycol moiety in chemically oxidized and gamma-irradiated deoxyribonucleic acid by high-pressure liquid chromatography analysis

5,6-Dihydroxy-5,6-dihydrothymine (thymine glycol) is formed in DNA by chemical oxidants and ionizing radiation. We describe the separation of thymine glycol, 5,6-dihydroxy-5,6-dihydrothymidine (thymidine glycol), thymine, and thymidine by high-pressure liquid chromatography (HPLC). Enzymatic hydrolysates of chemically oxidized or gamma-irradiated single-stranded DNA were cochromatographed with 14C-containing marker compounds. In chemically oxidized DNA, thymidine glycol was the major derivative formed. In addition, there were four rapidly eluting thymine-derived components. In irradiated DNA, thymidine glycol constituted about 5% of the modified thymines, and the rapidly eluting fractions were proportionately increased. DNA isolated from gamma-irradiated and nonirradiated HeLa cells grown in the presence of [3H]thymidine was subjected to enzymatic hydrolysis and HPLC analysis. In control DNA, 0.3% of the thymines were modified. Thirty-six kilorads of gamma radiation caused a 30% increase in thymine damage. Thus, most of the base damage was due to internal beta radiation from incorporated [3H]thymidine. The chromatographic patterns of irradiated and nonirradiated samples were qualitatively the same, but the yields of some products increased 2-fold, while others remained unchanged. A comparison of the HPLC profiles of hydrolysates of in vitro oxidized and irradiated DNA with those of the cellular DNA revealed one fast eluting peak to be absent in cellular DNA, suggesting that it was formed only in single-stranded DNA. In cellular DNA, the major modified thymine was a more hydrophobic derivative not formed by in vitro radiation nor chemical oxidation. As in in vitro irradiated DNA, thymidine glycol constituted 5% of the modified thymines. The presence of cis-thymidine glycol in hydrolysates was confirmed by chromatography on Sephadex LH-20 using water and borate as eluants.

Characterization of postreplication repair in Saccharomyces cerevisiae and effects of rad6, rad18, rev3 and rad52 mutations

Postreplication repair of nuclear DNA was examined in an excision defective haploid strain of yeast lacking mitochondrial DNA (rad1 rho 0). The size of the DNA synthesized in cells exposed to various fluences of ultraviolet light (UV) corresponds approximately to the average interdimer distance in the parental DNA. Upon further incubation of cells following exposure to 2.5 J/m2, the DNA increases in size; by 4 h, it corresponds to DNA from uniformly labeled cells. The alkaline sucrose sedimentation pattern of DNA pulse labeled at various times after UV irradiation, for up to 4 h, does not change substantially, indicating that dimers continue to block DNA replication. A significant amount of postreplication repair requires de novo protein synthesis, as determined by its inhibition by cycloheximide. The rad6 mutant does not carry out postreplication repair, the rad18 and rad52 mutants show great inhibition while the rev3 mutation does not affect postreplication repair. Both recombinational and nonrecombinational repair mechanisms may function in postreplication repair and most of postreplication repair is error free.

Abnormal recovery of DNA replication in ultraviolet-irradiated cell cultures of Drosophila melanogaster which are defective in DNA repair

Cell cultures prepared from embryos of a control stock of Drosophila melanogaster respond to ultraviolet light with a decline and subsequent recovery both of thymidine incorporation and in the ability to synthesize nascent DNA in long segments. Recovery of one or both capacities is absent or diminished in irradiated cells from ten nonallelic mutants that are defective in DNA repair and from four of five nonallelic mutagen-sensitive mutants that exhibit normal repair capabilities. Recovery of thymidine incorporation is not observed in nine of ten DNA repair-defective mutants. On the other hand, partial or complete recovery of incorporation is observed in all but one repair-proficient mutagen-sensitive mutant. Irradiated cells from two mutants that display no excision capacity exhibit a gradual arrest of thymidine incorporation within 20 h after the initial decline. This arrest of incorporation is not observed in mutants exhibiting only partial defects in excision repair. Recovery of the ability to synthesize nascent DNA in long segments is normal in cells from the two mutants that display no excision capacity, indicating that recovery does not depend upon the excision of pyrimidine dimers from cellular DNA. Recovery of that ability is not observed, however, in cells from one partially excision-defective mutant, two of three postreplication repair-defective mutants, two of four mutants defective in both excision and postreplication repair, and one of five repair-proficient mutagen-sensitive mutants. These results indicate that recovery of normal DNA replication in irradiated Drosophila cells depends upon the activity of several functions.

