Direct measurement of single-stranded DNA intermediates in mammalian cells by quantitative polymerase chain reaction

Single-stranded DNA (ssDNA) intermediates are formed in multiple cellular processes, including DNA replication and recombination. Here, we describe a quantitative polymerase chain reaction (qPCR)-based assay to quantitate ssDNA intermediates, specifically the 3′ ssDNA product of resection at specific DNA double-strand breaks induced by the AsiSI restriction enzyme in human cells. We protect the large mammalian genome from shearing by embedding the cells in low-gelling-point agar during genomic DNA extraction and measure the levels of ssDNA intermediates by qPCR following restriction enzyme digestion. This assay is more quantitative and precise compared with existing immunofluorescence-based methods.     

Dideoxynucleoside triphosphates inhibit a late stage of SV40 DNA replicationin vitro

Summary The role of DNA polymerases in the replication of SV40 DNA was studied using a T-antigen-dependent assay supplemented with a human KB cell extract. Inhibition of DNA polymerase α by addition of aphidicolin or monoclonal antibodies prevented DNA synthesis, confirming the requirement for this enzyme in replication. The replication process was unaffected by ddTTP at a concentration (5 μM) inhibitory to DNA polymerases β and γ, however, higher concentrations of ddTTP (200 μM) caused an apparent accumulation of relaxed circular plasmid with a concomitant decrease in DNA synthesis. An analysis of this replication intermediate indicated that it was formed during the replication reaction and that the replicative cycle was nearly complete. A kinetic study of ddTTP inhibition strongly suggested DNA polymerase ε (PCNA-independent DNA polymerase δ) was the target of the inhibitor and that this enzyme functions during the final stages of DNA replication.     

Lyase activities intrinsic to Escherichia coli polymerases IV and V

Escherichia coli DNA polymerase IV and V (pol IV and pol V) are error-prone DNA polymerases that are induced as part of the SOS regulon in response to DNA damage. Both are members of the Y-family of DNA polymerases. Their principal biological roles appear to involve translesion synthesis (TLS) and the generation of mutational diversity to cope with stress. Although neither enzyme is known to be involved in base excision repair (BER), we have nevertheless observed apurinic/apyrimidinic 5'-deoxyribose phosphate (AP/5'-dRP) lyase activities intrinsic to each polymerase. Pols IV and V catalyze cleavage of the phosphodiester backbone at the 3'-side of an apurinic/apyrimidinic (AP) site as well as the removal of a 5'-deoxyribose phosphate (dRP) at a preincised AP site. The specific activities of the two error-prone polymerase-associated lyases are approximately 80-fold less than the associated lyase activity of human DNA polymerase beta, which is a key enzyme used in short patch BER. Pol IV forms a covalent Schiff's base intermediate with substrate DNA that is trapped by sodium borohydride, as proscribed by a beta-elimination mechanism. In contrast, a NaBH(4) trapped intermediate is not observed for pol V, even though the lyase specific activity of pol V is slightly higher than that of pol IV. Incubation of pol V (UmuD'(2)C) with a molar excess of UmuD drives an exchange of subunits to form UmuD'D+insoluble UmuC causing inactivation of polymerase and lyase activities. The concomitant loss of both activities is strong evidence that pol V contains a bona fide lyase activity.     

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.     

Human DNA polymerase lambda possesses terminal deoxyribonucleotidyl transferase activity and can elongate RNA primers: implications for novel functions

DNA polymerase lambda is a novel enzyme of the family X of DNA polymerases. The recent demonstration of an intrinsic 5'-deoxyribose-5'-phosphate lyase activity, a template/primer dependent polymerase activity, a distributive manner of DNA synthesis and sequence similarity to DNA polymerase beta suggested a novel beta-like enzyme. All these properties support a role of DNA polymerase lambda in base excision repair. On the other hand, the biochemical properties of the polymerisation activity of DNA polymerase lambda are still largely unknown. Here we give evidence that human DNA polymerase lambda has an intrinsic terminal deoxyribonucleotidyl transferase activity that preferentially adds pyrimidines onto 3'OH ends of DNA oligonucleotides. Furthermore, human DNA polymerase lambda efficiently elongates an RNA primer hybridized to a DNA template. These two novel properties of human DNA polymerase lambda might suggest additional roles for this enzyme in DNA replication and repair processes.     

