Studies on the substrate specificity of the T 4 excision repair endonuclease

A history of the DNA repair and mutagenesis field: The discovery of base excision repair

This article reviews the early history of the discovery of an DNA repair pathway designated as base excision repair (BER), since in contrast to the enzyme-catalyzed removal of damaged bases from DNA as nucleotides [called nucleotide excision repair (NER)], BER involves the removal of damaged or inappropriate bases, such as the presence of uracil instead of thymine, from DNA as free bases.

Preferential binding of high mobility group 1 protein to UV-damaged DNA. Role of the COOH-terminal domain

Binding of chromosomal high mobility group 1 protein (HMG1) to UV-damaged DNA has been studied with oligonucleotides containing a single dipyrimidine site for formation of UV photolesions. Irradiation of an oligonucleotide with unique TT dinucleotide resulted in generation of cyclobutane pyrimidine dimer with no evidence for induction of (6-4) photoproducts, whereas the analysis of irradiated TC-containing oligonucleotide detected (6-4) photoproducts but not cyclobutane pyrimidine dimers. Mobility shift assays have revealed that HMG1 protein binds preferentially to irradiated TT and TC oligonucleotides. Photoreversal of cyclobutane pyrimidine dimers with DNA photolyase and hydrolysis of the (6-4) photoproducts with hot alkali substantially reduced but did not eliminate binding of HMG1. The protein, therefore, appears to bind the two main types of UV damages in DNA, but some other photolesion(s) contributes to the preferential binding of HMG1 to irradiated DNA. By quantifying gel shift assays and considering the efficiencies of lesion formation, we determined dissociation constants of 1.2 +/- 0.5 and 4.0 +/- 1.5 microM for irradiated TT and TC oligonucleotides, respectively, and 70 +/- 20 microM for the control non-irradiated probes. Tryptic removal of the acidic COOH-terminal domain of HMG1 significantly affected binding of the protein to both irradiated and intact oligonucleotides. The potential role of HMG1 in recognition of the UV lesions in DNA is discussed.

A novel phenotype of an excision-repair mutant in Neurospora crassa: mutagen sensitivity of the mus-18 mutant is specific to UV

A UV-sensitive mutant has been isolated from UV-mutagenized conidia of Neurospora crassa. The mutation responsible for the lesion was mapped in linkage group VL, proximal to the nucleolus organizer region. We designated the mutant mus-18. The sensitivity of the mus-18 mutant to UV-irradiation was not particularly high, being less than twice that of the wild-type strain. However, the frequency of mutations at the ad-3 loci induced by UV was extremely high even at low doses, under conditions where survival rates of mus-18 cells were almost identical to those of wild-type cells. Photo-reactivation of UV damage was normal in the mus-18 mutant. Sensitivity to other mutagens, such as gamma rays, 4-nitroquinoline-1-oxide, N-methyl-N'-nitro-N-nitrosoguanidine, mitomycin C and methyl methanesulfonate, was similar to that of the wild type. Fertility of the mus-18 mutant was normal in homozygous crosses. These results suggest that mus-18 is an excision-repair mutant. Measurement of endonuclease-sensitive sites (ESS) after liquid-holding recovery from UV damage revealed that ESS remained unrepaired for longer than 18 h in the mus-18 mutant, while most were eliminated within 6 h in wild-type cells and in other UV-sensitive mutants. This result suggests that mus-18 is defective in the incision step of dimer excision. The mus-18 mutant provides the first example of an excision-defective mutation in eukaryotes, which is specific to UV damage.