Mechanisms of tolerance to DNA lesions in mammalian cells

In recent years it has become clear that different pathways are involved in the process of removing lesions from DNA. In spite of a continuous surveillance of the genetic integrity by repair enzymes, quite often lesions are not eliminated before the portion of the genome where they have been inserted is used for DNA replication or transcription. Actually, the number of unexcised lesions a cell can tolerate without significantly losing its capacity to reproduce is surprising. As an example, human fibroblasts from certain patients with the genetic disease xeroderma pigmentosum (XP)† are virtually unable to excise pyrimidine dimers, the major DNA lesion produced by short-wavelength UV light.

DNA synthesis in UV-irradiated yeast

The amount and quality of DNA synthesized in excision-defective strains of yeast was assayed using alkaline sucrose gradients. It was observed that, in such strains, there was less newly synthesized DNA in irradiated cells and that this material was in smaller pieces than in unirradiated controls. The molecular weight was inversely proportional to dose. The low molecular weight DNA chased into normally high molecular weight material during a post-pulse incubation period. This chase was inhibited by higher doses of UV, by hydroxyurea, and required the function of the RAD18 gene. The RAD6 gene function was necessary to prevent degradation of template DNA in irradiated excision-defective strains.

Inhibition of DNA replication by hydroxyurea and caffeine in an ultraviolet-irradiated human fibroblast cell line

DNA replication in human fibroblasts with normal excision repair was investigated after ultraviolet irradiation and incubation with caffeine or hydroxyurea. The DNA synthesized soon after irradiation had a reduced size, but that synthesized later was near normal size. When caffeine was present before labeling, it reduced the size of DNA synthesized but when added after labeling it was without effect. When irradiated cells were allowed to grow, labeled DNA increased in size steadily for 60 min to a maximum that was below control and dose-dependent. Further growth resulted in a transition of some label to parental DNA sized, but a large fraction remained permanently blocked at smaller sizes, producing bimodal distributions of DNA. The steady increase in size was inhibited by hydroxyurea. Removing cells from hydroxyurea resulted in increases similar to or slightly slower than those observed immediately after labeling, and this protocol did not permit cells to acquire any induced or enhanced capacity to replicate damaged DNA.

Cytological evidence for DNA chain elongation after UV irradiation in the S phase

Human cells irradiated with UV light synthesize lower molecular weight DNA than unirradiated cells. This reduction in molecular weight is greater in xeroderma pigmentosum (XP) cells than in normal cells. The molecular weight of DNA is further reduced by the addition of caffeine to XP cells. By several hours after irradiation, DNA fragments are barely detectable. Cells from excision-proficient and excision-deficient XP patients were studied autoradiographically to produce cytological evidence of DNA chain elongation. Replicate cultures with and without caffeine were synchronized and irradiated with UV light during the S phase. Caffeine was removed in G2, and the cells were labeled with 3H-thymidine. Results showed significantly increased labeling during G2 of excision-deficient XP cells. Labeling was dependent on the time of irradiation and presence of caffeine. The XP variant cells had no increase in labeling for any irradiation time.

DNA repair after ultraviolet irradiation of ICR 2A frog cells. Pyrimidine dimers are long acting blocks to nascent DNA synthesis

The ability of ICR 2A frog cells to repair DNA damage induced by ultraviolet irradiation was examined. These cells are capable of photoreactivation but are nearly totally deficient in excision repair. They have the ability to convert the small molecule weight DNA made after irradiation into large molecules but do not show an enhancement in this process when the UV dose is delivered in two separate exposures separated by a 3- or 24-h incubation. Total DNA synthesis is depressed and low molecular weight DNA continues to be synthesized during pulse-labeling as long as 48 h after irradiation. The effects of pyrimidine dimer removal through exposure of UV irradiated cells to photoreactivating light indicate that dimers act as the critical lesions blocking DNA synthesis.

The early and late modes of DNA replication in ultraviolet irradiated Syrian hamster embryo cells

The nature of DNA replication in UV irradiated Syrian hamster embryo cells (HEC) was investigated by measuring the size distribution of nascent daughter strand DNA. During the early mode nascent strands are made in smaller pieces than in nonirradiated cells. The late mode begins when nascent strands recover to normal size. This was observed in HEC 5 h post-UV. When the late mode is operational, nascent strands elongate to parental size in greater than 2 h, whereas less than 3 h are required during early mode function. Evidence from split dose experiments demonstrates that the recovery of the size of nascent strands is not due to enhanced gap filling. Furthermore, pyrimidine dimers are probably recognized differently by the replication complex during early and late mode DNA synthesis. The late mode of replication could account for the ability of HEC to survive UV irradiation even though they are inefficient in both excision and postreplication repair.

