Reconstitution of DNA base excision-repair with purified human proteins: interaction between DNA polymerase beta and the XRCC1 protein.

Repair of a uracil-guanine base pair in DNA has been reconstituted with the recombinant human proteins uracil-DNA glycosylase, apurinic/apyrimidinic endonuclease, DNA polymerase beta and DNA ligase III. The XRCC1 protein, which is known to bind DNA ligase III, is not absolutely required for the reaction but suppresses strand displacement by DNA polymerase beta, allowing for more efficient ligation after filling of a single nucleotide patch. We show that XRCC1 interacts directly with DNA polymerase beta using far Western blotting, affinity precipitation and yeast two-hybrid analyses. In addition, a complex formed between DNA polymerase beta and a double-stranded oligonucleotide containing an incised abasic site was supershifted by XRCC1 in a gel retardation assay. The region of interaction with DNA polymerase beta is located within residues 84-183 in the N-terminal half of the XRCC1 protein, whereas the C-terminal region of XRCC1 is involved in binding DNA ligase III. These data indicate that XRCC1, which has no known catalytic activity, might serve as a scaffold protein during base excision-repair. DNA strand displacement and excessive gap filling during DNA repair were observed in cell-free extracts of an XRCC1-deficient mutant cell line, in agreement with the results from the reconstituted system.     

The ability of DNA polymerase beta to synthesize DNA beyond the gap with displacement of the non-replicated strand

Study was made of the ability of calf thymus DNA polymerases alpha and beta to replicate templates containing a small gap. It was found that during extensive replication of activated DNA or synthetic template.primers or specially prepared circular DNA containing a small gap, catalyzed by DNA polymerase alpha, the levels of incorporated nucleotides corresponded to the amounts of the single-stranded fraction of these templates. In contrast, in the reaction catalyzed by DNA polymerase beta the amounts of products were several times greater. The ability to synthesize the product in a great excess was a specific feature of the latter enzyme. An analysis of the gap-filling products by sucrose gradient centrifugation, gel electrophoresis and Southern hybridization showed that, contrary to DNA polymerase alpha, DNA polymerase beta exhibited the ability to synthesize DNA not only within but also beyond the gap. The "net" DNA product is complementary to the template strand. It is suggested that DNA was synthesized beyond the gap by displacement of the non-replicated strand.     

Characterization of messenger RNA for chick-embryo DNA polymerase beta and its translation product in vitro

A specific immunoprecipitation method, using rabbit anti-(chick DNA polymerase beta) IgG was applied to detect the polypeptide of DNA polymerase beta among translation products obtained in vitro with mRNA extracted from chick embryos. A polypeptide of Mr = 40 000 was specifically immunoprecipitated from [35S]methionine-labeled translation products and was competitive with the purified DNA polymerase beta for the antibody. Furthermore, the 40 000-Mr translation product obtained in vitro had DNA polymerase activity, which was detected by assay in situ after electrophoresis in a polyacrylamide gel containing DNA. The mRNA for DNA polymerase beta was polyadenylated and its content was estimated as the range of 0.001% of total poly(A)-rich RNA on the basis of [35S]methionine incorporation in the translation in vitro. The size of this mRNA was determined to be about 1800 nucleotides by zone sedimentation and agarose gel electrophoresis under denaturating conditions.     

Involvement of deoxyribonucleic acid polymerase beta in nuclear deoxyribonucleic acid synthesis.

The effects on DNA synthesis in vitro in mouse L929-cell nuclei of differential extraction of DNA polymerases alpha and beta were studied. Removal of all measurable DNA polymerase alpha and 20% of DNA polymerase beta leads to a 40% fall in the replicative DNA synthesis. Removal of 70% of DNA polymerase beta inhibits replicative synthesis by 80%. In all cases the nuclear DNA synthesis is sensitive to N-ethylmaleimide and aCTP (arabinosylcytosine triphosphate), though less so than DNA polymerase alpha. Addition of deoxyribonuclease I to the nuclear incubation leads to synthesis of high-molecular-weight DNA in a repair reaction. This occurs equally in nuclei from non-growing or S-phase cells. The former nuclei lack DNA polymerase alpha and the reaction reflects the sensitivity of DNA polymerase beta to inhibiton by N-ethylmaleimide and aCTP.     

