Plasmid-encoded Initiator Protein Research Articles

Functional amyloids as inhibitors of plasmid DNA replication.

DNA replication is tightly regulated to constrain the genetic material within strict spatiotemporal boundaries and copy numbers. Bacterial plasmids are autonomously replicating DNA molecules of much clinical, environmental and biotechnological interest. A mechanism used by plasmids to prevent over-replication is ‘handcuffing’, i.e. inactivating the replication origins in two DNA molecules by holding them together through a bridge built by a plasmid-encoded initiator protein (Rep). Besides being involved in handcuffing, the WH1 domain in the RepA protein assembles as amyloid fibres upon binding to DNA in vitro. The amyloid state in proteins is linked to specific human diseases, but determines selectable and epigenetically transmissible phenotypes in microorganisms. Here we have explored the connection between handcuffing and amyloidogenesis of full-length RepA. Using a monoclonal antibody specific for an amyloidogenic conformation of RepA-WH1, we have found that the handcuffed RepA assemblies, either reconstructed in vitro or in plasmids clustering at the bacterial nucleoid, are amyloidogenic. The replication-inhibitory RepA handcuff assembly is, to our knowledge, the first protein amyloid directly dealing with DNA. Built on an amyloid scaffold, bacterial plasmid handcuffs can bring a novel molecular solution to the universal problem of keeping control on DNA replication initiation.

78 Structural studies of rolling circle replication initiator proteins

Plasmids of the pT181 family replicate by a rolling-circle mechanism. The process is initiated by a plasmid-encoded Rep initiator protein, which has sequence-specific DNA nicking and religation activity. The plasmid replication origin is nicked by Rep, which binds covalently to one DNA strand via an active site tyrosine, initiating rolling circle replication and religating the strand at the end of the cycle. Rep proteins also associate with PcrA helicase to form a highly processive complex. We have determined the structure of the Rep protein from cryptic plasmid pSTK1 of Geobacillus stearothermophilus (Gst), and several variants of RepD from Staphylococcus aureus (Sau), representing the first structural information on this class of initiators. Cloning and expression of the designated 269 aa Rep product from pSTK1 failed to yield soluble, active protein. However, expression from an arbitrary point upstream yielded an elongated product capable of relaxing plasmid substrates encoding an inverted repeat sequence from pSTK1 which resembles the replication origin of the pT181 family. Both this product and a 31 kDa proteolytically derived fragment omitting the C-terminus additionally display activation of the cognate Gst PcrA helicase, but not that of S. aureus. The crystal structure of the 31 kDa fragment of Gst Rep has been solved at 2.3 Å resolution, showing an unusual ring-shaped dimer with a 20 Å diameter pore. The inner surface of the ring is largely formed by an 18-stranded β-sheet, while the outer surface is decorated with 18 α-helices. The protein represents a novel fold; however, the extended sheet does exhibit some similarities to those observed in both TATA-binding protein and transcription factor IID. The active site Tyr179 residues, one from each subunit, lie 26 Å apart across the pore, with a nearby catalytic magnesium ion coordinated by three carboxylate side-chains. Crystal structures for the Sau Rep variants termed RepDE, RepDN and RepDC have been solved by molecular repacement using the Gst Rep as a model, and show similar structural features. The implications for the mechanism of rolling circle replication will be discussed in the light of extensive functional data available for Sau RepD.

Characterization of pMRI 5.2, a rolling-circle-type plasmid from Lactobacillus plantarum BFE 5092 which harbours two different replication initiation genes