Structure-function studies of the T4 endonuclease V repair enzyme

Published data on the structure and mechanism of endonuclease V from bacteriophage T4 are reviewed with the objective of developing a working mechanistic model of this enzyme. Endonuclease V is an interesting and important candidate to be the first DNA-repair enzyme to have its structure determined by crystallography, and a more detailed model of the reaction process is needed to mechanistically interpret such a structure. Such a model should be sufficiently detailed to support future investigations of structure/function relationships between the enzyme and the DNA damage repair pathway it initiates, as probed by site-directed mutagenesis techniques and other methods. The early literature is presented in an historical perspective, followed by a description of prior models and biochemical investigations. The biochemical phenotypes of mutants in the enzyme structural gene are discussed. The results of computer analyses aimed at structural interpretations of the protein sequence are given, together with a brief discussion of the strengths and weaknesses of such experiments.

Demethylation enhances removal of pyrimidine dimers from the overall genome and from specific DNA sequences in Chinese hamster ovary cells

We have examined the effects of changes in cytosine methylation on DNA repair in UV-irradiated Chinese hamster ovary (CHO) cells. A hypomethylated derivative of the CHO K1B11 line, B11aza, was established by passaging B11 cells over several months in increasing concentrations of 5-azacytidine; greater than 60% demethylation was consistently demonstrated in these conditioned cells. Following a UV dose of 10 J/m2, the amount of repair replication performed within 24 h was approximately twofold higher in B11aza cells than in control B11 cells. Removal of T4 endonuclease V-sensitive sites (ESS) from specific restriction fragments within and around the dihydrofolate reductase (DHFR) gene was then examined in B11aza cells and compared with that in B11 cells. Although demethylation had little or no effect on repair in the 5' half of the DHFR gene, within a nontranscribed sequence immediately downstream from the gene, or within an extragenic region further downstream from the DHFR gene, significant increases in repair were observed at the 3' end of the DHFR gene and within an extragenic region upstream of the DHFR gene. However, the increases in DNA repair were not accompanied by any changes in overall cellular resistance to UV when colony-forming ability was assayed. We suggest that the level of DNA methylation may play an indirect role in the regulation of DNA repair, perhaps through an effect on chromatin structure or transcriptional activity.

Demethylation enhances removal of pyrimidine dimers from the overall genome and from specific DNA sequences in Chinese hamster ovary cells

We have examined the effects of changes in cytosine methylation on DNA repair in UV-irradiated Chinese hamster ovary (CHO) cells. A hypomethylated derivative of the CHO K1B11 line, B11aza, was established by passaging B11 cells over several months in increasing concentrations of 5-azacytidine; greater than 60% demethylation was consistently demonstrated in these conditioned cells. Following a UV dose of 10 J/m2, the amount of repair replication performed within 24 h was approximately twofold higher in B11aza cells than in control B11 cells. Removal of T4 endonuclease V-sensitive sites (ESS) from specific restriction fragments within and around the dihydrofolate reductase (DHFR) gene was then examined in B11aza cells and compared with that in B11 cells. Although demethylation had little or no effect on repair in the 5' half of the DHFR gene, within a nontranscribed sequence immediately downstream from the gene, or within an extragenic region further downstream from the DHFR gene, significant increases in repair were observed at the 3' end of the DHFR gene and within an extragenic region upstream of the DHFR gene. However, the increases in DNA repair were not accompanied by any changes in overall cellular resistance to UV when colony-forming ability was assayed. We suggest that the level of DNA methylation may play an indirect role in the regulation of DNA repair, perhaps through an effect on chromatin structure or transcriptional activity.

