Action of Single-strand-specific S1 Endonuclease on Locally Altered Structures in Double-stranded DNA

The cleavage of double-stranded DNA by S1 endonuclease was studied by sucrose density gradient centrifugation analysis. The enzyme introduced no single-strand breaks into native T7 DNA under conditions where heat-denatured T7 DNA was completely degraded. By using enzyme at about 6 times higher the amount required for complete degradation of the heat-denatured DNA, it was possible to make a few single-strand breaks in native T7 DNA. Under the conditions where native T7 DNA is absolutely resistant to the enzyme, the susceptibility of locally altered structures naturally present and/or artificially induced in native double-stranded DNA to the enzyme was studied. It was evidenced that S1 endonuclease can cleave circular covalently closed, superhelical fl RFI DNA, depurinated T7 DNA, bleomycin-treated T7 DNA containing internal single-strand breaks, but not cleave intercalating drug-bound T7 DNA.     

Two distinct human DNA diesterases that hydrolyze 3''-blocking deoxyribose fragments from oxidized DNA.

Mammalian cells were investigated for enzymes that help correct oxidative damages in DNA. We focused on 3'-repair diesterases, which process DNA ends at oxidative strand breaks by removing 3'-blocking fragments of deoxyribose that prevent DNA repair synthesis. Two enzymes were found in a variety of mouse, bovine and human tissues and cultured cells. The two activities were purified to differing degrees from HeLa cells. One enzyme had the properties of the known HeLa AP endonuclease (Mr approximately 38,000, with identical substrate specificity and reaction requirements, and cross-reactivity with anti-HeLa AP endonuclease antiserum) and is presumed identical to that protein. The second activity did not interact with anti-HeLa AP endonuclease antibodies and had relatively less AP endonuclease activity. This second enzyme may have been detected in other studies but never characterized. In addition to the 3'-repair diesterase and AP endonuclease, this partially purified preparation also harbored DNA 3'-phosphatase and 3'-deoxyribose diesterase activities. It is unknown whether all activities detected in the second preparation are due to a single protein, although activity against undamaged DNA was not detected. The in vivo roles of these two widely distributed 3'-repair diesterase/AP endonucleases have not been determined, but with the characterizations presented here such questions may now be focused.     

Fluorescence-based incision assay for human XPF-ERCC1 activity identifies important elements of DNA junction recognition

The structure-specific endonuclease activity of the human XPF-ERCC1 complex is essential for a number of DNA processing mechanisms that help to maintain genomic integrity. XPF-ERCC1 cleaves DNA structures such as stem-loops, bubbles or flaps in one strand of a duplex where there is at least one downstream single strand. Here, we define the minimal substrate requirements for cleavage of stem-loop substrates allowing us to develop a real-time fluorescence-based assay to measure endonuclease activity. Using this assay, we show that changes in the sequence of the duplex upstream of the incision site results in up to 100-fold variation in cleavage rate of a stem-loop substrate by XPF-ERCC1. XPF-ERCC1 has a preference for cleaving the phosphodiester bond positioned on the 3'-side of a T or a U, which is flanked by an upstream T or U suggesting that a T/U pocket may exist within the catalytic domain. In addition to an endonuclease domain and tandem helix-hairpin-helix domains, XPF has a divergent and inactive DEAH helicase-like domain (HLD). We show that deletion of HLD eliminates endonuclease activity and demonstrate that purified recombinant XPF-HLD shows a preference for binding stem-loop structures over single strand or duplex alone, suggesting a role for the HLD in initial structure recognition. Together our data describe features of XPF-ERCC1 and an accepted model substrate that are important for recognition and efficient incision activity.     

Partial purification and properties of a DNA-binding protein from nuclei of cells infected with polyoma virus.

A DNA-binding protein has been purified from nuclei of 3T3 cells infected with polyoma virus. The assay used to detect this activity measures the amount of double-stranded DNA retained on a nitrocellulose membrane filter in the presence of binding protein. The interaction between DNA and protein is salt dependent and occurs optimally at 0.8 M NaCl. The isolated protein can bind to both circular and linear duplex DNA. Incubation of the binding protein with PM2 or polyoma DNA results in the formation of a fast sedimenting DNA structure in neutral sucrose gradients. The isolated binding protein is also capable of producing a considerable stimulation of both Escherichia coli (Pol I) and T4 DNA polymerase activities when either single-stranded or intact, native T7 DNA is used as the template. The binding protein itself is free of detectable DNA polymerase or nuclease activity.     

