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

Structures of pMV158 replication initiator RepB with and without DNA reveal a flexible dual-function protein

DNA replication is essential to all living organisms as it ensures the fidelity of genetic material for the next generation of dividing cells. One of the simplest replication initiation mechanisms is the rolling circle replication. In the streptococcal plasmid pMV158, which confers antibiotic resistance to tetracycline, replication initiation is catalysed by RepB protein. The RepB N-terminal domain or origin binding domain binds to the recognition sequence (bind locus) of the double-strand origin of replication and cleaves one DNA strand at a specific site within the nic locus. Using biochemical and crystallographic analyses, here we show how the origin binding domain recognises and binds to the bind locus using structural elements removed from the active site, namely the recognition α helix, and a β-strand that organises upon binding. A new hexameric structure of full-length RepB that highlights the great flexibility of this protein is presented, which could account for its ability to perform different tasks, namely bind to two distinct loci and cleave one strand of DNA at the plasmid origin.

Generating a Small Shuttle Vector for Effective Genetic Engineering of Methanosarcina mazei Allowed First Insights in Plasmid Replication Mechanism in the Methanoarchaeon

Due to their role in methane production, methanoarchaea are of high ecological relevance and genetic systems have been ever more established in the last two decades. The system for protein expression in Methanosarcina using a comprehensive shuttle vector is established; however, details about its replication mechanism in methanoarchaea remain unknown. Here, we report on a significant optimisation of the rather large shuttle vector pWM321 (8.9 kbp) generated by Metcalf through a decrease in its size by about 35% by means of the deletion of several non-coding regions and the ssrA gene. The resulting plasmid (pRS1595) still stably replicates in M. mazei and—most likely due to its reduced size—shows a significantly higher transformation efficiency compared to pWM321. In addition, we investigate the essential gene repA, coding for a rep type protein. RepA was heterologously expressed in Escherichia coli, purified and characterised, demonstrating the significant binding and nicking activity of supercoiled plasmid DNA. Based on our findings we propose that the optimised shuttle vector replicates via a rolling circle mechanism with RepA as the initial replication protein in Methanosarcina. On the basis of bioinformatic comparisons, we propose the presence and location of a double-strand and a single-strand origin, which need to be further verified.

Exploration of DNA processing features unravels novel properties of ICE conjugation in Gram-positive bacteria

Integrative and conjugative elements (ICEs) are important drivers of horizontal gene transfer in prokaryotes. They are responsible for antimicrobial resistance spread, a major current health concern. ICEs are initially processed by relaxases that recognize the binding site of oriT sequence and nick at a conserved nic site. The ICESt3/Tn916/ICEBs1 superfamily, which is widespread among Firmicutes, encodes uncanonical relaxases belonging to a recently identified family called MOB_T. This family is related to the rolling circle replication initiators of the Rep_trans family. The nic site of these MOB_T relaxases is conserved but their DNA binding site is still unknown. Here, we identified the bind site of RelSt3, the MOB_T relaxase from ICESt3. Unexpectedly, we found this bind site distantly located from the nic site. We revealed that the binding of the RelSt3 N-terminal HTH domain is required for efficient nicking activity. We also deciphered the role of RelSt3 in the initial and final stages of DNA processing during conjugation. Especially, we demonstrated a strand transfer activity, and the formation of covalent DNA-relaxase intermediate for a MOB_T relaxase.

