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).     

Studies on temperature-dependent ultraviolet light-sensitive mutants of bacteriophage T4: the structural gene for T4 endonuclease V.

Mutants of bacteriophage T4 which exhibit increased sensitivity to ultraviolet radiation specifically at high temperature were isolated after mutagenesis with hydroxylamine. At 42 °C the mutants are twice as sensitive to ultraviolet light as T4D, whereas at 30 °C they exhibit survival curves almost identical to that of the wild-type strain. Complementation tests revealed that the mutants possess temperature-sensitive mutations in the v gene.Evidence is presented to show that T4 endonuclease V produced by the mutants is more thermolabile than the enzyme of the wild-type. (1) Extracts of cells infected with the mutants were capable of excising pyrimidine dimers from ultraviolet irradiated T4 DNA at 30 °C, but no selective release of dimers was induced at 42 °C. (2) Endonuclease V produced by the mutant was inactivated more rapidly than was the enzyme from T4D-infected cells when the purified enzymes were incubated in a buffer at 42 °C. From these results it is evident that the v gene is the structural gene for T4 endonuclease V, which plays an essential role in the excision-repair of ultraviolet light-damaged DNA.The time of action of the repair endonuclease was determined by using the mutant. Survival of a temperature-sensitive v mutant, exposed to ultraviolet light, increased when infected cells were incubated at 30 °C for at least ten minutes and then transferred to 42 °C. It appears that repair of DNA proceeds during an early stage of phage development.     

Endonuclease from Escherichia coli that acts specifically upon duplex DNA damaged by ultraviolet light, osmium tetroxide, acid, or x-rays.

An endonuclease which is active upon DNA exposed to ultraviolet light at a photoproduct other than thymine dimers has been extensively purified from Escherichia coli. The small (2.7 S) enzyme is active in the presence of EDTA, has a neutral pH optimum, and is inhibited by tRNA and 1 M NaCl. It has no detectable exonuclease, DNA-N-glycosidase, or ribonuclease activities. The enzyme also nicks duplex DNA exposed to OsO4, x-rays, or acid, but it does not act upon undamaged DNA or irradiated single-stranded DNA. The majority of sites of action in DNA exposed to ultraviolet light or OsO4 appear to be alkali-stable, but those in DNA exposed to x-rays or acid are not. The incisions created by the endonuclease contain 5'-phosphate termini. The enzyme is possibly the same as E. coli endonuclease III described by Radman (Radman, M. (1976) J. Biol. Chem. 251, 1438-1445), but it is distinguishable from the other endodeoxyribonucleases described from that organism.     

Evidence that the UV endonuclease activity induced by bacteriophage T4 contains both pyrimidine dimer-DNA glycosylase and apyrimidinic/apurinic endonuclease activities in the enzyme molecule.

We performed experiments to determine whether the phage T4-induced UV endonuclease activity is a single protein containing both pyrimidine dimer-DNA glycosylase and apyrimidinic endonuclease activities. The UV endonuclease activity is induced by the denV gene and codes for the glycosylase activity. We obtained several kinds of evidence that the protein containing the glycosylase activity also contains the apyrimidinic endonuclease activity. After chromatography on DEAE-cellulose, the two activities copurified during phosphocellulose chromatography and Sephadex G-100 chromatography, with a constant ratio of activities across the activity peaks. On Sephadex G-100 columns the molecular weights of the two activities agreed within 2,500 or less. When an extract of cells infected with the T4 V1 mutant was purified in exactly the same way as an extract of cells infected with T4 V1+, neither glycosylase nor apyrimidinic endonuclease activity was detected in the normal elution position of the T4 UV endonuclease activity. The glycosylase and apyrimidinic endonuclease activities were induced with similar kinetics, which were characteristic of immediate early rather than delayed early enzymes. This correlated well with the presumed major role of these activities in repairing thymine dimers in parental DNA before DNA replication begins. Finally, glycosylase and apyrimidinic endonuclease activities were lost in parallel during incubation of the enzyme at 46 degree C. Our results indicated that both of these enzyme activities are contained in the same enzyme molecule and, probably, in the same polypeptide.     

Photoalkylated DNA and ultraviolet-irradiated DNA are incised at cytosines by endonuclease III.

