[Investigation of the interaction of repair DNA polymerase beta and autonomous 3' --> 5'-exonucleases TREX1 and TREX2].

The possibility of interaction of recombinant proteins of human repair DNA polymerase beta with proofreading 3' --> 5'-exonucleases TREX1 and TREX2 was investigated in vitro for the first time. The results of gel filtration analysis show the formation of a complex between 3' --> 5' -exonucleases mTREX1 and hTREX2 and DNA polymerase beta. DNA polymerase activity is shown to increase four-fold in the presence of 3' --> 5'-exonuclease TREX2. The experiments with the use of immunodot and Western blot assays on the binding of DNA-polymerase beta with 3' --> 5'-exonucleases TREX1 and TREX2 immobilized on a nitrocellulose membrane provided additional evidence on the direct association of the above proteins in complexes.

[Ratio of 3' --> 5'-exonuclease and DNA-polymerase activities in normal and cancer cells of rodents and humans].

Mutations in the genes of corrective 3' --> 5'-exonucleases as well as in DNA polymerases lead to decrease in DNA biosynthesis accuracy all over genome. This is accompanied by the increase in mutagenesis and carcinogenesis probabilities. In this work, the activities of 3' --> 5'-exonucleases and DNA polymerases were studied in the extracts from normal and cancer cells of rodents and humans, and we are the first to measure their integral ratios. As example, in cultivated dermal fibroblasts of an adult human, the value of the ratio of activities of 3' --> 5'-exonucleases to DNA polymerase activity (3'-exo/pol) surpassed several folds the such a value for HeLa cells. Similar picture was observed during the comparison of normal fibroblasts of rat embryos and transformed fibroblasts of Chinese hamster A238. Experiments with cell-free extracts of some organs from healthy rats of various ages have shown that normal proliferating cells demonstrate higher 3' --> 5'-exonuclease activity and higher values of 3'-exo/pol that quiescent cells. Comparison of these data suggests a violation of the function of corrective 3' --> 5'-exonucleases in abnormally growing cancer cells.

[Mutator hypothesis of carcinogenesis and supermutagens in anticancer therapy].

The putative causative relationship between mutator nature of carcinogenesis and positive results of empirical application of supermutagens for anticancer therapy is discussed. Part 1 of the review is devoted to the substantiation of the mutator theory of carcinogenesis. Part 2 provides an explanation of positive results of empirical application of supermutagens for anticancer therapy in the framework of this theory.

[Complex of repair DNA polymerase beta with autonomous 3'-->5'-exonuclease shows increased accuracy of DNA synthesis].

The complexes of repair DNA polymerase beta with 3'-exonuclease and some other proteins were isolated from the chromatin of hepatocytes of normal rats for the first time. Biopolymers were extracted from the chromatin by the solution of NaCl and Triton X-100. The extract was fractionated by gel-filtration on Sephacryl S-300 columns successively in low and high ionic strength solutions, on hydroxyapatite, and on Sephadex G-100 columns. The complexes have molecular weights of 100 and 300 kDa. They dissociate to DNA polymerase and exonuclease in the course of chromatography on a DNA-cellulose column or after gel-filtration in the presence of 1 M NaCl. The co-purification of the polymerase and exonuclease is reconstituted in 0.1 M NaCl. The fidelity of monomeric and composite DNA polymerase beta was measured using phage phiX174 amber 3 as a primer/template. The products of the synthesis were transfected into Escherichia coli spheroplasts, and the frequency of reverse mutations was determined. The complex of DNA polymerase beta with 3'-exonuclease was shown to be 30 times more accurate than the monomeric polymerase, which can decrease the probability of repair mutagenesis and carcinogenesis.

[Eukaryotic error prone DNA polymerases: suggested roles in replication, repair and mutagenesis].

