Drosophila Rrp1 complements E. coli xth nfo mutants: protection against both oxidative and alkylation-induced DNA damage.

Drosophila Rrp1 protein has four tightly associated enzymatic activities: DNA strand transfer, ssDNA renaturation, dsDNA 3'-exonuclease and apurinic/apyrimidinic (AP) endonuclease. The carboxy-terminal region of Rrp1 is homologous to Escherichia coli exonuclease III and several eukaryotic AP endonucleases. All members of this protein family cleave abasic sites. Rrp1 protein was expressed under the control of the E. coli RNA polymerase tac promoter (pRrp1-tac) in two repair deficient E. coli strains (BW528 and LG101) lacking both exonuclease III (xth) and endonuclease IV (nfo). Rrp1 confers resistance to killing by oxidative, antitumor and alkylating agents that damage DNA (hydrogen peroxide, t-butylhydroperoxide, bleomycin, methyl methanesulfonate, and mitomycin C). Complementation of the repair deficiency by Rrp1 provides up to a two log increase in survival and requires the C-terminal nuclease region of Rrp1, but not its N-terminal region. The AP endonuclease activity in extracts from the repair deficient strain LG101 is increased up to 12-fold when the strain contains pRrp1-tac. These results indicate that pRrp1-tac directs the synthesis of active enzyme, and that the nuclease activities of Rrp1 are likely to be the cause of the increased resistance to DNA damage of the mutant cells.     

Differential effect of N-carboxymethylisatoylation on the DNA polymerase activity, the 5' leads to 3'-exonuclease activity and the 3' leads to 5'-exonuclease activity of DNA polymerase I of Escherichia coli

Treatment with native DNA polymerase I of Escherichia coli with the acylating agent N-carboxymethylisatoic acid anhydride (NCMIA) results under specific conditions in a rapid loss of polymerase activity, an increase in 5' leads to 3'-exonuclease activity and in unchanged 3' leads to 5'-exonuclease activity. When a nucleoside triphosphate and Mg2+ was present the polymerase activity was completely protected against the effect of NCMIA. Treatment with higher concentration of the acylating agent under these conditions led to a loss of 3' leads to 5'-exonuclease activity without any appreciable loss of polymerase activity. Treatment with NCMIA of the two catalytically active fragments of the enzyme led to very similar results. In this case both the polymerase activity and the 3' leads to 5'-exonuclease activity deteriorated more rapidly on treatment with the acylating reagent. The increase in 5' leads to 3'-exonuclease activity as a result of modification of the native enzyme appeared to be due to a change in the optimum conditions with regard to concentration of the assay buffer used. These changes are very similar to those seen when the polymerase is cleaved by limited proteolysis. From the results obtained it is concluded that NCMIA reacts primarily with a site at or near the triphosphate-Mg2+ complex binding site, leading to an almost complete loss of polymerase activity. The acylating reagent reacts also with another group on the native enzyme resulting in a modification of the 5' leads to 3'-exonuclease activity, and at high concentrations with a group leading to a slow loss of 3' leads to 5'-exonuclease activity.     

Action of Escherichia coli and human 5'----3' exonuclease functions at incised apurinic/apyrimidinic sites in DNA.

The 5'----3' exonuclease activity of E. coli DNA polymerase I and a related enzyme activity in mammalian cell nuclei, DNase IV, are unable to catalyse the excision of free deoxyribose-phosphate from apurinic/apyrimidinic (AP) sites incised by an AP endonuclease. Instead, the sugar phosphate residue is slowly released as part of a short oligonucleotide. These products have been characterised as dimers and trimers by comparison of their retention time on reverse-phase HPLC with reference compounds prepared by acid depurination of a dinucleotide, trinucleotide and tetranucleotide containing a 5'-terminal dAMP residue. The similar mode of action of these enzymes at 5'-incised AP sites provides an explanation for the minority of repair patches larger than one nucleotide observed when AP sites are repaired by E. coli and mammalian cell extracts in vitro and strengthens the functional analogy between the two activities.     

Properties of herpes simplex virus DNA polymerase and characterization of its associated exonuclease activity.

