Plasmid replication initiator protein RepD increases the processivity of PcrA DNA helicase

The replication initiator protein RepD encoded by the Staphylococcus chloramphenicol resistance plasmid pC221 stimulates the helicase activity of the Bacillus stearothermophilus PcrA DNA helicase in vitro. This stimulatory effect seems to be specific for PcrA and differs from the stimulatory effect of the Escherichia coli ribosomal protein L3. Whereas L3 stimulates the PcrA helicase activity by promoting co-operative PcrA binding onto its DNA substrate, RepD stimulates the PcrA helicase activity by increasing the processivity of the enzyme and enables PcrA to displace DNA from a nicked substrate. The implication of these results is that PcrA is the helicase recruited into the replisome by RepD during rolling circle replication of plasmids of the pT181 family.     

The PcrA3 mutant binds DNA and interacts with the RepC initiator protein of plasmid pT181 but is defective in its DNA helicase and unwinding activities

Plasmid rolling-circle replication initiates by covalent extension of a nick generated at the plasmid double-strand origin (dso) by the initiator protein. The RepC initiator protein binds to the plasmid pT181 dso in a sequence-specific manner and recruits the PcrA helicase through a protein-protein interaction. Subsequently, PcrA unwinds DNA at the nick site followed by replication by DNA polymerase III. The pcrA3 mutant of Staphylococcus aureus has previously been shown to be defective in plasmid pT181 replication. Suppressor mutations in the repC initiator gene have been isolated that allow pT181 replication in the pcrA3 mutant. One such suppressor mutant contains a D57Y change in the RepC protein. To identify the nature of the defect in PcrA3, we have purified this mutant protein and studied its biochemical activities. Our results show that while PcrA3 retains its DNA binding activity, it is defective in its helicase and RepC-dependent pT181 DNA unwinding activities. We have also purified the RepC D57Y mutant and shown that it is similar in its biochemical activities to wild-type RepC. RepC D57Y supported plasmid pT181 replication in cell-free extracts made from wild-type S. aureus but not from the pcrA3 mutant. We also demonstrate that both wild-type RepC and its D57Y mutant are capable of a direct physical interaction with both wild-type PcrA and the PcrA3 mutant. Our results suggest that the inability of PcrA3 to support pT181 replication is unlikely to be due to its inability to interact with RepC. Rather, it is likely that a defect in its helicase activity is responsible for its inability to replicate the pT181 plasmid.     

Vinylphosphonate internucleotide linkages inhibit the activity of PcrA DNA helicase

During the past 5 years a great deal of structural and biochemical information has given us a detailed insight into the molecular mechanism of action of the PcrA DNA helicase and challenged previous notions about the molecular mechanism of action of helicases in general. Despite this wealth of information the mechanisms of the interaction of helicases with their DNA substrates and their unidirectional translocation along ssDNA are poorly understood. In this study, we synthesized a chemically modified DNA substrate with reduced backbone rotational flexibility and minimal steric hindrance and studied its effect on the activity of the monomeric 3'-5' DNA helicase, PcrA. Our results show that a single modification on the backbone of the translocating strand is sufficient to inhibit the activity of PcrA helicase, suggesting that rotational flexibility of the backbone is important for efficient unwinding.     

The beta-propeller protein YxaL increases the processivity of the PcrA helicase

The DNA helicase PcrA is found in gram-positive bacteria and belongs to the superfamily 1 (SF1) of helicases, together with Rep and UvrD helicases from Escherichia coli. These helicases have been extensively studied in vitro and their mode of unwinding are well characterised. However, little is known about the putative cellular partners of such helicases. To identify PcrA-interacting factors, PcrA was used as a bait in a genome-wide yeast two-hybrid screen of a Bacillus subtilis library. Three proteins with unknown functions - YxaL, YwhK and YerB - were found to interact specifically with PcrA. The yxaL gene was cloned, the product was overexpressed and purified, and its effect on the PcrA activity was investigated in vitro. YxaL enhanced the processivity of the PcrA helicase. A comparison of the amino acid sequence of YxaL with other proteins from data banks suggests that YxaL belongs to a family of proteins with a repeated domain, which adopt a typical three-dimensional structure designated as a "beta-propeller". This raises the possibility that YxaL acts as a connector protein between PcrA and another cellular component.     

