An 18-base-pair sequence is sufficient for termination of rolling-circle replication of plasmid pT181.

pT181 and related plasmids of gram-positive bacteria replicate by a rolling-circle mechanism. The replication initiator protein of pT181, RepC, has origin-specific nicking-closing activities. Replication of the plasmid pT181 leading strand initiates by covalent extension of the RepC-generated nick, and the origin of replication contains signals for both initiation and termination of DNA replication. We have investigated the sequence requirements for the initiation and termination steps by using plasmids containing two pT181 origins. In vitro replication experiments showed that 18- and 24-bp synthetic oligonucleotides containing the RepC nick site were active in the termination of replication. However, initiation of replication required a larger region which also includes the RepC binding site. Plasmids containing the 18- and 24-bp region were also found to be nicked by the RepC protein. Our results demonstrate that sequence requirements for initiation and termination of pT181 replication overlap, but while the RepC binding site is required for initiation, it is dispensable for termination.     

Role of individual monomers of a dimeric initiator protein in the initiation and termination of plasmid rolling circle replication

Plasmids of the pT181 family encode initiator proteins that act as dimers during plasmid rolling circle (RC) replication. These initiator proteins bind to the origin of replication through a sequence-specific interaction and generate a nick at the origin that acts as the primer for RC replication. Previous studies have demonstrated that the initiator proteins contain separate DNA binding and nicking-closing domains, both of which are required for plasmid replication. The tyrosine residue at position 191 of the initiator RepC protein of pT181 is known to be involved in nicking at the origin. We have generated heterodimers of RepC that consist of different combinations of wild type, DNA binding, and nicking mutant monomers to identify the role of each of the two monomers in RC replication. One monomer with DNA binding activity was sufficient for the targeting of the initiator to the origin, and the presence of Tyr-191 in one monomer was sufficient for the initiation of replication. On the other hand, a dimer consisting of one monomer defective in DNA binding and the other defective in origin nicking failed to initiate replication. Our results demonstrate that the monomer that promotes sequence-specific binding to the origin must also nick the DNA to initiate replication. Interestingly, whereas Tyr-191 of the initiator was required for nicking at the origin to initiate replication, it was dispensable for termination, suggesting that alternate amino acids in the initiator may promote termination but not initiation.     

Specificity of RepC protein in plasmid pT181 DNA replication

The plasmid pT181 of Staphylococcus aureus consists of 4437 base pairs and encodes resistance to tetracycline. Initiation of pT181 DNA replication specifically requires the plasmid-encoded initiator protein, RepC. The initiator protein binds specifically to a 32-base pair sequence within the pT181 origin of replication. RepC protein also has a nicking-closing activity that is specific for the pT181 origin. Replication of pT181 initiates by covalent extension of the nick and proceeds by a rolling circle mechanism. Two other small, multicopy plasmids pC221 and pS194 belong to the pT181 family and have common structural organization and replication properties. The replication proteins and replication origins of these plasmids have extensive sequence homologies, although they belong to different incompatibility groups. In spite of this homology, the replication proteins and replication origins of these three plasmids do not show any cross-reactivity in vivo. We have carried out a series of in vitro experiments to determine the specificity of pT181-encoded initiator protein, RepC. DNA binding experiments showed that although the binding of RepC to the pT181 origin was very efficient, little or no binding was seen with pC221 and pS194 origins. The nicking-closing activity of RepC was found to be equally efficient with the pC221 and pS194 plasmids. The plasmids pC221 and pS194 replicated efficiently in a RepC-dependent in vitro system. However, replication of these plasmids was greatly reduced in the presence of a competing pT181 origin. The results presented here suggest that nicking-closing by RepC at the origin is not sufficient for maximal replication and that tight binding of RepC to the origin plays an important role in the initiation of DNA replication.     

Synthesis of single-stranded plasmid pT181 DNA in vitro. Initiation and termination of DNA replication

The origin of replication of plasmid pT181 is nicked by the plasmid-encoded RepC protein. The free 3'-hydroxyl end at the nick is presumably used as primer for leading strand DNA synthesis. In vitro replication of pT181 was found to generate single-stranded DNA in addition to the supercoiled, double-stranded DNA. The single-stranded DNA was circular and corresponded to the pT181 leading strand. Recombinant plasmids were constructed that contain two pT181 origins of replication in either direct or inverted orientation. In vitro replication of the plasmid carrying two origins in direct orientation was shown to generate circular, single-stranded DNA that corresponded to initiation of replication at one origin sequence and termination at the other origin. These results demonstrate that the origin of pT181 leading strand DNA replication also serves as the site for termination of replication. Interestingly, the presence of two origins in inverted orientation resulted in initiation of replication at one origin and stalling of the replisome at the other origin. These results suggest that RepC can reinitiate replication at the second origin by nicking partially replicated, relaxed DNA. These data are consistent with the replication of pT181 by a rolling circle mechanism and indicate that single-stranded DNA is an intermediate in pT181 replication.     

