Consequences of molecular engineering enhanced DNA binding in a DNA repair enzyme.

Facilitated one-dimensional diffusion is a general mechanism utilized by several DNA-interactive proteins as they search for their target sites within large domains of nontarget DNA. T4 endonuclease V is a protein which scans DNA in a nonspecifically bound state and processively incises DNA at ultraviolet (UV)-induced pyrimidine dimer sites. An electrostatic contribution to this mechanism of target location has been established. Previous studies indicate that a decrease in the affinity of endonuclease V for nontarget DNA results in a decreased ability to scan DNA and a concomitant decrease in the ability to enhance UV survival in repair-deficient Escherichia coli. This study was designed to question the contrasting effect of an increase in the affinity of endonuclease V for nontarget DNA. With this as a goal, a gradient of increasingly basic amino acid content was created along a proposed endonuclease V-nontarget DNA interface. This incremental increase in positive charge correlated with the stepwise enhancement of nontarget DNA binding, yet inversely correlated with enhanced UV survival in repair-deficient E. coli. Further analysis suggests that the observed reduction in UV survival is consistent with the hypothesis that enhanced nontarget DNA affinity results in reduced pyrimidine dimer-specific recognition and/or binding. The net effect is a reduction in the efficiency of pyrimidine dimer incision.     

Biological consequences of a reduction in the non-target DNA scanning capacity of a DNA repair enzyme

Numerous DNA-interactive proteins have been shown to locate specific sequences within large domains of non-target DNA in vitro and in vivo by a one-dimensional diffusion mechanism; however, the biological significance of this process has not been evaluated. We have examined the biological consequences of sliding for the pyrimidine dimer-specific DNA repair enzyme T4 endonuclease V, an enzyme which scans non-target DNA both in vitro and in vivo. An endonuclease V mutant was constructed whose only altered biochemical characteristic, measured in vitro, was a loss in its ability to slide on non-target DNA. In contrast to the native enzyme, when the mutated endonuclease V was expressed in DNA repair-deficient Escherichia coli, no enhanced ultraviolet survival was conferred. These results suggest that the mechanisms which DNA-interactive proteins employ to enhance the probability of locating their target sequences are of significant biological importance.     

Molecular analysis of plasmid DNA repair within ultraviolet-irradiated Escherichia coli. I. T4 endonuclease V-initiated excision repair

The process by which DNA-interactive proteins locate specific sequences or target sites on cellular DNA within Escherichia coli is a poorly understood phenomenon. In this study, we present the first direct in vivo analysis of the interaction of a DNA repair enzyme, T4 endonuclease V, and its substrate, pyrimidine dimer-containing plasmid DNA, within UV-irradiated E. coli. A pyrimidine dimer represents a small target site within large domains of DNA. There are two possible paradigms by which endonuclease V could locate these small target sites: a processive mechanism in which the enzyme "scans" DNA for dimer sites or a distributive process in which dimers are located by random three-dimensional diffusion. In order to discriminate between these two possibilities in E. coli, an in vivo DNA repair assay was developed to study the kinetics of plasmid DNA repair and the dimer frequency (i.e. the number of dimer sites on a given plasmid molecule) in plasmid DNA as a function of time during repair. Our results demonstrate that the overall process of plasmid DNA repair initiated by T4 endonuclease V (expressed from a recombinant plasmid within repair-deficient E. coli) occurs by a processive mechanism. Furthermore, by reducing the temperature of the repair incubation, the endonuclease V-catalyzed incision step has been effectively decoupled from the subsequent steps including repair patch synthesis, ligation, and supercoiling. By this manipulation, it was determined that the overall processive mechanism is composed of two phases: a rapid processive endonuclease V-catalyzed incision reaction, followed by a slower processive mechanism, the ultimate product of which is the dimer-free supercoiled plasmid molecule.     