The beta subunit of the Escherichia coli DNA polymerase III holoenzyme interacts functionally with the catalytic core in the absence of other subunits

We have previously demonstrated that the addition of a stoichiometric excess of the beta subunit of Escherichia coli DNA polymerase III holoenzyme to DNA polymerase III or holoenzyme itself can lead to an ATP-independent increase in the processivity of these enzyme forms (Crute, J. J., LaDuca, R. J., Johanson, K. O., McHenry, C. S., and Bambara, R. A. (1983) J. Biol. Chem. 258, 11344-11349). Here, we show that the beta subunit can interact directly with the catalytic core of the holoenzyme, DNA polymerase III, generating a new form of the enzyme with enhanced catalytic and processive capabilities. The addition of saturating levels of the beta subunit to the core DNA polymerase III enzyme results in as much as a 7-fold stimulation of synthetic activity. Two populations of DNA products were generated by the DNA polymerase III X beta enzyme complex. Short products resulting from the addition of 5-10 nucleotides/primer fragment were generated by DNA polymerase III in the presence and absence of added beta subunit. A second population of much longer products was generated only in beta-supplemented DNA polymerase III reactions. The DNA polymerase III-beta reaction was inhibited by single-stranded DNA binding protein and was unaffected by ATP, distinguishing it from the holoenzyme-catalyzed reaction. Complex formation of the DNA polymerase III core enzyme with beta increased the residence time of the enzyme on synthetic DNA templates. Our results demonstrate that the beta stimulation of DNA polymerase III can be attributed to a more efficient and highly processive elongation capability of the DNA polymerase III X beta complex. They also prove that at least part of beta's normal contribution to the DNA polymerase III holoenzyme reaction takes place through interaction with DNA polymerase III core enzyme components to produce the essential complex necessary for efficient elongation in vivo.     

The inhibitory effect of 4-hydroxy-nonenal on DNA-polymerases alpha and beta from rat liver and rapidly dividing Yoshida ascites hepatoma

The purpose of this study was to determine firstly whether the isolated enzyme DNA polymerase alpha, which functions within the DNA replicase system, exhibits different sensitivity against the thiol-blocking agent 4-hydroxy-nonenal (HNE) when adult rat liver and the rapidly dividing Yoshida ascites hepatoma were used as enzyme sources and, secondly, whether the reaction catalysed by DNA polymerase is the most sensitive step of the DNA replicase system of native cells. DNA polymerase alpha as well as the non-replicative DNA polymerase beta, isolated from both sources, were remarkably similar with regard to their sensitivity against HNE, as indicated by the incorporation of radioactive label from [3H]deoxy-thymidine-triphosphate into DNA. The transport of [14C]thymidine through the plasma membrane and the incorporation of this precursor into DNA were studied with neonatal hepatocytes and with hepatoma cells. The incorporation of thymidine was inhibited at lower concentrations of HNE in both cell lines than the transport process and the reaction catalysed by DNA polymerase alpha. It was concluded that in the DNA replicase system of native liver and hepatoma cells another process different from the reaction catalysed by DNA polymerase alpha is more sensitive to HNE.     

The base substitution fidelity of DNA polymerase beta-dependent single nucleotide base excision repair

Damaged DNA bases are removed from mammalian genomes by base excision repair (BER). Single nucleotide BER requires several enzymatic activities, including DNA polymerase and 5',2'-deoxyribose-5-phosphate lyase. Both activities are intrinsic to four human DNA polymerases whose base substitution error rate during gap-filling DNA synthesis varies by more than 10,000-fold. This suggests that BER fidelity could vary over a wide range in an enzyme dependent manner. To investigate this possibility, here we describe an assay to measure the fidelity of BER reactions reconstituted with purified enzymes. When human uracil DNA glycosylase, AP endonuclease, DNA polymerase beta, and DNA ligase 1 replace uracil opposite template A or G, base substitution error rates are 相似文献   