Six amino acids determine the sequence-specific DNA binding and replication specificity of the initiator proteins of the pT181 family.

The replication of pT181 and related plasmids of Staphylococcus aureus proceeds by a rolling circle mechanisms. The initiator proteins encoded by the plasmids of the pT181 family have sequence-specific DNA binding and topoisomerase activities. These proteins nick one strand of the DNA at the origin of replication. The free 3'-hydroxyl end at the nick is then used as a primer for the replication of the leading strand of the DNA. Although these initiator proteins are highly homologous, they show specificity in DNA binding and replication for their cognate DNAs. In this study, we have generated hybrid initiator proteins and studied their various biochemical activities in vitro. Our results show that 6 amino acids are sufficient to determine the DNA binding and replication specificities of such initiator proteins.     

Replication termination for staphylococcal plasmids: plasmids pT181 and pC221 cross-react in the termination process.

We present data which indicate that (i) the origin of replication of plasmids pT181 and pC221 can also function as termination signals; (ii) termination of replication occurs when a round of replication initiated either by RepC at the pT181 origin or by RepD at the pC221 origin reaches either of these origins, proving that the two plasmids cross-react for termination of replication; and (iii) the replication initiated at the origin of another staphylococcal plasmid, pE194, does not terminate at the origin of pT181 or pC221, indicating the existence of a specific relationship between the initiation and termination of a replication event.     

Origin recognition specificity in pT181 plasmids is determined by a functionally asymmetric palindromic DNA element.

The leading strand replication origin of pT181 plasmids consists of two adjacent inverted repeat elements (IR-II and IR-III), which are involved in origin recognition by the initiator (Rep) protein. The conserved core element, IR-II, which contains the initiation nick site, is induced by Rep to form a cruciform structure, probably the primary substrate for the initiation of rolling circle replication. The divergent repeat, IR-III, constitutes the determinant of origin recognition specificity. We show here that the distal arm of IR-III is not required for sequence-specific recognition, whereas the proximal arm and central region are required. Since the initiator is dimeric, we presume that it binds symmetrically to IR-III. A unique type of DNA-protein interaction is proposed, in which the lack of sequence requirement for the distal arm is a consequence of binding to the adjacent IR-II, which thereby polarizes the stringency of binding to the two arms of IR-III. In addition, genetic evidence indicates that both the spacing and the phasing of IR-II to IR-III are crucial for function and that the central segment of IR-III may serve to position the two flanking half-sites for optimal interaction of Rep with IR-III.     

Bacillus anthracis and Bacillus cereus PcrA helicases can support DNA unwinding and in vitro rolling-circle replication of plasmid pT181 of Staphylococcus aureus

Replication of rolling-circle replicating (RCR) plasmids in gram-positive bacteria requires the unwinding of initiator protein-nicked plasmid DNA by the PcrA helicase. In this report, we demonstrate that heterologous PcrA helicases from Bacillus anthracis and Bacillus cereus are capable of unwinding Staphylococcus aureus plasmid pT181 from the initiator-generated nick and promoting in vitro replication of the plasmid. These helicases also physically interact with the RepC initiator protein of pT181. The ability of PcrA helicases to unwind noncognate RCR plasmids may contribute to the broad-host-range replication and dissemination of RCR plasmids in gram-positive bacteria.     

Mechanism of plasmid pT181 DNA replication

The origin of replication of plasmid pT181 is nicked by the plasmid-encoded RepC protein. This nick presumably serves as the start-site of pT181 replication by extension synthesis. In vitro replication of pT181 was found to generate single-stranded DNA in addition to the supercoiled, double-stranded DNA. The single-stranded DNA was circular and corresponded to the pT181 leading strand. In vitro replication of a recombinant plasmid carrying two pT181 origins in direct orientation was shown to generate circular, single-stranded DNA that corresponded to initiation of replication at one origin sequence and termination at the other origin. These results demonstrate that the origin of pT181 leading-strand DNA replication also serves as the site for termination of replication. Interestingly, the presence of two PT181 origins in inverted orientation resulted in initiation of replication at one origin and stalling of the replisome at the other origin. These data are consistent with the replication of pT181 by a rolling circle mechanism and indicate that single-stranded DNA is an intermediate in pT181 replication.     

Functional analysis of the leading strand replication origin of plasmid pUB110 in Bacillus subtilis.