The molecular genetics of the incision step in the DNA excision repair process

This review describes the evolution of research into the genetic basis of how different organisms use the process of excision repair to recognize and remove lesions from their cellular DNA. One particular aspect of excision repair, DNA incision, and how it is controlled at the genetic level in bacteriophage, bacteria, S. cerevisae, D. melanogaster, rodent cells and humans is examined. In phage T4, DNA is incised by a DNA glycosylase-AP endonuclease that is coded for by the denV gene. In E. coli, the products of three genes, uvrA, uvrB and uvrC, are required to form the UVRABC excinuclease that cleaves DNA and releases a fragment 12-13 nucleotides long containing the site of damage. In S. cerevisiae, genes complementing five mutants of the RAD3 epistasis group, rad1, rad2, rad3, rad4 and rad10 have been cloned and analyzed. Rodent cells sensitive to a variety of mutagenic agents and deficient in excision repair are being used in molecular studies to identify and clone human repair genes (e.g. ERCC1) capable of complementing mammalian repair defects. Most studies of the human system, however, have been done with cells isolated from patients suffering from the repair defective, cancer-prone disorder, xeroderma pigmentosum, and these cells are now beginning to be characterized at the molecular level. Studies such as these that provide a greater understanding of the genetic basis of DNA repair should also offer new insights into other cellular processes, including genetic recombination, differentiation, mutagenesis, carcinogenesis and aging.

Enhanced transforming activity of pSV2 plasmids in human cells depends upon the type of damage introduced into the plasmid

When pSV2-gpt or pSV2-neo plasmids are introduced into human cells by calcium phosphate coprecipitation, the yield of stable transformants (Gpt+ or Neo+) is increased by irradiating the respective plasmid DNA in vitro with UV (254 nm). To identify specific lesions that can increase the transforming activity of plasmids in human cells we examined pSV2 plasmids containing different types of damage. Of the lesions tested, cyclobutane pyrimidine dimers produced the greatest increase, and can nearly fully account for the effect of 254 nm UV on transformation. The enhancement of transformation produced by UV was not altered by the additional treatment of the plasmid DNA with T4 endonuclease V, an enzyme that nicks DNA specifically at pyrimidine dimers. Treatment of plasmid DNA with osmium tetroxide to produce thymine glycols, or with acid and heat to produce apurinic sites did not affect transformation frequency. The enhancement occurred in all the human cell lines tested, whether they contained or not sequences homologous to those in the plasmids, and was independent of the repair capacity of the recipient cells.

Partial complementation of the UV sensitivity of E. coli and yeast excision repair mutants by the cloned denV gene of bacteriophage T4

The denV gene of bacteriophage T4 was reconstituted from two overlapping DNA fragments cloned in M13 vectors. The coding region of the intact gene was tailored into a series of plasmid vectors containing different promoters suitable for expression of the gene in E. coli and in yeast. Induction of the TAC promoter with IPTG resulted in overexpression of the gene, which was lethal to E. coli. Expression of the TACdenV gene in the absence of IPTG, or the use of the yeast GAL1 or ADH promoters resulted in partial complementation of the UV sensitivity of uvrA, uvrB, uvrC and recA mutants of E. coli and rad1, rad2, rad3, rad4 and rad10 mutants of S. cerevisiae. The extent of denV-mediated reactivation of excision-defective mutants was approximately equal to that of photoreactivation of such strains. Excision proficient E. coli cells transformed with a plasmid containing the denV gene were slightly more resistant to ultraviolet (UV) radiation than control cells without the denV gene. On the other hand, excision proficient yeast cells were slightly more sensitive to killing by UV radiation following transformation with a plasmid containing the denV gene. This effect was more pronounced in yeast mutants of the RAD52 epistasis group.

Lack of effect of 4-nitroquinoline 1-oxide on cellular NAD levels

Human KB cells were treated with doses of 4-nitroquinoline 1-oxide (4NQO) or dimethyl sulfate (DMS) that produced equal numbers of DNA-strand breaks when measured by velocity sedimentation analysis in an alkaline sucrose gradient. The DMS treatment also caused a profound and sustained lowering of cellular NAD content. The 4NQO treatment had no effect on the cellular NAD content. This result with 4NQO was not expected because strand breaks in DNA activate poly(ADP-ribose)polymerase and in the ensuing reaction NAD is consumed. Since 4NQO adducts are removed by an excision-repair process it is postulated that the strand breaks formed during the repair process are not accessible to poly(ADP-ribose)polymerase.