Effects of methylated xanthines on mammalian cells treated with bifunctional alkylating agents

Caffeine has been previously reported to enhance the lethal potential of many DNA-damaging agents in rodent cells1-5. This effect has most commonly been ascribed to the binding of caffeine to single-stranded DNA6, and the resulting inhibition of post-replication repair7-10, which is associated with the synthesis of abnormally small nascent DNA fragments7, 11-13. However, certain aspects of this theory remain unclear:(1) why does the addition of caffeine to damaged cells elevate the level of DNA synthesis when it supposedly blocks post-replication repair10,14, and (2) as pointed out by Cleaver15, why does caffeine continue to exert its synergistic lethal effects until completion of the S phase16, 17, even though the size of newly synthesized DNA seems normal much earlier18-20? The present studies with nitrogen mustard (HN2) fail to demonstrate any effect of non-lethal concentrations of methylated xanthines (MXs) on removal of DNA damage or post-replication repair in conditions producing synergistic lethal effects. We demonstrate an influence by MXs on initiation of DNA synthesis in damaged replicons, and propose that this effect is primarily responsible for the synergistic lethal properties of these drugs.

Xeroderma pigmentosum variants have a slow recovery of DNA synthesis after irradiation with ultraviolet light

Human cells (normal and xeroderma pigmentosum variant) irradiated with ultraviolet light and pulse-labelled with [3H]thymidine underwent transient decline and recovery of molecular weights of newly synthesized DNA and rates of [3H]thymidine incorporation. The ability to synthesize normal-sized DNA recovered more rapidly in both cell types than thymidine incorporation. During recovery cells steadily increased in their ability to replicate normal-sized DNA on damaged templates. The molecular weight versus time curves fitted exponential functions with similar rate constants in normal and heterozygous xeroderma pigmentosum cells, but with a slower rate in two xeroderma pigmentosum variant cell lines. Caffeine added during the post-irradiation period eliminated the recovery of molecular weights in xeroderma pigmentosum variant but not in normal cells. The recovery of the ability to synthesize normal-sized DNA represents a combination of a number of cellular regulatory processes, some of which are constitutive, and one of which is altered in the xeroderma pigmentosum variant such that recovery becomes slow and caffeine sensitive.

Postreplication repair: questions of its definition and possible alteration in xeroderma pigmentosum cell strains

DNA synthesis in normal cells and in excision-defective and variant xeroderma pigmentosum cells was investigated after irradiation with ultraviolet light. The sizes of DNA synthesized during brief pulses of [3H]thymidine 1-2 hr after irradiation were decreased, the xeroderma pigmentosum variant showing the smallest molecular weight. Once synthesized, however, labeled DNA increased in size at the same rat as control in all cell strains, and the rate was relatively insensitive to caffeine. After 2-3 hr, labeled DNA in each cell type reached a maximum size that was less than that in control cells, indicating the presence of long-lived blocks to DNA chain growth. This kind of experiment (pulse-chase) has in the past been used to investigate a repair process believed to be associated with the bypass of damaged sites in parental DNA: postreplication repair. We present an alternative model that does not involve a specific postreplication repair mechanism, but involve a specific postreplication repair mechanism, but involves normal chain elongation and termination mechanisms in which we conceive that dimers and other damaged sites act as well-or-nothing blocks to the progress of replication forks. No evidence could be found for any inducible process that enhanced the bypass of damaged sites.

Recovery of DNA synthesis after ultraviolet irradiation of xeroderma pigmentosum cells depends on excision repair and is blocked by caffeine

Normal human and xeroderma pigmentosum (XP, excision-defective group A) cells (both SV40-transformed) pulse-labeled with [(3)H]thymidine at various times after irradiation with ultraviolet light showed a decline and recovery of both the molecular weights of newly synthesized DNA and the rates of synthesis per cell. At the same ultraviolet dose, both molecular weights and rates of synthesis were inhibited more in XP than in normal cells. This indicates that excision repair plays a role in minimizing the inhibition of chain growth, possibly by excision of dimers ahead of the growing point. The ability to synthesize normal-sized DNA recovered more rapidly than rates of synthesis in normal cells, but both parameters recovered in phase in XP cells. During recovery in normal cells there are therefore fewer actively replicating clusters of replicons because the single-strand breaks involved in the excision of dimers inhibit replicon initiation. XP cells have few excision repair events and therefore fewer breaks to interfere with initiation, but chain growth is blocked by unexcised dimers. In both cell types recovery of the ability to synthesize normal-sized DNA was prevented by growing cells in caffeine after irradiation, possibly because of competition between the DNA binding properties of caffeine and replication proteins. Our observations imply that excision repair and semiconservative replication interact strongly in irradiated cells to produce a complex spectrum of changes in DNA replication which may be confused with parts of alternative systems such as post-replication repair.