Synthesis of γ-N-modified 8-oxo-2’-deoxyguanosine triphosphate and its characterization

8-OxodGTP is generated by the reaction between dGTP and reactive oxygen species and a considered mutagenic nucleotide. It can be incorporated into the duplex DNA during replication processes by the DNA polymerase, and thus the repair enzyme removes oxodGTP from the nucleotide pools in living cells. On the other hand, the γ-modified triphosphates show interesting properties for use as biological tools. Therefore, the γ-N-pyrenylalkyl-oxodGTP derivatives were synthesized and their effect on the enzymatic reactions were evaluated. The γ-N-pyrenylmethyl-oxodGTP was found to be accepted by the DNA polymerase just like oxodGTP, but showed a competitive inhibition property for the human oxodGTPase.     

Structures of the Leishmania infantum polymerase beta

Protozoans of the genus Leishmania, the pathogenic agent causing leishmaniasis, encode the family X DNA polymerase Li Pol β. Here, we report the first crystal structures of Li Pol β. Our pre- and post-catalytic structures show that the polymerase adopts the common family X DNA polymerase fold. However, in contrast to other family X DNA polymerases, the dNTP-induced conformational changes in Li Pol β are much more subtle. Moreover, pre- and post-catalytic structures reveal that Li Pol β interacts with the template strand through a nonconserved, variable region known as loop3. Li Pol β Δloop3 mutants display a higher catalytic rate, catalytic efficiency and overall error rates with respect to WT Li Pol β. These results further demonstrate the subtle structural variability that exists within this family of enzymes and provides insight into how this variability underlies the substantial functional differences among their members.     

The structure of a high fidelity DNA polymerase bound to a mismatched nucleotide reveals an "ajar" intermediate conformation in the nucleotide selection mechanism

To achieve accurate DNA synthesis, DNA polymerases must rapidly sample and discriminate against incorrect nucleotides. Here we report the crystal structure of a high fidelity DNA polymerase I bound to DNA primer-template caught in the act of binding a mismatched (dG:dTTP) nucleoside triphosphate. The polymerase adopts a conformation in between the previously established "open" and "closed" states. In this "ajar" conformation, the template base has moved into the insertion site but misaligns an incorrect nucleotide relative to the primer terminus. The displacement of a conserved active site tyrosine in the insertion site by the template base is accommodated by a distinctive kink in the polymerase O helix, resulting in a partially open ternary complex. We suggest that the ajar conformation allows the template to probe incoming nucleotides for complementarity before closure of the enzyme around the substrate. Based on solution fluorescence, kinetics, and crystallographic analyses of wild-type and mutant polymerases reported here, we present a three-state reaction pathway in which nucleotides either pass through this intermediate conformation to the closed conformation and catalysis or are misaligned within the intermediate, leading to destabilization of the closed conformation.     

ATP and the processivity of Xenopus laevis DNA polymerase α

We use specific restriction fragments as defined primers for DNA synthesis on single-stranded circular phage fd DNA. These structures are relatively poor templates for a highly purified DNA polymerase α from Xenopus laevis eggs. However, DNA synthesis is stimulated about 5-fold by addition of ATP to the reaction mixture. We show that the deoxynucleotide polymers, synthesized in the presence of ATP, are significantly longer than those produced in the absence of ATP. We also show that this effect is due to a more tenacious binding of DNA polymerase α to DNA and conclude that ATP increases the processivity of the enzyme.     

Thermostable DNA Polymerase from Thermus thermophilus B35: Preparation and Study of a Modified Form of the Enzyme with High Affinity to ddNTP

The hybrid protein consisting of Tte DNA polymerase fragment and mutant Taq DNA polymerase (F667Y) fragment in the ratio 20 : 1 was constructed. Affinity of the modified enzyme (substitutions F669Y, V667I, and S692Q) to ddNTP was two orders higher than that of the wild type enzyme. The modified enzyme was used for sequencing DNA fragment with total deoxyguanosine and deoxycytidine content of 68%. In the polymerase chain reaction, the modified enzyme exhibits properties typical of the wild type Tte DNA polymerase.     