Herpes simplex virus (HSV) DNA polymerase was isolated on a large-scale from African green monkey kidney cells infected with HSV type 1 (HSV-1) strain Angelotti. After DNA-cellulose chromatography the enzyme showed a specific activity of 48,000 units/mg protein. Three major single polypeptides with molecular weights of 144,000, 74,000 and 29,000 were copurified with the enzyme activity at the DNA-cellulose ste. By its chromatographic behavior and by template studies, the HSV DNA polymerase activity was clearly distinguishable from cellular alpha, beta and gamma DNA polymerase activities. Two exonucleolytic activities were found in the DNA-cellulose enzyme preparation. The main exonucleolytic activity, which degraded both single-stranded and double-stranded DNA to deoxynucleoside 5'-monophosphates, was separated by subsequent velocity sedimentation. The remaining exonucleolytic activity was not separable from the HSV DNA polymerase by several chromatographic steps and by velocity sedimentation at high ionic strength. This novel exonuclease and HSV DNA polymerase were equally sensitive both to phosphonoacetic acid and Zn2+ ions, inhibitors of the viral polymerase. Similar to the 3'-to-5'-exonuclease of procaryotic DNA polymerases and mammalian DNA polymerase delta, the HSV-polymerase-associated exonuclease catalyzed the removal of 3'-terminal nucleotides from the primer/template as well as the template-dependent conversion of deoxynucleoside triphosphates to monophosphates.     

Metal binding to DNA polymerase I, its large fragment, and two 3',5'-exonuclease mutants of the large fragment

DNA polymerase I (Pol I) is an enzyme of DNA replication and repair containing three active sites, each requiring divalent metal ions such as Mg2+ or Mn2+ for activity. As determined by EPR and by 1/T1 measurements of water protons, whole Pol I binds Mn2+ at one tight site (KD = 2.5 microM) and approximately 20 weak sites (KD = 600 microM). All bound metal ions retain one or more water ligands as reflected in enhanced paramagnetic effects of Mn2+ on 1/T1 of water protons. The cloned large fragment of Pol I, which lacks the 5',3'-exonuclease domain, retains the tight metal binding site with little or no change in its affinity for Mn2+, but has lost approximately 12 weak sites (n = 8, KD = 1000 microM). The presence of stoichiometric TMP creates a second tight Mn2+ binding site or tightens a weak site 100-fold. dGTP together with TMP creates a third tight Mn2+ binding site or tightens a weak site 166-fold. The D424A (the Asp424 to Ala) 3',5'-exonuclease deficient mutant of the large fragment retains a weakened tight site (KD = 68 microM) and has lost one weak site (n = 7, KD = 3500 microM) in comparison with the wild-type large fragment, and no effect of TMP on metal binding is detected. The D355A, E357A (the Asp355 to Ala, Glu357 to Ala double mutant of the large fragment of Pol I) 3',5'-exonuclease-deficient double mutant has lost the tight metal binding site and four weak metal binding sites. The binding of dGTP to the polymerase active site of the D355A,E357A double mutant creates one tight Mn2+ binding site with a dissociation constant (KD = 3.6 microM), comparable with that found on the wild-type enzyme, which retains one fast exchanging water ligand. Mg2+ competes at this site with a KD of 100 microM. It is concluded that the single tightly bound Mn2+ on Pol I and a weakly bound Mn2+ which is tightened 100-fold by TMP are at the 3',5'-exonuclease active site and are essential for 3',5'-exonuclease activity, but not for polymerase activity. Additional weak Mn2+ binding sites are detected on the 3',5'-exonuclease domain, which may be activating, and on the polymerase domain, which may be inhibitory. The essential divalent metal activator of the polymerase reaction requires the presence of the dNTP substrate for tight metal binding indicating that the bound substrate coordinates the metal.(ABSTRACT TRUNCATED AT 400 WORDS)     

Determination of DNA polymerase and nuclease activities of DNA-dependent polymerases using fluorescence detection under real-time conditions

A new method is proposed for estimation of polymerase activities using fluorescence detection during isothermal reaction. The method allows simultaneous determination of DNA-dependent DNA polymerase and 5'-3'-exonuclease activities using amplifiers supplied with an optical module for fluorescence detection under real-time conditions. Different primer-template combinations used as polymerase substrates were compared. Primer elongation (polymerase reaction) is detected by changes in SYBR Green I fluorescence upon binding to dsDNA during reaction; nuclease activities are detected by changes in fluorescence due to cleavage of the probe, containing the reporter fluorophore and fluorescence quencher, and hybridized in advance to the template single-stranded region. It was also shown that the method can be used for determination of relative activities of DNA polymerase preparations, estimation of temperature-time dissociation parameters of polymerase complexes with specific antibodies to its active center, and analysis of effects of inhibitors and activators of different nature on reaction rates of dsDNA polymerization and 5'-3'-exonuclease cleavage by polymerase. The method can be also used for estimation of endonuclease activities of DNA polymerases.     