Studies on an Endonuclease Activity Associated with the Bacteriophage T7 DNA-Membrane Complex

Infection of Escherichia coli with bacteriophage T7 results in the formation of an endonuclease which is selectively associated with the T7 DNA-membrane complex. A specificity of association with the complex is indicated by the finding that the enzyme is completely resolved from a previously described T7 endonuclease I. When membrane complexes containing (3)H-labeled in vivo synthesized DNA are incubated in the standard reaction mixture a specific cleavage product is formed which is about one-fourth the size of T7 DNA. The endonuclease associated with the complex produces a similar cleavage product after extensive incubation with native T7 DNA or T7 concatemers. Degradation of concatemers occurs by a mechanism in which the DNA is converted to molecules one-half the size of T7. This product is in turn converted to fragments one-fourth the size of mature phage DNA. The endonuclease is not present in membrane complexes from uninfected cells or cells infected with gene 1 mutants. The enzyme activity is, however, present in cells infected with mutants defective in T7 DNA synthesis or maturation.     

The characterization of a mammalian DNA structure-specific endonuclease.

The repair of some types of DNA double-strand breaks is thought to proceed through DNA flap structure intermediates. A DNA flap is a bifurcated structure composed of double-stranded DNA and a displaced single-strand. To identify DNA flap cleaving activities in mammalian nuclear extracts, we created an assay utilizing a synthetic DNA flap substrate. This assay has allowed the first purification of a mammalian DNA structure-specific nuclease. The enzyme described here, flap endonuclease-1 (FEN-1), cleaves DNA flap strands that terminate with a 5' single-stranded end. As expected for an enzyme which functions in double-strand break repair flap resolution, FEN-1 cleavage is flap strand-specific and independent of flap strand length. Furthermore, efficient flap cleavage requires the presence of the entire flap structure. Substrates missing one strand are not cleaved by FEN-1. Other branch structures, including Holliday junctions, are also not cleaved by FEN-1. In addition to endonuclease activity, FEN-1 has a 5'-3' exonuclease activity which is specific for double-stranded DNA. The endo- and exonuclease activities of FEN-1 are discussed in the context of DNA replication, recombination and repair.     

ATP phosphohydrolase (ATPase) activity of a polyoma virus T antigen

Among the various polyoma virus T antigens which have so far been identified, only the large-T and a 63 000-Mr polypeptide were found to bind to double-stranded calf thymus DNA. The proteins were not retained on single-stranded DNA-cellulose columns, and a purification procedure was designed on the basis of this observation. Purified fractions (approx. 1000-fold) exhibited an enzymatic activity which converts ATP into ADP and Pi. This activity was quantitatively inhibited after preincubation in the presence of anti-(polyoma T antigen) immunoglobulins and was shown to be dependent on a virus-coded gene product (alpha gene) on the basis of the following observations: (a) ATPase activity from cells infected with tsa mutants of polyoma was reduced after a shift to the restrictive temperature; (b) the enzyme purified from tsa-infected cells maintained at the permissive temperature was more thermolabile in vitro than that prepared in parallel from cells infected with wild-type virus.     

Cloning, expression, and purification of gene 3 endonuclease from bacteriophage T7

The structural gene for the single-stranded endonuclease coded for by gene 3 of bacteriophage T7 has been cloned in pGW7, a derivative of the plasmid pBR322, which contains the lambda PL promoter and the gene for the temperature-sensitive lambda repressor, cI857. The complete gene 3 DNA sequence has been placed downstream of the PL promoter, and the endonuclease is overproduced by temperature induction at mid-log phase of Escherichia coli carrying the recombinant plasmid pTP2. Despite the fact that cell growth rapidly declines due to toxic effects of the excess endonuclease, significant amounts of the enzyme can be isolated in nearly homogeneous form from the induced cells. An assay of nuclease activity has been devised using gel electrophoresis of the product DNA fragments from DNA substrates. These assays show the enzyme to have an absolute requirement for Mg(II) (10 mM), a broad pH optimum near pH 7, but significant activity from pH 3 to pH 9, and a 10-100-fold preference for single-stranded DNA (ssDNA). The enzyme is readily inactivated by ethylenediaminetetraacetic acid or high salt. The differential activity in favor of ssDNA can be exploited to map small single-stranded regions in double-stranded DNAs as shown by cleavage of the melted region of an open complex of T7 RNA polymerase and its promoter.     