In Vitro Processing of Heteroduplex Loops and Mismatches by Endonuclease VII

Endonuclease VII is a Holliday-structure resolving enzyme ofphage T4 which cleaves at junctions of branched DNAs and atmispairings. In extension of these findings we report the following:i) Endonuclease VII can discriminate between a large heteroduplexloop and a TT mismatch arranged in tandem, 6 nt distant fromeach other, in the same heteroduplex molecule. The enzyme cleavestwo nucleotides 3' from the base of the loop or the TT mismatch.ii) Similar to its reactions with mismatches cleavage of heteroduplexloops by endonucleave VII can also initiate correction of perfectdouble-strandedness by T4 DNA polymerase and T4 DNA-ligase invitro. Loops of 8 nt and 20 nt were repaired efficiently. iii)For the first time endonuclease VII cleavage sites were alsomapped in single-stranded DNA if it was part of the 20-nt loop.This suggests that looping of single-stranded DNA can induceformation of secondary structures, which are recognizable byendonuclease VII.     

A DNA topoisomerase activity copurifies with the DNA polymerase induced by herpes simplex virus

A DNA-relaxing enzyme was found to copurify along with herpes simplex virus type I (HSV-1)-induced DNA polymerase throughout a multistep purification scheme. Both the enzymes had similar sedimentation velocity, required high ionic strength for optimal enzymatic activities and showed time dependence of reaction. The DNA-relaxing enzyme however, differed from the HSV-1 DNA polymerase in its requirement for higher Mg²⁺ concentration, rATP and much broader pH dependence. Furthermore, phosphonoacetic acid, a potent inhibitor of HSV-1 DNA polymerase did not influence the DNA-relaxing activity even at a much higher concentration. On the other hand, the DNA-relaxing enzyme associated with the DNA polymerase may be specified by HSV-1 since IgG fraction of rabbit antisera against the virus-infected cells but not against the mock-infected cells strongly inhibited both the enzymatic activities. Thus, HSV-1-induced DNA polymerase which is known to be associated with a 3′ to 5′ exonuclease may also be associated with yet another enzymatic activity involved in DNA metabolism.     

The function of poly (ADP-ribosylation) in DNA breakage and rejoining

Poly (ADP-ribose) polymerase has an obligatory requirement for DNA strand-breaks in order to show full enzyme activity. Exposure of cells to DNA damaging agents activates this enzyme presumably through the production of DNA strand-breaks, either directly or via cellular enzymes. Recent evidence from manipulations of the cloned cDNA of this enzyme confirm the earlier evidence, obtained using enzyme inhibitors, that this enzyme is involved in DNA excision repair, probably at or near the ligation step. A very unusual human genetic disease has provided direct evidence for a link between the enzyme activities of poly (ADP-ribose) polymerase and of DNA ligase I. There is also some evidence that this enzyme may be involved in other cases of DNA breakage and rejoining, such as homologous and non-homologous DNA recombination, for example, in sister chromatid exchanges, in DNA transfection, in the intergration of retroviral proviral DNA and in variable antigen switching in African trypanosomes.     

Processing of DNA for nonhomologous end-joining by cell-free extract

In mammalian cells, nonhomologous end-joining (NHEJ) repairs DNA double-strand breaks created by ionizing radiation and V(D)J recombination. We have developed a cell-free system capable of processing and joining noncompatible DNA ends. The system had key features of NHEJ in vivo, including dependence on Ku, DNA-PKcs, and XRCC4/Ligase4. The NHEJ reaction had striking properties. Processing of noncompatible ends involved polymerase and nuclease activities that often stabilized the alignment of opposing ends by base pairing. To achieve this, polymerase activity efficiently synthesized DNA across discontinuities in the template strand, and nuclease activity removed a limited number of nucleotides back to regions of microhomology. Processing was suppressed for DNA ends that could be ligated directly, biasing the reaction to preserve DNA sequence and maintain genomic integrity. DNA sequence internal to the ends influenced the spectrum of processing events for noncompatible ends. Furthermore, internal DNA sequence strongly influenced joining efficiency, even in the absence of processing. These results support a model in which DNA-PKcs plays a central role in regulating the processing of ends for NHEJ.     

Distribution and roles of X-family DNA polymerases in eukaryotes

Four types of DNA polymerase (Pol beta, Pol lambda, Pol mu and TdT) have been identified in eukaryotes as members of the polymerase X-family. Only vertebrates have all four types of enzyme. Plants and fungi have one or two X-family polymerases, while protostomes, such as fruit flies and nematodes, do not appear to have any. It is possible that the well-known metabolic pathways in which these enzymes are involved are restricted to the vertebrate world. The distribution of the DNA polymerases involved in DNA repair across the various biological kingdoms differs from that of the DNA polymerases involved in chromosomal DNA replication. In this review, we focus on the interesting pattern of distribution of the X-family enzymes across biological kingdoms and speculate on their roles.     