Plasmid pMRI 5.2 from Lactobacillus plantarum BFE 5092 was sequenced and analysed. The sequence consists of 5206bp with a mol% G+C content of 35.8%. Nine putative open reading frames were identified. A typical pC194 family double strand origin (dso) and a putative single strand origin (sso) were predicted upstream of a rep gene. This rep gene encoded a replication protein of 314 amino acids exhibiting 98% amino acid sequence identity to the Rep protein of plasmid pLAB1000 from Lactobacillus hilgardii. A mob gene encoding a mobilization protein was also identified and this protein showed high amino acid similarity to Mob proteins from various L. plantarum plasmids. Downstream of the mob gene, a second putative replication region was identified that is similar to the pMV158 family of plasmids. It contains a dso as well as a putative sso, and encodes the 52 amino acid repressor-like protein RepA, the replication initiation protein RepB of 215 amino acids, and the 48 amino acid RepC that is similar to ORFD of the lactococcal plasmid pWVO1. RT-PCR and qRT-PCR expression analyses of the rep and repB genes showed that the repB gene was expressed at a higher level. To confirm that the plasmid replicated by the rolling-circle-type mechanism, the presence of a characteristic single strand intermediate DNA was shown to be produced during replication. Plasmid copy number was ca. 30 per equivalent chromosome copy number based on qRT-PCR analyses. The plasmid also encodes four additional putative proteins of unknown function. The unusual feature of a rolling-circle plasmid having two different plasmid-encoded replication initiation proteins from different replicon families suggests that the genes for these may have originated from different plasmids.

Replication Initiation at a Distance: DETERMINATION OF THE CIS- AND TRANS-ACTING ELEMENTS OF REPLICATION ORIGIN α OF PLASMID R6K

Plasmid R6K, which contains 3 replication origins called alpha, gamma, and beta, is a favorable system to investigate the molecular mechanism(s) of action at a distance, i.e. replication initiation at a considerable distance from the primary initiator protein binding sites (iterons). The centrally located gamma origin contains 7 iterons that bind to the plasmid-encoded initiator protein, pi. Ori alpha, located at a distance of approximately 4 kb from gamma, contains a single iteron that does not directly bind to pi but is believed to access the protein by pi-mediated alpha-gamma iteron-iteron interaction that loops out the intervening approximately 3.7 kb of DNA. Although the cis-acting components and the trans-acting proteins required for ori gamma function have been analyzed in detail, such information was lacking for ori alpha. Here, we have identified both the sequence elements located at alpha and those at gamma, that together promoted alpha activity. The data support the conclusion that besides the single iteron, a neighboring DNA primase recognition element called G site is essential for alpha-directed plasmid maintenance. Sequences preceding the iteron and immediately following the G site, although not absolutely necessary, appear to play a role in efficient plasmid maintenance. In addition, while both dnaA1 and dnaA2 boxes that bind to DnaA protein and are located at gamma were essential for alpha activity, only dnaA2 was required for initiation at gamma. Mutations in the AT-rich region of gamma also abolished alpha function. These results are consistent with the interpretation that a protein-DNA complex consisting of pi and DnaA forms at gamma and activates alpha at a distance by DNA looping.

Origin pairing (‘handcuffing’) and unpairing in the control of P1 plasmid replication

The P1 plasmid origin has an array of five binding sites (iterons) for the plasmid-encoded initiator protein RepA. Saturation of these sites is required for initiation. Iterons can also pair via their bound RepAs. The reaction, called handcuffing, is believed to be the key to control initiation negatively. Here we have determined some of the mechanistic details of the reaction. We show that handcuffed RepA-iteron complexes dissociate when they are diluted or challenged with cold competitor iterons, suggesting spontaneous reversibility of the handcuffing reaction. The complex formation increases with increased RepA binding, but decreases upon saturation of binding. Complex formation also decreases in the presence of molecular chaperones (DnaK and DnaJ) that convert RepA dimers to monomers. This indicates that dimers participate in handcuffing, and that chaperones are involved in reversing handcuffing. They could play a direct role by reducing dimers and an indirect role by increasing monomers that would compete out the weaker binding dimers from the origin. We propose that an increased monomer to dimer ratio is the key to reverse handcuffing.