A number of error-prone DNA polymerases is found among eukaryotes from yeasts up to mammalia including humans. According to the partial homology of a primary structure, they are united in families B, X, Y and display high infidelity on uninjured DNA-template, whereas they are rather accurate on DNA injuries. These DNA polymerases are characterized by the probability of base substitutions or frame shifts of 10(-3) to 7.5 x 10(-1) on DNA injuries, whereas the probability of spontaneous mutagenesis per replicated nucleotide accounts 10(-10) - 10(-12). Inaccurate DNA polymerases are terminal deoxynucleotidyl transferase (TdT), DNA polymerases beta, zeta, kappa, eta, iota, lamda, mu, and Rev1. Their principal properties are described in this review. All of the polymerases under study are deprived of the corrective 3'-->5' exonucleolytic activity. The specialization of these polymerases is contained in the capability to synthesize opposite DNA lesions (not eliminated by multiple repair systems) that is explained by the flexibility of their active sites or by the limited capability to exhibit the TdT activity. Classic DNA polymerases alpha, delta, epsilon, and gamma cannot elongate the primers with mismatched nucleotides on their 3'-ends (that leads to the replication block), whereas some of the specialized polymerases can do it. It is accompanied by the overcoming of a replication block, often with the expense of an elevated mutagenesis. How can a cell live under the conditions of such a huge infidelity of many DNA polymerases? Error-prone DNA polymerases are not found in all tissues though some of them are essential for an organism survival. Furthermore, cells must not allow for these polymerases to work effectively on uninjured DNA. After bypass of a lesion on DNA-template, it is necessary, as soon as possible, to switch catalysis of the DNA synthesis from the specialized polymerases on the relatively accurate DNA polymerases delta and epsilon (fidelity of 10(-5) - 10(-6)). It is made by the formation of the complexes of polymerases delta or epsilon with PCNA and replicative factors RP-A and RF-C. Such highly processive complexes manifest the bigger affinity to the correct primers than the specialized DNA polymerases do. The switching is stimulated by distributivity or weak processivity of the specialized DNA polymerases. The accuracy of these polymerases are augmented by the action of the corrective 3'-exonucleolytic function of DNA polymerases delta and epsilon as well as by the autonomous 3'-->5' exonucleases which are widespread among the representatives of the whole phylogenetic tree. Exonucleolytic correction slows down the replication in the presence of lesions in DNA-template but makes the replication more accurate that decreases the probability of mutagenesis and carcinogenesis.

[Antimutagenic role of autonomous 3'-->5'-exonucleases]. / Antimutagennaia rol' avtonomnykh 3'-5'-ékzonukleaz.

Our own and literary data about antimutagenic role of autonomous 3'-->5'-exonucleases (AE) are analyzed. AE are not bound covalently to DNA polymerases but often involved in replicative complexes. Intracellular overproduction of AE in bacteria is accompanied with the sharp suppression of mutagenesis, whereas the inactivation of AE in bacteria and higher fungi results in the increase of mutation rates by 2-3 orders of magnitude. The addition of AE in biologically meaningful concentrations to DNA polymerases elevates substantially the accuracy of their work in vitro. In these cases, the reverse mutation rates were measured in the DNA from phage (X174 amber 3, whereas the direct mutation rates--in the DNA from phage M13mp2, both being used as primer-templates for DNA synthesis and then transfected into spheroplasts of Escherichia coli. The accuracy of action of nuclease-free DNA polymerases alpha and beta are shown to raise in the presence of AE by 2-3 orders, the accuracy of moderately processive DNA polymerase I--by 2 orders, the accuracy of highly processive DNA polymerase delta--by 5-10 times, though the latter 2 polymerases display and their own 3'-->5'-exonucleolytic activity. AE, involved in the multienzyme DNA polymerase complexes, augment the accuracy of complexes action by 5-10 times. The model of "external" corrective role of AE in DNA biosynthesis is proposed. Study of 30 objects from all 3 kingdoms of live beings (from archae- and eubacteria to mammalia including human) has shown that AE account, as minimum, from 30 to 90% of the total cellular 3'-->5'-exonucleolytic activity. So AE increase essentially the intracellular ratio of values of 3'-->5'-exonuclease to DNA polymerase activities in the very various representatives from a phylogenetic tree that results always in the augmentation of the accuracy of DNA biosynthesis.

[The correcting role of autonomous 3'-->5' exonucleases in mammalian multienzyme DNA polymerase complexes]. / Korrektorskaia rol' avtonomnykh 3'-->5'-ékzonukleaz v sostave mul'tifermentnykh DNK-polimeraznykh kompleksov mlekopitaiushchikh.

A study was made of the correcting role of autonomous 3'-->5' exonucleases (AE) contained in multienzyme DNA polymerase complexes of rat hepatocytes or calf thymocytes. DNA was synthesized on phage psi X174 amber3 or M13mp2 primer-templates, and used to transfect Escherichia coli spheroplasts. Frequencies were estimated for direct and reverse mutations resulting from mistakes made in the course of in vitro DNA synthesis. The mistake rate of the hepatocytic complex was estimated at 3 x 10(-6) with equimolar dNTP, and increased tenfold when proteins accounting for 70% of the total 3'-->5' exonuclease activity of the complex were removed. The fidelity of DNA synthesis was completely restored in the presence of exogenous AE (epsilon subunit of E. coli DNA polymerase III). Nuclear (Pol delta n) and cytosolic (Pol delta c) forms of DNA polymerase delta were isolated from calf thymocytes. The former was shown to contain an AE (TREX2) absent from the latter. As compared with Pol delta c, Pol delta n had a 20-fold higher exo/pol ratio and allowed 4-5 times higher fidelity of DNA synthesis. The mistake rate of DNA polymerase complexes changed when dNTP were used in nonequimolar amounts.

[Isolation of protein phosphokinase from a complex form of DNA polymerase alpha from rat liver]. / Vydelenie proteinfosfokinazy iz kompleksnoi formy DNK-polimerazy alpha pecheni krysy.

