The Werner syndrome protein stimulates DNA polymerase beta strand displacement synthesis via its helicase activity

Werner syndrome is a hereditary premature aging disorder characterized by genomic instability. Genetic analysis and protein interaction studies indicate that the defective gene product (WRN) may play an important role in DNA replication, recombination, and repair. DNA polymerase beta (pol beta) is a central participant in both short and long-patch base excision repair (BER) pathways, which function to process most spontaneous, alkylated, and oxidative DNA damage. We report here a physical interaction between WRN and pol beta, and using purified proteins reconstitute of a portion of the long-patch BER pathway to examine a potential role for WRN in this repair response. We demonstrate that WRN stimulates pol beta strand displacement DNA synthesis and that this stimulation is dependent on the helicase activity of WRN. In addition, a truncated WRN protein, containing primarily the helicase domain, retains helicase activity and is sufficient to mediate the stimulation of pol beta. The WRN helicase also unwinds a BER substrate, providing evidence that WRN plays a role in unwinding DNA repair intermediates. Based on these findings, we propose a novel mechanism by which WRN may mediate pol beta-directed long-patch BER.     

Weak strand displacement activity enables human DNA polymerase beta to expand CAG/CTG triplet repeats at strand breaks

Using synthetic DNA constructs in vitro, we find that human DNA polymerase beta effectively catalyzes CAG/CTG triplet repeat expansions by slippage initiated at nicks or 1-base gaps within short (14 triplet) repeat tracts in DNA duplexes under physiological conditions. In the same constructs, Escherichia coli DNA polymerase I Klenow Fragment exo(-) is much less effective in expanding repeats, because its much stronger strand displacement activity inhibits slippage by enabling rapid extension through two downstream repeats into flanking non-repeat sequence. Polymerase beta expansions of CAG/CTG repeats, observed over a 32-min period at rates of approximately 1 triplet added per min, reveal significant effects of break type (nick versus gap), strand composition (CTG versus CAG), and dNTP substrate concentration, on repeat expansions at strand breaks. At physiological substrate concentrations (1-10 microm of each dNTP), polymerase beta expands triplet repeats with the help of weak strand displacement limited to the two downstream triplet repeats in our constructs. Such weak strand displacement activity in DNA repair at strand breaks may enable short tracts of repeats to be converted into longer, increasingly mutable ones associated with neurological diseases.     

Modeling translocation dynamics of strand displacement DNA synthesis by DNA polymerase I

A model is presented for the translocation dynamics of the strand displacement DNA synthesis by DNA polymerases such as polymerase I family. (i) The model gives an explanation to the experimental results which showed that the rate of strand displacement DNA synthesis is nearly consistent with that of single stranded primer extension synthesis, although the two are expected to have substantial differences in their energetics. (ii) During strand displacement DNA synthesis, the pausing at the specific sequence is considered to be due to an affinity of the fingers subdomain for the specific sequence of dsDNA downstream of the single strand. The theoretical results on the sequence-dependent pausing dynamics such as the mean pausing lifetimes and the distribution of the pausing lifetime are consistent with the experimental data. Moreover, predicted results are presented for the binding affinity of the fingers subdomain for the specific sequence of dsDNA and the dependence of the mean sequence-dependent pausing lifetime on the external force acting on the polymerase.     

Exonuclease of human DNA polymerase gamma disengages its strand displacement function

Pol γ, the only DNA polymerase found in human mitochondria, functions in both mtDNA repair and replication. During mtDNA base-excision repair, gaps are created after damaged base excision. Here we show that Pol γ efficiently gap-fills except when the gap is only a single nucleotide. Although wild-type Pol γ has very limited ability for strand displacement DNA synthesis, exo^? (3′–5′ exonuclease-deficient) Pol γ has significantly high activity and rapidly unwinds downstream DNA, synthesizing DNA at a rate comparable to that of the wild-type enzyme on a primer-template. The catalytic subunit Pol γA alone, even when exo^?, is unable to synthesize by strand displacement, making this the only known reaction of Pol γ holoenzyme that has an absolute requirement for the accessory subunit Pol γB.     