Expression of cloned bacteriophage T4 uvsW and uvsY genes in rec+ and rec- Escherichia coli

Chimeric plasmids containing the uvsY uvsW region of the T4 genome were examined for the expression of these genes. Certain of these plasmids were shown to express the uvsY or the uvsW gene products by their ability to complement the UV sensitivity of infecting uvsW or uvsY mutant phage. Also, a chimeric plasmid containing both the uvsW and uvsY genes increases the survival of UV-irradiated, methyl methane sulfonate- or ethyl methane sulfonate-treated recA hosts.

Pyrimidine dimer-DNA glycosylases: studies on bacteriophage T4-infected and on uninfected Escherichia coli

Pyrimidine dimer (PD)-DNA glycosylase activity has been reported in both the M. luteus and phage T4 UV endonucleases. In the present studies the T4 PD-DNA glycosylase has been purified close to physical homogeneity using an assay that measures the release of free thymine from UV-irradiated poly ([H5] dT):poly (dA), after the photo-reversal of thymine-thymine dimers. The activity has also been demonstrated in vivo following infection of UV-irradiated E. coli uvr- cells with phage T4. Under these conditions the T4 PD-DNA glycosylase accounts quantitatively for all thymine-containing PD excised from [3H] labeled E. coli DNA. In vitro the T4 PD-DNA glycosylase has an associated AP endonuclease activity that incises UV-irradiated DNA 3 to the apyrimidinic sites created by the glycosylase. However, the glycosylase/AP endonuclease reaction mechanism in vitro does not appear to be a concerted one. In addition, a T4 phage with a temperature-sensitive mutation in the denV gene shows wild-type levels of survival at the permissive temperature, despite the fact that in vitro, extracts of E. coli infected with this mutant show no detectable phage-coded AP endonuclease at 28 degrees C. Thus the exact role of the T4 AP endonuclease in the incision of UV-irradiated DNA dimer in vivo is not clear. The ratio of excised non-containing nucleotides to dimer-containing nucleotides following infection of UV-irradiated E. coli with phage T4 denV+ yields a calculated average repair patch size of approximately 7 nucleotides. In contrast, the calculated average patch size in uninfected E. coli is approximately 70 nucleotides. Thus the extent of excision/resynthesis of UV-irradiated DNA may be determined by the specific mode of incision of the DNA at PD. When uninfected E. coli (uvr+) is exposed to UV radiation, a fraction of the excised thymine-containing PD contain photolabile thymine, suggesting the presence of PD-DNA glycosylase in E. coli. The role of this putative activity in the metabolism of UV-irradiated DNA is under investigation.

Ligation of oligonucleotides by pyrimidine dimers--a missing 'link' in the origin of life?

One of the principal photochemical reactions of DNA on exposure to UV is the formation of intrastrand cyclobutane-type pyrimidine dimers. The efficiency of this reaction depends on both the wavelength of the UV2 and the specific nucleotide sequence in the DNA. The formation of the pyrimidine dimer and its repair in living cells have been studied extensively. We have examined the possibility that pyrimidines at the ends of DNA strands may be adequately juxtaposed for dimer formation by the presence of a complementary strand, even when no phosphodiester linkage joins their sugars. In these conditions the formation of a dimer will 'ligate' two DNA strands end-to-end. We report here that thymidine oligonucleotides annealed to polydeoxyadenylate can be ligated end-to-end by UV irradiation, via thymine dimerization of the terminal nucleotides in adjacent oligonucleotides. The linkages are susceptible to direct photoreversal by 254 nm UV, as expected for cyclobutane-type thymine dimers, but they are not cleaved by the bacteriophage T4 endonuclease V, a dimer-specific DNA repair enzyme. We demonstrate that the ligating dimers are also resistant to photolyase from Escherichia coli. Although the phosphodiester backbone is not required for dimer formation, it is required for recognition of dimers by these DNA repair enzymes. We discuss the possibility that high molecular weight polynucleotides in primordial seas might have been generated from oligonucleotides by pyrimidine dimerization under the intense solar UV flux unattenuated by an ozone layer.