Photoalkylation, the ultraviolet irradiation of DNA with isopropanol and di-tert-butylperoxide, causes a variety of base alterations. These include 8-(2-hydroxy-2-propyl)guanines, 8-(2-hydroxy-2-propyl)adenines and thymine dimers. An E. coli endonuclease against photoalkylated DNA was assayed by conversion of superhelical PM2 phage DNA to the nicked form. Enzyme activities were compared between extracts of strain BW9109 (xth-), lacking exonuclease III activity, and strain BW434 (xth-,nth-), deficient in both exonuclease III and endonuclease III. The endonuclease level in the double mutant against substrate photoalkylated DNA was under 20% of the activity in the mutant lacking only exonuclease III. Irradiation of the DNA substrate in the absence of isopropanol did not affect the activity in either strain. Analysis by polyacrylamide gel electrophoresis identified the sites of DNA cleavage by purified E. coli endonuclease III as cytosines, both in DNA irradiated at biologically significant wavelengths and in photoalkylated DNA. Neither 8-(2-hydroxy-2-propyl)purines, pyrimidine dimers, uracils nor 6-4'-(pyrimidin-2'-one)pyrimidines were substrates for the enzyme.     

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.     

Loss of thymine dimers from mammalian cell DNA. The kinetics for antibody-binding sites are not the same as that for T4 endonuclease V sites

Antiserum specific for thymine-containing dimers was used to assay DNA isolated from ultraviolet-irradiated cells following different repair periods. A 50% loss in antibody-binding sites was evident 1 h post-irradiation, and within 4 h 80% of the sites were removed. This result contrasts with data obtained with dimer-specific T4 endonuclease V and does not appear to be due to masking of the dimers by repair enzymes. T4 endonuclease V treatment of ultraviolet-irradiated DNA at 0 degree C resulted in conversion of the thymine dimers to apyrimidinic sites. This did not result in loss of antigenicity in either PM2 or CHO cell DNA. Likewise, treatment of ultraviolet-irradiated CHO cell DNA with T4 endonuclease at 37 degrees C did not change its antigenicity. These results suggest that aglycosylation of the dimers is not responsible for their inability to bind dimer-specific antibody 2-4 h post-irradiation. The possibility that T4 endonuclease V and the antiserum have different specificities for different dimers is discussed.     

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

Summary 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 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.AECL Refence No. 6370Communicated by B.A. Bridges     

On the recognition and cleavage mechanism of Escherichia coli endodeoxyribonuclease V, a possible DNA repair enzyme

Escherichia coli endodeoxyribonuclease V acts at many sites of damage in duplex DNA, including apurinic/apyrimidinic sites, lesions induced by ultraviolet light which are not pyrimidine dimers, adducts of 7-bromomethylbenz[a]anthracene, and, as demonstrated earlier (Gates, F. T., and Linn, S. (1977a) J. Biol. Chem. 252. 1647-1653), it degrades uracil-containing duplex DNA most efficiently. The cleavage rate increases with increasing substitution of uracil for thymine in T5 DNA, with a replacement of one-eight of thymine generating the apparent maximum cleavage rate. However, the apparent reaction limit with DNA containing 3.8% of thymine replaced by uracil corresponds to cleavage at only 6% of the dUMP residues. Evidently, the enzyme recognizes some peculiarities of abnormal DNA structure, but not simply distortions, since some lesions, including pyrimidine dimers, are not substrates. Endonuclease V generates double strand breaks in a constant ratio to single strand nicks, regardless of the substrate. It degrades DNA processively, completing the digestion of one substrate molecule before proceeding to the next. The enzyme also appears to act cooperatively. Cleavage at methylbenz[a]anthracene adducts is usually or always 5' to the lesion. Endonuclease V seems well suited to act as a DNA repair enzyme, surveying the genome for structural distortions generated by lesions for which specific repair systems might not exist.     

