Resolving Holliday junctions with Escherichia coli UvrD helicase

The Escherichia coli UvrD helicase is known to function in the mismatch repair and nucleotide excision repair pathways and has also been suggested to have roles in recombination and replication restart. The primary intermediate DNA structure in these two processes is the Holliday junction. UvrD has been shown to unwind a variety of substrates including partial duplex DNA, nicked DNA, forked DNA structures, blunt duplex DNA and RNA-DNA hybrids. Here, we demonstrate that UvrD also catalyzes the robust unwinding of Holliday junction substrates. To characterize this unwinding reaction we have employed steady-state helicase assays, pre-steady-state rapid quench helicase assays, DNaseI footprinting, and electron microscopy. We conclude that UvrD binds initially to the junction compared with binding one of the blunt ends of the four-way junction to initiate unwinding and resolves the synthetic substrate into two double-stranded fork structures. We suggest that UvrD, along with its mismatch repair partners, MutS and MutL, may utilize its ability to unwind Holliday junctions directly in the prevention of homeologous recombination. UvrD may also be involved in the resolution of stalled replication forks by unwinding the Holliday junction intermediate to allow bypass of the blockage.     

Characterization of the helicase activity and substrate specificity of Mycobacterium tuberculosis UvrD

UvrD is a helicase that is widely conserved in gram-negative bacteria. A uvrD homologue was identified in Mycobacterium tuberculosis on the basis of the homology of its encoded protein with Escherichia coli UvrD, with which it shares 39% amino acid identity, distributed throughout the protein. The gene was cloned, and a histidine-tagged form of the protein was expressed and purified to homogeneity. The purified protein had in vitro ATPase activity that was dependent upon the presence of DNA. Oligonucleotides as short as four nucleotides were sufficient to promote the ATPase activity. The DNA helicase activity of the enzyme was only fueled by ATP and dATP. UvrD preferentially unwound 3'-single-stranded tailed duplex substrates over 5'-single-stranded ones, indicating that the protein had a duplex-unwinding activity with 3'-to-5' polarity. A 3' single-stranded DNA tail of 18 nucleotides was required for effective unwinding. By using a series of synthetic oligonucleotide substrates, we demonstrated that M. tuberculosis UvrD has an unwinding preference towards nicked DNA duplexes and stalled replication forks, representing the likely sites of action in vivo. The potential role of M. tuberculosis UvrD in maintenance of bacterial genomic integrity makes it a promising target for drug design against M. tuberculosis.     

A Dimer of Escherichia coli UvrD is the active form of the helicase in vitro

The Escherichia coli UvrD protein is a 3' to 5' SF1 DNA helicase involved in methyl-directed mismatch repair and nucleotide excision repair of DNA. We have characterized in vitro UvrD-catalyzed unwinding of a series of 18 bp duplex DNA substrates with 3' single-stranded DNA (ssDNA) tails ranging in length from two to 40 nt. Single turnover DNA-unwinding experiments were performed using chemical quenched flow methods, as a function of both [UvrD] and [DNA] under conditions such that UvrD-DNA binding is stoichiometric. Although a single UvrD monomer binds tightly to the single-stranded/double-stranded DNA (dsDNA) junction if the 3' ssDNA tail is at least four nt, no unwinding was observed for DNA substrates with tail-lengths /=12 nt, and the unwinding amplitude displays a sigmoidal dependence on [UvrD(tot)]/[DNA(tot)]. Quantitative analysis of these data indicates that a single UvrD monomer bound at the ssDNA/dsDNA junction of any DNA substrate, independent of 3' ssDNA tail length, is not competent to fully unwind even a short 18 bp duplex DNA, and that two UvrD monomers must bind the DNA substrate in order to form a complex that is able to unwind short DNA substrates in vitro. Other proteins, including a mutant UvrD with no ATPase activity as well as a monomer of the structurally homologous E.coli Rep helicase, cannot substitute for the second UvrD monomer, suggesting a specific interaction between two UvrD monomers and that both must be able to hydrolyze ATP. Initiation of DNA unwinding in vitro appears to require a dimeric UvrD complex in which one subunit is bound to the ssDNA/dsDNA junction, while the second subunit is bound to the 3' ssDNA tail.     