Site-directed mutagenesis of the T4 endonuclease V gene: the role of arginine-3 in the target search

Endonuclease V, a pyrimidine dimer specific endonuclease in T4 bacteriophage, is able to scan DNA, recognize pyrimidine dimer photoproducts produced by exposure to ultraviolet light, and effectively incise DNA through a two-step mechanism at the damaged bases. The interaction of endonuclease V with nontarget DNA is thought to occur via electrostatic interactions between basic amino acids and the acidic phosphate DNA backbone. Arginine-3 was chosen as a potential candidate for involvement in this protein-nontarget DNA interaction and was extensively mutated to assess its role. The mutations include changes to Asp, Glu, Leu, and Lys and deleting it from the enzyme. Deletion of Arg-3 resulted in an enzyme that retained marginal levels of AP specificity, but no other detectable activity. Charge reversal to Glu-3 and Asp-3 results in proteins that exhibit AP-specific nicking and low levels of dimer-specific nicking. These enzymes are incapable of affecting cellular survival of repair-deficient Escherichia coli after irradiation. Mutations of Arg-3 to Lys-3 or Leu-3 also are unable to complement repair-deficient E. coli. However, these two proteins do exhibit a substantial level of in vitro dimer- and AP-specific nicking. The mechanism by which the Leu-3 and Lys-3 mutant enzymes locate pyrimidine dimers within a population of heavily irradiated plasmid DNA molecules appears to be significantly different from that for the wild-type enzyme. The wild-type endonuclease V processively incises all dimers on an individual plasmid prior to dissociation from that plasmid and subsequent reassociation with other plasmids, yet neither of these mutants exhibits any of the characteristics of this processive nicking activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Selective metal binding to Cys-78 within endonuclease V causes an inhibition of catalytic activities without altering nontarget and target DNA binding

T4 endonuclease V is a pyrimidine dimer-specific DNA repair enzyme which has been previously shown not to require metal ions for either of its two catalytic activities or its DNA binding function by virtue of its ability to function in the presence of metal-chelating agents. However, we have investigated whether the single cysteine within the enzyme was able to bind metal salts and influence the various activities of this repair enzyme. A series of metals (Hg2+, Ag+, Cu+) were shown to inactivate both endonuclease Vs pyrimidine dimer-specific DNA glycosylase activity and the subsequent apurinic nicking activity. The binding of metal to endonuclease V did not interfere with nontarget DNA scanning or pyrimidine dimer-specific binding. The Cys-78 codon within the endonuclease V gene was changed by oligonucleotide site-directed mutagenesis to Thr-78 and Ser-78 in order to determine whether the native cysteine was directly involved in the enzyme's DNA catalytic activities and whether the cysteine was primarily responsible for the metal binding. The mutant enzymes were able to confer enhanced ultraviolet light (UV) resistance to DNA repair-deficient Escherichia coli at levels equal to that conferred by the wild type enzyme. The C78T mutant enzyme was purified to homogeneity and shown to be catalytically active on pyrimidine dimer-containing DNA. The catalytic activities of the C78T mutant enzyme were demonstrated to be unaffected by the addition of Hg2+ or Ag+ at concentrations 1000-fold greater than that required to inhibit the wild type enzyme. These data suggest that the cysteine is not required for enzyme activity but that the binding of certain metals to that amino acid block DNA incision by either preventing a conformational change in the enzyme after it has bound to a pyrimidine dimer or sterically interfering with the active site residue's accessibility to the pyrimidine dimer.     

Site-directed mutagenesis of the T4 endonuclease V gene: role of tyrosine-129 and -131 in pyrimidine dimer-specific binding

T4 endonuclease V incises DNA at the sites of pyrimidine dimers through a two-step mechanism. These breakage reactions are preceded by the scanning of nontarget DNA and binding to pyrimidine dimers. In analogy to the synthetic tripeptides Lys-Trp-Lys and Lys-Tyr-Lys, which have been shown to be capable of producing single-strand scissions in DNA containing apurinic sites, endonuclease V has the amino acid sequence Trp-Tyr-Lys-Tyr-Tyr (128-132). Site-directed mutagenesis of the endonuclease V gene, denV, was performed at the Tyr-129 and at the Tyr-129 and Tyr-131 positions in order to convert the Tyr residues to nonaromatic amino acids to test their role in dimer-specific binding. The UV survival of repair-deficient (uvrA recA) Escherichia coli cells harboring the denV N-129 construction was dramatically reduced relative to wild-type denV+ cells. The survival of denV N-129,131 cells was indistinguishable from that of the parental strain lacking the denV gene. The mutant endonuclease V proteins were then characterized with regard to (1) dimer-specific nicking activity, (2) apurinic nicking activity, and (3) binding affinity to UV-irradiated DNA. Dimer-specific nicking activity and dimer-specific binding for both denV N-129 and N-129,131 were abolished, while apurinic-specific nicking was substantially retained in denV N-129,131 but was abolished in denV N-129. These results indicate that Tyr-129 and Tyr-131 positions of endonuclease V are at least important in pyrimidine dimer-specific binding and possibly nicking activity.     