Biochemical Investigations of Control of Replication Initiation of Plasmid R6K

The mechanistic basis of control of replication initiation of plasmid R6K was investigated by addressing the following questions. What are the biochemical attributes of mutations in the pi initiator protein that caused loss of negative control of initiation? Did the primary control involve only initiator protein-ori DNA interaction or did it also involve protein-protein interactions between pi and several host-encoded proteins? Mutations at two different regions of the pi-encoding sequence individually caused some loss of negative control as indicated by a relatively modest increase in copy number. However, combinations of the mutation P42L, which caused loss of DNA looping, with those located in the region between the residues 106 and 113 induced a robust enhancement of copy number. These mutant forms promoted higher levels of replication in vitro in a reconstituted system consisting of 22 purified proteins. The mutant forms of pi were susceptible to pronounced iteron-induced monomerization in comparison with the WT protein. As contrasted with the changes in DNA-protein interaction, we found no detectable differences in protein-protein interaction between wild type pi with DnaA, DnaB helicase, and DnaG primase on one hand and between the high copy mutant forms and the same host proteins on the other. The DnaG-pi interaction reported here is novel. Taken together, the results suggest that both loss of negative control due to iteron-induced monomerization of the initiator and enhanced iteron-initiator interaction appear to be the principal causes of enhanced copy number.

Reconstitution of R6K DNA Replication in Vitro Using 22 Purified Proteins

We have reconstituted a multiprotein system consisting of 22 purified proteins that catalyzed the initiation of replication specifically at ori gamma of R6K, elongation of the forks, and their termination at specific replication terminators. The initiation was strictly dependent on the plasmid-encoded initiator protein pi and on the host-encoded initiator DnaA. The wild type pi was almost inert, whereas a mutant form containing 3 amino acid substitutions that tended to monomerize the protein was effective in initiating replication. The replication in vitro was primed by DnaG primase, whereas in a crude extract system that had not been fractionated, it was dependent on RNA polymerase. The DNA-bending protein IHF was needed for optimal replication and its substitution by HU, unlike in the oriC system, was less effective in promoting optimal replication. In contrast, wild type pi-mediated replication in vivo requires IHF. Using a template that contained ori gamma flanked by two asymmetrically placed Ter sites in the blocking orientation, replication proceeded in the Cairns type mode and generated the expected types of termination products. A majority of the molecules progressed counterclockwise from the ori, in the same direction that has been observed in vivo. Many features of replication in the reconstituted system appeared to mimic those of in vivo replication. The system developed here is an important milestone in continuing biochemical analysis of this interesting replicon.

A multifunctional plasmid-encoded replication initiation protein both recruits and positions an active helicase at the replication origin.

The DnaA replication initiation protein has been shown to be essential for DNA strand opening at the AT-rich region of the replication origin of the Escherichia coli chromosome as well as serving to recruit and position the DnaB replicative helicase at this open region. Homologues of the dnaA gene of E. coli have been found in most bacterial species, and the DnaA protein has been shown to be required for the initiation of replication of both chromosomal and plasmid DNA. For several plasmid elements it has been found that a plasmid-encoded initiation protein is required along with the DnaA protein to bring about opening of the AT-rich region at the replication origin. The broad host range plasmid RK2 encodes two forms of its replication initiation protein (TrfA-33 and TrfA-44) that differ by an additional 98 aa at the N terminus of the larger (TrfA-44) form. Both forms initiate replication of RK2 in E. coli in vitro by a DnaA-dependent mechanism. However, as shown in this study, TrfA-44 specifically interacts with the DnaB replicative helicase of Pseudomonas putida and Pseudomonas aeruginosa and initiates the formation of a prepriming open complex in the absence of DnaA protein. Thus, the TrfA-44 initiation protein has the multifunctional properties of recruiting and positioning an active form of the DnaB helicase at the RK2 replication origin by a DnaA-independent process. This unique property for a replication initiation protein undoubtedly plays an important role in extending the host range of the RK2 antibiotic resistance plasmid.

A broad host range replicon with different requirements for replication initiation in three bacterial species.

Plasmid RK2 is unusual in its ability to replicate stably in a wide range of Gram-negative bacteria. The replication origin (oriV) and a plasmid-encoded initiation protein (TrfA; expressed as 33 and 44 kDa forms) are essential for RK2 replication. To examine initiation events in bacteria unrelated to Escherichia coli, the genes encoding the replicative helicase, DnaB, of Pseudomonas putida and Pseudomonas aeruginosa were isolated and used to construct protein expression vectors. The purified proteins were tested for activity along with E.coli DnaB at RK2 oriV. Each helicase could be recruited and activated at the RK2 origin in the presence of the host-specific DnaA protein and the TrfA protein. Escherichia coli or P.putida DnaB was active with either TrfA-33 or TrfA-44, while P.aeruginosa DnaB required TrfA-44 for activation. Moreover, unlike the E.coli DnaB helicase, both Pseudomonas helicases could be delivered and activated at oriV in the absence of an ATPase accessory protein. Thus, a DnaC-like accessory ATPase is not universally required for loading the essential replicative helicase at a replication origin.