Cloning, sequencing, and expression of ruvB and characterization of RuvB proteins from two distantly related thermophilic eubacteria.

The ruvB genes of the highly divergent thermophilic eubacteria Thermus thermophilus and Thermotoga maritima were cloned, sequenced, and expressed in Escherichia coli. Both thermostable RuvB proteins were purified to homogeneity. Like E. coli RuvB protein, both purified thermostable RuvB proteins showed strong double-stranded DNA-dependent ATPase activity at their temperature optima (> or = 70 degrees C). In the absence of ATP, T. thermophilus RuvB protein bound to linear double-stranded DNA with a preference for the ends. Addition of ATP or gamma-S-ATP destabilized the T. thermophilus RuvB-DNA complexes. Both thermostable RuvB proteins displayed helicase activity on supercoiled DNA. Expression of thermostable T. thermophilus RuvB protein in the E. coli ruvB recG mutant strain N3395 partially complemented the UV-sensitive phenotype, suggesting that T. thermophilus RuvB protein has a function similar to that of E. coli RuvB in vivo.     

Further characterization of DNA helicase activity of mouse DNA-dependent adenosinetriphosphatase B (DNA helicase B)

The DNA helicase activity of DNA-dependent ATPase B purified from mouse FM3A cells [Seki, M., Enomoto, T., Hanaoka, F., & Yamada, M. (1987) Biochemistry 26, 2924-2928] has been further characterized. The helicase activity was assayed with partially duplex DNA substrates in which oligonucleotides to be released by the enzyme were radiolabeled. Oligonucleotides with or without phosphate at the 5' termini or with a deoxy- or dideoxyribose at the 3'-terminal nucleotides were displaced by this enzyme with essentially the same efficiency and with the same ATP (and dATP) and Mg2+ requirements. Thus, there was no strict structure requirement for both ends of duplex regions of substrates to be unwound by the enzyme. Shorter strands were released more readily than longer strands up to the length of 140 bases. The attachment of the enzyme to a single-stranded DNA region was a prerequisite for the neighboring duplex to be unwound; the enzyme-catalyzed unwinding was inhibited competitively by the coaddition of single-stranded DNAs which act as cofactors of the ATPase activity. Their activities as the inhibitor of helicase were well correlated with those as the cofactor of ATPase. The helicase B was found to migrate along single-stranded DNA in the 5' to 3' direction by the use of single strands with short duplex regions at both 3' and 5' ends as substrate. A possible role of this enzyme in DNA replication in mammalian cells is discussed.     

Kinetic mechanism for formation of the active,dimeric UvrD helicase-DNA complex

Escherichia coli UvrD protein is a 3' to 5' SF1 helicase required for DNA repair as well as DNA replication of certain plasmids. We have shown previously that UvrD can self-associate to form dimers and tetramers in the absence of DNA, but that a UvrD dimer is required to form an active helicase-DNA complex in vitro. Here we have used pre-steady state, chemical quenched flow methods to examine the kinetic mechanism for formation of the active, dimeric helicase-DNA complex. Experiments were designed to examine the steps leading to formation of the active complex, separate from the subsequent DNA unwinding steps. The results show that the active dimeric complex can form via two pathways. The first, faster path involves direct binding to the DNA substrate of a pre-assembled UvrD dimer (dimer path), whereas the second, slower path proceeds via sequential binding to the DNA substrate of two UvrD monomers (monomer path), which then assemble on the DNA to form the dimeric helicase. The rate-limiting step within the monomer pathway involves dimer assembly on the DNA. These results show that UvrD dimers that pre-assemble in the absence of DNA are intermediates along the pathway to formation of the functional dimeric UvrD helicase.     

Characterisation of Bacillus stearothermophilus PcrA helicase: evidence against an active rolling mechanism.