Demonstration of pyrimidine dimer-DNA glycosylase activity in vivo: bacteriophage T4-infected Escherichia coli as a model system

An approach to the detection of pyrimidine dimer-DNA glycosylase activity in living cells is presented. Mutants of Escherichia coli defective in uvr functions required for incision of UV-irradiated DNA were infected with phage T4 denV+ or denV- (defective in the T4 pyrimidine dimer-DNA glycosylase activity). In the former case the denV gene product catalyzed the incision of UV-irradiated host DNA, facilitating the subsequent excision of thymine-containing pyrimidine dimers. Isolation of these dimers from the acid-soluble fraction of infected cells was achieved by a multistep thin-layer chromatographic system. Exposure of the dimers to irradiation that monomerizes pyrimidine dimers (direct photoreversal) resulted in the stoichiometric formation of free thymine. Thus, in vivo incision of UV-irradiated DNA dependent on a pyrimidine dimer-DNA glycosylase can be demonstrated.

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.

Unscheduled DNA synthesis induced by 4-nitroquinoline-1-oxide in xeroderma pigmentosum cells and their complementing heterodikaryons

Unscheduled DNA synthesis (UDS) induced by 4-nitroquinoline-1-oxide (rNQO) in the complementation groups A to E and variant xeroderma pigmentosum (XP) cells, and various pairs of complementing XP heterokaryons were investigated. The pattern of UDS induced by various concentrations of 4NQO in normal cells was quite different from those in groups A to D XP cells. The patterns of UDS in group E and variant XP cells were indistinguishable from those of normal cells under our experimental conditions. The levels of UDS induced by 5 x 10(-6) M 4NQO were 13% of normal in group A, 9% in group B, 17% in group C, 25% in group D. The heterokaryons obtained by pair-wise fusions between different complementation groups of XP strains showed restored UDS induced by 5 x 10(-6) M 4NQO, while the dikaryons obtained from fusion between the same groups did not.

A pyrimidine dimer-DNA glycosylase activity associated with the v gene product of bacterophage T4

Mutations in the v gene of bacteriophage T4 are associated with a marked increase in sensitivity to killing by UV radiation at 254 nm, but not to a variety of other forms of base damage to DNA. Early studies from this laboratory provided evidence for a role of the v gene in the excision of pyrimidine dimers (PD) from DNA. Specifically, it was shown that extracts of T4v+-infected Escherichia coli catalyse the formation of single-strand breaks (nicks) and/or alkali-labile sites in UIV-irradiated duplex DNA. Comparable hydrolysis of phosphodiester bonds is not observed with extracts of E. coli infected with the mutant T4v1 (ref. 5). The product of the v gene has been extensively purified in a number of laboratories; however, convincing evidence of purification to physical homogeneity has not yet been presented.

Endonuclease alpha from Saccharomyces cerevisiae shows increased activity on ultraviolet irradiated native DNA

Endonuclease alpha isolated from the nucleus of the yeast Saccharomyces cerevisiae is a DNA endonuclease which has been shown to act preferentially on denatured T7 DNA. The purified enzyme is more active with UV-irradiated native T7 DNA than with unirradiated substrate. The relation between damage, measured by pyrimidine dimer concentration, and excess endonuclease activity is most readily explained by local denaturation caused by presence of pyrimidine dimers. When three radiation sensitive mutants of yeast were tested for the level of endonuclease alpha present, none were found lacking the enzyme. However, nuclei of strain rad 1-1, a mutant that may be defective in heteroduplex repair as well as excision repair, were found to contain reduced levels of the endonuclease. The enzyme isolated from this strain had less than one half the specific activity of similar preparations from wild type yeast.