Isolation of an inner membrane-derived subfraction that supports in vitro replication of a mini-RK2 plasmid in Escherichia coli.

Previous results have demonstrated that the inner, but not the outer, membrane fraction of Escherichia coli is the site of membrane-associated DNA replication of plasmid RK2, a broad-host-range plasmid capable of replication in a wide variety of gram-negative hosts (K. Michaels, J. Mei, and W. Firshein, Plasmid 32:19-31, 1994). To resolve the inner membrane replication site further, the procedure of Ishidate et al. (K. Ishidate, E. S. Creeger, J. Zrike, S. Deb, G. Glauner, T. J. MacAlister, and L. I. Rothfield, J. Biol. Chem. 261:428-443, 1986) was used to separate the inner membrane into a number of subfractions, of which only one, a small subfraction containing only 10% of the entire membrane, was found to synthesize DNA inhibited by antibody prepared against the plasmid-encoded initiation protein TrfA. This is the same subfraction that was also found to bind oriV and TrfA to the greatest extent in filter binding assays (J. Mei, S. Benashski, and W. Firshein, J. Bacteriol. 177:6766-6772, 1995).

TrfA dimers play a role in copy-number control of RK2 replication.

Copy-number regulation of the broad-host-range plasmid RK2 is dependent on the plasmid-encoded initiator protein, TrfA, and the RK2 origin of replication. The handcuffing model for copy-number control proposes that TrfA-bound oris reversibly couple to prevent the further initiation of plasmid replication when the copy number in vivo is at or above the replicon-specific copy number. TrfA mutants have been isolated which allow for oriV replication at elevated copy numbers. To better understand the mechanism of 'handcuffing', the copy-up TrfA(G254D/S267L) mutant was characterized further. In the present study we show by size exclusion chromatography and native gel electrophoresis that unlike wt TrfA which is largely dimeric, purified His6-TrfA(G254D/S267L) is primarily monomeric. In vivo, TrfA33(G254D/S267L) supports replication of an RK2 ori plasmid in trans at a greatly elevated copy number, while in cis the plasmid exhibits runaway replication. However, expression of either of two previously isolated DNA-binding defective TrfA mutants, TrfA33(P151S) or TrfA33(S257F), in a cell transformed with a mini-RK2 replicon encoding TrfA33(G254D/S267L) results in suppression of the runaway phenotype. His6-TrfA(P151S) and His6-TrfA(S257F) purify as dimers, and when expressed in vivo are incapable of supporting RK2 plasmid replication. In contrast, combination of the trfA(P151S) or trfA(S257F) mutation with the trfA(G254D/S267L) mutations results in the expression of mutant TrfA proteins which are mainly monomers and which can no longer restore copy control to replication directed by TrfA33(G254D/S267L) in vivo. On the basis of these findings a handcuffing model is proposed, whereby oriV-bound TrfA monomers are coupled by dimeric TrfA molecules.

Replication and control of circular bacterial plasmids.