In vitro synthesis of short DNA pieces by DNA polymerase alpha from mouse myeloma

The DNA chain elongation mechanisms of mouse DNA polymerases alpha and beta have been analyzed by using denatured DNA with a (dT)n block at the 3'-end as a template in combination with RNA ((rA)12-20)primer. The (rA)12-20-primed DNA product synthesized by DNA polymerase alpha was 3-5 s in size even after prolonged reaction; instead of a size increase, the number of 3-5 s molecules increased with the reaction time. The size of products was not affected by differences in 3H-labeled substrate (dATP or dTTP), enzyme amount, KCl concentration, or the length of 3'-(dT)n blocks. On the other hand, DNA polymerase beta synthesized long DNA products by a highly distributive reaction mechanism. 3-5 sDNA pieces synthesized by DNA polymerase alpha were not elongated any further by DNA polymerase alpha, but were converted into long DNA chains by DNA polymerase beta. The results imply that DNA polymerase alpha recognizes the size of the product DNA, and shuts off further elongation.     

Analysis of the ATPase subassembly which initiates processive DNA synthesis by DNA polymerase III holoenzyme.

The gamma complex (gamma delta delta' chi psi) subassembly of DNA polymerase III holoenzyme transfers the beta subunit onto primed DNA in a reaction which requires ATP hydrolysis. Once on DNA, beta is a "sliding clamp" which tethers the polymerase to DNA for highly processive synthesis. We have examined beta and the gamma complex to identify which subunit(s) hydrolyzes ATP. We find the gamma complex is a DNA dependent ATPase. The beta subunit, which lacks ATPase activity, enhances the gamma complex ATPase when primed DNA is used as an effector. Hence, the gamma complex recognizes DNA and couples ATP hydrolysis to clamp beta onto primed DNA. Study of gamma complex subunits showed no single subunit contained significant ATPase activity. However, the heterodimers, gamma delta and gamma delta', were both DNA-dependent ATPases. Only the gamma delta ATPase was stimulated by beta and was functional in transferring the beta from solution to primed DNA. Similarity in ATPase activity of DNA polymerase III holoenzyme accessory proteins to accessory proteins of phage T4 DNA polymerase and mammalian DNA polymerase delta suggests the basic strategy of chromosome duplication has been conserved throughout evolution.     

Interaction of APE1 and other repair proteins with DNA duplexes imitating intermediates of DNA repair and replication

Interactions of APE1 (human apurinic/apyrimidinic endonuclease 1) and DNA polymerase beta with various DNA structures imitating intermediates of DNA repair and replication were investigated by gel retardation and photoaffinity labeling. Photoaffinity labeling of APE1 and DNA polymerase beta was accomplished by DNA containing photoreactive group at the 3 -end in mouse embryonic fibroblast (MEF) cell extract or for purified proteins. On the whole, modification efficiency was the same for MEF-extract proteins and for purified APE1 and DNA polymerase beta depending on the nature of the 5 -group of a nick/gap in the DNA substrate. Some of DNA duplexes used in this work can be considered as short-patch (DNA with the 5 -phosphate group in the nick/gap) or long-patch (DNA containing 5 -sugar phosphate or 5 -flap) base excision repair (BER) intermediates. Other DNA duplexes (3 -recessed DNA and DNA with the 5 -hydroxyl group in the nick/gap) have no relation to intermediates forming in the course of BER. As shown by both methods, APE1 binds with the highest efficiency to DNA substrate containing 5 -sugar phosphate group in the nick/gap, whereas DNA polymerase beta binds to DNA duplex with a mononucleotide gap flanked by the 5 -p group. When APE1 and DNA polymerase beta are both present, a ternary complex APE1-DNA polymerase beta-DNA is formed with the highest efficiency with DNA product of APE1 endonuclease activity and with DNA containing 5 -flap or mononucleotide-gapped DNA with 5 -p group. It was found that APE1 stimulates DNA synthesis catalyzed by DNA polymerase beta, and a human X-ray repair cross-complementing group 1 protein (XRCC1) stimulates APE1 3 -5 exonuclease activity on 3 -recessed DNA duplex.     