Postreplication repair in mammalian cells after ultraviolet irradiation: a model

A model is presented for bypass of ultraviolet-induced damage in DNA during replication. The overall process is initiated by the introduction of a single-strand break into parental DNA near the point of arrest of synthesis, followed by a transient crossing-over step similar to that envisaged in genetic recombination. The mechanism proposed provides an alternative explanation to existing models and is entirely consistent with available data on postreplication repair in mammalian cells. In addition the model explains the low level of recombination repair observed in mammalian cells.

Enhancement of postreplication repair in ultraviolet-light-irradiated Chinese hamster cells by irradiation in G2 or S-phase

Postreplication repair in synchronous Chinese hamster cells was determined after split doses of ultraviolet (UV) radiation. Repair was enhanced by irradiation of cells in G2 or S-phase with a small dose of UV radiation at least 1.5 h before a three-fold larger dose of UV. There was significantly greater enhancement when the first dose was given in G2 than when it was given in the S-phase 0.5-1.5 h before the test dose. These data indicate that enhancement of postreplication repair does not require active DNA replication and qualitatively is independent of when in the cell cycle the cells are irradiated.

Effects of ultraviolet irradiation and postirradiation incubation on heterogenous nuclear RNA size in murine cells

We have analyzed the decrease in synthesis of individual size classes of heterogeneous nuclear RNA (hnRNA) in ultraviolet (UV)-irradiated Merwin plasmacytoma (MPC-11) cells at various times of postirradiation incubation. HnRNA from nonirradiated control cells is distributed over a wide range from approximately 60S to 5S, with 42S RNA carrying more label than any other size class. HnRNA from UV-irradiated cells shows a dose-dependent shift in size distribution toward lower molecular weight. The size distribution of hnRNA synthesized after prolonged times of postirradiation incubation is restored toward normal, i.e., synthesis of long RNA molecules increases relative to the synthesis of short ones. Analysis of the total number of hnRNA chains synthesized during a 20-min [(3)H]uridine pulse shows a considerable reduction in their number with increasing UV dose. Murine cell lines are excision-repair-deficient but capable of post replication repair inhibited by caffeine. HnRNA transcripts of cells incubated in its presence were studied. The caffeine, which has no effect on hnRNA size in control cells, inhibits to a considerable extent the restoration of full-length transcripts during postirradiation incubation. The lack of excision repair in MPC-11 was confirmed by the analysis of pyrimidine dimers in trichloracetic acid-insoluble and soluble fractions within 8 h of postirradiation incubation.The size of parental and daughter strand DNA in UV-irradiated cells was correlated with RNA transcript size. The parental DNA in these experiments does not change its size as a consequence of UV exposure and postirradiation incubation. In contrast, daughter DNA strands are short in UV-irradiated cells and they increase in size during postirradiation incubation to reach the size of parental strands after 8 h.

DNA replication and repair in a human melanoma cell-line resistant to ultra-violet-radiation

The effect of ultra-violet (U.V.)-irradiation on DNA replication was studied in a U.V.-resistant, human melanoma cell-line (MM96). Semi-conservative synthesis of DNA was decreased about five-fold by a U.V.-dose of 100 ergs/mm2. The size of DNA fragments synthesized in irradiated cells at short times after U.V. was smaller than those synthesized in unirradiated cells. Elongation of these fragments occurred with time, and 6 hours after irradiation cells synthesized DNA in fragments of the same size as obtained in unirradiated cells. In this post-replication repair process, elongation appeared to involve de novo synthesis and was not inhibited by theophylline.