Mutations in endonuclease V that affect both protein-protein association and target site location

A general mechanism by which proteins locate their target sites within large domains of DNA is a one-dimensional facilitated diffusion process in which the protein scans DNA in a nonspecifically bound state. An electrostatic contribution to this type of mechanism has been previously established. This study was designed to question whether other characteristics of a protein's structure might contribute to the scanning mechanism of target site location. In this regard, T4 endonuclease V was shown to establish an ionic strength dependent monomer-dimer equilibrium in solution. A protein dimer interaction site was postulated to exist along a putative alpha-helix containing amino acid residues 54-62. The conservative substitutions of Phe-60----Leu-60 and Phe-59, Phe-60----Leu-59, Leu-60 resulted in mutant enzymes which remained in the monomeric state independent of the ionic strength of the solution. The target site location mechanism of these mutants has also been altered. Under conditions where wild-type endonuclease V processively scans nontarget DNA, the target location mechanism of the monomeric mutant proteins was shifted toward a less processive search. This decrease in the processivity of the mutants was especially surprising because the nontarget DNA binding affinity was found to be significantly increased. Thus, an additional component of the endonuclease V DNA scanning mechanism appears to be the formation of a stable endonuclease V dimer complex.     

UV endonuclease-mediated enhancement of UV survival in Micrococcus luteus: evidence revealed by deficiency in the Uvr homolog.

Unlike its phage T4 counterpart (also known as endonuclease V), Micrococcus luteus UV endonuclease (pyrimidine dimer DNA glycosylase/apurinic-apyrimidinic endonuclease) has suffered from lack of genetic evidence to implicate it in the promotion of UV survival of the cell, i.e., mutants with its deficiency are no more UV-sensitive than the wild type. On the assumption that the contribution of UV endonuclease is obscured by the presence of a homolog of Escherichia coli UvrABC endonuclease, which has recently been identified in this bacterium, survival studies were carried out in its absence. With 254-nm UV irradiation, which generates not only pyrimidine dimers but also 6-4 photoproducts as lethal lesions, a double mutant defective in both UV endonuclease and the Uvr homolog was shown to be more sensitive than a single mutant defective only in the latter, with a dose reduction factor of approximately 2 at the survival level of 37%. Furthermore, molecular photosensitization, which produces only pyrimidine dimers, revealed an even greater difference in sensitivity, the dose reduction factor being about 3.4. These results indicate that the contribution to cell survival of UV endonuclease, an enzyme specific for pyrimidine dimers, is manifest if the backup by the Uvr homolog is absent.     

In Vitro Packaging of UV Radiation-Damaged DNA from Bacteriophage T7

When DNA from bacteriophage T7 is irradiated with UV light, the efficiency with which this DNA can be packaged in vitro to form viable phage particles is reduced. A comparison between irradiated DNA packaged in vitro and irradiated intact phage particles shows almost identical survival as a function of UV dose when Escherichia coli wild type or polA or uvrA mutants are used as the host. Although uvrA mutants perform less host cell reactivation, the polA strains are identical with wild type in their ability to support the growth of irradiated T7 phage or irradiated T7 DNA packaged in vitro into complete phage. An examination of in vitro repair performed by extracts of T7-infected E.coli suggests that T7 DNA polymerase may substitute for E. coli DNA polymerase I in the resynthesis step of excision repair. Also tested was the ability of a similar in vitro repair system that used extracts from uninfected cells to restore biological activity of irradiated DNA. When T7 DNA damaged by UV irradiation was treated with an endonuclease from Micrococcus luteus that is specific for pyrimidine dimers and then was incubated with an extract of uninfected E. coli capable of removing pyrimidine dimers and restoring the DNA of its original (whole genome size) molecular weight, this DNA showed a higher packaging efficiency than untreated DNA, thus demonstrating that the in vitro repair system partially restored the biological activity of UV-damaged DNA.     

Pyrimidine dimer excision in Escherichia coli strains deficient in exonucleases V and VII and in the 5' leads to 3' exonuclease of DNA polymerase I.