An essential feature of bacterial plasmids is their ability to replicate as autonomous genetic elements in a controlled way within the host. Therefore, they can be used to explore the mechanisms involved in DNA replication and to analyze the different strategies that couple DNA replication to other critical events in the cell cycle. In this review, we focus on replication and its control in circular plasmids. Plasmid replication can be conveniently divided into three stages: initiation, elongation, and termination. The inability of DNA polymerases to initiate de novo replication makes necessary the independent generation of a primer. This is solved, in circular plasmids, by two main strategies: (i) opening of the strands followed by RNA priming (theta and strand displacement replication) or (ii) cleavage of one of the DNA strands to generate a 3'-OH end (rolling-circle replication). Initiation is catalyzed most frequently by one or a few plasmid-encoded initiation proteins that recognize plasmid-specific DNA sequences and determine the point from which replication starts (the origin of replication). In some cases, these proteins also participate directly in the generation of the primer. These initiators can also play the role of pilot proteins that guide the assembly of the host replisome at the plasmid origin. Elongation of plasmid replication is carried out basically by DNA polymerase III holoenzyme (and, in some cases, by DNA polymerase I at an early stage), with the participation of other host proteins that form the replisome. Termination of replication has specific requirements and implications for reinitiation, studies of which have started. The initiation stage plays an additional role: it is the stage at which mechanisms controlling replication operate. The objective of this control is to maintain a fixed concentration of plasmid molecules in a growing bacterial population (duplication of the plasmid pool paced with duplication of the bacterial population). The molecules involved directly in this control can be (i) RNA (antisense RNA), (ii) DNA sequences (iterons), or (iii) antisense RNA and proteins acting in concert. The control elements maintain an average frequency of one plasmid replication per plasmid copy per cell cycle and can "sense" and correct deviations from this average. Most of the current knowledge on plasmid replication and its control is based on the results of analyses performed with pure cultures under steady-state growth conditions. This knowledge sets important parameters needed to understand the maintenance of these genetic elements in mixed populations and under environmental conditions.

Synthesis of RepK of rolling circle plasmid pKYM is regulated by countertranscript and HU protein.

Replication of rolling circle plasmid pKYM was regulated by RepK, a plasmid-encoded initiator protein, with HU protein and antisense RNA (copRNA) that block the expression of RepK. HU protein bound to the repK promoter in the presence of RepK protein and inhibited the transcription of repK mRNA. The copRNA would hybridize to repK mRNA and induce a stem-loop structure in which the repK Shine-Dalgarno sequence is sequestered by base pairing. Sequence substitution experiments demonstrated that this stem-loop not only inhibits translation but induces premature termination.

Interactions of the origin of replication (oriV) and initiation proteins (TrfA) of plasmid RK2 with submembrane domains of Escherichia coli.

It has been possible to locate a submembrane domain representing less than 10% of the total membrane that appears to be responsible for sequestering some essential components required for plasmid RK2 DNA replication. This subfraction, whose cellular location in the membrane prior to extraction is still unknown, is derived from the inner membrane fraction, since it possesses enzyme marker activity (NADH oxidase) exclusively associated with the inner membrane. The subfraction was detected by a modification of the methods of Ishidate et al. (K. Ishidate, E. S. Kreeger, J. Zrike, S. Deb, B. Glauner, T. MacAlister, and L. I. Rothfield, J. Biol. Chem. 261:428-443, 1986) in which low pressure in a French pressure cell and lysozyme were used to preserve the supercoil plasmid DNA template during cell disruption. This was followed by successive cycles of sucrose gradient sedimentation and flotation density gradient centrifugation to reveal a number of subfractions, including the one of interest. The characteristics of plasmid interaction with the subfraction include the presence of supercoil DNA after extraction, the binding of the origin of plasmid replication (oriV) in vitro, and the association of the two plasmid-encoded initiation (TrfA) proteins (encoded by overlapping genes). However, another peak, the outer membrane fraction, also binds oriV in vitro, contains plasmid DNA in vivo, and associates with the TrfA initiation proteins. Nevertheless, it contains much less of the initiation proteins, and the specific activity of binding oriV is also much reduced compared with the other subfraction. There is a strong correlation between the association of the TrfA initiation proteins with a particular membrane fraction and the binding of oriV in vitro or plasmid DNA in vivo. Since the proteins are known to bind to repeated sequences in oriV (S. Perri, D. R. Helinski, and A. Toukdarian, J. Biol. Chem. 266:12536-1254, 1991; M. Pinkney, R. Diaz, E. Lanka, and C. M. Thomas, J. Mol. Biol. 203: 927-938, 1988), it appears that the initiation proteins themselves could be responsible, at least in part, for the association of plasmid DNA to the membrane.

Minimal essential origin of plasmid pSC101 replication: requirement of a region downstream of iterons.