Purification and characterization of HeLa endonuclease R. A G-specific mammalian endonuclease

We previously reported a double-stranded endonuclease from HeLa cells, endonuclease R (endo R), which specifically cleaves duplex DNA at sites rich in G.C base pairs. In this report we describe the purification of endo R to near homogeneity by conventional and affinity chromatography. The molecular mass of the active form of endo R is approximately 115-125 kDa. SDS-gel electrophoresis reveals a major protein species of 100 kDa. The enzyme requires Mg2+ as a cofactor and is equally active on closed circular and linear duplex DNA substrates that contain G-rich sequences. A 50% reduction in cleavage activity is observed with Ca2+ ions and no double-stranded cleavage occurs with Zn2+. Use of Mn2+ causes an altered specificity at low concentrations of enzyme or divalent metal ion and nonspecific degradation of the substrate at higher concentrations. Endo R is strongly inhibited by sodium or potassium chloride and exhibits a wide pH optimum of 6.0-9.0. The pI of the enzyme is between 6.5 and 7.0. A 2-fold stimulation is observed with the addition of dGTP or dATP but specific cleavage is inhibited by ATP at an equivalent concentration. Cleavage activity is competitively inhibited 10-fold more efficiently by single-stranded poly(dG)12 than by other DNA competitors. The ends of endo R cleavage products contain 5'-phosphate and 3'-hydroxyl groups, and a significant portion of these products were substrates for T4 DNA ligase. Endo R appears to be a previously uncharacterized mammalian endonuclease.     

Stimulated activity of human topoisomerases IIalpha and IIbeta on RNA-containing substrates.

Eukaryotic topoisomerase II is a dimeric nuclear enzyme essential for DNA metabolism and chromosome dynamics. Central to the activities of the enzyme is its ability to introduce transient double-stranded breaks in the DNA helix, where the two subunits of the enzyme become covalently attached to the generated 5'-ends through phosphotyrosine linkages. Here, we demonstrate that human topoisomerases IIalpha and IIbeta are able to cleave ribonucleotide-containing substrates. With suicide substrates, which are partially double-stranded molecules containing a 5'-recessed strand, cleavage of both strands was stimulated approximately 8-fold when a ribonucleotide rather than a deoxyribonucleotide was present at the scissile phosphodiester of the recessed strand. The existence of a ribonucleotide at the same position in a normal duplex substrate also enhanced topoisomerase II-mediated cleavage, although to a lesser extent. The enzyme covalently linked to the 5'-ribonucleotide in the cleavage complex efficiently performed ligation, and ligation occurred equally well to acceptor molecules terminated by either a 3'-ribo- or deoxyribonucleotide. Besides the enhanced topoisomerase II-mediated cleavage of ribonucleotide-containing substrates, cleavage of such substrates could be further stimulated by ATP or antitumor drugs. In conclusion, the observed in vitro activities of the human topoisomerase II isoforms indicate that the enzymes can operate on RNA or RNA-containing substrates and thus might possess an intrinsic RNA topoisomerase activity, as has previously been demonstrated for Escherichia coli topoisomerase III.     

Human HeLa cell enzymes that remove phosphoglycolate 3''-end groups from DNA.

We have purified three chromatographically distinct human enzyme activities from HeLa cells, that are capable of converting bleomycin-treated DNA into a substrate for E. coli DNA polymerase I. The bleomycin-treated DNA substrate used in this study has been characterized via a 32P-postlabeling assay and shown to contain strand breaks with 3'-phosphoglycolate termini as greater than 95% of the detectable dose-dependent lesions. The purified HeLa cell enzymes were shown to be capable of removing 3'-phosphoglycolates from this substrate. Also 3'-phosphoglycolate removal and nucleotide incorporation were enzyme dependent. In addition, all three Hela cell enzymes have been determined to possess Class II AP endonuclease activity. The enzymes lack 3'----5' exonuclease activity and are, therefore, dissimilar to exonuclease III--an E. coli enzyme that can remove 3'-phosphoglycolate.     