Biochemical characterization of the Staphylococcus aureus PcrA helicase and its role in plasmid rolling circle replication

Previous genetic studies have suggested that a putative chromosome-encoded helicase, PcrA, is required for the rolling circle replication of plasmid pT181 in Staphylococcus aureus. We have overexpressed and purified the staphylococcal PcrA protein and studied its biochemical properties in vitro. Purified PcrA helicase supported the in vitro replication of plasmid pT181. It had ATPase activity that was stimulated in the presence of single-stranded DNA. Unlike many replicative helicases, PcrA was highly active as a 5' --> 3' helicase and had a weaker 3' --> 5' helicase activity. The RepC initiator protein encoded by pT181 nicks at the origin of replication and becomes covalently attached to the 5' end of the DNA. The 3' OH end at the nick then serves as a primer for displacement synthesis. PcrA helicase showed an origin-specific unwinding activity with supercoiled plasmid pT181 DNA that had been nicked at the origin by RepC. We also provide direct evidence for a protein-protein interaction between PcrA and RepC proteins. Our results are consistent with a model in which the PcrA helicase is targeted to the pT181 origin through a protein-protein interaction with RepC and facilitates the movement of the replisome by initiating unwinding from the RepC-generated nick.     

Evidence for a functional dimeric form of the PcrA helicase in DNA unwinding

PcrA helicase, a member of the superfamily 1, is an essential enzyme in many bacteria. The first crystal structures of helicases were obtained with PcrA. Based on structural and biochemical studies, it was proposed and then generally believed that PcrA is a monomeric helicase that unwinds DNA by an inchworm mechanism. But a functional state of PcrA from unwinding kinetics studies has been lacking. In this work, we studied the kinetic mechanism of PcrA-catalysed DNA unwinding with fluorometric stopped-flow method under both single- and multiple-turnover conditions. It was found that the PcrA-catalysed DNA unwinding depended strongly on the PcrA concentration as well as on the 3′-ssDNA tail length of the substrate, indicating that an oligomerization was indispensable for efficient unwinding. Study of the effect of ATP concentration on the unwinding rate gave a Hill coefficient of ~2, suggesting strongly that PcrA functions as a dimer. It was further determined that PcrA unwound DNA with a step size of 4 bp and a rate of ~9 steps per second. Surprisingly, it was observed that PcrA unwound 12-bp duplex substrates much less efficiently than 16-bp ones, highlighting the importance of protein-DNA duplex interaction in the helicase activity. From the present studies, it is concluded that PcrA is a dimeric helicase with a low processivity in vitro. Implications of the experimental results for the DNA unwinding mechanism of PcrA are discussed.     

Escherichia coli ribosomal protein L3 stimulates the helicase activity of the Bacillus stearothermophilus PcrA helicase.

Escherichia coli ribosomal protein L3 stimulates the in vitro helicase activity of Bacillus stearothermophilus PcrA helicase upon a variety of different substrates. L3 has no intrinsic helicase or ATPase activity nor is it able to stimulate the ATPase activity of PcrA. Gel mobility shift assays revealed that the affinity of PcrA for a variety of different DNA species (single-stranded, nicked and 3'-tailed) was enhanced in the presence of L3. We suggest that the stimulatory effect of L3 upon the helicase activity of PcrA is mediated via a protein-protein interaction which promotes cooperative binding of PcrA to its DNA substrate. This activity of L3 appears to be specific for PcrA helicase.     