Differential inhibition of DNA polymerases of calf thymus by 9-beta-D-arabinofuranosyladenine-5'-triphosphate.

The effect of 9-beta-D-arabinofuranosyladenine-5'-triphosphate (araATP) on the reactions of DNA polymerases alpha and beta [E.C. 2.7.7.7] purified from calf thymus was examined. The reaction of DNA polymerase alpha was shown to be more sensitive to the inhibition than that of DNA polymerase beta. The K1 value of DNA polymerase beta for araATP was 45 micrometer; 15 times higher than that of DNA polymerase alpha (3 micrometer). The mode of inhibition by araATP was essentially competitive to deoxyadenosine triphosphate (dATP) in the reactions catalyzed by both DNA polymerase alpha and beta using activated DNA as a template-primer. However, in the reactions of the alpha-enzyme, araATP also inhibited the incorporation of deoxyribonucleotides othan than dATP non-competitively.     

The DNA polymerase beta reaction with ultraviolet-irradiated DNA incised by correndonuclease

Covalently closed circular Col E1 DNA was ultraviolet-irradiated with a dose of 60 J/m2, thus introducing about 3.2 pyrimidine dimers per DNA molecule. Treatment of irradiated Col E1 DNA with Micrococcus luteus correndonuclease resulted, in the vicinity of pyrimidine dimers, in an average of 3.3 incisions per DNA molecule, and converted DNA to the open circular form. Incised Col E1 DNA stimulated no reaction with calf thymus DNA polymerase alpha but was recognized as a template by DNA polymerase beta. The latter enzyme incorporated about 1.6 molecules of dTMP (corresponding to 6 molecules od dNMP) per one correndonuclease incision. The length of the DNA polymerase beta product was comparable to the anticipated length of the DNA region within which the hydrogen bonds were disrupted owing to dimer formation. The enzyme required Mg(2)=nd four dNTPs for reaction and was resistant to N-ethylmaleimide or p-mercuribenzoate. The average numbers of deoxynucleotides incorporated per one DNAase I incision or per one nonspecific break, measured in control samples, were equal, amounting to 0.3 dTMP molecule. This value corresponded to 1.2 dNMP molecule; in our opinion, this reflects contaminating nuclease activity of the system used. The present results testify to the ability of DNA polymerase beta to repair synthesis by the "patch and cut' mechanism.     

Mammalian DNA polymerase beta can substitute for DNA polymerase I during DNA replication in Escherichia coli.

Mammalian DNA polymerase beta is the smallest known eukaryotic polymerase and is expressed as an active protein in Escherichia coli harboring a plasmid containing its cDNA. Since some catalytic functions of DNA polymerase beta and E. coli DNA polymerase I are similar, we wished to determine if DNA polymerase beta could substitute for DNA polymerase I in bacteria. We found that the expression of mammalian DNA polymerase beta in E. coli restored growth in a DNA polymerase I-defective bacterial mutant. Sucrose density gradient analysis revealed that DNA polymerase beta complements the replication defect in the mutant by increasing the rate of joining of Okazaki fragments. These findings demonstrate that DNA polymerase beta, believed to function in DNA repair in mammalian cells, can also function in DNA replication. Moreover, this complementation system will permit study of the in vivo function of altered species of DNA polymerase beta, an analysis currently precluded by the difficulty in isolating mutants in mammalian cells.     

Selective inhibition of phiX RFII compared with fd RFII DNA synthesis in vitro. II. Resolution of discrimination reaction into multiple steps.