Excision repair of pyrimidine dimers from simian virus 40 minichromosomes in vitro

The ability of DNA repair enzymes to carry out excision repair of pyrimidine dimers in SV40 minichromosomes irradiated with 16 to 64 J/m2 of UV light was examined. Half of the dimers were substrate for the DNA glycosylase activity of phage T4 UV endonuclease immediately after irradiation, but this limit decreased to 27% after 2 h at 0 degrees C. Moreover, the apyrimidinic (AP) endonuclease activity of the enzyme did not incise all of the AP sites created by glycosylase activity, although all AP sites were substrate for HeLa AP endonuclease II. The initial rate of the glycosylase was 40% that upon DNA. After incision by the T4 enzyme, excision was mediated by HeLa DNase V (acting with an exonuclease present in the chromatin preparation). Under physiological salt conditions, excision did not proceed appreciably beyond the damaged nucleotides in DNA or chromatin. With chromatin, about 70% of the accessible dimers were removed, but at a rate slower than for DNA. Finally, HeLa DNA polymerase beta was able to fill the short gaps created after dimer excision, and these patches were sealed by T4 DNA ligase. Overall, roughly 30% of the sites incised by the endonuclease were ultimately sealed by the ligase. The resistance of some sites was due to interference with the ligase by the chromatin structure, as only 30-40% of the nicks created in chromatin by pancreatic DNase could be sealed by T4 or HeLa DNA ligases. The overall excision repair process did not detectably disrupt the chromatin structure, since the repair label was recovered in Form I DNA present in 75 S condensed minichromosomes. Although other factors might stimulate the rate of this repair process, it appears that the enzymes utilized could carry out excision repair of chromatin to a limit near that observed at the initial rate in mammalian cells in vivo.     

Characterization of a wide range base-damage-endonuclease activity of mammalian rpS3

Mammalian rpS3, a ribosomal protein S3 with a DNA repair endonuclease activity, nicks heavily UV-irradiated DNA and DNA containing AP sites. RpS3 calls for a novel endonucleolytic activity on AP sites generated from pyrimidine dimers by T4 pyrimidine dimer glycosylase activity. This study revealed that rpS3 cleaves the lesions including AP sites, thymine glycols, and other UV damaged lesions such as pyrimidine dimers. This enzyme does not have a glycosylase activity as predicted from its amino acid sequence. However, it has an endonuclease activity on DNA containing thymine glycol, which is exactly overlapped with UV-irradiated or AP DNAs, indicating that rpS3 cleaves phosphodiester bonds of DNAs containing altered bases with broad specificity acting as a base-damage-endonuclease. RpS3 cleaves supercoiled UV damaged DNA more efficiently than the relaxed counterpart, and the endonuclease activity of rpS3 was inhibited by MgCl2 on AP DNA but not on UV-irradiated DNA.     

Effect of photoreactivation on mutagenesis of lambda phage by ultraviolet light

There is disagreement in the literature as to whether the major mutagenic photoproduct induced in DNA by ultraviolet light is the cyclobutane dipyrimidine dimer, the most common product, or the [6-4] photoproduct, the next most frequent. In the experiments reported here, cyclobutane dimers were removed from irradiated lambda phage DNA by enzymatic photoreactivation, a process thought to affect no other photoproduct. Photoreactivation of lambda phage in host cells and of lambda DNA in solution reduced clear plaque mutants per plaque-forming unit by two-thirds, in host cells with a constant and near-maximal expression of the SOS functions required for mutagenesis. This result is interpreted to mean that removal of cyclobutane dimers in or near the mutated gene reduces mutation induced by ultraviolet light by two-thirds; therefore, cyclobutane dimers in the phage DNA are responsible for most observed mutations. DNA sequences of mutations in photoreactivated phage showed a smaller fraction of G.C to A.T transitions and a larger fraction of A.T to G.C transitions, compared to phage that were not photoreactivated. This suggests that cyclobutane dimers at TC and CC sites are particularly mutagenic.     