Supercoiled plasmid DNA is the substrate for initiation of pUB110 replication, and - by inference - for binding of its initiator protein (RepU) to the plasmid replication origin (oriU) in vivo. No hairpin structure is required for RepU-oriU recognition. RepH (the pC194 replication initiation protein) failed to initiate replication in trans at oriU. The nucleotides that determine the specificity of the replication initiation process are located within oriU but termination is unefficient. Therefore the segment that forms the full recognition signal for termination is probably located 3' of the oriU recognition sequence. Two overlapping domains, one for initiation and one required for termination, compose the leading strand replication origin of plasmid pUB110.     

Role of the double-strand origin cruciform in pT181 replication

pT181 is a small rolling-circle plasmid from Staphylococcus aureus whose initiator protein, RepC, melts the plasmid's double-strand origin (DSO) and extrudes a cruciform involving IR II, a palindrome flanking the initiation nick site. We have hypothesized that the cruciform is required for initiation, providing a single-stranded region for the assembly of the replisome (R. Jin et al., 1997, EMBO J. 16, 4456-4566). In this study, we have tested the requirement for cruciform extrusion by disrupting the symmetry of the IR II palindrome or by increasing its length. The modified DSOs were tested for replication with RepC in trans. Rather surprisingly, disruption of the IR II symmetry had no detectable effect on replication or on competitivity of the modified DSO, though plasmids with IR II disrupted were less efficiently relaxed than the wild type by RepC. However, in conjunction with IR II disruption, modification of the tight RepC binding site IR III blocked replication. These results define two key elements of the pT181 initiation mechanism--the IR II conformation and the RepC binding site (IR III)--and they indicate that pT181 replication initiation is sufficiently robust to be able to compensate for significant modifications in the configuration of the DSO.     

Precise determination, cross-recognition, and functional analysis of the double-strand origins of the rolling-circle replication plasmids in haloarchaea

The precise nick site in the double-strand origin (DSO) of pZMX201, a 1,668-bp rolling-circle replication (RCR) plasmid from the haloarchaeon Natrinema sp. CX2021, was determined by electron microscopy and DSO mapping. In this plasmid, DSO nicking occurred between residues C404 and G405 within a heptanucleotide sequence (TCTC/GGC) located in the stem region of an imperfect hairpin structure. This nick site sequence was conserved among the haloarchaeal RCR plasmids, including pNB101, suggesting that the DSO nick site might be the same for all members of this plasmid family. Interestingly, the DSOs of pZMX201 and pNB101 were found to be cross-recognized in RCR initiation and termination in a hybrid plasmid system. Mutation analysis of the DSO from pZMX201 (DSO_Z) in this hybrid plasmid system revealed that: (i) the nucleotides in the middle of the conserved TCTCGGC sequence play more-important roles in the initiation and termination process; (ii) the left half of the hairpin structure is required for initiation but not for termination; and (iii) a 36-bp sequence containing TCTCGGC and the downstream sequence is essential and sufficient for termination. In conclusion, these haloarchaeal plasmids, with novel features that are different from the characteristics of both single-stranded DNA phages and bacterial RCR plasmids, might serve as a good model for studying the evolution of RCR replicons.     

Cleavage of single-stranded DNA by plasmid pT181-encoded RepC protein.

RepC protein encoded by plasmid pT181 has single-stranded endonuclease and topoisomerase-like activities. These activities may be involved in the initiation (and termination) of pT181 replication by a rolling circle mechanism. RepC protein cleaves the bottom strand of DNA within the origin of replication at a single, specific site when the DNA is in the supercoiled or linear (double or single-stranded) form. We have found that RepC protein will also cleave single-stranded DNA at sites other than the origin of replication. We have mapped the secondary cleavage sites on pT181 DNA. When the DNA is in the supercoiled, or linear, double-stranded form, only the primary site within the origin is cleaved. However, when the DNA is present in the single-stranded form, several strong and weak cleavage sites are observed. The DNA sequence at these cleavage sites shows a strong similarity with the primary cleavage site. The presence of Escherichia coli SSB protein inhibited cleavage at all of the secondary nick sites while the primary nick site remained susceptible to cleavage.     

Specificity of origin recognition by replication initiator protein in plasmids of the pT181 family is determined by a six amino acid residue element.