An isogenic series of Escherichia coli strains deficient in various combinations of three 5' leads to 3' exonucleases (exonuclease V, exonuclease VII, and the 5' leads to 3' exonuclease of DNA polymerase I) was constructed and examined for the ability to excise pyrimidine dimers after UV irradiation. Although the recB and recC mutations (deficient in exonuclease V) proved to be incompatible with the polA(Ex) mutation (deficient in the 5' leads to 3' exonuclease of DNA polymerase I), it was possible to reduce the level of the recB,C exonuclease by the use of temperature-sensitive recB270 recC271 mutants. It was found that, by employing strains deficient in exonuclease V, postirradiation DNA degradation could be reduced and dimer excision measurements could be facilitated. Mutants deficient in exonuclease V were found to excise dimers at a rate comparable to that of the wild type. Mutants deficient in exonuclease V and the 5' leads to 3' exonuclease of DNA polymerase I are slightly slower than the wild type at removing dimers accumulated after doses in excess of 40 J/m2. However, although strains with reduced levels of exonuclease VII excised dimers at the same rate as the wild type, the addition of an exonuclease VII deficiency to a strain with reduced levels of exonuclease V and the 5' leads to 3' exonuclease of DNA polymerase I caused a marked decrease in the rate and extent of dimer excision. These observations support previous indications that the 5' leads to 3' exonuclease of DNA polymerase I is important in dimer removal and also suggest a role for exonuclease VII in the excision repair process.     

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.     

Sensitive determination of pyrimidine dimers in DNA of UV-irradiated mammalian cells. Introduction of T4 endonuclease V into frozen and thawed cells

Endonuclease V from E. coli infected with phage T4 was used to evaluate the frequency and the removal of pyrimidine dimers from DNA in cultured mammalian cells. Cellular membranes were made permeable to the enzyme by two cycles of rapid freezing and thawing. The number of endonuclease-sensitive sites in DNA was assayed by sedimentation in alkaline sucrose gradients upon which the cells were lysed directly. Comparison of the frequency of endonuclease-sensitive sites with the frequency of pyrimidine dimers determined by chromatographic analysis of hydrolysed DNA indicated that about 50% of the dimers in the permeabilized cells were substrates for T4 endonuclease V. This was confirmed by observation that when DNA treated with the enzyme in situ was purified, it contained the expected additional number of endonuclease-sensitive sites if again treated with the enzyme. The percentage of pyrimidine dimers recognized by T4 endonuclease V was enhanced to nearly 100% by exposing the permeabilized cells to 2 M NaCl before the enzyme was introduced. This method allowed the measurement of frequencies of endonuclease-sensitive sites after doses of UV irradiation at low as 0.5 J/m2. Loss of endonuclease sites from cellular DNA was observed during post-irradiation incubation of V79 Chinese hamster cells and several human cell strains. A comparison of the results obtained in human cells with or without the high-salt exposure before endonuclease treatment suggested that the dimers recognized under low-salt conditions may be removed slightly faster than those recognized only after high-salt exposure.     

A eukaryotic gene encoding an endonuclease that specifically repairs DNA damaged by ultraviolet light.

Many eukaryotic organisms, including humans, remove ultraviolet (UV) damage from their genomes by the nucleotide excision repair pathway, which requires more than 10 separate protein factors. However, no nucleotide excision repair pathway has been found in the filamentous fungus Neurospora crassa. We have isolated a new eukaryotic DNA repair gene from N.crassa by its ability to complement UV-sensitive Escherichia coli cells. The gene is altered in a N.crassa mus-18 mutant and responsible for the exclusive sensitivity to UV of the mutant. Introduction of the wild-type mus-18 gene complements not only the mus-18 DNA repair defect of N.crassa, but also confers UV-resistance on various DNA repair-deficient mutants of Saccharomyces cerevisiae and a human xeroderma pigmentosum cell line. The cDNA encodes a protein of 74 kDa with no sequence similarity to other known repair enzymes. Recombinant mus-18 protein was purified from E.coli and found to be an endonuclease for UV-irradiated DNA. Both cyclobutane pyrimidine dimers and (6-4)photoproducts are cleaved at the sites immediately 5' to the damaged dipyrimidines in a magnesium-dependent, ATP-independent reaction. This mechanism, requiring a single polypeptide designated UV-induced dimer endonuclease for incision, is a substitute for the role of nucleotide excision repair of UV damage in N.crassa.     