Pyrimidine dimers are not the principal pre-mutagenic lesions induced in lambda phage DNA by ultraviolet light

Experiments were performed to examine the role of cyclobutyl pyrimidine dimers in the process of mutagenesis by ultraviolet (u.v.) light. Lambda phage DNA was irradiated with u.v. and then incubated with an Escherichia coli photoreactivating enzyme, which monomerizes cyclobutyl pyrimidine dimers upon exposure to visible light. The photoreactivated DNA was packaged into lambda phage particles, which were used to infect E. coli uvr- host cells that had been induced for SOS functions by ultraviolet irradiation. Photoreactivation removed most toxic lesions from irradiated phage, but did not change the frequency of induction of mutations to the clear-plaque phenotype. This implies that cyclobutyl pyrimidine dimers can be lethal, but usually do not serve as sites of mutations in the phage. The DNA sequences of mutants derived from photoreactivated DNA showed that almost two-thirds (16/28) were transitions, the same fraction found for u.v. mutagenesis without photoreactivation. These results show that in this system, the lesion inducing transitions (the major type of u.v.-induced mutation) is not the cyclobutyl pyrimidine dimer; a strong candidate for a mutagenic lesion is the Pyr(6-4)Pyo photoproduct. On the other hand, photoreactivation of SOS-induced host cells before infection with u.v.-irradiated phage reduced mutagenesis substantially. In this case, photoreversal of cyclobutyl dimers serves to reduce expression of the SOS functions that are required in the process of targeted u.v. mutagenesis.     

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.     

Restriction enzyme cleavage of ultraviolet-damaged simian virus 40 and pBR322 DNA

Cleavage of specific DNA sequences by the restriction enzymes EcoRI, HindIII and TaqI was prevented when the DNA was irradiated with ultraviolet light. Most of the effects were attributed to cyclobutane pyrimidine dimers in the recognition sequences; the effectiveness of irradiation was directly proportional to the number of potential dimer sites in the DNA. Combining EcoRI with dimer-specific endonuclease digestion revealed that pyrimidine dimers blocked cleavage within one base-pair on the strand opposite to the dimer but did not block cleavage three to four base-pairs away on the same strand. These are the probable limits for the range of influence of pyrimidine dimers along the DNA, at least for this enzyme. The effect of irradiation on cleavage by TaqI seemed far greater than expected for the cyclobutane dimer yield, possibly because of effects from photoproducts flanking the tetranucleotide recognition sequence and the effect of non-cyclobutane (6-4)pyrimidine photoproducts involving adjacent T and C bases.     

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.     

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.     

Processive action of T4 endonuclease V on ultraviolet-irradiated DNA.

The action of the dimer-specific endonuclease V of bacteriophage T4 was studied on UV-irradiated, covalently-closed circular DNa. Form I ColE1 DNA preparations containing average dimer frequencies ranging from 2.5 to 35 pyrimidine dimers per molecule were treated with T4 endonuclease V and analysed by agarose gel electrophoresis. At all dimer frequencies examined, the production of form III DNA was linear with time and the double-strand scissions were made randomly on the ColE1 DNA genome. Since the observed fraction of form III DNA increased with increasing dimer frequency but the initial rate of loss of form I decreased with increasing dimer frequency, it was postulated that multiple single-strand scissions could be produced in a subset of the DNA population while some DNA molecules contained no scissions. When DNA containing an average of 25 dimers per circle was incubated with limiting enzyme concentrations, scissions appeared at most if not all dimmer sites in some molecules before additional strand scissions were produced in other DNA molecules. The results support a processive model for the interaction of T4 endonuclease V with UV-irradiated DNA.     

Repair of Single-Strand Deoxyribonucleic Acid Breaks in Ultraviolet Light-Irradiated Haemophilus influenzae

The wild-type strain and mutants of Haemophilus influenzae, sensitive or resistant to ultraviolet light (UV) as defined by colony-forming ability, were examined for their ability to perform the incision and rejoining steps of the deoxyribonucleic acid (DNA) dark repair process. Although UV-induced pyrimidine dimers are excised by the wild-type Rd and a resistant mutant BC200, the expected single-strand DNA breaks could not be detected on alkaline sucrose gradients. Repair of the gap resulting from excision must be rapid when experimental conditions described by us are employed. Single-strand DNA breaks were not detected in a UV-irradiated sensitive mutant (BC100) incapable of excising pyrimidine dimers, indicating that this mutant may be defective in a dimer-recognizing endonuclease. No single-strand DNA breaks were detected in a lysogen BC100(HP1c1) irradiated with a UV dose large enough to induce phage development in 80% of the cells.     

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)