RepD-mediated recruitment of PcrA helicase at the Staphylococcus aureus pC221 plasmid replication origin,oriD

Plasmid encoded replication initiation (Rep) proteins recruit host helicases to plasmid replication origins. Previously, we showed that RepD recruits directionally the PcrA helicase to the pC221 oriD, remains associated with it, and increases its processivity during plasmid unwinding. Here we show that RepD forms a complex extending upstream and downstream of the core oriD. Binding of RepD causes remodelling of a region upstream from the core oriD forming a ‘landing pad’ for the PcrA. PcrA is recruited by this extended RepD–DNA complex via an interaction with RepD at this upstream site. PcrA appears to have weak affinity for this region even in the absence of RepD. Upon binding of ADPNP (non-hydrolysable analogue of ATP), by PcrA, a conformational rearrangement of the RepD–PcrA–ATP initiation complex confines it strictly within the boundaries of the core oriD. We conclude that RepD-mediated recruitment of PcrA at oriD is a three step process. First, an extended RepD–oriD complex includes a region upstream from the core oriD; second, the PcrA is recruited to this upstream region and thirdly upon ATP-binding PcrA relocates within the core oriD.     

Srs2 helicase of Saccharomyces cerevisiae selectively unwinds triplet repeat DNA

Trinucleotide repeat expansions are the mutational cause of at least 15 genetic diseases. In vitro, single-stranded triplet repeat DNA forms highly stable hairpins, depending on repeat sequence, and a strong correlation exists between hairpin-forming ability and the risk of expansion in vivo. Hairpins are viewed, therefore, as likely mutagenic precursors to expansions. If a helicase unwinds the hairpin, it would be less likely to expand. Previous work indicated that yeast Srs2 DNA helicase selectively blocks expansions in vivo (Bhattacharyya, S., and Lahue, R. S. (2004) Mol. Cell. Biol. 24, 7324-7330). For example, srs2 mutants, including an ATPase-defective point mutant, exhibit substantially higher expansion rates than wild type controls. In contrast, mutation of another helicase gene, SGS1, had little effect on expansion rates. These findings prompted the idea that Srs2 might selectively unwind triplet repeat hairpins. In this study, DNA helicase assays were performed with purified Srs2, Sgs1, and Escherichia coli UvrD (DNA helicase II). Srs2 shows substantially faster unwinding than Sgs1 or UvrD on partial duplex substrates containing (CTG) x (CTG) sequences, provided that Srs2 encounters the triplet repeat DNA immediately on entering the duplex. Srs2 was also faster at unwinding (CAG) x (CAG)- and (CCG) x (CCG)-containing substrates and an intramolecular (CTG) x (CTG) hairpin. In contrast, all three enzymes unwind about equally well control substrates with either Watson-Crick base pairs or mismatched substrates with non-CNG repeats. Overall, the selective unwinding activity of Srs2 on triplet repeat hairpin DNA helps explain the genetic evidence that Srs2, not the RecQ homolog Sgs1, is a preferred helicase for preventing expansions.     

Supercoiling unwinds two-micrometer plasmid yeast DNA at the origin of replication

All studied origins of replication of DNA in Saccharomyces cerevisiae contain DNA unwinding elements. The introduction of unrestrained negative supercoiling leads to melting of the two DNA strands in DNA unwinding elements. To understand the mechanism of DNA replication it is important to know whether the most unstable region of DNA coincides with the origin of replication. Two-micrometer plasmid DNA from S. cerevisiae inserted in pBR322 was investigated by cleaving with snake venom phosphodiesterase. Its single-strand endonucleolytic activity allows cutting of negatively supercoiled DNA in the DNA unwinding elements. The sites of the venom phosphodiesterase hydrolysis were mapped by restriction enzymes. This study shows that the unwinding of the two-micrometers plasmid DNA of S. cerevisiae takes place only in the origin of replication as a result of unrestrained negative supercoiling.     

