Structure of the replication fork in ultraviolet light-irradiated human cells.

The DNA extracted from xeroderma pigmentosum human fibroblasts previously irradiated with 12.5 J/m2 of UV light and pulse-labeled for 45 min with radioactive and (or) heavy precursors, was used to determine the structural characteristics of the replication fork. Density equilibrium centrifugation experiments showed that a fork moved 6 micrometer in 45 min and bypassed 3 pyrimidine dimers in both strands. The same length was covered in 15-20 min in control cells. The delay in irradiated cells was apparently due to pyrimidine dimers acting as temporary blocks to the fork movement. Evidence for this interpretation comes from kinetics of incorporation of [3H]thymidine into DNA, which show that the time necessary to attain a new stable level of DNA synthesis in irradiated cells is equivalent to that required for the replication fork to cover the interdimer distance in one strand. On the other hand, the action of S1 nuclease on DNA synthesized soon after irradiation gives rise to a bimodal distribution in neutral sucrose gradients, one peak corresponding to 43 X 10(6) daltons and the other to 3 X 10(6) daltons. These two DNA species are generated by the attack of the S1 nuclease on single-stranded regions associated with the replication fork. A possible explanation for these results is given by a model according to which there is a delayed bypass of the dimer in the leading strand and the appearance of gaps opposite pyrimidine dimers in the lagging strand, as a direct consequence of the discontinuous mode of DNA replication. In terms of the model, the DNA of 43 X 10(6) daltons corresponds to the leading strand, linked to the unreplicated branch of the forks, whereas the piece of 3 X 10(6) daltons is the intergap DNA coming from the lagging strand. Pulse and chase experiments reveal that the low molecular weight DNA grows in a pattern that suggests that more than one gap may be formed per replication fork.     

Evidence that dimers remaining in preinduced Escherichia coli B/r Hcr+ become insensitive after DNA replication to the extract from Micrococcus luteus.

In Escherichia coli B/r Her+ irradiated with two separate fluences, dimer excision is prematurely interrupted. The present study was designed to follow tha fate of dimers remaining unexcised. The results imply that these dimers (or distortions containing dimers) are transformed on replication from the state of sensitivity to the state of insensitivity to endonuclease from Micrococcus luteus. This conclusion is based on the following findings: (a) dimers were radiochromatographically detectable in DNA replicated after UV, which indicated that they were tolerated on replication. (b) Similar amounts of dimers were detected radiochromatographically both in DNA remaining unreplicated and DNA twice replicated after UV, This along with the low transfer of parental label into daughter DNA, indicated that dimers remained in situ in parental chains. (c) Immediately after UV, all parental DNA contained numerous sites sensitive to the extract from M. luteus. 2 h after UV, a portion of parental DNA still contained a number of endonuclease-sensitive (Es) sites, while another portion of parental DNA and all daughter DNA were free of Es sites. (d) The occurrence of parental DNA free of Es sites was not temporally correlated with dimer excision, but with the first round of DNA replication. (e) The amount of DNA free of Es sites corresponded to the amount of replicated DNA. (f) Separation of replicated and unreplicated DNA, and detection of Es sites in both portions separately showed that the replicated DNA was almost free of Es sites, whereas unreplicated DNA contained a number of such sites.     

