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.     

Monofunctional alkylating agent-induced S-phase-dependent DNA damage

Alkylating agents are S-phase-dependent clastogenic agents: Chromosome aberrations are not observed unless the treated cells have first undergone a replicative DNA synthesis. While DNA gaps resulting from misreplication of the alkylated template are believed to underlie aberration formation, the specific alkylated DNA lesions that produce these DNA gaps are not known. To quantitate the DNA strand break induction that results from replication of an alkylated DNA template and attempt to identify those alkylated lesions which underlie DNA strand breakage. [14C]thymidine-labeled Chinese hamster ovary (CHO) cells were treated with either N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) or methyl methanesulfonate (MMS) in G1 and then allowed to progress through S phase in the presence of [3H]thymidine. When analyzed at the subsequent mitosis, DNA strand breaks were found in the nonalkylated ([3H]thymidine-labeled) DNA strand. This did not appear to be the consequence of any recombinational or endonuclease-mediated event and was more likely due to DNA gaps produced by incomplete replication off the alkylated template. A portion of these breaks probably result from a failure to replicate past 3-methyladenine. Differences between MNNG and MMS in the frequency of S-phase-dependent breaks they produce relative to the overall alkylation damage suggest that the O6-methylguanine lesion might also be involved in S-phase-dependent DNA strand breakage.     

Caffeine inhibits excision of 7-bromomethylbenz (a) anthracene-DNA adducts from exponentially growing but not from stationary phase Chinese hamster cells.

Excision of 7-bromomethylbenz(a)anthracene (7-BMBA)-DNA adducts from exponentially growing cultures of Chinese hamster V79-379A cells followed logarithmic kinetics with a half of approximately 20 hrs. Post-treatment incubation in the presence of a sub-toxic concentration of caffeine markedly reduced this loss. Caffeine brought about a concomitant increase in overall DNA synthetic rate in treated exponential cultures. Excision in stationary, non-DNA-replicating cultures, was slower and caffeine did not affect this reduced rate of excision. These findings lend support to a previous proposition that the caffeine-induced inhibition of elongation of nascent DNA on a template containing chemical lesions results in an interference with the excision repair mechanism that removes these lesions.     

Influence of template strandedness on in vitro replication of mutagen-damaged DNA

We analyzed the ability of DNA polymerases to bypass damage on single- and double-stranded templates. In vitro DNA synthesis was studied on UV-irradiated and polyaromatic hydrocarbon reacted (benzo[a]pyrenediol epoxide and oxiranylpyrene) double-stranded templates by a protocol involving initiation on a uniquely nicked circular double-stranded template. The template was prepared by treating single-stranded (+)M13mp2 circular strands with mutagen and then hybridizing with restricted M13 RFmp2, followed by isolation of the nicked RFII forms. The protocol permits either (+), (-), or both strands to carry lesions. We found that the rules for termination and bypass of lesions previously observed with single-stranded DNA templates also hold for double-stranded templates. Termination of synthesis occurs primarily one nucleotide 3' to the lesion in the template strand. Bypass of UV-induced lesions can be followed in a series of three partial reactions in the presence of Mn2+ and dGMP, which relax the specificity of nucleotide insertion and 3'----5' exonuclease activity, respectively. There is no evidence for greater permissivity of bypass in double-as opposed to single-stranded templates. As with single-stranded templates, purines and preferentially deoxyadenosine (dA) are inserted opposite lesions. Lesions in the nontemplate strand elicit neither termination nor pausing. The addition of Rec A protein resulted in a measurable increase of bypass in this system.     

