Eukaryotic DNA polymerases in DNA replication and DNA repair

DNA polymerases carry out a large variety of synthetic transactions during DNA replication, DNA recombination and DNA repair. Substrates for DNA polymerases vary from single nucleotide gaps to kilobase size gaps and from relatively simple gapped structures to complex replication forks in which two strands need to be replicated simultaneously. Consequently, one would expect the cell to have developed a well-defined set of DNA polymerases with each one uniquely adapted for a specific pathway. And to some degree this turns out to be the case. However, in addition we seem to find a large degree of cross-functionality of DNA polymerases in these different pathways. DNA polymerase α is almost exclusively required for the initiation of DNA replication and the priming of Okazaki fragments during elongation. In most organisms no specific repair role beyond that of checkpoint control has been assigned to this enzyme. DNA polymerase δ functions as a dimer and, therefore, may be responsible for both leading and lagging strand DNA replication. In addition, this enzyme is required for mismatch repair and, together with DNA polymerase ζ, for mutagenesis. The function of DNA polymerase ɛ in DNA replication may be restricted to that of Okazaki fragment maturation. In contrast, either polymerase δ or ɛ suffices for the repair of UV-induced damage. The role of DNA polymerase β in base-excision repair is well established for mammalian systems, but in yeast, DNA polymerase δ appears to fullfill that function. Received: 20 April 1998 / Accepted: 8 May 1998     

Present-Day DNA Contamination in Ancient DNA Datasets

Present-day contamination can lead to false conclusions in ancient DNA studies. A number of methods are available to estimate contamination, which use a variety of signals and are appropriate for different types of data. Here an overview of currently available methods highlighting their strengths and weaknesses is provided, and a classification based on the signals used to estimate contamination is proposed. This overview aims at enabling researchers to choose the most appropriate methods for their dataset. Based on this classification, potential avenues for the further development of methods are discussed.     

Application of DNA methyltransferases in targeted DNA methylation

Taxol is a valuable plant-derived drug showing activity against various cancer types. Worldwide efforts had been made to overcome the supply problem, because the supply by isolation from the bark of the slow-growing yew trees is limited. Plant cell cultures as well as chemical and biotechnological semisynthesis are processes, which are intensively investigated for the production of taxanes paclitaxel (Taxol) and docetaxel (Taxotere) in the last few years. This article provides a comparison of the current research on taxane biosynthesis and production in yew cell cultures.     

Counterintuitive DNA Sequence Dependence in Supercoiling-Induced DNA Melting

The metabolism of DNA in cells relies on the balance between hybridized double-stranded DNA (dsDNA) and local de-hybridized regions of ssDNA that provide access to binding proteins. Traditional melting experiments, in which short pieces of dsDNA are heated up until the point of melting into ssDNA, have determined that AT-rich sequences have a lower binding energy than GC-rich sequences. In cells, however, the double-stranded backbone of DNA is destabilized by negative supercoiling, and not by temperature. To investigate what the effect of GC content is on DNA melting induced by negative supercoiling, we studied DNA molecules with a GC content ranging from 38% to 77%, using single-molecule magnetic tweezer measurements in which the length of a single DNA molecule is measured as a function of applied stretching force and supercoiling density. At low force (<0.5pN), supercoiling results into twisting of the dsDNA backbone and loop formation (plectonemes), without inducing any DNA melting. This process was not influenced by the DNA sequence. When negative supercoiling is introduced at increasing force, local melting of DNA is introduced. We measured for the different DNA molecules a characteristic force F _char, at which negative supercoiling induces local melting of the dsDNA. Surprisingly, GC-rich sequences melt at lower forces than AT-rich sequences: F _char = 0.56pN for 77% GC but 0.73pN for 38% GC. An explanation for this counterintuitive effect is provided by the realization that supercoiling densities of a few percent only induce melting of a few percent of the base pairs. As a consequence, denaturation bubbles occur in local AT-rich regions and the sequence-dependent effect arises from an increased DNA bending/torsional energy associated with the plectonemes. This new insight indicates that an increased GC-content adjacent to AT-rich DNA regions will enhance local opening of the double-stranded DNA helix.     