DNA Repair in Potorous tridactylus

The DNA synthesized shortly after ultraviolet (UV) irradiation of Potorous tridactylis (PtK) cells sediments more slowly in alkali than that made by nonirradiated cells. The size of the single-strand segments is approximately equal to the average distance between 1 or 2 cyclobutyl pyrimidine dimers in the parental DNA. These data support the notion that dimers are the photoproducts which interrupt normal DNA replication. Upon incubation of irradiated cells the small segments are enlarged to form high molecular weight DNA as in nonirradiated cells. DNA synthesized at long times (~ 24 h) after irradiation is made in segments approximately equal to those synthesized by nonirradiated cells, although only 10-15% of the dimers have been removed by excision repair. These data imply that dimers are not the lesions which initially interrupt normal DNA replication in irradiated cells. In an attempt to resolve these conflicting interpretations, PtK cells were exposed to photoreactivating light after irradiation and before pulse-labeling, since photoreactivation repair is specific for only one type of UV lesion. After 1 h of exposure ~ 35% of the pyrimidine dimers have been monomerized, and the reduction in the percentage of dimers correlates with an increased size for the DNA synthesized by irradiated cells. Therefore, we conclude that the dimers are the lesions which initially interrupt DNA replication in irradiated PtK cells. The monomerization of pyrimidine dimers correlates with a disappearance of repair endonuclease-sensitive sites, as measured in vivo immediately after 1 h of photoreactivation, indicating that some of the sites sensitive to the repair endonuclease (from Micrococcus luteus) are pyrimidine dimers. However, at 24 h after irradiation and 1 h of photoreactivation there are no endonuclease-sensitive sites, even though ~ 50% of the pyrimidine dimers remain in the DNA. These data indicate that not all pyrimidine dimers are accessible to the repair endonuclease. The observation that at long times after irradiation DNA is made in segments equal to those synthesized by nonirradiated cells although only a small percentage of the dimers have been removed suggests that an additional repair system alters dimers so that they no longer interrupt DNA replication.     

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.     

Replication and mutagenesis of UV-damaged DNA templates in human and monkey cell extracts.

We have used in vitro DNA replication systems from human HeLa cells and monkey CV-1 cells to replicate a UV-damaged simian virus 40-based shuttle vector plasmid, pZ189. We found that replication of the plasmid was inhibited in a UV fluence-dependent manner, but even at UV fluences which caused damage to essentially all of the plasmid molecules some molecules became completely replicated. This replication was accompanied by an increase (up to 15-fold) in the frequency of mutations detected in the supF gene of the plasmid. These mutations were predominantly G:C-->A:T transitions similar to those observed in vivo. Treatment of the UV-irradiated plasmid DNA with Escherichia coli photolyase to reverse pyrimidine cyclobutane dimers (the predominant UV-induced photoproduct) before replication prevented the UV-induced inhibition of replication and reduced the frequency of mutations in supF to background levels. Therefore, the presence of pyrimidine cyclobutane dimers in the plasmid template appears to be responsible for both inhibition of replication and mutation induction. Further analysis of the replication of the UV-damaged plasmid revealed that closed circular replication products were sensitive to T4 endonuclease V (a pyrimidine cyclobutane dimer-specific endonuclease) and that this sensitivity was abolished by treatment of the replicated DNA with E. coli photolyase after replication but before T4 endonuclease treatment. These results demonstrate that these closed circular replication products contain pyrimidine cyclobutane dimers. Density labeling experiments revealed that the majority of plasmid DNA synthesized in vitro in the presence of bromodeoxyuridine triphosphate was hybrid density whether or not the plasmid was treated with UV radiation before replication; therefore, replication of UV-damaged templates appears to occur by the normal semiconservative mechanism. All of these data suggest that replication of UV-damaged templates occurs in vitro as it does in vivo and that this replication results in mutation fixation.     

Mutagenic DNA repair in Escherichia coli. XXI. A stable SOS-inducing signal persisting after excision repair of ultraviolet damage.

Mutations to streptomycin resistance induced by ultraviolet light in Escherichia coli can lose their susceptibility to photoreversing light during excision repair and in the absence of chromosomal replication and protein synthesis, i.e., under conditions where SOS induction cannot occur. Using fusions of lac with sulA and umuC we have shown that after excision of UV damage in the presence of chloramphenicol there is a persisting, relatively stable signal capable of inducing SOS genes when protein sysnthesis is subsequently permitted. The persisting signal is formed roughly in proportion to the square of the UV dose and is about 30% photoreversible. It is suggested that the persisting SOS-inducing signal comprises a UV photoproduct (the target lesion) opposite a gap in the opposing DNA strand, and is formed by excision of one (the ancillary lesion) of a pair of closely opposed photoproducts. Calculations suggest that as few as two or three such configurations in a cell can lead to induction a sulA when protein synthesis is permitted. It is not clear whether these configurations can directly induce the SOS system because of their region of single-stranded DNA or whether the ultimate SOS-inducing signal is a more extensive single-stranded region formed when such configurations encounter a replication fork. Photoproduct/gap configurations have been previously suggested to be potentially mutagenic. UV-induced mutations to streptomycin resistance are mostly at A:T sites and are not photoreversible in fully SOS-induced bacteria in the absence of excision repair, indicating that they are not targeted at cyclobutane-type pyrimidine dimers. In SOS-induced excision-proficient bacteria there is about 39% photoreversibility which is rapidly lost after UV. This photoreversibility is attributed to many ancillary lesions being cyclobutane-type pyrimidine dimers which are excised leading to the exposure of target lesions on the opposing strand which, at these particular sites, are mostly non-photoreversible photoproducts.     