Rrp5p, a trans-acting factor in yeast ribosome biogenesis, is an RNA-binding protein with a pronounced preference for U-rich sequences

Rrp5p is a trans-acting factor important for biogenesis of both the 40S and 60S subunit of the Saccharomyces cerevisiae ribosome. The protein contains 12 tandemly repeated S1 RNA binding motifs in its N-terminal region, suggesting the ability to interact directly with the pre-rRNA. In vitro binding studies, using immunopurified Rrp5p and in vitro transcribed, 32P-UTP-labeled RNA fragments, revealed that Rrp5p is a general RNA-binding protein with a strong preference for single-stranded sequences rich in uridines. Co-immunoprecipitation studies in yeast cells expressing ProtA-tagged Rrp5p showed that the protein is still associated with pre-ribosomal particles containing 27SA2 pre-rRNA but not with particles containing the 27SB precursor. Thus, Rrp5p appears to dissociate from the 66S pre-ribosome upon or immediately after further processing of 27SA2 pre-rRNA, suggesting the presence of (an) important binding site(s) within the 3'-terminal portion of ITS1. The location of these possible binding site(s) was further delimited using rrp2-1 mutant cells, which accumulate the 5'-extended 5.8S pre-rRNA species. The results indicate that association of Rrp5p with the pre-ribosome is abolished upon removal of a 30-nt region downstream from site A2, which contains two short, single-stranded U stretches. Sequence comparison shows that only the most 5' of these two U-rich stretches is conserved among yeast species whose ITS1 can functionally replace the S. cerevisiae spacer. The implications for the role of Rrp5p in yeast ribosome biogenesis are discussed.     

Modulation of the 3'-->5'-exonuclease activity of human apurinic endonuclease (Ape1) by its 5'-incised Abasic DNA product

The major abasic endonuclease of human cells, Ape1 protein, is a multifunctional enzyme with critical roles in base excision repair (BER) of DNA. In addition to its primary activity as an apurinic/apyrimidinic endonuclease in BER, Ape1 also possesses 3'-phosphodiesterase, 3'-phosphatase, and 3'-->5'-exonuclease functions specific for the 3' termini of internal nicks and gaps in DNA. The exonuclease activity is enhanced at 3' mismatches, which suggests a possible role in BER for Ape1 as a proofreading activity for the relatively inaccurate DNA polymerase beta. To elucidate this role more precisely, we investigated the ability of Ape1 to degrade DNA substrates that mimic BER intermediates. We found that the Ape1 exonuclease is active at both mismatched and correctly matched 3' termini, with preference for mismatches. In our hands, the exonuclease activity of Ape1 was more active at one-nucleotide gaps than at nicks in DNA, even though the latter should represent the product of repair synthesis by polymerase beta. However, the exonuclease activity was inhibited by the presence of nearby 5'-incised abasic residues, which result from the apurinic/apyrimidinic endonuclease activity of Ape1. The same was true for the recently described exonuclease activity of Escherichia coli endonuclease IV. Exonuclease III, the E. coli homolog of Ape1, did not discriminate among the different substrates. Removal of the 5' abasic residue by polymerase beta alleviated the inhibition of the Ape1 exonuclease activity. These results suggest roles for the Ape1 exonuclease during BER after both DNA repair synthesis and excision of the abasic deoxyribose-5-phosphate by polymerase beta.     

Mechanism of DNA strand nicking at apurinic/apyrimidinic sites by Escherichia coli [formamidopyrimidine]DNA glycosylase.