Probing the ATP-induced conformational flexibility of the PcrA helicase protein using molecular dynamics simulation

Helicases are enzymes that unwind double-stranded DNA (dsDNA) into its single-stranded components. It is important to understand the binding and unbinding of ATP from the active sites of helicases, as this knowledge can be used to elucidate the functionality of helicases during the unwinding of dsDNA. In this work, we investigated the unbinding of ATP and its effect on the active-site residues of the helicase PcrA using molecular dynamic simulations. To mimic the unbinding process of ATP from the active site of the helicase, we simulated the application of an external force that pulls ATP from the active site and computed the free-energy change during this process. We estimated an energy cost of ~85 kJ/mol for the transformation of the helicase from the ATP-bound state (1QHH) to the ATP-free state (1PJR). Unbinding led to conformational changes in the residues of the protein at the active site. Some of the residues at the ATP-binding site were significantly reoriented when the ATP was pulled. We observed a clear competition between reorientation of the residues and energy stabilization by hydrogen bonds between the ATP and active-site residues. We also checked the flexibility of the PcrA protein using a principal component analysis of domain motion. We found that the ATP-free state of the helicase is more flexible than the ATP-bound state.     

DNA helicase activity of PcrA is not required for the displacement of RecA protein from DNA or inhibition of RecA-mediated strand exchange

PcrA is a conserved DNA helicase present in all gram-positive bacteria. Bacteria lacking PcrA show high levels of recombination. Lethality induced by PcrA depletion can be overcome by suppressor mutations in the recombination genes recFOR. RecFOR proteins load RecA onto single-stranded DNA during recombination. Here we test whether an essential function of PcrA is to interfere with RecA-mediated DNA recombination in vitro. We demonstrate that PcrA can inhibit the RecA-mediated DNA strand exchange reaction in vitro. Furthermore, PcrA displaced RecA from RecA nucleoprotein filaments. Interestingly, helicase mutants of PcrA also displaced RecA from DNA and inhibited RecA-mediated DNA strand exchange. Employing a novel single-pair fluorescence resonance energy transfer-based assay, we demonstrate a lengthening of double-stranded DNA upon polymerization of RecA and show that PcrA and its helicase mutants can reverse this process. Our results show that the displacement of RecA from DNA by PcrA is not dependent on its translocase activity. Further, our results show that the helicase activity of PcrA, although not essential, might play a facilitatory role in the RecA displacement reaction.     

Identification of the PcrA DNA helicase reaction pathway by applying advanced targeted molecular dynamic simulations

PcrA DNA helicase uses the free energy of hydrolysis and binding of ATP to unwind double-stranded DNA (ds-DNA). There are two states of PcrA, termed the substrate and product complexes and, through the conformational changes between these two states, PcrA moves along ds-DNA and separates the two strands. In this study, two different methods, namely chain minimisation (CM, less reliable method) and auto targeted molecular dynamic (TMD) simulation (more reliable), were performed to generate two different initial reaction pathways between these two states, and then fixed root mean square distance (RMSD) TMD simulation was performed to optimise these two initial pathways. In general, the two optimised pathways share very similar major conformational changes, but are different in the minor motions. The potential energy profiles of the two improved pathways are generally similar, but the one generated by the improved TMD path is slightly lower. Considering the poor reliability of the initial path generated by CM and insignificant improvements of the auto-TMD path, our study suggests that fixed RMSD TMD simulation can generate reliable reaction pathways, but the different initial paths still have some influence on the detailed conformational analysis.     