Recognition of (dG)n.(dC)n sequences by endonuclease G. Characterization of the calf thymus nuclease

We report the purification of endonuclease G (Ruiz-Carrillo, A., and Renaud, J. (1987) EMBO J. 6, 401-407) from calf thymus nuclei and whole tissue. The enzyme has been enriched 29,000-fold, and the activity was unambiguously identified with a 26-kDa protein after renaturation following sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The native nuclease behaves as a 50-kDa species by gel filtration, suggesting that it is composed of two subunits, presumably identical. In terms of absolute amounts, endonuclease G (endo G) is a nuclear enzyme although it was also detected in purified mitochondria. Endo G is highly specific for (dG)n.(dC)n tracts in DNA, nicking either strand of relaxed substrates with similar kinetics. The sensitivity of the homopolymer tracts is proportional to their length (from n = 8 to 29), insofar as the flanking sequences are constant. However, the overall rate of cleavage is influenced by the composition of the flanking DNA. Minor cleavage sites contain shorter (dG)n.(dC)n clusters (n = 3-7). Endo G efficiently cleaves (dC)n but not (dG)n runs in single-stranded DNA, suggesting that it may recognize an asymmetric strand conformation of the homopolymer tracts. Endo G does not recognize other homo(co)-polymer sequences or cruciform structures in DNA.     

A new endonuclease from Escherichia coli acting at apurinic sites in DNA.

A new DNA endonuclease has been purified 3000-fold from Escherichia coli. The enzyme specifically catalyzes the formation of single strand breaks at apurinic and apyrimidinic sites in DNA, but has no activity on intact or single-stranded DNA. Further, the enzyme shows little or no activity on heavily ultraviolet-irradiated DNA, but cleaves x-irradiated DNA, presumably at apurinic and apyrimidinic sites introduced by the radiation treatment. The enzyme, which is tentatively named endonuclease IV, has no detectable associated exonuclease or DNA N-glycosidase activity and does not seem to be identical with any previously known E. coli endonuclease. Endonuclease IV has no Mg2+ requirement, and is fully active in the presence of EDTA. Enzyme activity is stimulated by 0.2 to 0.3 M NaCl and is unusually salt-resistant. Further, the enzyme is fairly heat-stable, and is not inhibited by tRNA. The sidimentation coefficient, S(o)20,w, is 3.4 S. It seems that endonuclease IV is active in DNA repair.     

BALB/3T3 cells infected by the ts3 mutant of polyoma virus fail to accumulate virus-specific early RNA at the nonpermissive temperature.

We measured the accumulation of virus-specific early RNA in BALB/3T3 cells infected by the ts3 mutant of polyoma virus by annealing cytoplasmic RNA from infected cells to purified, radiolabeled, "early" strand of polyoma DNA. Cells infected by the ts3 mutant fail to accumulate virus-specific early RNA at the nonpermissive temperature.     

A possible role of Ku in mediating sequential repair of closely opposed lesions

One of the hallmarks of ionizing radiation exposure is the formation of clustered damage that includes closely opposed lesions. We show that the Ku70/80 complex (Ku) has a role in the repair of closely opposed lesions in DNA. DNA containing a dihydrouracil (DHU) close to an opposing single strand break was used as a model substrate. It was found that Ku has no effect on the enzymatic activity of human endonuclease III when the substrate DNA contains only DHU. However, with DNA containing a DHU that is closely opposed to a single strand break, Ku inhibited the nicking activity of human endonuclease III as well as the amount of free double strand breaks induced by the enzyme. The inhibition on the formation of a free double strand break by Ku was found to be much greater than the inhibition of human endonuclease III-nicking activity by Ku. Furthermore, there was a concomitant increase in the formation of Ku-DNA complexes when endonuclease III was present. Similar results were also observed with Escherichia coli endonuclease III. These results suggest that Ku reduces the formation of endonuclease III-induced free double strand breaks by sequestering the double strand breaks formed as a Ku-DNA complex. In doing so, Ku helps to avoid the formation of the intermediary free double strand breaks, possibly helping to reduce the mutagenic event that might result from the misjoining of frank double strand breaks.     

Interaction of EcoRII restriction and modification enzymes with synthetic DNA fragments. V. Study of single-strand cleavages.

Concatemer DNA duplexes which contain at the EcoRII restriction endonuclease cleavage sites (formula; see text) phosphodiester, phosphoamide or pyrophosphate internucleotide bonds have been synthesized. It has been shown that this enzyme did not cleave the substrate at phosphoamide bond. EcoRII endonuclease catalyzes single-strand cleavages both in dA- and dT-containing strands of the recognition site if the cleavage of the other strand has been blocked by modification of scissile bond or if the other strand has been cleaved. This enzyme interacts with both strands of the DNA recognition site, each of them being cleaved independently on the cleavage of another one. Nucleotide sequences flanking the EcoRII site on both sides are necessary for effective cleavage of the substrate.     

den V gene of bacteriophage T4 codes for both pyrimidine dimer-DNA glycosylase and apyrimidinic endonuclease activities.