Escherichia coli [formamidopyrimidine]DNA glycosylase catalyses the nicking of both the phosphodiester bonds 3' and 5' of apurinic or apyrimidinic sites in DNA so that the base-free deoxyribose is replaced by a gap limited by 3'-phosphate and 5'-phosphate ends. The two nickings are not the results of hydrolytic processes; the [formamidopyrimidine]DNA glycosylase rather catalyses a beta-elimination reaction that is immediately followed by a delta-elimination. The enzyme is without action on a 3'-terminal base-free deoxyribose or on a 3'-terminal base-free unsaturated sugar produced by a beta-elimination reaction nicking the DNA strand 3' to an apurinic or apyrimidinic site.     

Further characterization of DNA helicase activity of mouse DNA-dependent adenosinetriphosphatase B (DNA helicase B)

The DNA helicase activity of DNA-dependent ATPase B purified from mouse FM3A cells [Seki, M., Enomoto, T., Hanaoka, F., & Yamada, M. (1987) Biochemistry 26, 2924-2928] has been further characterized. The helicase activity was assayed with partially duplex DNA substrates in which oligonucleotides to be released by the enzyme were radiolabeled. Oligonucleotides with or without phosphate at the 5' termini or with a deoxy- or dideoxyribose at the 3'-terminal nucleotides were displaced by this enzyme with essentially the same efficiency and with the same ATP (and dATP) and Mg2+ requirements. Thus, there was no strict structure requirement for both ends of duplex regions of substrates to be unwound by the enzyme. Shorter strands were released more readily than longer strands up to the length of 140 bases. The attachment of the enzyme to a single-stranded DNA region was a prerequisite for the neighboring duplex to be unwound; the enzyme-catalyzed unwinding was inhibited competitively by the coaddition of single-stranded DNAs which act as cofactors of the ATPase activity. Their activities as the inhibitor of helicase were well correlated with those as the cofactor of ATPase. The helicase B was found to migrate along single-stranded DNA in the 5' to 3' direction by the use of single strands with short duplex regions at both 3' and 5' ends as substrate. A possible role of this enzyme in DNA replication in mammalian cells is discussed.     

Interactions of azidothymidine triphosphate with the cellular DNA polymerases alpha, delta, and epsilon and with DNA primase.

The interactions of azidothymidine triphosphate, the metabolically active form of the anti-AIDS drug azidothymidine (zidovudine), with the cellular DNA polymerases alpha, delta, and epsilon, as well as with the RNA primer-forming enzyme DNA primase were studied in vitro. DNA polymerase alpha was shown to incorporate azidothymidine monophosphate into a growing polynucleotide chain. This occurred 2000-fold slower than the incorporation of natural dTTP. Despite the ability of polymerase alpha to use azidothymidine triphosphate as an alternate substrate, this compound was only marginally inhibitory to the enzyme (Ki greater than 1 mM). Furthermore, the DNA primase activity associated with DNA polymerase alpha was barely inhibited by azidothymidine triphosphate (Ki greater than 1 mM). Inhibition was more pronounced for DNA polymerases delta and epsilon. The type of inhibition was competitive with respect to dTTP, with Ki values of 250 and 320 microM, respectively. No incorporation of azidothymidine monophosphate was detectable with these two DNA polymerases because their associated 3'- to 5'-exonuclease activities degraded primer molecules prior to any measurable elongation. Template-primer systems with a preformed 3'-azidothymidine-containing primer terminus inhibited the three replicative polymerases rather potently. DNA polymerase alpha was inhibited with a Ki of 150 nM and polymerases delta and epsilon with Ki values of 25 and 20 nM, respectively. The type of inhibition was competitive with respect to the unmodified substrate poly(dA).oligo(dT) for all DNA polymerases tested. Performed 3'-azidothymidine-containing primers hybridized to poly(dA) were rather resistant to degradation by the 3'- to 5'-exonuclease of DNA polymerases epsilon and more susceptible to the analogous activity that copurified with DNA polymerase delta. It is proposed that the repair of 3'-azidothymidine-containing primers might become rate-limiting for the process of DNA replication in cells that have been treated with azidothymidine triphosphate.     