The study of interactions between DNA and PcrA DNA helicase by using targeted molecular dynamic simulations

DNA helicases are important enzymes involved in all aspects of nucleic acid metabolism, ranging from DNA replication and repair to recombination, rescue of stalled replication and translation. DNA helicases are molecular motors. Through conformational changes caused by ATP hydrolysis and binding, they move along the template double helix, break the hydrogen bonds between the two strands and separate the template chains, so that the genetic information can be accessed. In this paper, targeted molecular dynamic simulations were performed to study the important interactions between DNA and PcrA DNA helicase, which can not be observed from the crystal structures. The key residues on PcrA DNA helicase that have strong interactions with both double stranded DNA (ds-DNA) and single stranded DNA (ss-DNA) have been identified, and it was found that such interactions mostly exist between the protein and DNA backbone, which indicates that the translocation of PcrA is independent of the DNA sequence. The simulations indicate that the ds-DNA is separated upon ATP rebinding, rather than ATP hydrolysis, which suggests that the two strokes in the mechanism have two different major roles. Firstly, in the power stroke (ATP hydrolysis), most of the translocations of the bases from one pocket to the next occur. In the relaxation stroke (ATP binding), most of the ‘work’ is being done to ‘melt’ the DNA at the separation fork. Therefore, we propose a mechanism whereby the translocation of the ss-DNA is powered by ATP hydrolysis and the separation of the ds-DNA is powered by ATP binding.     

Crystal structures of complexes of PcrA DNA helicase with a DNA substrate indicate an inchworm mechanism

We have determined two different structures of PcrA DNA helicase complexed with the same single strand tailed DNA duplex, providing snapshots of different steps on the catalytic pathway. One of the structures is of a complex with a nonhydrolyzable analog of ATP and is thus a "substrate" complex. The other structure contains a bound sulphate ion that sits in a position equivalent to that occupied by the phosphate ion produced after ATP hydrolysis, thereby mimicking a "product" complex. In both complexes, the protein is monomeric. Large and distinct conformational changes occur on binding DNA and the nucleotide cofactor. Taken together, these structures provide evidence against an "active rolling" model for helicase action but are instead consistent with an "inchworm" mechanism.     

Interaction of the initiator protein of an IncB plasmid with its origin of DNA replication

The replication initiator protein RepA of the IncB plasmid pMU720 was purified and used in DNase I protection assays in vitro. RepA protected a 68-bp region of the origin of replication of pMU720. This region, which lies immediately downstream of the DnaA box, contains four copies of the sequence motif 5'AANCNGCAA3'. Mutational analyses identified this sequence as the binding site specifically recognized by RepA (the RepA box). Binding of RepA to the RepA boxes was ordered and sequential, with the box closest to the DnaA binding site (box 1) occupied first and the most distant boxes (boxes 3 and 4) occupied last. However, only boxes 1, 2, and 4 were essential for origin activity, with box 3 playing a lesser role. Changing the spacing between box 1 and the other three boxes affected binding of RepA in vitro and origin activity in vivo, indicating that the RepA molecules bound to ori(B) interact with one another.     

DNA helicase activity is associated with the replication initiator protein rep of tomato yellow leaf curl geminivirus

The Rep protein of tomato yellow leaf curl Sardinia virus (TYLCSV), a single-stranded DNA virus of plants, is the replication initiator essential for virus replication. TYLCSV Rep has been classified among ATPases associated with various cellular activities (AAA+ ATPases), in superfamily 3 of small DNA and RNA virus replication initiators whose paradigmatic member is simian virus 40 large T antigen. Members of this family are DNA- or RNA-dependent ATPases with helicase activity necessary for viral replication. Another distinctive feature of AAA+ ATPases is their quaternary structure, often composed of hexameric rings. TYLCSV Rep has ATPase activity, but the helicase activity, which is instrumental in further characterization of the mechanism of rolling-circle replication used by geminiviruses, has been a longstanding question. We present results showing that TYLCSV Rep lacking the 121 N-terminal amino acids has helicase activity comparable to that of the other helicases: requirements for a 3' overhang and 3'-to-5' polarity of unwinding, with some distinct features and with a minimal AAA+ ATPase domain. We also show that the helicase activity is dependent on the oligomeric state of the protein.