Sulfolobus chromatin proteins modulate strand displacement by DNA polymerase B1

Strand displacement by a DNA polymerase serves a key role in Okazaki fragment maturation, which involves displacement of the RNA primer of the preexisting Okazaki fragment into a flap structure, and subsequent flap removal and fragment ligation. We investigated the role of Sulfolobus chromatin proteins Sso7d and Cren7 in strand displacement by DNA polymerase B1 (PolB1) from the hyperthermophilic archaeon Sulfolobus solfataricus. PolB1 showed a robust strand displacement activity and was capable of synthesizing thousands of nucleotides on a DNA-primed 72-nt single-stranded circular DNA template. This activity was inhibited by both Sso7d and Cren7, which limited the flap length to 3–4 nt at saturating concentrations. However, neither protein inhibited RNA displacement on an RNA-primed single-stranded DNA minicircle by PolB1. Strand displacement remained sensitive to modulation by the chromatin proteins when PolB1 was in association with proliferating cell nuclear antigen. Inhibition of DNA instead of RNA strand displacement by the chromatin proteins is consistent with the finding that double-stranded DNA was more efficiently bound and stabilized than an RNA:DNA duplex by these proteins. Our results suggest that Sulfolobus chromatin proteins modulate strand displacement by PolB1, permitting efficient removal of the RNA primer while inhibiting excessive displacement of the newly synthesized DNA strand during Okazaki fragment maturation.     

Characterization of strand displacement synthesis catalyzed by bacteriophage T7 DNA polymerase

The DNA polymerase induced after infection of Escherichia coli by bacteriophage T7 can exist in two forms. One distinguishing property of Form I, the elimination of nicks in double-stranded DNA templates, strongly suggests that this form of the polymerase catalyzes limited DNA synthesis at nicks, resulting in displacement of the downstream strand. In this paper, we document this reaction by a detailed characterization of the DNA product. DNA synthesis on circular, duplex DNA templates containing a single site-specific nick results in circular molecules bearing duplex branches. Analysis of newly synthesized DNA excised from the product shows that the majority of the branches are less than 500 base pairs in length and that they arise from a limited number of sites. The branches have fully base-paired termini but are attached by two noncomplementary DNA strands that have a combined length of less than 30 nucleotides. The product molecules are topologically constrained as a result of the duplex branch. DNA sequence analysis has provided an unequivocal structure of one such product molecule. We conclude that strand displacement synthesis catalyzed by Form I of T7 DNA polymerase is terminated by a template-switching reaction. We propose two distinct models for template-switching that we call primer relocation and rotational strand exchange. Strand displacement synthesis catalyzed by Form I of T7 DNA polymerase effectively converts T7 DNA circles that are held together by hydrogen bonds in their 160-nucleotide-long terminal redundancy to T7-length linear molecules. We suggest that strand displacement synthesis catalyzed by T7 DNA polymerase is essential in vivo to the processing of a T7 DNA concatemer to mature T7 genomes.     

Mechanism of strand displacement DNA synthesis by the coordinated activities of human mitochondrial DNA polymerase and SSB

Many replicative DNA polymerases couple DNA replication and unwinding activities to perform strand displacement DNA synthesis, a critical ability for DNA metabolism. Strand displacement is tightly regulated by partner proteins, such as single-stranded DNA (ssDNA) binding proteins (SSBs) by a poorly understood mechanism. Here, we use single-molecule optical tweezers and biochemical assays to elucidate the molecular mechanism of strand displacement DNA synthesis by the human mitochondrial DNA polymerase, Polγ, and its modulation by cognate and noncognate SSBs. We show that Polγ exhibits a robust DNA unwinding mechanism, which entails lowering the energy barrier for unwinding of the first base pair of the DNA fork junction, by ∼55%. However, the polymerase cannot prevent the reannealing of the parental strands efficiently, which limits by ∼30-fold its strand displacement activity. We demonstrate that SSBs stimulate the Polγ strand displacement activity through several mechanisms. SSB binding energy to ssDNA additionally increases the destabilization energy at the DNA junction, by ∼25%. Furthermore, SSB interactions with the displaced ssDNA reduce the DNA fork reannealing pressure on Polγ, in turn promoting the productive polymerization state by ∼3-fold. These stimulatory effects are enhanced by species-specific functional interactions and have significant implications in the replication of the human mitochondrial DNA.     

DNA polymerase beta -mediated long patch base excision repair. Poly(ADP-ribose)polymerase-1 stimulates strand displacement DNA synthesis.

