DNA Polymerase-Associated and Autonomous 3"→5" Exonucleases in Invertebrates, Unicellulars, and Bacteria

Recently we have revealed a high content of autonomous 3"5" exonucleases (AE), i.e., those not bound covalently with DNA polymerases, in cells of vertebrates, from fish to human [1]. In the present work, using gel filtration method, cell-free extracts were studied from 15 objects located at different positions on the phylogenetic tree, such as archaebacteria, eubacteria, fungi, infusorians, coelenterates, annelids, and arthropods. It is shown that enzymatic activity of AE accounts for from 30 to 88% of the total 3"5" exonuclease activity of the extracts. A part of AE is revealed in zone of high-molecular DNA polymerases and can be separated by change of the chromatography conditions. It indicates a probable formation of complexes of AE with DNA polymerases. The high AE activity in cells of different organisms, from archae- and eubacteria to human, allows suggesting these enzymes to play a significant role in correction of polymerase errors in the processes of DNA replication and reparation, as well as in postreplicative correction of heteroduplexes in DNA.     

DNA polymerases and carcinogenesis

There are many various chromosomal and gene mutations in human cancer cells. The total mutation rate in normal human cells is 2·10⁻⁷ mutations/gene/division. From 6 to 12 carcinogenic mutations can arise by the end of the life, and these can affect the structure of ∼150 protooncogenes and genes encoding suppressors of tumor growth. However, this does not explain the tens and hundreds of thousands of mutations detectable in cancer cells. Mutation is any change of nucleotide sequence in cellular DNA. Gene mutations are mainly consequences of errors of DNA polymerases, especially of their specialized fraction (inaccurate DNA polymerases β, ζ, η, θ, ι, κ, λ, μ, σ, ν, Rev1, and terminal deoxynucleotidyl transferase, and only polymerases θ and σ manifest a slight 3′-exonuclease activity) and also consequences of a decrease in the rate of repair of these errors. Inaccurate specialized human polymerases are able to synthesize DNA opposite lesions in the DNA template, but their accuracy is especially low during synthesis on undamaged DNA. In the present review fundamental features of such polymerases are considered. DNA synthesis stops in the area of its lesion, but this block is overcome due to activities of inaccurate specialized DNA polymerases. After the lesion is bypassed, DNA synthesis is switched to accurate polymerases α, δ, ɛ, or γ. Mechanisms of direct and reverse switches of DNA polymerases as well as their modifications during carcinogenesis are discussed.     

The Correcting Role of Autonomous 3" →="" 5"="" exonucleases="" contained="" in="" mammalian="" multienzyme="" dna="" polymerase="" complexes"="

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 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 error rate of the hepatocyte complex was estimated at 3·10^–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 ( subunit of E. coli DNA polymerase III). Nuclear (Pol _n) and cytosolic (Pol _c) forms of DNA polymerase were isolated from calf thymocytes. The former was shown to contain an AE (TREX2) absent from the latter. As compared with Pol _c, Pol _n had a 20-fold higher exo/pol ratio and allowed 4–5 times higher fidelity of DNA synthesis. The error rate of DNA polymerase complexes changed when dNTP were used in nonequimolar amounts.     

DNA Polymerase-associated and autonomous vertebrate 3′→5′ exonuleases

Using methods of gel filtration and ultracentrifugation, cell-free extracts from 12 objects representing the main vertebrate representatives (bony fish, amphibian, reptiles, birds, mammals, including human) were studied. The enzyme activity of autonomous 3′→5′-exonucleases (AE) has been established to be 25–90% of the total 3′→5′ exonuclease activity of the extracts. A part of the AE is revealed in a zone of the DNA polymerases of the α-family and can be separated by changing Chromatographic conditions or by repeated fractionation. The high activity of AE allows suggesting their substantial participation in the replicative correction of the DNA-poly-merase errors as well as in the postreplicative correction of the heteroduplexes in the vertebrate DNA.     

Complex of repair DNA polymerase β with autonomous 3′→5′ exonuclease shows increased accuracy of DNA synthesis

The complexes of repair DNA polymerase β 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 β was measured using phase ?X174 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 β 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.     

Autonomous 3'-->5' exonucleases can proofread for DNA polymerase beta from rat liver

Autonomous 3'-->5'exonucleases are not bound covalently to DNA polymerases but are often involved in replicative complexes. Such exonucleases from rat liver, calf thymus and Escherichia coli (molecular masses of 28+/-2 kDa) are shown to increase more than 10-fold the accuracy of DNA polymerase beta (the most inaccurate mammalian polymerase) from rat liver in the course of reduplication of the primed DNA of bacteriophage phiX174 amber 3 in vitro. The extent of correction increases together with the rise in 3'-->5' exonuclease concentration. Extrapolation of the in vitro DNA replication fidelity to the cellular levels of rat exonuclease and beta-polymerase suggests that exonucleolytic proofreading could augment the accuracy of DNA synthesis by two orders of magnitude. These results are not explained by exonucleolytic degradation of the primers ("no synthesis-no errors"), since similar data are obtained with the use of the primers 15 or 150 nucleotides long in the course of a fidelity assay of DNA polymerases, both alpha and beta, in the presence of various concentrations of 3'-->5' exonuclease.     

Ratio of 3′ → 5′-exonuclease and DNA polymerase activities in normal and cancer cells of rodents and human

Mutations in genes of DNA polymerases or corrective 3′ → 5′-exonucleases lead to a decrease in the fidelity of DNA biosynthesis throughout the genome, which is accompanied by an increase in the probability of mutagenesis and carcinogenesis. In the present work, activities of 3′ → 5′-exonucleases and DNA polymerases are studied in extracts of rodents and human normal and cancer cells and, for the first time, their integral ratios are measured to elucidate the role of correcting exonucleases in carcinogenesis. Thus, in experiments on cells growing in culture, it has been found that in adult human dermal fibroblasts the value of ratio of activity of 3′ → 5′-exonucleases to the DNA polymerase activity (3′-exo/pol) exceeds this ratio for HeLa cells. A similar situation is also observed in a comparison of normal rat embryo fibroblasts and Syrian hamster A238 transformed fibroblasts. Experiments with extracts of the cells some organs of healthy rats of different ages have shown that in norm the proliferating cells are characterized by higher activities of 3′ → 5′-exonucleases and higher 3′-exo/pol values than in quiescent cells. A comparison of these data allows us to conlude that a disturbance in the functions of corrective 3′ → 5′-exonucleases occurs in pathologically growing cancer cells.