In the presence of RNA polymerase, RNase H, discriminatory factors alpha and beta, Escherichia coli binding protein, DNA elongation factor I, DNA elongation factor II preparation, DNA polymerase III, and ATP, UTP, GTP, CTP, dATP, dTTP, dGTP, and dCTP, fd viral DNA can be quantitatively converted to RFII containing a unique gap in the linear minus strand. This gap, mapped with the aid of restriction endonucleases HinII and HpaII, is located within Fragment Hpa-H of the fd genome. The discrimination reaction has been resolved into two steps: Step A, fd viral DNA, E. coli binding protein, and discriminatory factors alpha and beta form a protein DNA complex; Step B, the complex isolated by agarose gel filtration selectively forms fd RFII when supplemented with RNase H, RNA polymerase, and the DNA elongation proteins. The omission of any of the proteins described above during the first reaction resulted in either no discrimination or a decrease in discrimination when the missing protein was added during the second step. Results are presented which indicate that E. coli binding protein, discriminatory factors alpha and beta, and RNase H must be present during the time RNA synthesis occurs in order to selectively form RFII from fd DNA and not phiX RFII. The amount of fd and phiX174 RNA-DNA hybrid formed in vitro is directly related to the DNA synthesis observed. Thus, under discriminatory conditions, only fd viral DNA leads to fd RNA-DNA complexes and no phiX RNA-DNA hybrid is formed. Under nondiscriminatory conditions, both DNAs yield RNA-DNA hybrids and DNA synthesis. In the absence of discriminatory factor alpha, no RNA-DNA hybrid is formed with either DNA, and in turn, no DNA synthesis is detected with either DNA template.     

Escherichia coli DNA polymerase II is stimulated by DNA polymerase III holoenzyme auxiliary subunits

DNA polymerase III of Escherichia coli requires multiple auxiliary factors to enable it to serve as a replicative complex. We demonstrate that auxiliary components of the DNA polymerase III holoenzyme, the gamma delta complex and beta subunit, markedly stimulate DNA polymerase II on long single-stranded templates. DNA polymerase II activity is enhanced by single-stranded DNA binding protein, but the stimulation by gamma delta and beta can be observed either in the absence or presence of single-stranded DNA binding protein. In contrast with DNA polymerase III, the requirement of DNA polymerase II for gamma delta cannot be bypassed by large excesses of the beta subunit at low ionic strength in the absence of the single-stranded DNA binding protein. The product of the DNA polymerase II-gamma delta-beta reaction on a uniquely primed single-stranded circle is of full template length; the reconstituted enzyme apparently is incapable of strand displacement synthesis. The possible biological implications of these observations are discussed.     

The beta subunit modulates bypass and termination at UV lesions during in vitro replication with DNA polymerase III holoenzyme of Escherichia coli

The cycling time of DNA polymerase III holoenzyme during replication of UV-irradiated single-stranded (ss) DNA was longer than with unirradiated DNA (8 versus 3 min, respectively), most likely due to slow dissociation from lesion-terminated nascent DNA strands. Initiation of elongation on primed ssDNA was not significantly inhibited by the presence of UV lesions as indicated by the identical distribution of replication products synthesized at early and late reaction times and by the identical duration of the initial synthesis bursts on both unirradiated and UV-irradiated DNA templates. When replication was performed with DNA polymerase III* supplemented with increasing quantities of purified beta 2 subunit, the cycling time on UV-irradiated DNA decreased from 14.8 min at 1.7 nM beta 2 down to 6 min at 170 nM beta 2, a concentration in which beta 2 was in large excess over the polymerase. In parallel to the reduction in cycling time, also the bypass frequency of cyclobutane-photodimers decreased with increasing beta 2 concentration, and at 170 nM beta 2, bypass of photodimers was essentially eliminated. It has been shown that polymerase complexes with more than one beta 2 per polymerase molecule were formed at high beta 2 concentrations (Lasken, R. S., and Kornberg, A. (1987) J. Biol. Chem. 262, 1720-1724). It is plausible that polymerase complexes obtained under high beta 2 concentration dissociate from lesion-terminated primers faster than polymerase complexes formed at a low beta 2 concentration. This is expected to favor termination over bypass at pyrimidine photodimers and thus decrease their bypass frequency. These results suggest that the beta 2 subunit might act as a sensor for obstacles to replication caused by DNA damage, and that it terminates elongation at these sites by promoting dissociation. The intracellular concentration of beta 2 was estimated to be 250 nM (Kwon-Shin, O., Bodner, J. B., McHenry, C. S., and Bambara, R. A. (1987) J. Biol. Chem. 262, 2121-2130) and is 15-fold higher than the estimated intracellular concentration of DNA polymerase III holoenzyme (15 nM). This high concentration of beta 2 may be responsible for the observation that very little (if any) bypass of pyrimidine photodimers occurred in vivo when the SOS system was not induced. Moreover, it predicts that bypass synthesis under SOS conditions might be associated with an altered form of the beta subunit.     