Recently, photoaffinity labeling experiments with mouse cell extracts suggested that PARP-1 functions as a surveillance protein for a stalled BER intermediate. To further understand the role of PARP-1 in BER, we examined the DNA synthesis and flap excision steps in long patch BER using a reconstituted system containing a 34-base pair BER substrate and five purified human enzymes: uracil-DNA glycosylase, apurinic/apyrimidinic endonuclease, DNA polymerase beta, flap endonuclease-1 (FEN-1), and PARP-1. PARP-1 stimulates strand displacement DNA synthesis by DNA polymerase beta in this system; this stimulation is dependent on the presence of FEN-1. PARP-1 and FEN-1, therefore, cooperate to activate long patch BER. The results are discussed in the context of a model for BER sub-pathway choice, illustrating a dual role for PARP-1 as a surveillance protein for a stalled BER intermediate and an activating factor for long patch BER DNA synthesis.     

Participation of the fingers subdomain of Escherichia coli DNA polymerase I in the strand displacement synthesis of DNA

The replication of the genome requires the removal of RNA primers from the Okazaki fragments and their replacement by DNA. In prokaryotes, this process is completed by DNA polymerase I by means of strand displacement DNA synthesis and 5 '-nuclease activity. Here, we demonstrate that the strand displacement DNA synthesis is facilitated by the collective participation of Ser(769), Phe(771), and Arg(841) present in the fingers subdomain of DNA polymerase I. The steady and presteady state kinetic analysis of the properties of appropriate mutant enzymes suggest that: (a) Ser(769) and Phe(771) together are involved in the strand separation via the formation of a flap structure, and (b) Arg(841) interacts with the template strand to achieve the optimal strand separation and DNA synthesis. The amino acid residues Ser(769) and Phe(771) are constituents of the O1-helix, which together with O and O2 helices form a 3-helix bundle structure. We note that this 3-helix bundle motif also exists in prokaryotic RNA polymerase. Thus in both DNA and RNA polymerases, this motif may have been adopted to achieve the strand separation function.     

Autographa californica nuclear polyhedrosis virus DNA polymerase: measurements of processivity and strand displacement

The DNA polymerase (DNApol) of Autographa californica nuclear polyhedrosis virus was purified to homogeneity from recombinant baculovirus-infected cells. DNApol was active in polymerase assays on singly primed M13 template, and full-length replicative form II product was synthesized at equimolar ratios of enzyme to template. The purified recombinant DNApol was shown to be processive by template challenge assay. Furthermore, DNApol was able to incorporate hundreds of nucleotides on an oligo(dT)-primed poly(dA) template with limiting amounts of polymerase. DNApol has moderate strand displacement activity, as it was active on nicked and gapped templates, and displaced a primer in a replication-dependent manner. Addition of saturating amounts of LEF-3, the viral single-stranded DNA-binding protein (SSB), increased the innate strand displacement ability of DNApol. However, when LEF-3 was added prior to the polymerase, it failed to stimulate DNApol replication on a singly primed M13 template because the helix-destabilizing activity of LEF-3 caused the primer to dissociate from the template. Escherichia coli SSB efficiently substituted for LEF-3 in the replication of a nicked template, suggesting that specific protein-protein interactions were not required for strand displacement in this assay.     

The ability of cestodes to synthesize serotonin

The ability of the parasitic flat worms Hymenolepis diminuta and Mesocestoides corti to synthetize serotonin (5-HT) has been investigated by means of incubation the worms in metabolic precursor of 5-HT, L-tryptophan, and monoamineoxidase inhibitor, indopan, followed by spectrofluorimetric determination of the tissue level of 5-HT. To avoid possible inhibition of 5-HT synthesis by exogenous 5-HT of the host, experiments were carried out on worms in which the level of 5-HT was previously decreased by reserpine. The increase in the level of 5-HT in tissues after incubation of the worms in L-tryptophan and indopan was observed, indicating their ability to synthetize serotonin from tryptophan.     

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.     