Function of DNA Polymerase III in DNA Replication

RECENTLY an in vitro system for DNA replication has been described. This system could be divided into two fractions (A and B) both of which are necessary for proper DNA replication¹. Fraction A, the “soluble” fraction, contains those proteins which do not tightly bind to membranes or native DNA. Fraction B, the “insoluble” fraction, consists of DNA and membranous structures and proteins which are bound to either of them. It was shown that the soluble fraction contains at least one component which is needed at about in vivo concentration¹. Studies of one such component are described in the following.     

Accuracy of DNA polymerase-alpha in copying natural DNA

The fidelity of DNA polymerase-alpha from calf thymus (9S enzyme) in copying bacteriophage phi174am16 DNA in vitro has been determined from the frequency of production of different revertants. In the self-priming reaction we were able to measure the frequencies of base pairing mismatches during the course of replication on biasing the ratios of deoxynucleoside triphosphates. The frequency of dGTP:T, dGTP:G and dATP:G mismatches were 7.6 x 10(-5), 4.4 x 10(-5) and 2.8 x 10(-5), respectively, at equal concentrations of the deoxynucleoside triphosphates. dCTP:A, dGTP:A, dCTP:T and dTTP:T mismatches were below the limit of detection (<5 x 10(-6)). A synthetic dodecamer primer with a 3' end covering the first two bases of the amber codon was used to determine the misinsertion frequency of the first nucleotide incorporated. This gave a misinsertion frequency of 1.5 x 10(-4) for the dGTP:T mismatch, which is slightly higher than that observed from the pool bias studies. Further, it showed no sensitivity to biasing the nucleotide pool, suggesting a different mechanism for the incorporation of the first nucleotide. These data do not support 'energy-relay'-like models for achieving high accuracy in eukaryotes. The observed misinsertion frequencies were corrected for mismatch repair of the heteroduplexes during the transfection experiments by parallel experiments using a mismatched primer. This was synthesized to have the same G:T mismatch as produced in the preceding experiment.     

DNA: DNA Hybridization studies in black flies

The phylogenetic relationships of six species of black flies were investigated using the hybridization of iodinated unique DNA sequences. The thermal stability of these labelled hybrids allowed the construction of a phylogenetic tree based on base mismatch between chains of the heterologous duplex.     

Uracil in DNA

The data confirming the formation of dUMP residues in DNA to be a continuous process taking place in the living cells are reviewed. All living organisms produce specific enzymes repairing the lesion of this type. The possible ways for uracil incorporation into DNA are described. The main of them are as follows: cytosine deamination in DNA molecules and utilization of dUTP by DNA polymerases during replication. The spontaneous mutability, the decrease in chain length of the newly synthesized DNA and the increase in recombination frequencies are discussed as possible consequences of this phenomenon.     

Solitons in DNA

DNA is modeled as a homogeneous, cylindrical rod with nonlinear elasticity using the Ostrovskii-Sutin equation (OSE) with periodic boundary conditions. This equation predicts that longitudinal sound waves will be concentrated into packets called solitons. From a study of the damped OSE, we conclude that decay time is almost independent of the solitonic character of the solution. For the damped, driven OSE, on the other hand, we find that spectral features (such as absorption line widths and fine structure) are strongly influenced by the presence of anharmonicity. This effect is enhanced as the length of the DNA is increased.     

Dual roles for DNA polymerase eta in homologous DNA recombination and translesion DNA synthesis

Chicken B lymphocyte precursors and DT40 cells diversify their immunoglobulin-variable (IgV) genes through homologous recombination (HR)-mediated Ig gene conversion. To identify DNA polymerases that are involved in Ig gene conversion, we created DT40 clones deficient in DNA polymerase eta (poleta), which, in humans, is defective in the variant form of xeroderma pigmentosum (XP-V). Poleta is an error-prone translesion DNA synthesis polymerase that can bypass UV damage-induced lesions and is involved in IgV hypermutation. Like XP-V cells, poleta-disrupted (poleta) clones exhibited hypersensitivity to UV. Remarkably, poleta cells showed a significant decrease in the frequency of both Ig gene conversion and double-strand break-induced HR when compared to wild-type cells, and these defects were reversed by complementation with human poleta. Our findings identify a DNA polymerase that carries out DNA synthesis for physiological HR and provides evidence that a single DNA polymerase can play multiple cellular roles.     

