Specificity of the interactions between the Rep proteins and the origins of replication of Staphylococcus aureus plasmids pT181 and pC221

Summary pT181 and pC221 are closely relatedStaphylococcus aureus plasmids with the same genome organization, which is characterized by the overlapping of the origin of replication with the sequence encoding a protein, Rep, essential for plasmid replication. Former results have shown the lack of in vivo cross-complementation between these two plasmids, while in vitro studies have revealed the ability of both Rep proteins to act on either origin. One possible explanation for this difference was based on a previous analysis of the incompatibility expressed by the origin of replication of these plasmids, showing that the origin embedded in therep gene competes for Rep utilization with the origin of a test plasmid and that changes in the sequence of the origin reduce its ability to compete. To avoid this problem, in the present work special hybrids were constructed in which the origin of replication overlapping therep gene was mutationally inactivated, without changing the amino acid sequence of the encoded protein. The level of Rep expression by these hybrids could be varied by taking advantage of what is presently known about the control of Rep synthesis in plasmid pT181. The results of complenentation studies conducted using these hybrids have shown that: (i) at the usual level of expression for a wild-type plasmid each Rep protein can initiate replication strictly from its corresponding origin; (ii) when overproduced, the pT181 RepC protein could also act efficiently on the pC221 origin; a functional pT181 origin present in the same host completely prevented this complementation; (iii) in excess, the RepD protein encoded by pC221 could replicate a plasmid carrying the pT181 origin but could not ensure the hereditary stability of such a plasmid in the absence of another active replication system; (iv) when overproduced both RepC and RepD could act on the origin of replication of three other related plasmids pS194, pC223 and pUB112.     

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.     

Comparative analysis of five related staphylococcal plasmids

The genomic organization of five small multicopy staphylococcal plasmids comprising the pT181 family has been analyzed. In addition to pT181, the family presently includes the streptomycin resistance plasmid pS194 and the chloramphenicol resistance plasmids pC221, pC223, and pUB112. Although they belong to five different incompatibility groups, the five plasmids have similar basic replicons, use the same basic copy control mechanism, and have a common structural organization. It has been demonstrated previously that pT181 and pC221 encode trans-active replication proteins (RepC and RepD, respectively) which specifically recognize the respective plasmid's origin of replication in both cases is initiated by site-specific nicking and 3' extension. The other three plasmids in this family encode similar replication proteins; 63% of the predicted amino acid residues are identical for all five and the least similar pair shows 75% identity at the amino acid level. However, despite this homology, the replication proteins and origins of replication of different members in this family did not show cross complementation in vivo. Outside of the basic replicon, which comprises about one-third of each plasmid's genome, functional organization is also conserved. The resistance determinants are all located in the same position, immediately downstream of the replication protein coding sequence, and all are transcribed in the same direction. The three chloramphenicol resistance determinants encode highly homologous chloramphenicol transacetylases which are unrelated to the tet and str gene products. Three of the five plasmids form relaxation complexes and the involved genome segments are closely related. The other two are not homologous to these three in the corresponding region, but are homologous to each other and encode a site-specific recombinase, Pre. It is suggested that the replication, resistance, and relaxation complex regions of these plasmids can be regarded as conserved segments ("cassettes") assembled in various combinations, but always with the same spatial arrangement.     

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.     

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.     

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.     

Sequence requirements for the termination of rolling-circle replication of plasmid pT181

Most small multicopy plasmids of Gram-positive bacteria and many in Gram-negative bacteria replicate by a rolling-circle (RC) mechanism. The replication initiator proteins encoded by the RC plasmids and single-stranded bacteriophages of Escherichia coli have origin-specific nicking-closing activities that are required for the initiation and termination of RC replication. We have investigated the sequence requirements for termination of RC replication of plasmid pT181. The initiator nick site is located in the loop of a hairpin region (IRII) within the pT181 origin of replication. By mutational analysis, we have found that several nucleotides within the stem of IRII which are critical for the initiation activity are dispensable for termination of replication. We also demonstrate that nucleotides in the right arm of IRII, but not the left arm, are absolutely required for termination of RC replication. We have also identified specific nucleotides in IRII that are critical for its termination activity. The sequence of the right arm of the hairpin must be located downstream of the initiator nick site for termination, suggesting that termination requires a specific orientation of the initiator protein at the origin.     