PcrA from Bacillus stearothermophilus is a DNA helicase for which, despite the availability of a crystal structure, there is very little biochemical information. We show that the enzyme has a broad nucleotide specificity, even being able to hydrolyse ethenonucleotides, and is able to couple the hydrolysis to unwinding of DNA substrates. In common with the Escherichia coli helicases Rep and UvrD, PcrA is a 3'-5' helicase but at high protein concentrations it can also displace a substrate with a 5' tail. However, in contrast to Rep and UvrD, we do not see any evidence for dimerisation of the protein even in the presence of DNA. The enzyme shows a specificity for the DNA substrate in gel mobility assays, with the preferred substrate being one with both single and double stranded regions of DNA. We propose that these data, together with existing structural evidence, support an inchworm rather than a rolling model for 3'-5' helicase activity.     

The UvrD303 Hyper-helicase Exhibits Increased Processivity

DNA helicases use energy derived from nucleoside 5′-triphosphate hydrolysis to catalyze the separation of double-stranded DNA into single-stranded intermediates for replication, recombination, and repair. Escherichia coli helicase II (UvrD) functions in methyl-directed mismatch repair, nucleotide excision repair, and homologous recombination. A previously discovered 2-amino acid substitution of residues 403 and 404 (both Asp → Ala) in the 2B subdomain of UvrD (uvrD303) confers an antimutator and UV-sensitive phenotype on cells expressing this allele. The purified protein exhibits a “hyper-helicase” unwinding activity in vitro. Using rapid quench, pre-steady state kinetic experiments we show the increased helicase activity of UvrD303 is due to an increase in the processivity of the unwinding reaction. We suggest that this mutation in the 2B subdomain results in a weakened interaction with the 1B subdomain, allowing the helicase to adopt a more open conformation. This is consistent with the idea that the 2B subdomain may have an autoregulatory role. The UvrD303 mutation may enable the helicase to unwind DNA via a “strand displacement” mechanism, which is similar to the mechanism used to processively translocate along single-stranded DNA, and the increased unwinding processivity may contribute directly to the antimutator phenotype.     

Evidence for a physical interaction between the Escherichia coli methyl-directed mismatch repair proteins MutL and UvrD.

UvrD (DNA helicase II) is an essential component of two major DNA repair pathways in Escherichia coli: methyl-directed mismatch repair and UvrABC-mediated nucleotide excision repair. In addition, it has an undefined role in the RecF recombination pathway and possibly in replication. In an effort to better understand the role of UvrD in these various aspects of DNA metabolism, a yeast two-hybrid screen was used to search for interacting protein partners. Screening of an E.coli genomic library revealed a potential interaction between UvrD and MutL, a component of the methyl-directed mismatch repair pathway. The interaction was confirmed by affinity chromatography using purified proteins. Deletion analysis demonstrated that the C-terminal 218 amino acids (residues 398-615) of MutL were sufficient to produce the two-hybrid interaction with UvrD. On the other hand, both the N- and C-termini of UvrD were required for interaction with MutL. The implications of this interaction for the mismatch repair mechanism are discussed.     

Modulation of UvrD Helicase Activity by Covalent DNA-Protein Cross-links

UvrD (DNA helicase II) has been implicated in DNA replication, DNA recombination, nucleotide excision repair, and methyl-directed mismatch repair. The enzymatic function of UvrD is to translocate along a DNA strand in a 3′ to 5′ direction and unwind duplex DNA utilizing a DNA-dependent ATPase activity. In addition, UvrD interacts with many other proteins involved in the above processes and is hypothesized to facilitate protein turnover, thus promoting further DNA processing. Although UvrD interactions with proteins bound to DNA have significant biological implications, the effects of covalent DNA-protein cross-links on UvrD helicase activity have not been characterized. Herein, we demonstrate that UvrD-catalyzed strand separation was inhibited on a DNA strand to which a 16-kDa protein was covalently bound. Our sequestration studies suggest that the inhibition of UvrD activity is most likely due to a translocation block and not helicase sequestration on the cross-link-containing DNA substrate. In contrast, no inhibition of UvrD-catalyzed strand separation was apparent when the protein was linked to the complementary strand. The latter result is surprising given the earlier observations that the DNA in this covalent complex is severely bent (∼70°), with both DNA strands making multiple contacts with the cross-linked protein. In addition, UvrD was shown to be required for replication of plasmid DNAs containing covalent DNA-protein complexes. Combined, these data suggest a critical role for UvrD in the processing of DNA-protein cross-links.     