Dark Repair of Ultraviolet-Irradiated Deoxyribonucleic Acid by Bacteriophage T4: Purification and Characterization of a Dimer-Specific Phage-Induced Endonuclease

The purification and properties of an ultraviolet (UV) repair endonuclease are described. The enzyme is induced by infection of cells of Escherichia coli with phage T4 and is missing from extracts of cells infected with the UV-sensitive and excision-defective mutant T4V(1). The enzyme attacks UV-irradiated deoxyribonucleic acid (DNA) containing either hydroxymethylcytosine or cytosine, but does not affect native DNA. The specific substrate in UV-irradiated DNA appears to be pyrimidine dimer sites. The purified enzyme alone does not excise pyrimidine dimers from UV-irradiated DNA. However, dimer excision does occur in the presence of the purified endonuclease plus crude extract of cells infected with the mutant T4V(1).     

Site-directed mutagenesis of the T4 endonuclease V gene: mutations which enhance enzyme specific activity at low salt concentrations

Previous structure/function analyses of the DNA repair enzyme, T4 endonuclease V, have suggested that the extreme carboxyl portion of the enzyme is associated with pyrimidine dimer-specific binding (Recinos and Lloyd, and Stump and Lloyd, Biochemistry 27:1832-1838 and 1839-1843, 1988, respectively). Within the final 11 amino acids there are 5 aromatic, 2 basic, and no acidic residues and it has been proposed that these residues stack with and electrostatically interact with the kinked DNA at the site of a pyrimidine dimer. The role of the tyrosine residue at position 129 has been investigated by oligonucleotide site-directed mutagenesis in which the codon for Tyr-129 has been altered to reflect conservative changes of Trp and Phe and more dramatic changes of Ser, a stop codon, deletion of the codon or introduction of a frameshift. Both changes to the aromatic amino acids resulted in proteins which accumulated well in E. coli and not only significantly enhanced the UV survival of repair-deficient cells but also complemented a defective denV gene within UV-irradiated T4 phage. Partially purified preparations of the Tyr-129----Trp and Tyr-129----Phe mutants were assayed for their ability to processively incise UV-irradiated plasmid DNA (a nicking reaction carried out at low 25 mM salt concentrations). The mutant enzymes Tyr-129----Phe and Tyr-129----Trp displayed a 1000% and 500% enhanced specific nicking activity, respectively. These reactions were also shown to be completely processive. Assays performed at higher (100 mM) salt concentrations reduced the specific activities of the mutant enzymes approximately to that of wild type for the Tyr-129----Phe mutant and to 20% that of wild type for the Tyr-129----Trp mutant.     

Excision repair and DNA synthesis with a combination of HeLa DNA polymerase beta and DNase V

The ability of HeLa DNA polymerases to carry out DNA synthesis from incisions made by various endodeoxyribonucleases which recognize or form baseless sites in DNA was examined. DNA polymerase beta carried out limited strand displacement synthesis from 3'-hydroxyl nucleotide termini made by HeLa apurinic/apyrimidinic (AP) endonuclease II at the 5'-side of apurinic sites. Escherichia coli endonuclease III incises at the 3'-side of apurinic sites to produce nicks with 3'-deoxyribose termini which did not efficiently support DNA synthesis with beta-polymerase. However, these nicks could be activated to support limited DNA synthesis by HeLa AP endonuclease II, an enzyme which removes the baseless sugar phosphate from the 3'-termini, thus creating a one-nucleotide gap. With dGTP as the only nucleoside triphosphate present, the beta-polymerase catalyzed one-nucleotide DNA repair synthesis from those gaps which lacked dGMP. In contrast, HeLa DNA polymerase alpha was unreactive with all of the above incised DNA substrates. Larger patches of DNA synthesis were produced by nick translation from one-nucleotide gaps with HeLa DNA polymerase beta and HeLa DNase V. Moreover, incisions made by E. coli endonuclease III were activated to support DNA synthesis by the DNase V which removed the 3'-deoxyribose termini. HeLa DNase V also stimulated both the rate and extent of DNA synthesis by DNA polymerase beta from AP endonuclease II incisions. In this case the baseless sugar phosphate was removed from the 5'-termini, and nick translational synthesis occurred. Complete DNA excision repair of pyrimidine dimers was achieved with the beta-polymerase, DNase V, and DNA ligase from incisions made in UV-irradiated DNA by T4 UV endonuclease and HeLa AP endonuclease II. Such incisions produce a one-nucleotide gap containing 3'-hydroxyl nucleotide and 5'-thymine: thymidylate cyclobutane dimer termini. DNase V removes pyrimidine dimers primarily as a dinucleotide and then promotes nick translational DNA synthesis.     