We have investigated the specificity of replication origin recognition by the initiator proteins of a set of six closely related Staphylococcus aureus plasmids, the pT181 family. These plasmids replicate by an asymmetric rolling-circle mechanism using plasmid-coded initiators that nick the replication origins and form a phosphotyrosine bond at the 5' nick terminus. Five of the plasmids are in different incompatibility groups and their initiator proteins do not cross-complement the cloned origins of any but their own plasmid. One pair is weakly incompatible and their initiator proteins and origins do cross-complement for replication in vivo. This pattern of cross-reactivity led to the prediction that the determinant of specificity would correspond to a homologously positioned set of six residues in the C-terminal domain of the protein, some 80 residues away from the active site tyrosine, that are divergent for all of the compatible plasmids and identical for the incompatible pair. Site-directed mutagenesis was used to exchange these six residues among three pairs of plasmids and these exchanges brought about the predicted switching of origin recognition specificity. Single substitution within this six residue set reduced or eliminated the activity of the protein but did not alter the origin recognition specificity. These six and flanking residues cannot form an amphipathic alpha-helix nor do they conform to the classical helix-turn-helix or other known DNA binding motifs. A novel type of interaction is suggested in which the protein binds to its recognition site, bends and melts the DNA, and causes or enhances the extrusion of an adjacent cruciform containing the nick site. This configuration would juxtapose the nicking target and the active site tyrosine residue and would unwind the highly G + C-rich replication origin.     

Staphylococcus aureus chromosomal mutations that decrease efficiency of Rep utilization in replication of pT181 and related plasmids.

Staphylococcus aureus chromosomal mutants which maintain pT181 and related plasmids at a much reduced copy number but which do not affect the replication of other plasmids have been isolated. The origin of replication and the initiator protein of the affected plasmids are the only elements required for the response to these mutations. The host mutations do not interfere with the pT181 replication control mechanism.     

Why is the initiation nick site of an AT-rich rolling circle plasmid at the tip of a GC-rich cruciform?

pT181 and other closely related rolling circle plasmids have the nicking site for initiation of replication between the arms of a GC-rich inverted repeat sequence adjacent to the binding site for the dimeric initiator protein. Replication is initiated by the initiator-induced extrusion of this sequence as a cruciform, creating a single-stranded region for nicking by the protein. Nicking is followed by assembly of the replisome without relaxation of the secondary structure. Following termination, the initiator protein is released with a short oligonucleotide attached to one subunit, which prevents it from being recycled, a necessary feature of the plasmid's replication control system. The modified initiator can cleave single-stranded substrates and can nick and relax supercoiled plasmid DNA weakly. Although it can bind to its recognition sequence in the leading strand origin, the modified protein cannot induce cruciform extrusion, and it is proposed that this inability is the key to understanding the biological rationale for having the nicking site at the tip of a cruciform: the need to provide the functional initiator with a catalytic advantage over the modified one sufficient to offset the numerical advantage and metabolic stability of the latter.     

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.     

In vitro studies of the initiation of staphylococcal plasmid replication. Specificity of RepD for its origin (oriD) and characterization of the Rep-ori tyrosyl ester intermediate

Several staphylococcal plasmids from different incompatibility (inc) groups which replicate by a rolling circle mechanism each specify a replication initiator protein (Rep) which is homologous with that of the inc3 tetracycline resistance plasmid pT181. The rep gene sequences of six pT181-like plasmids are known, each encoding proteins of molecular mass 38 kDa with 62% overall amino acid sequence identity. The initiation of replication in vivo by each of the Rep proteins is plasmid specific, acting in trans only at the cognate replication origin (ori) of the encoding plasmid. Previous studies in vitro of the RepC protein of pT181 demonstrated replication initiator, topoisomerase-like, and DNA binding activities, which appeared to be specific for the origin (oriC) of pT181 when compared with unrelated staphylococcal plasmids. Although RepD, specified by the inc4 chloramphenicol resistance plasmid pC221, has a range of activities similar to those noted previously for RepC, manipulation of in vitro conditions has revealed discrete steps in the overall reaction of RepD with oriD. In addition, factors have been identified which are necessary not only for sequence-dependent discrimination in vitro by Rep proteins for all pT181-like plasmids but also for the absolute specificity of RepD for its cognate pC221 replication origin (oriD), the latter occurring in vivo and a function of the topological state of the ori-containing target DNA. Here we also demonstrate the presence of a covalent phosphoryl-tyrosine linkage between the RepD protein of plasmid pC221 and an oligonucleotide substrate corresponding to its replication origin (oriD). The reactive tyrosine (Tyr-188) was identified from amino acid sequences of 32P-labeled peptide-oligonucleotide fragments. Substitution of Tyr-188 with phenylalanine confirms the importance of the tyrosyl hydroxyl group since the Y188F protein retains the sequence-specific DNA-binding capabilities of wild-type RepD but is unable to attach covalently to the replication origin or participate in the nicking-closing reaction in vitro.     

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.