Dideoxynucleoside triphosphate-sensitive DNA polymerase from rice is involved in base excision repair and immunologically similar to mammalian DNA pol beta

A single polypeptide with ddNTP-sensitive DNA polymerase activity was purified to near homogeneity from the shoot tips of rice seedlings and analysis of the preparations by SDS-PAGE followed by silver staining showed a polypeptide of 67 kDa size. The DNA polymerase activity was found to be inhibitory by ddNTP in both in vitro DNA polymerase activity assay and activity gel analysis. Aphidicolin, an inhibitor of other types of DNA polymerases, had no effect on plant enzyme. The 67 kDa rice DNA polymerase was found to be recognized by the polyclonal antibody (purified IgG) made against rat DNA polymerase beta (pol beta) both in solution and also on Western blot. The recognition was found to be very specific as the activity of Klenow enzyme was unaffected by the antibody. The ability of rice nuclear extract to correct G:U mismatch of oligo-duplex was observed when oligo-duplex with 32P-labeled lower strand containing U (at 22nd position) was used as substrate. Differential appearance of bands at 21-mer, 22-mer, and 51-mer position in presence of dCTP was visible only with G:U mismatch oligo-duplex, but not with G:C oligo-duplex. While ddCTP or polyclonal antibody against rat-DNA pol beta inhibits base excision repair (BER), aphidicolin had no effect. These results for the first time clearly demonstrate the ability of rice nuclear extract to run BER and the involvement of ddNTP-sensitive pol beta type DNA polymerase. Immunological similarity of the ddNTP-sensitive DNA polymerase beta of rice and rat and its involvement in BER revealed the conservation of structure and function of ddNTP-sensitive DNA pol beta in plant and animal.     

Inhibitors of DNA polymerase beta: activity and mechanism

Bioassay-guided fractionation of extracts prepared from Couepia polyandra and Edgeworthia gardneri resulted in the isolation of the DNA polymerase beta (pol beta) inhibitors oleanolic acid (1), edgeworin (2), betulinic acid (3), and stigmasterol (4). Study of these pol beta inhibitors revealed that three of them inhibited both the lyase and polymerase activities of DNA polymerase beta, while stigmasterol inhibited only the lyase activity. Further investigation indicated that the four inhibitors had substantially different effects on the DNA-pol beta binary complex that is believed to be an obligatory intermediate in the lyase reaction. It was found that the inhibitors potentiated the inhibitory action of the anticancer drug bleomycin in cultured A549 cells, without any influence on the expression of pol beta in the cells. The results of the unscheduled DNA synthesis assay support the thesis that the potentiation of bleomycin cytotoxicity by DNA pol beta inhibitors was a result of an inhibition of DNA repair synthesis.     

Identification of an intrinsic 5'-deoxyribose-5-phosphate lyase activity in human DNA polymerase lambda: a possible role in base excision repair.

Base excision repair (BER) is a major repair pathway in eukaryotic cells responsible for repair of lesions that give rise to abasic (AP) sites in DNA. Pivotal to this process is the 5'-deoxyribose-5-phosphate lyase (dRP lyase) activity of DNA polymerase beta (Pol beta). DNA polymerase lambda (Pol lambda) is a recently identified eukaryotic DNA polymerase that is homologous to Pol beta. We show here that human Pol lambda exhibits dRP lyase, but not AP lyase, activity in vitro and that this activity is consistent with a beta-elimination mechanism. Accordingly, a single amino acid substitution (K310A) eliminated more than 90% of the wild-type dRP lyase activity, thus suggesting that Lys(310) of Pol lambda is the main nucleophile involved in the reaction. The dRP lyase activity of Pol lambda, in coordination with its polymerization activity, efficiently repaired uracil-containing DNA in an in vitro reconstituted BER reaction. These results suggest that Pol lambda may participate in "single-nucleotide" base excision repair in mammalian cells.