Cleavage of double-stranded DNA by the intrinsic 3'-5' exonuclease activity of DNA polymerase B1 from the hyperthermophilic archaeon Sulfolobus solfataricus at high temperature

The substrate requirement of the intrinsic 3'-5' exonuclease of DNA polymerase B1 from the hyperthermophilic archaeon Sulfolobus solfataricus P2 (Sso polB1) was investigated. Sso polB1 degraded both single-stranded (ss) and double-stranded (ds) DNA at similar rates in vitro at temperatures of physiological relevance. No difference was found in the cleavage of 3'-recessive, 3'-protruding and blunt-ended DNA duplexes at these temperatures. However, a single-stranded nick in duplex DNA was less readily employed by the enzyme to initiate cleavage than a free 3' end. At lower temperatures, Sso polB1 cleaved ssDNA more efficiently than dsDNA. The strong 3'-5' exonuclease activity of polB1 was inhibited by 50% in the presence of 2 microM dNTPs, but remained measurable at up to 600 microM dNTPs. In view of the strong exonuclease activity of Sso polB1 on matched dsDNA, we suggest that S. solfataricus may have evolved mechanisms to regulate the exonuclease/polymerase ratio of the enzyme, thereby reducing the cost of proofreading at high temperature.     

Enzymatic release of 5'-terminal deoxyribose phosphate residues from damaged DNA in human cells.

Activities that catalyze or promote the release of 5'-terminal deoxyribose phosphate residues from DNA abasic sites previously incised by an AP endonuclease have been identified in soluble extracts of several human cell lines and calf thymus. Such excision of base-free sugar phosphate residues from apurinic/apyrimidinic sites is expected to be obligatory prior to repair by gap filling and ligation. The most efficient excision function is due to a DNA deoxyribophosphodiesterase similar to the protein found in Escherichia coli. The human enzyme has been partially purified and freed from detectable exonuclease activity. This DNA deoxyribophosphodiesterase is a Mg(2+)-requiring hydrolytic enzyme with an apparent molecular mass of approximately 47 kDa and is located in the cell nucleus. By comparison, the major nuclear 5'----3' exonuclease, DNase IV, is unable to catalyze the release of 5'-terminal deoxyribose phosphate residues as free sugar phosphates but can liberate them at a slow rate as part of small oligonucleotides. Nonenzymatic removal of 5'-terminal deoxyribose phosphate from DNA by beta-elimination promoted by polyamines and basic proteins is a very slow mechanism of release compared to enzymatic hydrolysis. We conclude that a DNA deoxyribophosphodiesterase acts at an intermediate stage between an AP endonuclease and a DNA polymerase during DNA repair at apurinic/apyrimidinc sites in mammalian cells, but several alternative routes also exist for the excision of deoxyribose phosphate residues.     

In vitro mutagenesis in the lacI gene of Escherichia coli: fate of 3'-terminal mispairs versus internal base mispairs in a transfection assay

The fate of G.T mismatches and frameshifts, present at the 3'-terminus of primer-template or internally, has been studied with a combined transfection and electrophoretic assay following in vitro polymerization by DNA polymerase I (Klenow enzyme) of Escherichia coli. Several synthetic oligodeoxynucleotide primers were synthesized and annealed to uracil-containing single-stranded DNA of M13 phage bearing the lacI gene, to produce 1-3 consecutive G.T mismatches in the middle of the duplex region or at the 3'-OH end of the primer. Additional mismatched primer-templates were prepared, in which the primer had a deleted nucleotide, an extra nucleotide or both G.T mismatch and an extra nucleotide. The extension or degradation of these primers during in vitro DNA synthesis in the presence of all 4 dNTPs ('complete' reaction) or in the absence of dATP ('-A' reaction) was monitored by gel electrophoresis. Duplex DNA products were used in a transfection assay and the nucleotide changes in i-mutant progeny were determined by sequence analysis. The results suggest that whereas a single 3'-terminal G.T mismatch is relatively stable in chain elongation by Klenow enzyme, multiple terminal G.T mismatches are degraded by the 3'-exonuclease activity of this polymerase prior to primer extension. This editing activity is increased with the number of 3'-terminal mispairs. Single, double and triple T----C base substitutions were efficiently recovered when the mismatches occurred internally. Also, single-base eliminations or additions were readily recovered when the mutagenic primers contained an internal base deletion or addition, respectively. When products of the '-A' misincorporation reaction (catalyzed by Klenow enzyme) were assayed by transfection, base substitutions (exclusively T----C), but no frameshifts, were recovered. The results indicate that the absence of multiple tandem base substitutions among i- mutants recovered following primer elongation under mutagenic 'minus' conditions was due to the efficient action of the 3'-exonuclease activity of the Klenow enzyme on multiple terminal mismatches during in vitro polymerization, rather than to in vivo events (lack of expression or occurrence of mismatch repair) in the M13-lacI transfection assay.     