Expression of the bacteriophage T4 denV structural gene in Escherichia coli.

The expression of the T4 denV gene, which previously had been cloned in plasmid constructs downstream of the bacteriophage lambda hybrid promoter-operator oLpR, was analyzed under a variety of growth parameters. Expression of the denV gene product, endonuclease V, was confirmed in DNA repair-deficient Escherichia coli (uvrA recA) by Western blot analyses and by enhancements of resistance to UV irradiation.     

The roles of different excision-repair mechanisms in the resistance of Micrococcus luteus to UV and chemical mutagens

M. luteus mutants showing increased sensitivity to both UV and 4-NQO were isolated after the treatment of parental ATCC4698 strain with MNNG. The mutants were also highly sensitive to mitomycin C, cis-platinum, 8-methoxypsoralen (8-MOP) plus near-UV and angelicin plus near-UV in various degrees. The endonuclease activity specific for pyrimidine dimers in UV-irradiated DNA was normally detected in extract of the mutants. With regard to host-cell reactivation ability the mutants fell into two groups. The hcr- mutants lacked the ability to reactivate UV-damaged N6 phage and were resistant to X-rays. The incision of DNA did not occur during incubation after the treatment with angelicin plus near-UV in the hcr- mutants, whereas it occurred in the parental strain. The facts indicate that the hcr- mutants are defective in the incision mechanism which has a wide substrate specificity, similar to the UVRABC nuclease of E. coli. On the other hand, the incision of DNA and the removal of UV-induced thymine dimers from DNA occurred in the hcr- mutants as well as in the parental strain, which is ascribed to the UV endonuclease activity. Compared with the hcr- mutants, hcr+ mutants were highly sensitive to X-rays, like recA- mutants of E. coli.     

Perturbations in simian virus 40 DNA synthesis by ultraviolet light.

Perturbations of Simian Virus 40 (SV40) DNA replication by ultraviolet (UV) light during the lytic cycle in permissive monkey CV-1 cells resemble those seen in host cell DNA replication. Formation of Form I DNA molecules (i.e. completion of SV40 DNA synthesis) was more sensitive to UV irradiation than synthesis of replicative intermediates or Form II molecules, consistent with inhibition of DNA chain elongation. The observed amounts of [3H]thymidine incorporated in UV-irradiated molecules could be predicted on the assumption that pyrimidine dimers are responsible for blocking nascent DNA strand growth. The relative proportion of labeled Form I molecules in UV-irradiated cultures rapidly increased to near-control values with incubation after 20 or 40 J/m2 of light (0.9--1.0 or 1.8--2.0 dimers per SV40 genome, respectively). This rapid increase and the failure of Form II molecules to accumulate suggest that SV40 growing forks can rapidly bypass many dimers. Form II molecules formed after UV irradiation were not converted to linear (Form III) molecules by the dimer-specific T4 endonuclease V, suggesting either that there are no gaps opposite dimers in these molecules or that T4 endonuclease V cannot use Form II molecules as substrates.     

Microinjection of T4 endonuclease V produced by a synthetic denV gene stimulates unscheduled DNA synthesis in both xeroderma pigmentosum and normal cells

A structural gene for T4 endonuclease V was constructed by ligating synthetic oligonucleotides. The endonuclease V was overproduced in E. coli under control of the E. coli tryptophan promoter and purified to apparent homogeneity. The product had comparable DNA glycosylase and apurinic/apyrimidinic (AP) endonuclease activities to the natural enzyme in vitro. When this endonuclease V was microinjected into the cytoplasm of xeroderma pigmentosum (XP) cells of complementation group A, B, C, D, F, G or H, unscheduled DNA synthesis (UDS) above the residual level was detected in all the cells at a dose of about 10(3) molecules following UV irradiation. The gain numbers of UDS in these XP cells increased with increase in the dose of enzyme and reached a plateau at the normal cell level on introduction of about 10(4) molecules. Introduction of more enzyme into either XP cells or normal human cells did not increase the grain number under regular labelling conditions (2.5 h, 37 degrees C). In normal mouse cells, introduction of the enzyme increased the grain number more than 4-fold under the same conditions during at least 8.5 h following UV irradiation. Furthermore, with a labelling time of 30 min, the enzyme more than doubled the grain number even in normal human cells.