RNA template-dependent 5' nuclease activity of Thermus aquaticus and Thermus thermophilus DNA polymerases

DNA replication and repair require a specific mechanism to join the 3'- and 5'-ends of two strands to maintain DNA continuity. In order to understand the details of this process, we studied the activity of the 5' nucleases with substrates containing an RNA template strand. By comparing the eubacterial and archaeal 5' nucleases, we show that the polymerase domain of the eubacterial enzymes is critical for the activity of the 5' nuclease domain on RNA containing substrates. Analysis of the activity of chimeric enzymes between the DNA polymerases from Thermus aquaticus (TaqPol) and Thermus thermophilus (TthPol) reveals two regions, in the "thumb" and in the "palm" subdomains, critical for RNA-dependent 5' nuclease activity. There are two critical amino acids in those regions that are responsible for the high activity of TthPol on RNA containing substrates. Mutating glycine 418 and glutamic acid 507 of TaqPol to lysine and glutamine, respectively, increases its RNA-dependent 5' nuclease activity 4-10-fold. Furthermore, the RNA-dependent DNA polymerase activity is controlled by a completely different region of TaqPol and TthPol, and mutations in this region do not affect the 5' nuclease activity. The results presented here suggest a novel substrate binding mode of the eubacterial DNA polymerase enzymes, called a 5' nuclease mode, that is distinct from the polymerizing and editing modes described previously. The application of the enzymes with improved RNA-dependent 5' nuclease activity for RNA detection using the invasive signal amplification assay is discussed.     

Self-association equilibria of Escherichia coli UvrD helicase studied by analytical ultracentrifugation

The Escherichia coli UvrD protein (helicase II) is an SF1 superfamily helicase required for methyl-directed mismatch repair and nucleotide excision repair of DNA. We have characterized quantitatively the self-assembly equilibria of the UvrD protein as a function of [NaCl], [glycerol], and temperature (5-35 degrees C; pH 8.3) using analytical sedimentation velocity and equilibrium techniques, and find that UvrD self-associates into dimeric and tetrameric species over a range of solution conditions (t相似文献   

Differential inhibition of the DNA translocation and DNA unwinding activities of DNA helicases by the Escherichia coli Tus protein.

Binding of the Escherichia coli Tus protein to its cognate nonpalindromic binding site on duplex DNA (a Ter sequence) is sufficient to arrest the progression of replication forks in a Ter orientation-dependent manner in vivo and in vitro. In order to probe the molecular mechanism of this inhibition, we have used a strand displacement assay to investigate the effect of Tus on the DNA helicase activities of DnaB, PriA, UvrD (helicase II), and the phi X-type primosome. When the substrate was a short oligomer hybridized to a circular single-stranded DNA, strand displacement by DnaB, PriA, and the primosome (in both directions), but not UvrD, was blocked by Tus in a polar fashion. However, no inhibition of either DnaB or UvrD was observed when the substrate carried an elongated duplex region. With this elongated substrate, PriA helicase activity was only inhibited partially (by 50%). On the other hand, both the 5'----3' and 3'----5' helicase activities of the primosome were inhibited almost completely by Tus with the elongated substrate. These results suggest that while Tus can inhibit the translocation of some proteins along single-stranded DNA in a polar fashion, this generalized effect is insufficient for the inhibition of bona fide DNA helicase activity.     