The minimal replication origin (ori) of the plasmid pSC101 was defined as an about 220-bp region under the condition that the Rep (or RepA) protein, a plasmid-encoded initiator protein, was supplied in trans. The DnaA box is located at one end of ori, as in other plasmids, like mini-F and P1. The other border is a strong binding site (IR-1) of Rep which is palindromic sequence and lies in an about 50-bp region beyond the repeated sequences (iterons) in ori. This IR-1 is located just upstream of another strong Rep binding site (IR-2), the operator site of the structure gene of Rep (rep), but its function has not been determined. The present study shows that the IR-1 sequence capable of binding to Rep is essential for plasmid replication with a nearly normal copy number. Furthermore, a region between the third iteron and IR-1 is also required in a sequence-specific fashion, since some one-base substitution in this region inactivate the origin function. It is likely that the region also is a recognition site of an unknown protein. Three copy number mutations of rep can suppress any one-base substitution mutation. On the other hand, the sequence of a spacer region between the second and the third iterons, which is similar to that of the downstream region of the third iteron, can be changed without loss of the origin function. The requirement of the region downstream of iterons in pSC101 seems to be unique among iteron-driven plasmid replicons.

Binding of RepE initiator protein to mini-F DNA origin (ori2). Enhancing effects of repE mutations and DnaJ heat shock protein.

Replication of mini-F plasmid in Escherichia coli requires the plasmid-encoded RepE initiator protein and a number of host factors and is regulated by interaction of RepE with specific sequences near the replication origin, ori2. We have examined DNA binding properties of several hyperactive mutant RepE proteins with single amino acid substitutions. Plasmids carrying these (repE) mutations, unlike the parental plasmid, can replicate in bacterial hosts lacking the heat shock sigma factor (sigma 32) or deficient in the DnaK, DnaJ, or GrpE heat shock protein. Using gel-retardation assays, the mutant RepE proteins were shown to bind the ori2 repeated sequences with much increased affinities compared to the wild type RepE, whereas they bound to the repE operator with slightly reduced affinities. These results agreed well with the properties of mutant RepE proteins studied in vivo and accounted for the high RepE initiator activities and the high copy numbers of mutant plasmids. In addition, the DnaJ heat shock protein was found to markedly enhance the binding of wild type RepE to ori2 or the operator. DnaK protein with or without ATP failed to show such enhancements. Thus, among the heat shock proteins required for mini-F replication, DnaJ appears to play a major role in RepE binding to ori2 and the operator, perhaps accompanied by RepE activation.

Antiparallel plasmid-plasmid pairing may control P1 plasmid replication.

The copy number of the P1 plasmid replicon is stringently controlled, giving only one or two copies per newborn cell. Control is achieved by the action of the copy-control locus incA, which contains nine repeats of the 19-basepair binding site for the plasmid-encoded initiator protein RepA. A set of five similar repeats are present in the replication origin where RepA acts to trigger initiation. Using an in vitro replication system consisting of an Escherichia coli extract, the P1 origin as a template, and purified RepA protein, we show that supercoiled DNA circles containing the incA locus block origin function in trans. Shutdown becomes complete at a 1:1 ratio of origin to incA sequences. This is not due to titration of the RepA protein, as an excess of RepA can be added without restoring activity. Rather, the incA sequences appear to block the origin by direct contact in a plasmid-plasmid pairing event. When both the origin and the incA locus are present on one plasmid, trans contacts with daughter molecules appear to predominate over cis looping. The results are consistent with a model for replication control where daughter plasmids block their own replication by a pairing in which each origin is in contact with the incA locus of its partner.

Initiation of rolling-circle replication in pT181 plasmid: initiator protein enhances cruciform extrusion at the origin.

Plasmid pT181 DNA secondary structures have been analyzed in vitro by nuclease S1 digestion and in vivo by bromoacetaldehyde treatment. A cruciform structure occurring at the pT181 replication origin in vitro is greatly enhanced by the binding of the plasmid-encoded initiator protein RepC. In vivo a DNA secondary structure also existed in the replication origin. Its frequency of formation was correlated with efficiency of RepC utilization. These data suggest that cruciform extrusion at the origin is involved in initiation of pT181 rolling-circle replication. A neighboring DNA structure influences the conformation of the origin in vivo.

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.

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.