Aphidicolin inhibits repair of DNA in UV-irradiated human fibroblasts

Aphidicolin, a specific inhibitor of DNA polymerase α, is shown to inhibit DNA repair in human diploid fibroblasts. Although aphidicolin has no apparent effect on the DNA of unirradiated cells, it causes a large number of strand breaks to accumulate in UV-irradiated cellular DNA. The number of breaks is the same as the number observed following a similar dose of ultraviolet light when cells are treated with arabinofuranosyl cytosine (araC) and hydroxyurea (HU), known inhibitors of repair. Moreover, two-dimensional paper chromatography shows that aphidicolin completely blocks removal of pyrimidine dimers. These observations are discussed in light of the proposed roles of DNA polymerases α β in DNA replication and repair and the action of aphidicolin on polymerase α.     

Postreplicative chromatin assembly by Drosophila and human chromatin assembly factor 1.

To study the relationship between DNA replication and chromatin assembly, we have purified a factor termed Drosophila chromatin assembly factor 1 (dCAF-1) to approximately 50% homogeneity from a nuclear extract derived from embryos. dCAF-1 appears to consist of four polypeptides with molecular masses of 180, 105, 75, and 55 kDa. dCAF-1 preferentially mediates chromatin assembly of newly replicated DNA relative to unreplicated DNA during T-antigen-dependent simian virus 40 DNA replication in vitro, as seen with human CAF-1. Analysis of the mechanism of DNA replication-coupled chromatin assembly revealed that both dCAF-1 and human CAF-1 mediate chromatin assembly preferentially with previously yet newly replicated DNA relative to unreplicated DNA. Moreover, the preferential assembly of the postreplicative DNA was observed at 30 min after inhibition of DNA replication by aphidicolin, but this effect slowly diminished until it was no longer apparent at 120 min after inhibition of replication. These findings suggest that the coupling between DNA replication and chromatin assembly may not necessarily involve a direct interaction between the replication and assembly factors at a replication fork.     

Structure of replicating simian virus 40 minichromosomes. The replication fork, core histone segregation and terminal structures

The structure of replicating simian virus 40 (SV40) minichromosomes was studied by DNA crosslinking with trimethyl-psoralen. The procedure was used both in vitro with extracted SV40 minichromosomes as well as in vivo with SV40-infected cells. Both procedures gave essentially the same results. Mature SV40 minichromosomes are estimated to contain about 27 nucleosomes (error +/- 2), except for those molecules with a nucleosome-free gap, which are interpreted to contain 25 nucleosomes (error +/- 2). In replicative intermediates, nucleosomes are present in the unreplicated parental stem with the replication fork possibly penetrating into the nucleosomal DNA before the histone octamer is removed. Nucleosomes reassociate on the newly replicated DNA branches at distances from the branch point of 225 ( +/- 145) nucleotides on the leading strand and of 285( +/- 120) nucleotides on the lagging strand. In the presence of cycloheximide, daughter duplexes contained unequal numbers of nucleosomes, supporting dispersive and random segregation of parental nucleosomes. These were arranged in clusters with normal nucleosome spacing. We detected a novel type of interlocked dimer comprising two fully replicated molecules connected by a single-stranded DNA bridge. We cannot decide whether these dimers represent hemicatenanes or whether the two circles are joined by a Holliday-type structure. The joining site maps within the replication terminus. We propose that these dimers represent molecules engaged in strand segregation.     