Recent studies have shown purified preparations of phage T4 UV DNA-incising activity (T4 UV endonuclease or endonuclease V of phage T4) contain a pyrimidine dimer-DNA glycosylase activity that catalyzes hydrolysis of the 5' glycosyl bond of dimerized pyrimidines in UV-irradiated DNA. Such enzyme preparations have also been shown to catalyze the hydrolysis of phosphodiester bonds in UV-irradiated DNA at a neutral pH, presumably reflecting the action of an apurinic/apyrimidinic endonuclease at the apyrimidinic sites created by the pyrimidine dimer-DNA glycosylase. In this study we found that preparations of T4 UV DNA-incising activity contained apurinic/apyrimidinic endonuclease activity that nicked depurinated form I simian virus 40 DNA. Apurinic/apyrimidinic endonuclease activity was also found in extracts of Escherichia coli infected with T4 denV+ phage. Extracts of cells infected with T4 denV mutants contained significantly lower levels of apurinic/apyrimidinic endonuclease activity; these levels were no greater than the levels present in extracts of uninfected cells. Furthermore, the addition of DNA containing apurinic or apyrimidinic sites to reactions containing UV-irradiated DNA and T4 enzyme resulted in competition for pyrimidine dimer-DNA glycosylase activity against the UV-irradiated DNA. On the basis of these results, we concluded that apurinic/apyrimidinic endonuclease activity is encoded by the denV gene of phage T4, the same gene that codes for pyrimidine dimer-DNA glycosylase activity.     

Resistance of 3'-phosphoglycolate DNA ends to digestion by mammalian DNase III

An essential step in the repair of free radical-mediated DNA strand breaks is the removal of sugar fragments such as phosphoglycolate from the 3' termini. While the abasic endonuclease Ape1 can remove phosphoglycolate from single-strand breaks in double-stranded DNA, an enzyme capable of removing it from 3' overhangs of double-strand breaks has yet to be identified. We therefore tested DNase III, the predominant 3' --> 5' exonuclease in mammalian cell extracts, for possible 3'-phosphoglycolate-removing activity. However, all 3'-phosphoglycolate substrates, as well as a 3'-phosphate substrate, were resistant to DNase III under conditions in which the analogous 3'-hydroxyl substrates were extensively degraded. The DNA end-binding protein Ku (an equimolar mixture of Ku70, now known as G22P1, and Ku86, now known as XRCC5) did not alter the resistance of the 3'-phosphoglycolate substrates, but the protein modulated the susceptibility of 3'-hydroxyl substrates, allowing DNase III to remove a 3' overhang but inhibiting digestion of the double-stranded portion of the substrate.     

Defining amino acid residues involved in DNA-protein interactions and revelation of 3'-exonuclease activity in endonuclease V

Endonuclease V is an enzyme that initiates a conserved DNA repair pathway by making an endonucleolytic incision at the 3' side one nucleotide from a deaminated base lesion. Site-directed mutagenesis analysis was conducted at seven conserved motifs of the thermostable Thermotoga maritima endonuclease V to probe for residues that affect DNA-protein interactions. Y80, G83, and L85 in motif III, H116 and G121 in motif IV, A138 in motif V, and S182 in motif VI affect binding of both the double-stranded inosine-containing DNA substrate and the nicked double-stranded inosine-containing DNA product, resulting in multiple enzymatic turnovers. The substantially reduced DNA cleavage activity observed in G113 in motif IV and G136 in motif V can be partly attributed to their defect in metal cofactor coordination. Alanine substitution at amino acid 118 primarily reduces the level of binding to the nicked product, suggesting that R118 plays a significant role in postcleavage DNA-protein interaction. Binding and cleavage analyses of multiple mutants at positions Y80 and H116 underscore the role these residues play in protein-DNA interaction and implicate their potential involvement as a hydrogen bond donor in recognition of deaminated DNA bases. DNA cleavage analysis using mutants defective in DNA binding reveals a novel 3'-exonuclease activity in endonuclease V. An alternative model is proposed that entails lesion specific cleavage and endonuclease to 3'-exonuclease mode switch by endonuclease V for removal of deaminated base lesions during endonuclease V-mediated repair.     

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

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