Ultraviolet mutagenesis and inducible DNA repair in Escherichia coli

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Replicative bypass repair of ultraviolet damage to DNA of mammalian cells: caffeine sensitive and caffeine resistant mechanisms

Replicative bypass repair of UV damage to DNA was studied in a wide variety of human, mouse and hamster cells in culture. Survival curve analysis revealed that in established cell lines (mouse L, Chinese hamster V79, HeLa S3 and SV40-transformed xeroderma pigmentosum (XP)), post-UV caffeine treatment potentiated cell killing by reducing the extrapolation number and mean lethal UV fluence (Do). In the Do reduction as the result of random inactivation by caffeine of sensitive repair there were marked clonal differences among such cell lines, V79 being most sensitive to caffeine potentiation. However, other diploid cell lines (normal human, excision-defective XP and Syrian hamster) exhibited no obvious reduction in Do by caffeine. In parallel, alkaline sucrose sedimentation results showed that the conversion of initially smaller segments of DNA synthesized after irradiation with 10 J/m2 to high-molecular-weight DNA was inhibited by caffeine in transformed XP cells, but not in the diploid human cell lines. Exceptionally, diploid XP variants had a retarded ability of bypass repair which was drastically prevented by caffeine, so that caffeine enhanced the lethal effect of UV. Neutral CsC1 study on the bypass repair mechanism by use of bromodeoxyuridine for DNA synthesis on damaged template suggests that the pyrimidine dimerer acts as a block to replication and subsequently it is circumvented presumably by a new process involving replicative bypassing following strand displacement, rather than by gap-filling de novo. This mechanism worked similarly in normal and XP cells, whether or not caffeine was present, indicating that excision of dimer is not always necessary. However, replicative bypassing become defective in XP variant and transformed XP cells when caffeine was present. It appears, therefore, that the replicative bypass repair process is either caffeine resistant or sensitive, depending on the cell type used, but not necessarily on the excision repair capability.

Inhibition of DNA replication by ultraviolet light

DNA replication in ultraviolet-irradiated HeLa cells was studied by two different techniques: measurements of the kinetics of semiconservative DNA synthesis, and DNA fiber autoradiography. In examining the kinetics of semiconservative DNA synthesis, density label was used to avoid measuring the incorporation due to repair replication. The extent of inhibition varied with time. After doses of less than 10J/m2 the rate was initially depressed but later showed some recovery. After higher doses, a constant, low rate of synthesis was seen for at least the initial 6 h. An analysis of these data indicated that the inhibition of DNA synthesis could be explained by replication forks halting at pyrimidine dimers. DNA fiber autoradiography was used to further characterize replication after ultraviolet irradiation. The average length of labeled segments in irradiated cells increased in the time immediately after irradiation, and then leveled off. This is the predicted pattern if DNA synthesis in each replicon continued at its previous rate until a lesion is reached, and then halted. The frequency of lesions that block synthesis is approximately the same as the frequency of pyrimidine dimers.

DNA strand breaking and rejoining in response to ultraviolet light in normal human and xeroderma pigmentosum cells

We describe a reproducible technique for measuring DNA strand breaking and rejoining in cells after treatment with U.V.-light. Results obtained with normal human cells, xeroderma pigmentosum cells (XP, complementation group A) and XP variant cells suggest that all three of these cell-types can carry out single-strand incision with equal rapidity. However, the breaks so induced appeared to be only slowly rejoined in the XP variant cells and rejoined not at all in XP complementation group A cells. Furthermore, parental strand rejoining was inhibited by caffeine in XP variant cells but not in normal cells.

DNA replication and post-replication repair in U.V.-sensitive mouse neuroblastoma cells

Mouse neuroblastoma cells differentiate when grown in the absence of serum; differentiation is reversed on the addition of serum. Differentiated cells are more sensitive to U.V.-radiation than proliferating cells. Whereas addition of serum to differentiated neuroblastoma cells normally results in immediate, synchronous entry into S phase, irradiation just before the addition of serum results in a long delay in the onset of DNA replication. During this lag period, incorporated 3H-thymidine appears in the light density region of CsCl gradientss, reflecting either repair synthesis or abortive replication. Post-replication repair (gap-filling) was found to be present in proliferating cells and at certain times in differentiated cells. It is suggested that the sensitivity of differentiated neuroblastoma cells to U.V.-radiation may be due to ineffective post-replication repair or to deficiencies in more than one repair mechanism, with reduction in repair capacity beyond a critical threshold.