Mechanisms of inhibition of DNA replication by ultraviolet light in normal human and xeroderma pigmentosum fibroblasts

The inhibition of DNA replication in ultraviolet-irradiated human fibroblasts was characterized by quantitative analysis of radiation-induced alterations in the steady-state distribution of sizes of pulse-labeled, nascent DNA. Low, noncytotoxic fluences (<1 J/m², producing less than one pyrimidine dimer per replicon) rapidly produced an inhibition of DNA synthesis in half-replicon-size replication intermediates without noticeably affecting synthesis in multi-repliconsize intermediates. With time, the inhibition produced by low fluences spread progressively to include multi-replicon-size intermediates. The results indicate that ultraviolet radiation inhibits the initiation of DNA synthesis in replicons. Higher (>1 J/m², producing more than one dimer per replicon) cytotoxic fluences inhibited DNA synthesis in operating replicons presumably because the elongation of nascent strands was blocked where pyrimidine dimers were present in template strands. Xeroderma pigmentosum fibroblasts with deficiencies in DNA excision repair exhibited an inhibition of replicon initiation after low radiation fluences. indicating the effect was not solely dependent upon operation of the nucleotidyl excision repair pathway. Owing to their inability to remove pyrimidine dimers ahead of DNA growing points, the repair-deficient cells also were more sensitive than normal cells to the ultraviolet-induced inhibition of chain elongation. Xeroderma pigmentosum cells belonging to the variant class were even more sensitive to inhibition of chain elongation than the repair-deficient strains despite their ability to remove pyrimidine dimers. This analysis suggests that normal and repair-deficient human fibroblasts either are able to rapidly bypass certain dimers or these dimers are not recognized by the chain elongation machinery.     

DNA Chain Elongation and Joining in Normal Human and Xeroderma Pigmentosum Cells after Ultraviolet Irradiation

DNA synthesized in human cells after ultraviolet (UV) irradiation is made in segments of lower molecular weight than in unirradiated cells. Within several hours after irradiation these smaller units are both elongated and joined together. This repair process has been observed in normal human fibroblasts, HeLa cells, and fibroblasts derived from three types of xeroderma pigmentosum patients—uncomplicated with respect to neurological problems, complicated (de Sanctis-Cacchione syndrome), and one with the clinical symptoms of xeroderma pigmentosum but with normal repair replication. The ability of human cells to elongate and to join DNA strands despite the presence of pyrimidine dimers enables them to divide without excising the dimers present in their DNA. It may be this mechanism which enables xeroderma pigmentosum cells to tolerate small doses of UV radiation.     

Repair of pyrimidine dimer ultraviolet light photoproducts by human cell extracts

A newly developed method allows human cell extracts to carry out repair synthesis on ultraviolet light irradiated closed circular plasmid DNA [Wood, R. D., Robins, P., & Lindahl, T. (1988) Cell 53, 97-106]. The identity of the photodamage that leads to this repair replication was investigated. Removal of stable pyrimidine hydrates from irradiated plasmid pAT153 did not significantly affect the amount of repair replication in the fluence range of 0-450 J/m2, because of the low yield of these products and their short DNA repair patch size. Photoreactivation of irradiated DNA using purified Escherichia coli DNA photolyase to remove more than 95% of the cyclobutane dimers from the DNA reduced the observed repair synthesis by 20-40%. The greater part of the repair synthesis is highly likely to be caused by (6-4) pyrimidine dimer photoproducts. This class of lesions is rapidly repaired by mammalian cells, and their removal is known to be important for cell survival after ultraviolet irradiation.     

Analysis of DNA replication forks encountering a pyrimidine dimer in the template to the leading strand.