Rrp1 translocase and ubiquitin ligase activities restrict the genome destabilising effects of Rad51 in fission yeast

Rad51 is the key protein in homologous recombination that plays important roles during DNA replication and repair. Auxiliary factors regulate Rad51 activity to facilitate productive recombination, and prevent inappropriate, untimely or excessive events, which could lead to genome instability. Previous genetic analyses identified a function for Rrp1 (a member of the Rad5/16-like group of SWI2/SNF2 translocases) in modulating Rad51 function, shared with the Rad51 mediator Swi5-Sfr1 and the Srs2 anti-recombinase. Here, we show that Rrp1 overproduction alleviates the toxicity associated with excessive Rad51 levels in a manner dependent on Rrp1 ATPase domain. Purified Rrp1 binds to DNA and has a DNA-dependent ATPase activity. Importantly, Rrp1 directly interacts with Rad51 and removes it from double-stranded DNA, confirming that Rrp1 is a translocase capable of modulating Rad51 function. Rrp1 affects Rad51 binding at centromeres. Additionally, we demonstrate in vivo and in vitro that Rrp1 possesses E3 ubiquitin ligase activity with Rad51 as a substrate, suggesting that Rrp1 regulates Rad51 in a multi-tiered fashion.     

DNA primase-DNA polymerase alpha from simian cells: sequence specificity of initiation sites on simian virus 40 DNA.

Unique single-stranded regions of simian virus 40 DNA, phage M13 virion DNA, and several homopolymers were used as templates for the synthesis of (p)ppRNA-DNA chains by CV-1 cell DNA primase-DNA polymerase alpha. Intact RNA primers, specifically labeled with an RNA capping enzyme, were typically 6 to 8 ribonucleotides long, although their lengths ranged from 1 to 9 bases. The fraction of intact RNA primers 1 to 4 ribonucleotides long was 14 to 73%, depending on the template used. RNA primer length varied among primers initiated at the same nucleotide, as well as with primers initiated at different sites. Thus, the size of an RNA primer depended on template sequence. Initiation sites were identified by mapping 5' ends of nascent RNA-DNA chains on the template sequence, identifying the 5'-terminal ribonucleotide, and partially sequencing one RNA primer. A total of 56 initiation events were identified on simian virus 40 DNA, an average of 1 every 16 bases. Some sites were preferred over others. A consensus sequence for initiation sites consisted of either 3'-dCTTT or 3'-dCCC centered within 7 to 25 pyrimidine-rich residues; the 5' ends of RNA primers were complementary to the dT or dC. High ATP/GTP ratios promoted initiation of RNA primer synthesis at 3'-dCTTT sites, whereas low ATP/GTP ratios promoted initiation at 3'-dCCC sites. Similarly, polydeoxythymidylic acid and polydeoxycytidylic acid were the only effective homopolymer templates. Thus, both template sequence and ribonucleoside triphosphate concentrations determine which initiation sites are used by DNA primase-DNA polymerase alpha. Remarkably, initiation sites selected in vitro were strikingly different from initiation sites selected during simian virus 40 DNA replication in vivo.     

Novel properties of Escherichia coli exonuclease III.

The specificity of hydrolysis of polynucleotide termini by Escherichia coli exonuclease III was studied with the use of oligothymidylate annealed to polydeoxyadenylate. The size of the products after 3' leads to 5'-hydrolysis of 5'-labeled substrate is temperature-dependent. At 25 degrees the enzyme can hydrolyze a polynucleotide chain up to the last 5'-terminal dinucleotide. A gradation of higher 5'-terminal oligonucleotides of defined chain lengths is produced after limit digestion by the enzyme when the temperature is raised between 25 degrees to 60 degrees. When the oligothymidylate was labeled at the 3'-ends with ribonucleotides, it was observed that exonuclease III can cleave a single or two consecutive ribonucleotides regardless of whether the ribonucleotides are base-paired or mismatched.