RepC is rate limiting for pT181 plasmid replication

The effect on pT181 plasmid replication of the concentration of the plasmid-coded initiator protein, RepC, has been analyzed. In one type of experiment, plasmid replication was found to stop immediately after the addition of an inhibitory concentration of chloramphenicol (Cm) to growing cultures. Chromosomal replication showed the slow turnoff that is usual for Cm inhibition. Because plasmid replication rate is determined autogenously, no host factor can be rate limiting, suggesting that the specific factor affected is Rep C. In another type of experiment, we constructed a translational fusion between the repC coding sequence and a translationally inducible Cm-acetylase gene, cat-86, using pUB110 as the carrier replicon. The fusion plasmid showed an eightfold amplification of its own copy number and a similar amplification of a co-resident pT181 plasmid upon Cm induction. The amplified plasmids did not show autocatalytic runaway replication but rather established stable elevated copy numbers, indicating the existence of a secondary level of regulation. These results suggest that RepC is rate limiting for pT181 replication and support the hypothesis that pT181 replication is regulated at the level of RepC synthesis. The nature of the secondary regulation is unknown.     

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.     

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.     

Intermediates in plasmid pT181 DNA replication.

Staphylococcus aureus plasmid pT181 is thought to replicate via an asymmetric rolling-circle mechanism. By studying pulse labeled replicative intermediates, here we report that pT181 replication involves: (1) a post-replicative hypersupercoiled monomer and (2) a partially replicated intermediate which lacks superhelicity but is unlike a typical rolling-circle intermediate in that only nascent strands of less than unit length are released by alkali denaturation. A model for pT181 replication is proposed to accommodate this apparent discrepancy.     

Plasmid pT181 replication is decreased at high levels of RepC per plasmid copy

The replication of staphylococcal plasmid pT181 is indirectly controlled at the level of the synthesis of its replication initiator, RepC. As a result, high levels of RepC synthesis per plasmid copy were expected to lead to autocatalytic plasmid replication, which secondarily would affect host physiology. Surprisingly, RepC overexpression was found to lead to a rapid decrease in pT181 copy number and replication rate. These effects depended on the ratio of RepC lo the PT181 replication origin rather than on the absolute amount of RepC in the cell. In a wild-type host, the increase in RepC/plasmid copy also inhibited chromosome replication and cell division. The changes in host physiology did not play any role in the decrease in pT181 replication caused by RepC overexpression since pT181 replication responded in the same way in a host mutant insensitive to the effects of RepC induction. These results suggest that pT181, the prototype of an entire class of plasmids from Gram-positive bacteria, responds to overexpression of its replication initiator by a decrease in plasmid replication.     

In vitro inhibitory activity of RepC/C*, the inactivated form of the pT181 plasmid initiation protein, RepC.

pT181 is a Staphylococcus aureus rolling circle plasmid that regulates its replication by controlling the synthesis of its dimeric initiator protein RepC/C and by inactivating the protein following its use in replication (A. Rasooly and R. P. Novick, Science 262:1048-1050, 1993). This inactivation consists of the addition of an oligonucleotide, representing several nucleotides immediately 3' to the initiation nick site, to the active site tyrosine of one of the two subunits, generating a heterodimer, RepC/C*. Previous results suggested that the inactive form was metabolically stable and was present at a much higher level than the active form (A. Rasooly and R. P. Novick, Science 262:1048-1050, 1993). In the present study we have measured total RepC antigen as a function of plasmid copy number and have analyzed the interaction of the two forms. We find that pT181-containing staphylococci contain approximately one RepC dimer per plasmid copy over a 50-fold range of copy numbers. This is consistent with previous measurements of the rate of RepC synthesis, which suggested that one RepC dimer is synthesized per replication event (J. Bargonetti, P.-Z. Wang and R. P. Novick, EMBO J. 12:3659-3667, 1993). The RepC/C* heterodimer, which is inactive for replication, is a competitive inhibitor of the replication and the topoisomerase-like and cruciform-enhancing activities of the native protein. These results suggest that the inactive form may have a specific regulatory role in vivo. Since the known plasmid-determined controls, which maintain a constant plasmid copy number, are designed to ensure the synthesis of one RepC/C dimer per plasmid replication event, it is difficult to envision any role for yet another negative regulator of replication. Conceivably, under conditions where the initiator is overproduced, such as in the absence of the normal antisense regulation of initiator production, RepC/C* could serve as a fail-safe means of preventing autocatalytic replication.     

Functional organization of the plasmid pT181 replication origin

Replication of the staphylococcal plasmid pT181 is initiated at the origin (ori) with the introduction of a site-specific nick by the plasmid-encoded initiator protein RepC. Deletion analysis showed that a sequence of about 70 base-pairs is required for full ori function, including the ability to compete with a co-resident wild-type origin for the trans-acting RepC protein. A shorter sequence of 43 base-pairs is sufficient for origin function in the absence of competition. Single and double point mutations within these 43 base-pairs were used to determine the sequence requirement for replication within the minimal origin. Deletion mutants and point mutants were tested in replication and competition assays in vivo and in vitro, and in a RepC-mediated nicking assay.     

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.     