Structural relationships among chloramphenicol-resistance plasmids of Staphylococcus aureus

Abstract Twelve different chloramphenicol-resistance (Cm^r) plasmids detected in Staphylococcus aureus strains isolated between 1952 and 1981 were characterized by restriction endonuclease, DNA hybridization and heteroduplex analyses. These studies revealed three families of Cm^r plasmids which were distinguished by their chloramphenicol acetyltransferase sequences; the prototype plasmids of the families were pC221, pC223 and pC194. The cat and replication ( rep ) genes of the plasmid pC221 were highly conserved in other pC221 family members and were related to their homologs in the pC223 family plasmids; however, the cat and rep genes of the pC194 family plasmids were distinct.     

Replication origin of a single-stranded DNA plasmid pC194.

The replication of the single-stranded (ss) DNA plasmid pC194 by the rolling circle mechanism was investigated using chimeric plasmids that possess two pC194 replication origins. One of the origins was intact, whereas the other was either intact or mutated. The origins were activated by inducing synthesis of the pC194 replication protein, under the control of lambda phage pL promoter. Initiation of pC194 replication at one origin and termination at the other generated circular ssDNA molecules smaller than the parental chimeric plasmid. From the nature and the amount of ssDNA circles, the activity of an origin could be assessed. Our results show that (i) the signal for initiation of pC194 replication is more stringent than that for termination; (ii) the sequence and structure of the origin are important for its activity and (iii) successful termination of one replication cycle is not followed by reinitiation of another. This last observation differentiates a ssDNA plasmid (pC194) from a ssDNA phage (phi X174).     

Localization of the start sites of lagging-strand replication of rolling-circle plasmids from Gram-positive bacteria

A number of small, multicopy plasmids from Gram-positive bacteria replicate by an asymmetric rolling-circle mechanism. Previous studies with several of these plasmids have identified a palindromic sequence, SSO_A, that acts as the single-strand origin (SSO) for the replication of the lagging-strand DNA. Although not all the SSO_A sequences share ONA sequence homology, they are structurally very similar. We have used an in vitro system to study the lagging-strand replication of several plasmids from Gram-positive bacteria using the SSO_A sequences of pT181, pE194 and pSN2 as representative of three different groups of Staphylococcus aureus plasmids. In addition, we have investigated the lagging-strand replication of the pUB110 plasmid that contains an alternative single-strand origin, sso_u. Our results confirm that RNA polymerase is involved in lagging-strand synthesis from both SSO_A and ssou-type lagging-strand origins. Interestingly, while initiation of lagging-strand DNA synthesis of pUB110 occurred predominantly at a single position within sso_u, replication of pT181, pSN2 and pE194 plasmids initiated at multiple positions from SSO_A.     

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.     

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.     

Insertion of foreign DNA into plasmids from gram-positive bacteria induces formation of high-molecular-weight plasmid multimers.

Plasmids pUB110, pC194, pE194, and pT181 are commonly used as cloning vectors in both Bacillus subtilis and Staphylococcus aureus. We report that insertion of foreign DNA into any of these plasmids results in the generation of high-molecular-weight plasmid multimers (HMW) of the recombinant, present as tandem head-to-tail copies. HMW was detected in wild-type B. subtilis and S. aureus strains. The production of HMW depended on the nature of the DNA insertion. Inserts of Escherichia coli DNA, e.g., pBR322 or pUC18, resulted in large amounts of HMW, whereas some inserts of S. aureus DNA of the same size had no effect on plasmid profile. The generation of HMW depended on the mode of plasmid replication; plasmids which replicate via a single-stranded DNA intermediate produced HMW upon foreign DNA insertion, whereas plasmid pAM beta 1, which does not generate single-stranded DNA, did not generate HMW. We propose that HMW is a product of imparied termination of rolling-circle replication and that the impairment is due to the nature of the DNA insertion.     