A polymerization-based method to construct a plasmid containing clustered DNA damage and a mismatch

Exposure of biological materials to ionizing radiation often induces clustered DNA damage. The mutagenicity of clustered DNA damage can be analyzed with plasmids carrying a clustered DNA damage site, in which the strand bias of a replicating plasmid (i.e., the degree to which each of the two strands of the plasmid are used as the template for replication of the plasmid) can help to clarify how clustered DNA damage enhances the mutagenic potential of comprising lesions. Placement of a mismatch near a clustered DNA damage site can help to determine the strand bias, but present plasmid-based methods do not allow insertion of a mismatch at a given site in the plasmid. Here, we describe a polymerization-based method for constructing a plasmid containing clustered DNA lesions and a mismatch. The presence of a DNA lesion and a mismatch in the plasmid was verified by enzymatic treatment and by determining the relative abundance of the progeny plasmids derived from each of the two strands of the plasmid.     

Requirement of RAD52 group genes for postreplication repair of UV-damaged DNA in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, replication through DNA lesions is promoted by Rad6-Rad18-dependent processes that include translesion synthesis by DNA polymerases eta and zeta and a Rad5-Mms2-Ubc13-controlled postreplicational repair (PRR) pathway which repairs the discontinuities in the newly synthesized DNA that form opposite from DNA lesions on the template strand. Here, we examine the contributions of the RAD51, RAD52, and RAD54 genes and of the RAD50 and XRS2 genes to the PRR of UV-damaged DNA. We find that deletions of the RAD51, RAD52, and RAD54 genes impair the efficiency of PRR and that almost all of the PRR is inhibited in the absence of both Rad5 and Rad52. We suggest a role for the Rad5 pathway when the lesion is located on the leading strand template and for the Rad52 pathway when the lesion is located on the lagging strand template. We surmise that both of these pathways operate in a nonrecombinational manner, Rad5 by mediating replication fork regression and template switching via its DNA helicase activity and Rad52 via a synthesis-dependent strand annealing mode. In addition, our results suggest a role for the Rad50 and Xrs2 proteins and thereby for the MRX complex in promoting PRR via both the Rad5 and Rad52 pathways.     

Mechanism of stimulation of T7 DNA polymerase by Escherichia coli single-stranded DNA binding protein (SSB)

Single-stranded DNA binding protein is a key component in growth of bacteriophage T7. In addition, DNA synthesis by the purified in vitro replication system is markedly stimulated when the DNA template is coated with Escherichia coli single-stranded DNA binding protein (SSB). In an attempt to understand the mechanism for this stimulation, we have studied the effect of E. coli SSB on DNA synthesis by the T7 DNA polymerase using a primed single-stranded M13 DNA template which serves as a model for T7 lagging strand DNA synthesis. Polyacrylamide gel analysis of the DNA product synthesized on this template in the absence of SSB indicated that the T7 DNA polymerase pauses at many specific sites, some stronger than others. By comparing the position of pausing with the DNA sequence of this region and by using a DNA template that contains an extremely stable hairpin structure, it was found that many, but not all, of these pause positions correspond to regions of potential secondary structure. The presence of SSB during synthesis resulted in a large reduction in the frequency of hesitations at many sites that correspond to these secondary structures. However, the facts that a large percentage of the pause sites remain unaffected even at saturating levels of SSB and that SSB stimulates synthesis on a singly primed poly(dA) template suggested that other mechanisms also contribute to the stimulation of DNA synthesis caused by SSB. Using a sucrose gradient analysis, we found that SSB increases the affinity of the polymerase for single-stranded DNA that this increased binding is only noticed when the polymerase concentration is limiting. The effect of this difference in polymerase affinity was clearly observed by a polyacrylamide gel analysis of the product DNA synthesized during a limited DNA synthesis reaction using conditions where only two nucleotides are added to the primer. Under these circumstances, where the presence of hairpin structures should not contribute to the stimulatory effect of SSB, we found that the extension of the primer is stimulated 4-fold if the DNA template is coated with SSB. Furthermore, SSB had no effect on this synthesis at large polymerase to template ratios.     