Mouse DNA replicase. DNA polymerase associated with a novel RNA polymerase activity to synthesize initiator RNA of strict size

De novo DNA synthesis on poly(dT) by a novel mouse DNA polymerase, here named "DNA replicase," was examined for the synthesis of RNA which functions as a primer in the subsequent synthesis of DNA. As has been reported previously (Yagura, T., Kozu, T., and Seno, T. (1982) J. Biochem. (Tokyo) 91, 607-618), a novel RNA polymerase activity, which is distinguished from those of classical RNA polymerases, is associated with DNA replicase. The synthesis of RNA and DNA by DNA replicase (Mr = 16 X 10(4), by glycerol gradient sedimentation analysis) was greatly stimulated by a specific stimulating factor (Mr = 13 X 10(4), by glycerol gradient sedimentation analysis) which was found to consist of two subunits (Mr = 63 X 10(3), by sodium dodecyl sulfate-polyacrylamide gel electrophoresis). Nearest neighbor analysis in which transfer of 32P from alpha-labeled nucleoside triphosphates to ribo- and deoxyribonucleotides was examined, showed th at RNA of 8-10 nucleotides long was covalently linked to the 5'-end of the DNA product molecule. This RNA, named initiator RNA, had a triphosphate group at its 5' terminus and its size and synthesis were little affected by the addition of high concentrations of deoxynucleoside triphosphate, while in these conditions deoxyribonucleotides were incorporated into initiator RNA to a limited extent. The characteristics of the DNA replicase and stimulating factor that cooperate to synthesize initiator RNA for subsequent DNA synthesis on single-stranded DNA are important because these components seem to be involved in a reaction required to initiate the synthesis of discontinuous earliest DNA intermediates (Okazaki fragments) in chromosomal DNA replication of eukaryotic cells.     

DNA strand displacement, strand annealing and strand swapping by the Drosophila Bloom's syndrome helicase

Genetic analysis of the Drosophila Bloom's syndrome helicase homolog (mus309/DmBLM) indicates that DmBLM is required for the synthesis-dependent strand annealing (SDSA) pathway of homologous recombination. Here we report the first biochemical study of DmBLM. Recombinant, epitope-tagged DmBLM was expressed in Drosophila cell culture and highly purified protein was prepared from nuclear extracts. Purified DmBLM exists exclusively as a high molecular weight (~1.17 MDa) species, is a DNA-dependent ATPase, has 3′→5′ DNA helicase activity, prefers forked substrate DNAs and anneals complementary DNAs. High-affinity DNA binding is ATP-dependent and low-affinity ATP-independent interactions contribute to forked substrate DNA binding and drive strand annealing. DmBLM combines DNA strand displacement with DNA strand annealing to catalyze the displacement of one DNA strand while annealing a second complementary DNA strand.     

First passage time study of DNA strand displacement

DNA strand displacement, in which a single-stranded nucleic acid invades a DNA duplex, is pervasive in genomic processes and DNA engineering applications. The kinetics of strand displacement have been studied in bulk; however, the kinetics of the underlying strand exchange were obfuscated by a slow bimolecular association step. Here, we use a novel single-molecule fluorescence resonance energy transfer approach termed the “fission” assay to obtain the full distribution of first passage times of unimolecular strand displacement. At a frame time of 4.4 ms, the first passage time distribution for a 14-nucleotide displacement domain exhibited a nearly monotonic decay with little delay. Among the eight different sequences we tested, the mean displacement time was on average 35 ms and varied by up to a factor of 13. The measured displacement kinetics also varied between complementary invaders and between RNA and DNA invaders of the same base sequence, except for T → U substitution. However, displacement times were largely insensitive to the monovalent salt concentration in the range of 0.25–1 M. Using a one-dimensional random walk model, we infer that the single-step displacement time is in the range of ～30–300 μs, depending on the base identity. The framework presented here is broadly applicable to the kinetic analysis of multistep processes investigated at the single-molecule level.     

Insights into strand displacement and processivity from the crystal structure of the protein-primed DNA polymerase of bacteriophage phi29

The DNA polymerase from phage phi29 is a B family polymerase that initiates replication using a protein as a primer, attaching the first nucleotide of the phage genome to the hydroxyl of a specific serine of the priming protein. The crystal structure of phi29 DNA polymerase determined at 2.2 A resolution provides explanations for its extraordinary processivity and strand displacement activities. Homology modeling suggests that downstream template DNA passes through a tunnel prior to entering the polymerase active site. This tunnel is too small to accommodate double-stranded DNA and requires the separation of template and nontemplate strands. Members of the B family of DNA polymerases that use protein primers contain two sequence insertions: one forms a domain not previously observed in polymerases, while the second resembles the specificity loop of T7 RNA polymerase. The high processivity of phi29 DNA polymerase may be explained by its topological encirclement of both the downstream template and the upstream duplex DNA.     