Electron microscopy (EM) was used to visualize intermediates of in vitro replication of closed circular DNA plasmids. Cell-free extracts were prepared from human cells that are proficient (IDH4, HeLa) or deficient (CTag) in bypass replication of pyrimidine dimers. The DNA substrate was either undamaged or contained a single cis, syn thymine dimer. This lesion was inserted 385 bp downstream from the center of the SV40 origin of replication and sited specifically in the template to the leading strand of the newly synthesized DNA. Products from 30 minute reactions were crosslinked with psoralen and UV, linearized with restriction enzymes and spread for EM visualization. Extended single-stranded DNA regions were detected in damaged molecules replicated by either bypass-proficient or deficient extracts. These regions could be coated with Escherichia coli single-stranded DNA binding protein. The length of duplex DNA from a unique restriction site to the single-stranded DNA region was that predicted from blockage of leading strand synthesis by the site-specific dimer. These results were confirmed by S1nuclease treatment of replication products linearized with single cutting restriction enzymes, followed by detection of the diagnostic fragments by gel electrophoresis. The absence of an extended single-stranded DNA region in replication forks that were clearly beyond the dimer was taken as evidence of bypass replication. These criteria were fulfilled in 17 % of the molecules replicated by the IDH4 extract.     

Accommodation of pyrimidine dimers during replication of UV-damaged simian virus 40 DNA.

UV irradiation of simian virus 40-infected cells at fluences between 20 and 60 J/m2, which yield one to three pyrimidine dimers per simian virus 40 genome, leads to a fluence-dependent progressive decrease in simian virus 40 DNA replication as assayed by incorporation of [3H]deoxyribosylthymine into viral DNA. We used a variety of biochemical and biophysical techniques to show that this decrease is due to a block in the progression of replicative-intermediate molecules to completed form I molecules, with a concomitant decrease in the entry of molecules into the replicating pool. Despite this UV-induced inhibition of replication, some pyrimidine dimer-containing molecules become fully replicated after UV irradiation. The fraction of completed molecules containing dimers goes up with time such that by 3 h after a UV fluence of 40 J/m2, more than 50% of completed molecules contain pyrimidine dimers. We postulate that the cellular replication machinery can accommodate limited amounts of UV-induced damage and that the progressive decrease in simian virus 40 DNA synthesis after UV irradiation is due to the accumulation in the replication pool of blocked molecules containing levels of damage greater than that which can be tolerated.     

Mutagenic DNA repair in Escherichia coli XXI. A stable SOS-inducing signal persisting after excision repair of ultraviolet damage

Mutations to streptomycin resistance induced by ultraviolet light in Escherichia coli can lose their susceptibility to photoreversing light during excision repair and in the absence of chromosomal replication and protein synthesis, i.e., under conditions where SOS induction cannot occur. Using fusions of lac with sulA and umuC we have shown that after excision of UV damage in the presence of chloramphenicol there is a persisting, relatively stable signal capable of inducing SOS genes when protein sysnthesis is subsequently permitted. The persisting signal is formed roughly in proportion to the square of the UV dose and is about 30% photoreversible. It is suggested that the persisting SOS-inducing signal comprises a UV photoproduct (the target lesion) opposite a gap in the opposing DNA strand, and is formed by excision of one (the ancillary lesion) of a pair of closely opposed photoproducts. Calculations suggest that as few as two or three such configurations in a cell can lead to induction a sulA when protein synthesis is permitted. It is not clear whether these configurations can directly induce the SOS system because of their region of single-stranded DNA or whether the ultimate SOS-inducing signal is a more extensive single-stranded region formed when such configurations encounter a replication fork. Photoproduct/gap configurations have been previously suggested to be potentially mutagenic. UV-induced mutations to streptomycin resistance are mostly at A:T sites and are not photoreversible in fully SOS-induced bacteria in the absence of excision repair, indicating that they are not targeted at cyclobutane-type pyrimidine dimers. In SOS-induced excision-proficient bacteria there is about 39% photoreversibility which is rapidly lost after UV. This photoreversibility is attributed to many ancillary lesions being cyclobutane-type pyrimidine dimers which are excised leading to the exposure of target lesions on the opposing strand which, at these particular sites, are mostly non-photoreversible photoproducts.