Purification of pT181-encoded repC protein required for the initiation of plasmid replication

The plasmid pT181 of Staphylococcus aureus consists of 4437 base pairs and encodes resistance to tetracycline. Initiation of pT181 replication specifically requires the plasmid-encoded repC protein. An in vitro system has been shown to carry out semiconservative replication of pT181 and its derivative plasmids (Khan, S A., Carleton, S. M., and Novick, R. P. (1981) Proc. Natl. Acad. Sci. U. S. A. 78, 4902-4906). We have used this replication assay to isolate repC protein, which was purified to near homogeneity. The repC gene was cloned into the pKJB825 plasmid that contains the phage lambda temperature-sensitive repressor gene, cI857, and the rightward promoter, PR. Upon temperature induction, Escherichia coli clones containing the recombinant plasmid overproduced repC protein, which was purified in significant quantities. The molecular weight of repC protein under denaturing conditions is 38,000, which is consistent with the size predicted from the DNA sequence data. Presence of repC protein was absolutely essential for the initiation of replication of pT181 and its derivatives in vitro.     

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.     

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.     

Modification of the plasmid initiator protein RepC active site during replication

Abstract pT181 is a Staphylococcus aureus rolling circle replicating plasmid whose copy number is controlled by regulating the synthesis and activity of the initiator protein, RepC. The RepC dimer is modified during pT181 replication by the addition of an oligodeoxynucleotide, giving rise to a new form, RepC*. To purify RepC*, RepC was expressed in S. aureus as a fusion protein with a polyhistidine tail. The histidine-tagged RepC retains its initiation and topoisomerase activities in vitro. Histagged RepC/RepC and RepC/RepC* were purified in a two-step procedure. Peptide mapping, mass spectrometric analysis and protein sequencing of purified RepC and RepC* were carried out, and both proteins appeared identical, except that the peptide containing the RepC active site tyrosine used in nicking activity was absent when the purified RepC* sample was analyzed. The absence of the active site in RepC* suggests that this site was modified during replication. The results provide the first direct biochemical evidence that RepC* is a modified form of RepC, and support a model in which RepC replication of pT181 leaves RepC with an oligonucleotide blocking the active site of one of its subunits.     

Control of pT181 replication I. The pT181 copy control function acts by inhibiting the synthesis of a replication protein

pT181 is a fully sequenced 4.4-kb 20 copy Tcr plasmid from Staphylococcus aureus. Its replication system involves a unique unidirectional origin embedded in the coding sequence for a plasmid-determined protein, RepC, that is required for initiation. When joined to a 55 copy carrier plasmid, pE194, pT181 excludes autonomous isologous replicons by inhibiting their replication. Two types of spontaneous pT181 copy mutants have been isolated, one that eliminates sensitivity to this inhibition and another that does not. A spontaneous 180-bp deletion, delta 144, eliminates both the inhibitory activity and sensitivity to it. This deletion increases copy number by 50-fold and RepC production by at least 10-fold. It is located directly upstream from the repC coding sequence and the deletion-bearing plasmid supports the replication of inhibitor-sensitive plasmids in cells containing active inhibitor. This effect is probably due to the overproduction of RepC by the delta 144 plasmid. On the basis of these results, it is suggested that RepC synthesis is negatively controlled by an inhibitor that is encoded directly upstream from the repC coding sequence and acts as a tareget set in the same region. It is likely, therefore, that pT181 replication rate is determined by the level of RepC.     

Binding of a novel host factor to the pT181 plasmid replication enhancer.

Replication enhancers are cis-acting genetic elements that stimulate the activity of origins of DNA replication. The enhancer found in plasmid pT181 of Staphylococcus aureus, called cmp, functions at a distance of 1 kb from the origin of DNA replication to stimulate the interaction between the replication initiation protein and the origin. DNA encoding cmp-binding activity was isolated by screening an expression library of S. aureus DNA in Escherichia coli, and a novel gene, designated cbf1, was identified. The cbf1 locus codes for a polypeptide of 313 amino acid residues (cmp-binding factor 1 [CBF1]; Mr = 35,778). In its COOH-terminal region, the protein sequence contains the helix-turn-helix motif common to many DNA binding proteins that usually bend DNA. The specificity of CBF1 binding for cmp was demonstrated by affinity chromatography using cmp DNA and by competition binding studies. DNase I footprinting analysis of the CBF1-cmp complexes revealed DNase I-hypersensitive sites in phase with the helical periodicity of DNA, implying that CBF1 increases distortion of the intrinsically bent cmp DNA.     

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.     

The Inc3B determinant of plasmid pT181

Summary A region encompassing the origin of replication of staphylococcal plasmid pT181 has previously been shown to express an incompatibility effect denoted Inc3B, when cloned into another replicon (Novick et al. 1984). In an attempt to understand the mechanism of this incompatibility effect, and its relationship with the function of the replication origin, mutants deficient in this property were isolated and characterized. The results obtained suggest that the Inc3B effect is due to the competition for replication between the replication origin cloned in a hybrid and the origin of an autonomous plasmid. The Inc3B-deficient mutants isolated expressed different degrees of residual incompatibility. The inc3B mutations which did not express any incompatibility were found also to inactivate the function of the replication origin. All the other mutants which expressed residual Inc3B had a functional origin but presented a significantly reduced ability to use this origin when coexisting with a plasmid using a wild-type pT181 origin. It is suggested that these inc3B mutations represent a new type of origin mutation which affects the ability of the origin to compete with other origins using the same replication system, though the function per se of the origin is not significantly impaired.