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.     

Complete nucleotide sequence of pTZ12, a chloramphenicol-resistance plasmid of Bacillus subtilis

The complete nucleotide sequence of pTZ12, a chloramphenicol-resistance (CmR) plasmid (2517 bp) derived from Corynebacterium xerosis plasmid pTZ10, has been determined after propagation in Bacillus subtilis. The nucleotide sequence of pTZ12 suggests that a recombination event may have occurred naturally within the open reading frames for the Rep protein of pT181 (or a pT181-like plasmid) and pC221 (or a pC221-like plasmid).     

Effect of the deletion of a fragment dispensable for the autonomous maintenance of plasmid pT181 on the competition between incompatible plasmids

The deletion of the 560-bp HindIII C fragment from pT181 derivatives does not change the stability or copy number of the plasmid but affects its ability to compete with undeleted, incompatible plasmids for maintenance in the host cell. The disadvantage of the deleted plasmids seems to be manifested at the level of replication. It results that for plasmid pT181 a sequence dispensable for autonomous maintenance and replication control could affect the outcome of the competition between autonomous, incompatible plasmids.     

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.     

An accessory protein is required for relaxosome formation by small staphylococcal plasmids

Mobilization of the staphylococcal plasmid pC221 requires at least one plasmid-encoded protein, MobA, in order to form a relaxosome. pC221 and closely related plasmids also possess an overlapping reading frame encoding a protein of 15 kDa, termed MobC. By completing the nucleotide sequence of plasmid pC223, we have found a further example of this small protein, and gene knockouts have shown that MobC is essential for relaxosome formation and plasmid mobilization in both pC221 and pC223. Primer extension analysis has been used to identify the nic site in both of these plasmids, located upstream of the mobC gene in the sense strand. Although the sequence surrounding the nic site is highly conserved between pC221 and pC223, exchange of the oriT sequence between plasmids significantly reduces the extent of relaxation complex formation, suggesting that the Mob proteins are selective for their cognate plasmids in vivo.     

Analysis of two chloramphenicol resistance plasmids from Staphylococcus aureus: Insertional inactivation of Cm resistance, mapping of restriction sites, and construction of cloning vehicles

Chloramphenicol (Cm) resistance plasmids pCW7 and pC221 of Staphylococcus aureus have been characterized by the construction of detailed restriction maps and by the identification of restriction sites on both plasmids which map within either the structural gene encoding CAT or its controlling elements. The number and order of recognition sites for endonucleases AluI, HinfI, and TaqI on pCW7 and pC221 were determined from multiple enzyme digestion results and by the 5′-terminal labeling procedure of Smith and Birnstiel (1976). Endonuclease sites mapping within the Cm-resistance determinant were identified by the construction of recombinant plasmids in vitro from pC221 or pCW7 and the tetracycline-resistance plasmid pCW3. Site-specific mutations were then introduced by filling in the complementary ends of selected restriction sites present on pCW7 or pC221 with E. coli polymerase I followed by recircularization of the recombinant plasmid by blunt-end ligation. Pol I treatment of the BstEII site of pC221 and the BstEII or BglII site present on pCW7 resulted not only in the loss of those recognition sites but also in the loss of Cm resistance encoded by the plasmid. Circularization of the largest MboI fragment (1.8kb) from pC221 formed a stable replicon which encoded an inducible CAT but did not exhibit the relaxation phenomenon associated with pC221. The possible roles of several of the recombinant plasmids as cloning vehicles within S. aureus and Bacillus subtilis are discussed.