Recombinational repair of alkylation lesions in phage T4. II. Ethyl methanesulfonate

Treatment of bacteriophage T4 by ethyl methanesulfonate (EMS) caused more than a doubling in recombination between two rII markers. The functions of genes 47, 46, 32, 30, uvsX and y are known to be required for genetic recombination, and mutants defective in these genes were found to be more sensitive to inactivation by EMS than wild-type phage. This suggests that a recombinational pathway involving the products of these genes may be employed in repairing EMS induced lethal lesions. Genes 45 and denV are apparently not involved in recombination, and mutants defective in these genes were not EMS-sensitive. Gene 47, 46 and y mutants which were defective in the repair of EMS induced lethal lesions had no detectable deficiency in their ability to undergo EMS-induced mutation. This implies that recombinational repair of EMS lesions does not contribute substantially to EMS mutagenesis. The results obtained here with EMS are general similar to the results reported in the preceding paper with MNNG, suggesting that the lesions caused by both of these monofunctional alkylating agents may be eliminated by similar recombinational repair processes.

Recombinational repair of alkylation lesions in phage T4. I. N-methyl-N'-nitro-N-nitrosoguanidine

Treatment of phage T4-host adsorption complexes by MNNG increased recombination between two rII markers by about three-fold. Temperature sensitive mutants defective in genes 32, 46 and 47, which cause reductions in recombination at semirestrictive temperature, proved to be substantially more sensitive to MNNG at such temperatures than wild-type phage. In addition, the recombination defective mutants xm(uvsX) and y10(y) were sensitive to MNNG than wild-type, whereas mutants defective in genes 45 and denV, which are apparently not involved in recombination, were not MNNG sensitive. These findings suggest that a recombination pathway involving the products of genes 32, 46, 47, uvsX and y is employed in repairing MNNG-induced lethal lesions. This mechanism is effective in cells infected by single phage, implying post-replication recombinational repair between daughter chromosomes. MNNG-induced lesions are subjects to multiplicity reactivation, but mutants defective in genes 46 to 47 showed the same degree of multiplicity reactivation as wild-type phage. The gene 32 and gene 47 recombination defective mutants were tested for their effects of MNNG-induced reversion of an rII marker. No reduction in induced reversion was found. Thus, it appears that the postulated recombinational repair pathway employing the products of genes 32 and 47 does not contribute substanitally to induced mutagenesis.

Evidence for a near UV-induced photoproduct of 5-hydroxymethylcytosine in bacteriophage T4 that can be recognized by endonuclease V

Non-photoreactivable endonuclease V-sensitive sites have been detected in the DNA of wild type bacteriophage T4 irradiated with near UV light (320 nm). Such sites were not detected in the DNA of (a) wild type T4 irradiated with far UV (254 nm) or (B) in T4 mutants in which non-glucosylated 5-hydroxy-methylcytosine (5HMC) or cytosine replaces glucosylated 5HMC normally present in T4, irradiated with 320 nm or 254 nm light. Although the non-photoreactivable sites accounted for approximately 50% of the endonuclease V-sensitive sites in the DNA of glucosylated T4 irradiated with near UV, there was very little difference in the sensitivities of T4 containing glucosylated 5HMC, non-glucosylated 5HMC and cytosine to near UV (313 nm). We propose that the photoproduct responsible for the non-photoreactivable, but endonuclease V-sensitive, sites in glucosylated DNA is formed from glucosylated 5HMC and that a similar photoproduct is formed from non-glucosylated 5HMC or cytosine in the appropriate phage strains. We further propose that the glucosylated 5HMC photoproduct is non-photoreactivable whereas the cytosine and non-glucosylated 5HMC photoproducts are photoreactivable and are therefore possibly cyclobutane dimers.