Selective bypass of a lagging strand roadblock by the eukaryotic replicative DNA helicase

The eukaryotic replicative DNA helicase, CMG, unwinds DNA by an unknown mechanism. In some models, CMG encircles and translocates along one strand of DNA while excluding the other strand. In others, CMG encircles and translocates along duplex DNA. To distinguish between these models, replisomes were confronted with strand-specific DNA roadblocks in Xenopus egg extracts. An ssDNA translocase should stall at an obstruction on the translocation strand but not the excluded strand, whereas a dsDNA translocase should stall at obstructions on either strand. We found that replisomes bypass large roadblocks on the lagging strand template much more readily than on the leading strand template. Our results indicate that CMG is a 3' to 5' ssDNA translocase, consistent with unwinding via "steric exclusion." Given that MCM2-7 encircles dsDNA in G1, the data imply that formation of CMG in S phase involves remodeling of MCM2-7 from a dsDNA to a ssDNA binding mode.     

Replication of simian virus 40 DNA after UV irradiation: evidence of growing fork blockage and single-stranded gaps in daughter strands.

The molecular mechanisms of in vivo inhibition of mammalian DNA replication by exposure to UV light (at 254 nm) was studied in monkey and human cells infected with simian virus 40. Analysis of viral DNA by electron microscopy and sucrose gradients confirmed that the presence of UV-induced lesions severely blocks DNA synthesis, and thus the conversion of replicative intermediates (RIs) into fully replicated form I DNA is inhibited by UV irradiation. These blocked RI molecules present several special features when visualized by electron microscopy. (i) In excision repair-proficient monkey and human cells they are composed of a double-stranded circular DNA with a double-stranded tail whose size corresponds to the average interpyrimidine dimer distance, as determined by the dimer-specific T4 endonuclease V. (ii) In excision repair-deficient human cells from patients with xeroderma pigmentosum, UV-irradiated RIs present a Cairns-like structure similar to that observed for replicating molecules obtained from unirradiated infected cells. (iii) Single-stranded gaps are visualized in the replicated portions of UV-irradiated RI molecules; such regions are detected and clearly distinguishable from double-stranded DNA when probed by a specific single-stranded DNA-binding protein such as the bacteriophage T4 gene 32 product. Consistent with the presence of gaps in UV-irradiated RI molecules, single-strand-specific S1 nuclease digestion causes a shift in their sedimentation properties when analyzed in neutral sucrose gradients compared with undamaged molecules. These results are in agreement with and reinforce the model in which UV lesions are a barrier to the replication fork movement when present in the template for the leading strand; when lesions are in the template for the lagging strand they inhibit synthesis or completion of Okazaki fragments, leaving gaps opposite the lesion. Moreover, cellular DNA repair-linked endonucleolytic activity may induce double-stranded breaks in the blocked region of the replication forks, resulting in the tailed structures observed in viral DNA molecules obtained from excision repair-proficient cell lines.     

The relationship between sister-chromatid exchange and perturbations in DNA replication in mutant EM9 and normal CHO cells

The majority of the high (12-fold elevated) baseline sister-chromatid exchanges (SCEs) that occur in the CHO mutant line EM9 appear to be a consequence of incorporated BrdUrd, and they arise during replication of DNA containing BrdUrd in a template strand. In normal CHO cells the alkaline elution patterns of DNA newly replicated on a BrdUrd-containing template are significantly altered compared with those seen during the replication on an unsubstituted template. The nascent DNA synthesized on such an altered template is delayed in reaching mature size, possibly because replication forks are temporarily blocked at sites occurring randomly along the template. Transient blockage of replication forks may be a prerequisite for SCE. The delay in replication on BrdUrd-substituted templates was greater in EM9 cells than in parental AA8 cells and was also greater in AA8 cells treated with benzamide, an inhibitor of poly(ADPR) polymerase, than in untreated AA8 cells. Under these conditions, treatment with benzamide also produced a 7-fold increase in SCEs in AA8. An EM9-derived revertant line that has a low baseline SCE frequency showed less delay in replication on BrdUrd-substituted templates than did EM9. However, under conditions where the template strand contained CldUrd, which was shown to produce 4-fold more SCEs than BrdUrd in AA8 cells, the replication delay in AA8 was not any greater in the CldUrd-substituted cells. Thus, other factors besides the delay appear to be involved in the production of SCEs by the template lesions resulting from incorporation of the halogen-substituted pyrimidine molecules.     