3' to 5' exonuclease activity of herpes simplex virus type 1 DNA polymerase modulates its strand displacement activity

Using a minicircle DNA primer-template, the wild-type catalytic subunit of herpes simplex virus type 1 (HSV-1) DNA polymerase (pol) was shown to lack significant strand displacement activity with or without its processivity factor, UL42. However, an exonuclease-deficient (exo(-)) pol (D368A) was capable of slow strand displacement. Although UL42 increased the rate (2/s) and processivity of strand displacement by exo(-) pol, the rate was slower than that for gap-filling synthesis. High inherent excision rates on matched primer-templates and rapid idling-turnover (successive rounds of excision and polymerization) of exo-proficient polymerases correlated with poor strand displacement activity. The results suggest that the exo activity of HSV-1 pol modulates its ability to engage in strand displacement, a function that may be important to the viability and genome stability of the virus.     

On the biophysics and kinetics of toehold-mediated DNA strand displacement

Dynamic DNA nanotechnology often uses toehold-mediated strand displacement for controlling reaction kinetics. Although the dependence of strand displacement kinetics on toehold length has been experimentally characterized and phenomenologically modeled, detailed biophysical understanding has remained elusive. Here, we study strand displacement at multiple levels of detail, using an intuitive model of a random walk on a 1D energy landscape, a secondary structure kinetics model with single base-pair steps and a coarse-grained molecular model that incorporates 3D geometric and steric effects. Further, we experimentally investigate the thermodynamics of three-way branch migration. Two factors explain the dependence of strand displacement kinetics on toehold length: (i) the physical process by which a single step of branch migration occurs is significantly slower than the fraying of a single base pair and (ii) initiating branch migration incurs a thermodynamic penalty, not captured by state-of-the-art nearest neighbor models of DNA, due to the additional overhang it engenders at the junction. Our findings are consistent with previously measured or inferred rates for hybridization, fraying and branch migration, and they provide a biophysical explanation of strand displacement kinetics. Our work paves the way for accurate modeling of strand displacement cascades, which would facilitate the simulation and construction of more complex molecular systems.     

RNA aptamers selected against DNA polymerase beta inhibit the polymerase activities of DNA polymerases beta and kappa

DNA polymerase β (polβ), a member of the X family of DNA polymerases, is the major polymerase in the base excision repair pathway. Using in vitro selection, we obtained RNA aptamers for polβ from a variable pool of 8 × 10¹² individual RNA sequences containing 30 random nucleotides. A total of 60 individual clones selected after seven rounds were screened for the ability to inhibit polβ activity. All of the inhibitory aptamers analyzed have a predicted tri-lobed structure. Gel mobility shift assays demonstrate that the aptamers can displace the DNA substrate from the polβ active site. Inhibition by the aptamers is not polymerase specific; inhibitors of polβ also inhibited DNA polymerase κ, a Y-family DNA polymerase. However, the RNA aptamers did not inhibit the Klenow fragment of DNA polymerase I and only had a minor effect on RB69 DNA polymerase activity. Polβ and κ, despite sharing little sequence similarity and belonging to different DNA polymerase families, have similarly open active sites and relatively few interactions with their DNA substrates. This may allow the aptamers to bind and inhibit polymerase activity. RNA aptamers with inhibitory properties may be useful in modulating DNA polymerase actvity in cells.     

Mechanism of strand displacement synthesis by DNA replicative polymerases

Replicative holoenzymes exhibit rapid and processive primer extension DNA synthesis, but inefficient strand displacement DNA synthesis. We investigated the bacteriophage T4 and T7 holoenzymes primer extension activity and strand displacement activity on a DNA hairpin substrate manipulated by a magnetic trap. Holoenzyme primer extension activity is moderately hindered by the applied force. In contrast, the strand displacement activity is strongly stimulated by the applied force; DNA polymerization is favoured at high force, while a processive exonuclease activity is triggered at low force. We propose that the DNA fork upstream of the holoenzyme generates a regression pressure which inhibits the polymerization-driven forward motion of the holoenzyme. The inhibition is generated by the distortion of the template strand within the polymerization active site thereby shifting the equilibrium to a DNA-protein exonuclease conformation. We conclude that stalling of the holoenzyme induced by the fork regression pressure is the basis for the inefficient strand displacement synthesis characteristic of replicative polymerases. The resulting processive exonuclease activity may be relevant in replisome disassembly to reset a stalled replication fork to a symmetrical situation. Our findings offer interesting applications for single-molecule DNA sequencing.