Further purification and characterization of T4 endonuclease V

T4 endonuclease V, which is involved in repair of ultraviolet-damaged DNA, has been purified 3600 fold from T4D-infected Escherichia coli. The enzyme shows optimal activity at pH 7.2 and does not require added divalent ions. Endonuclease V attacks both native and heat-denatured DNA provided that the DNA has been irradiated, and the enzyme activity is dependent on the dose of ultraviolet irradiation. The rate and the extent of the reaction are greater with irradiated native DNA although the Km values for the two types of DNA are the same (2.25 - 10(-5) M). The enzyme is readily inactivated by heat and is sensitive to p-chloromercuribenzoate. Endonuclease V-treated irradiated DNA is degraded by spleen phosphodiesterase only when the DNA has been treated with alkaline phosphatase, suggesting that the enzyme produces 5'-phosphoryl termini.

Enzymic mechanism of excision-repair in T4-infected cells

Excision of pyrimidine dimers from ultraviolet-irradiated DNA in a cell-free system of Escherichia coli infected with bacteriophage T4 consists of two different steps, one to induce a single-strand break at a point close to a pyrimidine dimer and the other to release dimer-containing nucleotide from the DNA. The enzymes responsible for these steps were isolated and the reactions were characterized; T4 endonuclease V introduces a break at the 5' side of a dimer and 5' in equilibrium 3' exonucleases, which are also induced by T4, act at the break to excise dimer-containing nucleotides. We isolated temperature-dependent v mutants, which exhibit increased sensitivity to UV at 42 degrees C but not at 30 degrees C, and found that the mutants induce temperature-sensitive T4 endonuclease V, indicating that the v gene of T4 is indeed the structural gene for T4 endonuclease V and that the enzyme is responsible for the first step of excision-repair. A possible mechanism of excision-repair in T4-infected cells is discussed.

Excision of thymine dimers in vitro by extracts of bacteriophage-infected Escherichia coli

Extracts of DNA polymerase I defective Escherichia coli infected with phage T4 contain an exonuclease activity that removes thymine dimers from UV-irradiated DNA previously nicked with T4 UV endonuclease. This activity is not expressed if cells are infected in the presence of chloramphenicol. The enzyme has a requirement for divalent cation and is not affected by caffeine, but excision is inhibited in the presence of proflavine. The enzyme is present in all phage T4 mutants thus far examined, including 25 UV-sensitive mutants isolated during the course of the experiments, all of which are defective in the v gene. A similar activity can be detected in cells infected with phages T2, T3, and T6, but not in cells infected with phage T7.

Biochemical studies on the chi mutation of bacteriophage T4: differential inhibition of chi+ and chi DNA synthesis by mitomycin C

Biochemical studies were carried out to determine the effect of chi mutation on T4 DNA synthesis. The rate and final extent of DNA synthesis are almost the same with T4D- and T4chi-infected cells, although the burst size of T4chi is about one-sixth that of the wild type. The DNA synthesis of T4chi-infected cells is more readily inhibited by mitomycin C than is that of T4 wild type. When mitomycin C was added during active phage growth, DNA synthesis of T4chi halted almost immediately. T4 DNA polymerases isolated from chi(+)- and chi-infected cells, however, exhibit no difference with regard to their sensitivities to mitomycin C, priming activities with alkylated or ultraviolet light-irradiated templates and other enzymatic properties.

Deoxyribonucleic acid repair in bacteriophage T4: observations on the roles of the x and v genes and of host factors

Studies were carried out to determine the effect of mutation in the host pol I gene on survival of ultraviolet (UV)-irradiated bacteriophage T4. Whereas a slightly reduced survival was observed in Escherichia coli strain P-3478 (pol A(1)) compared to strain W-3110 (pol A(+)), no such difference was observed in two strains isogenic except for the pol A gene. It was also shown that, whereas bacteriophage T4x is sensitive to UV irradiation, X irradiation, and treatment with methyl-methanesulfonate (MMS), phage T4v(1) is sensitive only to UV irradiation. The survival of damaged phage T4x is neither affected by the presence of the rec A, rec B, or pol A mutations in the host, nor is there evidence that phage T4 effects repair of rec A or pol A mutants previously treated with either UV or MMS.