Protein kinase activity was revealed in complex forms of rat liver DNA polymerase alpha containing 3'-5'-exonuclease, primase, helicase, DNA ligase. Protein kinase (mol. mass about 200 kDa) has been partially purified from a specimen of high molecular mass DNA polymerase alpha of nuclear membrane of regenerating liver. The protein kinase activity of the complex form of DNA polymerase alpha was maximal in the cytosol in normal rat liver cells and in the nuclear membrane in dividing cells (40 h after partial hepatectomy). The main phosphokinase properties of this enzyme were determined.

[Contribution of 3'---5'-exonuclease from rat liver nuclei in precision of DNA synthesis, catalyzed by mammalian DNA polymerase alpha]. / Vklad 3'---5'-ekzonukleaz iz iader pecheni krysy v tochnost' sinteza DNK, kataliziruemogo DNK-polimerazami alpha mlekopitaiushchikh.

Mammalian nuclear DNA polymerases alpha and beta are known to be devoid of editing 3'-->5'exonucleolytic activity. Presumably this activity could be effected by the exonucleases non-associated covalently with DNA polymerases. Two 3'-->5'exonucleases with molecular masses of 40 and 50 kDa have been isolated from rat liver nuclei and purified to near homogeneity. They are shown to excise mismatched nucleotides from a poly [d(A-T)] template respectively 10- and 2-fold faster than the matched ones. Upon addition of any of these exonucleases to DNA polymerase alpha from rat liver or calf thymus, the fidelity of in vitro reproduction of primed DNA from bacteriophage phi X174 amber 3 is increased 5-10-fold, the levels of exonuclease and polymerase activities being approximately the same. The extrapolation of replication fidelity to cellular activities of the exonucleases and alpha-polymerase suggests that exonuclease proofreading augments the accuracy of DNA synthesis at least by three orders of magnitude.

[3'-->5'-exonucleases of the rat liver and the correction of replication errors]. / 3'-->5'-ékzonukleazy pecheny krysy i korrektsiia oshibok replikatsii.

Mammalian nuclear DNA polymerases alpha and beta are lack of the proofreading 3'-->5' exonucleolytic activity. 40 and 50 kDa 3'-->5' exonucleases were isolated from rat liver. The exonucleases were shown to excise mismatched nucleotides from poly[d(A--T)] template 10 and 2 fold faster than matched ones. The addition of either exonuclease to DNA polymerase alpha from rat liver or calf thymus 5-10 times increased the accuracy of reproduction of primed DNA from bacteriophage phi X174 amber 3, values of exonuclease and DNA polymerase activities being approximately equal. The exonuclease activity surpasses the DNA polymerase one by an order of magnitude in chromatin and nuclear membrane. These data, taken together, are indicative of potent proofreading into hepatocytes.

[Autonomic replication of plasmids containing DNA fragments from rat liver alpha-polymerase complex]. / Avtonomnaia replikatsiia plazmid, soderzhashchikh fragmenty DNK iz alpha-polimeraznogo kompleksa pecheni krysy.

We have cloned a number of plasmids pori, containing DNA fragments derived from rat liver alpha-polymerase complex. Colony hybridization identified 30 clones with homologies to origin SV40. Five clones of pori were examined in transfected V79 hamster cells. Plasmid DNA was isolated at time intervals after transfection and screened by the CfuI resistance assay or by the bromodeoxyuridine substitution. We have identified two plasmids pori22 and pori32 that can support plasmid replication in mammalian cells. Thus, at least two DNA fragments from rat liver alpha-polymerase complex act as origins of replication in a mammalian system. Five days after transfection of pori32 Hirt the supernatant contains the molecules of RNA which hybridize with pUC19. Our results indicated that pori32 has an origin of replication and promotor of transcription.

[Homogeneous 3'----5'-exonucleases and their multienzyme complexes from the rat liver]. / Gomogennye 3'----5'-ékzonukleazy i ikh mul'tifermentnye kompleksy iz pecheni krysy.

Isolation and general properties of 3'-5' exonucleases I and II (EC 3.1.4.26), which are specific to single-stranded DNA, are described. Such enzymes, being components of replication complexes, could correct replication errors. Homogeneous exonucleases I and II consist of a single subunit with molecular mass of 50 and 40 kDa, respectively. These enzymes are located preferentially in the nuclear membrane and chromatin. They form complexes with nuclear DNA polymerases and some other proteins and are not observed practically in a free state. Molecular masses of the complexes amount from 70 to 1.500 kDa. The complexes dissociate as a result of solution hydrophobization and can be reconstituted after the decrease of hydrophobization. The heavy membrane complex form of 3'----5' exonuclease I manifests enzymatic activities of DNA polymerase alpha (EC 2.7.7.7), non-specific nucleoside triphosphatase (EC 3.1.3.2), nucleotidase (EC 3.1.3.31) and faint activity of endonuclease (EC 3.1.4.5). Complexes under study do not display activity of thymidine kinase (EC 2.7.1.21), marker protein of replitase, neither in G0 nor in S-period.