Effects of ultraviolet irradiation on the rate and sequence of DNA replication in synchronized Chinese hamster cells

The effects of ultraviolet light (UV) irradiation on the rate of DNA replication in synchronized Chinese hamster ovary (CHO) cells were investigated. A technique for measuring semiconservative DNA replication was employed that involved growing the cells in medium containing 5-bromodeoxyuridine and subsequently determining the amount of DNA that acquired hybrid buoyant density in CsCl density gradients. One of the advantages of this technique was that it allowed a characterization of the extent of DNA replication as well as rate after irradiation. It was found that while there was a dose-dependent reduction in the rate of DNA replication following UV-irradiation, doses of up to 10 J/m2 (which produce many dimers per replication) did not prevent the ultimate replication of the entire genome. Hence, we conclude that dimers cannot be absolute blocks to DNA replication. In order to account for the total genome replication observed, a mechanism must exist that allows genome replication between dimers. The degree of reduction in the rate of replication by UV was the same whether the cells were irradiated at the G1-S boundary or 1 h into S-phase. Previous work had shown that cells in early S-phase are considerably more sensitive to UV than cells at the G1-S boundary. Experiments specifically designed to test for reiterative replication showed that UV does not induce a second round of DNA replication within the same S-phase.

T4-endonuclease V-sensitive sites in DNA from ultraviolet-irradiated human cells

Human diploid cells (WI38) were pre-labeled with 32Pi, exposed to ultraviolet irradiation and then pulse labeled with [3H]thymidine. The extracted DNA from these cells was subsequently treated with the T4-endonuclease V, an enzyme which specifically nicks DNA strands at positions adjacent to pyrimidine dimers. Sedimentation in alkaline sucrose gradients revealed that the DNA synthesized after irradiation, as well as that made before, contained endonuclease-sensitive sites. Our results suggest that pyrimidine dimers are transferred from parental to daughter DNA strands during post-irradiation incubation. Sedimentation in neutral sucrose gradients showed that the molecular weight of native DNA was not affected by the endonuclease treatment, suggesting that the gaps appearing in daughter strands after irradiation are not opposite dimers or that the enzyme cannot recognize dimers in the gap regions.

Inhibition by caffeine of post-replication repair in Chinese hamster cells treated with cis platinum (II) Diamminedichloride: the extent of platinum binding to template DNA in relation to the size of low molecular weight nascent DNA

Treatment of Chinese hamster lung V79-379A cells with the anti-tumour agent cis platinum (II) diamminedichloride, (cis Pt(II)), resulted in an immediate recuction in the rate of DNA synthesis. Sedimentation of newly synthesised DNA through alkaline sucrose gradients revealed it to be approximately the same size as that obtained from untreated cells. In contrast, in the presence of 0.75 mM caffeine, the rate of DNA synthesis rapidly returned to control levels, although sedimentation analysis showed the DNA synthesised in cis Pt(II)-treated cells to be of lower molecular weight than in untreated cells. The reduction in molecular weight was directly proportional to the initial dose of the platinum compound. Furthermore, the results of separate binding studies suggested that at several levels of reaction the new DNA was synthesised up to a size approximately equal to the interplatinum distance in the template strand. This has been interpreted as being the result of the formation of a gap in the daughter DNA strand opposite every DNA-platinum product in the template strand. If caffeine was removed from the culture medium, there was a rapid increase in the molecular weight of the nascent DNA strands. However, if caffeine remained in the medium, the DNA remained of lower molecular weight than in untreated cells. It is proposed that this effect of caffeine is the result of the inhibition of a post-replicative DNA repair process which allows the eventual synthesis of a continuous DNA strand on a template containing unexcised lesions. It is further proposed that inhibition of this post-replicative DNA repair process provides a molecular basis for the previously observed potentiation by caffeine of cis Pt(II)-induced chromosomal aberrations and lethality.

The effect of lexA and recF mutations on post-replication repair and DNA synthesis in Escherichia coli K-12

We have examined lexA1 uvrA6 and recF143 uvrBdelta derivatives of Escherichia coli K-12 for post-replication repair and DNA synthesis after UV irradiation. Compared to corresponding lex+ rec+ strains, we found that the lexA and recF cells were defective in (1) converting short DNA segments synthesized after irradiation to DNA of normal size; (2) synthesizing high molecular weight DNA after irradiation; (3) transferring pyrimidine dimers from irradiated DNA into unirradiated daughter strands. Our results support the hypothesis that after UV irradiation the formation of large DNA molecules in excision-deficient cells of E.coli depends directly or indirectly upon joining short DNA segments into longer strands, concomitant with the transfer of DNA from irradiated tamplates into unirradiated daughter strands. This process appears to require the activity of lexA and recF genes.