DNA Products in In Vitro DNA Synthesis Using Bacteriophage ϕX174 Single-stranded DNA

We described product analysis of DNA synthesized in chloroplast lysate from liverwort Marchantia polymorpha L. cell suspension cultures. Characteristics of in vitro DNA synthesis by chloroplast lysate using bacteriophage ?X174 single-stranded DNA were very similar to those in the case of double-stranded calf thymus DNA reported previously. Autoradiographic analysis clearly showed the incorporation of radioactive [α-³²P]-dCTP into DNA molecules associated with bacteriophage ?X174 single-stranded template DNA, indicating conversion of bacteriophage ?X174 single-stranded DNA to double-stranded DNA (RF III, double-stranded linear molecule). Experiments on the fate of [³²P]-labeled single-stranded DNA also showed a clear conversion of the single-stranded DNA to double-stranded DNA. Furthermore, patterns of sucrose density gradient centrifugations (neutral and alkaline) showed the production of two major components in in vitro DNA synthesis by chloroplast lysate. This also indicated conversion of bacteriophage ?X174 single-stranded DNA to double-stranded DNA (RF III form). Our results suggest that the mechanism of chloroplast DNA replication could be the mode of strand-displacement DNA synthesis as seen in animal mitochondrial DNA synthesis.     

A role for DNA primase in coupling DNA replication to DNA damage response.

The temperature-sensitive yeast DNA primase mutant pri1-M4 fails to execute an early step of DNA replication and exhibits a dominant, allele-specific sensitivity to DNA-damaging agents. pri1-M4 is defective in slowing down the rate of S phase progression and partially delaying the G1-S transition in response to DNA damage. Conversely, the G2 DNA damage response and the S-M checkpoint coupling completion of DNA replication to mitosis are unaffected. The signal transduction pathway leading to Rad53p phosphorylation induced by DNA damage is proficient in pri1-M4, and cell cycle delay caused by Rad53p overexpression is counteracted by the pri1-M4 mutation. Altogether, our results suggest that DNA primase plays an essential role in a subset of the Rad53p-dependent checkpoint pathways controlling cell cycle progression in response to DNA damage.     

Homologous recombination in DNA repair and DNA damage tolerance

Homologous recombination （HR） comprises a series of interrelated pathways that function in the repair of DNA double-stranded breaks （DSBs） and interstrand crosslinks （ICLs）. In addition, recombination provides critical support for DNA replication in the recovery of stalled or broken replication forks, contributing to tolerance of DNA damage. A central core of proteins, most critically the RecA homolog Rad51, catalyzes the key reactions that typify HR： homology search and DNA strand invasion. The diverse functions of recombination are reflected in the need for context-specific factors that perform supplemental functions in conjunction with the core proteins. The inability to properly repair complex DNA damage and resolve DNA replication stress leads to genomic instability and contributes to cancer etiology. Mutations in the BRCA2 recombination gene cause predisposition to breast and ovarian cancer as well as Fanconi anemia, a cancer predisposition syndrome characterized by a defect in the repair of DNA interstrand crosslinks. The cellular functions of recombination are also germane to DNA-based treatment modalities of cancer, which target replicating cells by the direct or indirect induction of DNA lesions that are substrates for recombination pathways. This review focuses on mechanistic aspects of HR relating to DSB and ICL repair as well as replication fork support.     

DNA Base composition and repetitious DNA in several conifers

Coniferous DNA was analyzed by ultraoentrifugation and thermal denaturation and renaturation to determine base composition and the presence of repetitive sequences. The percent quanine plus cytosine values among species were constant and independent of DNA quantity per cell, whereas the proportion of repetitive DNA per genome was greatest in those species that had the highest DNA content.