Replication of hepatic DNA in rats treated with dimethylnitrosamine.

Replication of DNA containing unrepaired lesions such as depurinated sites, single-strand breaks or methylated bases such as O-6 and N-7 methylguanine was studied in the rat liver. Rat liver DNA was damaged by administering 10 mug dimethylnitrosamine (DMN)/g body wt i.p. 4 h prior to partial hepatectomy. The analysis of DNA on alkaline sucrose gradient revealed considerable damage to the parental strand at the time of and 48 h subsequent to partial hepatectomy. During this time interval, the synthesis of new strands was studied using labeled thymidine. In the control liver, radioactivity in DNA appeared as small fragments at 15 and 30 min following the administration of labeled thymidine which became bigger within 4 h. In the carcinogen-treated livers, the newly made DNA remained as small fragments for longer periods of time. Sometime between 4 and 24 h these became bigger in size than the parental damaged template DNA. Thus, with a delay, the newly made strands became eventually bigger, in spite of the fact that the parental template DNA strand was damaged. Such replication of DNA with unrepaired lesions (miscoding and/or non-coding) offers a mechanism by which the original damage to DNA caused by the carcinogen can be permanently imprinted on the newly made cell, a phenomenon that could account for the initiation of carcinogenesis under certain circumstances.     

Mechanism of DNA damage tolerance

DNA damage may compromise genome integrity and lead to cell death. Cells have evolved a variety of processes to respond to DNA damage including damage repair and tolerance mechanisms, as well as damage checkpoints. The DNA damage tolerance(DDT) pathway promotes the bypass of single-stranded DNA lesions encountered by DNA polymerases during DNA replication. This prevents the stalling of DNA replication. Two mechanistically distinct DDT branches have been characterized. One is translesion synthesis(TLS) in which a replicative DNA polymerase is temporarily replaced by a specialized TLS polymerase that has the ability to replicate across DNA lesions. TLS is mechanistically simple and straightforward, but it is intrinsically error-prone. The other is the error-free template switching(TS) mechanism in which the stalled nascent strand switches from the damaged template to the undamaged newly synthesized sister strand for extension past the lesion. Error-free TS is a complex but preferable process for bypassing DNA lesions. However, our current understanding of this pathway is sketchy. An increasing number of factors are being found to participate or regulate this important mechanism, which is the focus of this editorial.     

Lagging strand synthesis in coordinated DNA synthesis by bacteriophage t7 replication proteins

The proteins of bacteriophage T7 DNA replication mediate coordinated leading and lagging strand synthesis on a minicircle template. A distinguishing feature of the coordinated synthesis is the presence of a replication loop containing double and single-stranded DNA with a combined average length of 2600 nucleotides. Lagging strands consist of multiple Okazaki fragments, with an average length of 3000 nucleotides, suggesting that the replication loop dictates the frequency of initiation of Okazaki fragments. The size of Okazaki fragments is not affected by varying the components (T7 DNA polymerase, gene 4 helicase-primase, gene 2.5 single-stranded DNA binding protein, and rNTPs) of the reaction over a relatively wide range. Changes in the size of Okazaki fragments occurs only when leading and lagging strand synthesis is no longer coordinated. The synthesis of each Okazaki fragment is initiated by the synthesis of an RNA primer by the gene 4 primase at specific recognition sites. In the absence of a primase recognition site on the minicircle template no lagging strand synthesis occurs. The size of the Okazaki fragments is not affected by the number of recognition sites on the template.     

Requirements for synthesis of ribonucleic acid primers during lagging strand synthesis by the DNA polymerase and gene 4 protein of bacteriophage T7.