Structure and conformational dynamics of base excision repair DNA glycosylases

DNA glycosylases play a key role in DNA repair, which maintains the integrity of the cell genome. The structures of many DNA glycosylases have been solved to date. The review considers these structures and the dynamics of DNA glycosylase interactions with DNA. The available data suggest that lesion recognition by DNA glycosylases is a highly dynamic process that is accompanied by multiple conformational changes in the enzyme and DNA substrate.     

Genetic evidence that aphidicolin inhibits in vivo DNA synthesis in Chinese hamster ovary cells

Using a genetic approach, Chinese hamster ovary (CHO) cells sensitive (aph^S) and resistant (aph^R) to aphidicolin were grown in the presence or absence of various DNA polymerase inhibitors, and the newly synthesized DNA isolated from [³²P]dNMP-labelled, detergent-permeabilized cells, was characterized after fractionation by gel electrophoresis. The particular aph ^Rmutant CHO cell line used was one selected for resistance to aphidicolin and found to possess an altered DNA polymerase of the a-family. The synthesis of a 24 kb replication intermediate was inhibited in wild-type CHO cells grown in the presence of aphidicolin, whereas the synthesis of this replication intermediate was not inhibited by this drug in the mutant CHO cells or in the aphidicolin-resistant somatic cell hybrid progeny constructed by fusion of wild-type and mutant cell lines. Arabinofuranosylcytosine (ara-C), like aphidicolin, inhibited the synthesis of this 24 kb DNA replication intermediate in the wild-type CHO cells but not in the aph^R mutant cells. However, carbonyldiphosphonate (COMDP) inhibited the synthesis of the 24 kb replication intermediate in both wild-type and mutant cells. N²-(p-n-Butylphenyl)-2 deoxyguanisine-5-triphosphate (BuPdGTP) was found to inhibit the formation of Okazaki fragments equally well in the wild-type and mutant cell lines and thus led to inhibition of synthesis of DNA intermediates in both cases. It appears that aphidicolin and ara-C both affect a common target on the DNA polymerase, which is different from that affected by COMDP in vivo. These data also show that aphidicolin, ara-C and COMDP affect the elongation activity of DNA polymerase but not the initiation activity of the enzyme during DNA replication. This is the first report of such differentiation of the DNA polymerase activities during nuclear DNA replication in mammalian cells. The method of analysis described here for replication intermediates can be used to examine the inhibitory activities of other chemicals on DNA synthesis.     

Influence of DNA aptamer structure on the specificity of binding to Taq DNA polymerase

The secondary structure of DNA aptamer to Taq DNA polymerase was established as a hairpin. Both stem and loop structures of DNA ligand were shown to be involved in the interaction with Taq DNA polymerase. Moreover, the structure and sequence of DNA aptamer that was the most effective inhibitor of DNA polymerase activity were established. This crucial structure was evaluated as a GC-rich stem longer than 17 bp, and a loop consisting of 12 bases with strictly determined nucleotide sequence. It was demonstrated that nucleotide in position 23 counting from the 5"-end of DNA ligand was involved in direct contact with Taq DNA polymerase. The ability of optimized DNA aptamer TQ21-11 to form a complex with the enzyme was increased 5-fold in comparison to the initial aptamer.     

Structure and enzymatic properties of a chimeric bacteriophage RB69 DNA polymerase and single-stranded DNA binding protein with increased processivity

In vivo, replicative DNA polymerases are made more processive by their interactions with accessory proteins at the replication fork. Single-stranded DNA binding protein (SSB) is an essential protein that binds tightly and cooperatively to single-stranded DNA during replication to remove adventitious secondary structures and protect the exposed DNA from endogenous nucleases. Using information from high resolution structures and biochemical data, we have engineered a functional chimeric enzyme of the bacteriophage RB69 DNA polymerase and SSB with substantially increased processivity. Fusion of RB69 DNA polymerase with its cognate SSB via a short six amino acid linker increases affinity for primer-template DNA by sixfold and subsequently increases processivity by sevenfold while maintaining fidelity. The crystal structure of this fusion protein was solved by a combination of multiwavelength anomalous diffraction and molecular replacement to 3.2 A resolution and shows that RB69 SSB is positioned proximal to the N-terminal domain of RB69 DNA polymerase near the template strand channel. The structural and biochemical data suggest that SSB interactions with DNA polymerase are transient and flexible, consistent with models of a dynamic replisome during elongation.