Thermus scotoductus and Rhodothermus marinus DNA ligases have higher ligation efficiencies than thermus thermophilus DNA ligase

To mimic large numbers of nicked DNA duplexes we used a technique that produces nicked duplex DNA substrates by hybridization of complementary oligonucleotides, adjacent to an initiating primer, which are ligated together by a thermostable DNA ligase. Sequential ligation of nonanucleotides to this primary duplex results in the formation of polymers that can be analyzed by gel electrophoresis. The extent of polymerization is a measure of the efficiency of ligation. We determined the efficiency of ligation of nonanucleotides, using various length initiating primers, with three thermostable DNA ligases: Thermus thermophilus (Tth), Thermus scotoductus (Ts), and Rhodothermus marinus (Rm). Analysis of the effect of temperature for each ligase, and for each directing primer length, revealed that at 37 and 41 degrees C there was variation between ligase efficiency in the order Rm > or = Ts > or = Tth. The higher temperature of 46 degrees C was optimal for polymerization with each of the ligases and Rm ligase was the most efficient. Analysis of directionality of the ligations reactions suggests that for each of the Thermus ligases we tested, there was a bias to polymerization of nonanucleotides in a 5'-3' direction.     

The DNA repair helicase UvrD is essential for replication fork reversal in replication mutants

Replication forks arrested by inactivation of the main Escherichia coli DNA polymerase (polymerase III) are reversed by the annealing of newly synthesized leading- and lagging-strand ends. Reversed forks are reset by the action of RecBC on the DNA double-strand end, and in the absence of RecBC chromosomes are linearized by the Holliday junction resolvase RuvABC. We report here that the UvrD helicase is essential for RuvABC-dependent chromosome linearization in E. coli polymerase III mutants, whereas its partners in DNA repair (UvrA/B and MutL/S) are not. We conclude that UvrD participates in replication fork reversal in E. coli.     

Electron microscopic analysis of DNA forks generated by Escherichia coli DNA helicase II

T7 phage DNA eroded with lambda exonuclease (to create 3'-protruding strands) or exonuclease III (to create 5'-protruding strands) was treated under unwinding assay conditions with DNA helicase II. Single-stranded DNA-binding protein (of Escherichia coli or phage T4) was added to disentangle the denatured DNA and the complexes were examined in the electron microscope. DNA helicase II complexes filtered through a gel column before assay retain the ability to generate forks suggesting that DNA helicase II unwinds in a preformed complex by translocating along the bound DNA strand. The enzyme initiates preferentially at the ends of the lambda-exonuclease-treated duplexes and is found at a fork on the initially protruding strand. It also initiates at the ends of the exonuclease-III-treated duplexes where, as with approximately 5% of the forks traceable back to a single-stranded gap, it is found on the initially recessed strand. The results are consistent with the view that DNA helicase II unwinds in the 3'-5' direction relative to the bound strand. They also confirm that the enzyme can initiate at the end of a fully base-paired strand. At a fork, DNA helicase II is bound as a tract of molecules of approximately 110 nm in length. Tracts of enzyme assemble from non-cooperatively bound molecules in the presence of ATP. During unwinding, DNA helicase II apparently can translocate to the displaced strand which conceivably can deplete the leading strand of the enzyme. Continued adsorption of enzyme to DNA might replenish forks arrested by strand switch of the unwinding enzyme.     

Regulation of UvrD Helicase Activity by MutL

Escherichia coli UvrD is a superfamily 1 helicase/translocase involved in multiple DNA metabolic processes including methyl-directed mismatch DNA repair. Although a UvrD monomer can translocate along single-stranded DNA, a UvrD dimer is needed for processive helicase activity in vitro. E. coli MutL, a regulatory protein involved in methyl-directed mismatch repair, stimulates UvrD helicase activity; however, the mechanism is not well understood. Using single-molecule fluorescence and ensemble approaches, we find that a single MutL dimer can activate latent UvrD monomer helicase activity. However, we also find that MutL stimulates UvrD dimer helicase activity. We further find that MutL enhances the DNA-unwinding processivity of UvrD. Hence, MutL acts as a processivity factor by binding to and presumably moving along with UvrD to facilitate DNA unwinding.