DNA polymerase and gene 4 protein of bacteriophage T7 catalyze DNA synthesis on duplex DNA templates. Synthesis is initiated at nicks in the DNA template, and this leading strand synthesis results in displacement of one of the parental strands. In the presence of ribonucleoside 5'-triphosphates the gene 4 protein catalyzes the synthesis of oligoribonucleotide primers on the displaced single strand, and their extension by T7 dna polymerase accounts for lagging strand synthesis. Since all the oligoribonucleotide primers bear adenosine 5'-triphosphate residues at their 5' termini, [gamma 32P]ATP is incorporated specifically into the product molecule, thus providing a rapid and sensitive assay for the synthesis of the RNA primers. Both primer synthesis and DNA synthesis are stimulated 3- to 5-fold by the presence of either Escherichia coli or T7 helix-destabilizing protein (DNA binding protein). ATP and CTP together fully satisfy the requirement for rNTPs and provide maximum synthesis of primers and DNA. Provided that T7 DNA polymerase is present, RNA-primed DNA synthesis occurs on either duplex or single-stranded DNA templates and to equal extents on either strand of T7 DNA. No primer-directed DNA synthesis occurs on poly(dT) or poly(dG) templates, indicating that synthesis of primers is template-directed.     

Gap-Directed Translesion DNA Synthesis of an Abasic Site on Circular DNA Templates by a Human Replication Complex

DNA polymerase ε (pol ε) is believed to be the leading strand replicase in eukaryotes whereas pols λ and β are thought to be mainly involved in re-synthesis steps of DNA repair. DNA elongation by the human pol ε is halted by an abasic site (apurinic/apyrimidinic (AP) site). We have previously reported that human pols λ, β and η can perform translesion synthesis (TLS) of an AP site in the presence of pol ε. In the case of pol λ and β, this TLS requires the presence of a gap downstream from the product synthetized by the ε replicase. However, since these studies were conducted exclusively with a linear DNA template, we decided to test whether the structure of the template could influence the capacity of the pols ε, λ, β and η to perform TLS of an AP site. Therefore, we have investigated the replication of damaged “minicircle” DNA templates. In addition, replication of circular DNA requires, beyond DNA pols, the processivity clamp PCNA, the clamp loader replication factor C (RFC), and the accessory proteins replication protein A (RPA). Finally we have compared the capacity of unmodified versus monoubiquitinated PCNA in sustaining TLS by pols λ and η on a circular template. Our results indicate that in vitro gap-directed TLS synthesis by pols λ and β in the presence of pol ε, RPA and PCNA is unaffected by the structure of the DNA template. Moreover, monoubiquitination of PCNA does not affect TLS by pol λ while it appears to slightly stimulate TLS by pol η.     

Biochemical evidence of a physical interaction between <Emphasis Type="Italic">Sulfolobus solfataricus</Emphasis> B-family and Y-family DNA polymerases

The hyper-thermophilic archaeon Sulfolobus solfataricus possesses two functional DNA polymerases belonging to the B-family (Sso DNA pol B1) and to the Y-family (Sso DNA pol Y1). Sso DNA pol B1 recognizes the presence of uracil and hypoxanthine in the template strand and stalls synthesis 3–4 bases upstream of this lesion (“read-ahead” function). On the other hand, Sso DNA pol Y1 is able to synthesize across these and other lesions on the template strand. Herein we report evidence that Sso DNA pol B1 physically interacts with DNA pol Y1 by surface plasmon resonance measurements and immuno-precipitation experiments. The region of DNA pol B1 responsible for this interaction has been mapped in the central portion of the polypeptide chain (from the amino acid residue 482 to 617), which includes an extended protease hyper-sensitive linker between the N- and C-terminal modules (amino acid residues Asn482-Ala497) and the α-helices forming the “fingers” sub-domain (α-helices R, R′ and S). These results have important implications for understanding the polymerase-switching mechanism on the damaged template strand during genome replication in S. solfataricus.