The Facts and Family Secrets of Plasmids That Replicate via the Rolling-Circle Mechanism

Plasmids are self-replicative DNA elements that are transferred between bacteria. Plasmids encode not only antibiotic resistance genes but also adaptive genes that allow their hosts to colonize new niches. Plasmid transfer is achieved by conjugation (or mobilization), phage-mediated transduction, and natural transformation. Thousands of plasmids use the rolling-circle mechanism for their propagation (RCR plasmids). They are ubiquitous, have a high copy number, exhibit a broad host range, and often can be mobilized among bacterial species. Based upon the replicon, RCR plasmids have been grouped into several families, the best known of them being pC194 and pUB110 (Rep_1 family), pMV158 and pE194 (Rep_2 family), and pT181 and pC221 (Rep_trans family). Genetic traits of RCR plasmids are analyzed concerning (i) replication mediated by a DNA-relaxing initiator protein and its interactions with the cognate DNA origin, (ii) lagging-strand origins of replication, (iii) antibiotic resistance genes, (iv) mobilization functions, (v) replication control, performed by proteins and/or antisense RNAs, and (vi) the participating host-encoded functions. The mobilization functions include a relaxase initiator of transfer (Mob), an origin of transfer, and one or two small auxiliary proteins. There is a family of relaxases, the MOB_V family represented by plasmid pMV158, which has been revisited and updated. Family secrets, like a putative open reading frame of unknown function, are reported. We conclude that basic research on RCR plasmids is of importance, and our perspectives contemplate the concept of One Earth because we should incorporate bacteria into our daily life by diminishing their virulence and, at the same time, respecting their genetic diversity.

Dynamics of DNA nicking and unwinding by the RepC-PcrA complex

The rolling-circle replication is the most common mechanism for the replication of small plasmids carrying antibiotic resistance genes in Gram-positive bacteria. It is initiated by the binding and nicking of double-stranded origin of replication by a replication initiator protein (Rep). Duplex unwinding is then performed by the PcrA helicase, whose processivity is critically promoted by its interaction with Rep. How Rep and PcrA proteins interact to nick and unwind the duplex is not fully understood. Here, we have used magnetic tweezers to monitor PcrA helicase unwinding and its relationship with the nicking activity of Staphylococcus aureus plasmid pT181 initiator RepC. Our results indicate that PcrA is a highly processive helicase prone to stochastic pausing, resulting in average translocation rates of 30 bp s-1, while a typical velocity of 50 bp s-1 is found in the absence of pausing. Single-strand DNA binding protein did not affect PcrA translocation velocity but slightly increased its processivity. Analysis of the degree of DNA supercoiling required for RepC nicking, and the time between RepC nicking and DNA unwinding, suggests that RepC and PcrA form a protein complex on the DNA binding site before nicking. A comprehensive model that rationalizes these findings is presented.

MOBscan: Automated Annotation of MOB Relaxases

Relaxase-based plasmid classification has become popular in the past 10 years. Nevertheless, it is not obvious how to assign a query protein to a relaxase MOB family. Automated protein annotation is commonly used to classify them into families, gathering evolutionarily related proteins that likely perform the same function, while circumventing the problem of different naming conventions. Here, we implement an automated method, MOBscan, to identify relaxases and classify them into any of the nine MOB families. MOBscan is a web tool that carries out a HMMER search against a curated database of MOB profile Hidden Markov models. It is freely available at https://castillo.dicom.unican.es/mobscan/ .

Characterization of a relaxase belonging to the MOBT family, a widespread family in Firmicutes mediating the transfer of ICEs

BACKGROUND

Conjugative spread of antibiotic resistance and virulence genes in bacteria constitutes an important threat to public health. Beyond the well-known conjugative plasmids, recent genome analyses have shown that integrative and conjugative elements (ICEs) are the most widespread conjugative elements, even if their transfer mechanism has been little studied until now. The initiator of conjugation is the relaxase, a protein catalyzing a site-specific nick on the origin of transfer (oriT) of the ICE. Besides canonical relaxases, recent studies revealed non-canonical ones, such as relaxases of the MOBT family that are related to rolling-circle replication proteins of the Rep_trans family. MOBT relaxases are encoded by ICEs of the ICESt3/ICEBs1/Tn916 superfamily, a superfamily widespread in Firmicutes, and frequently conferring antibiotic resistance.

RESULTS

Here, we present the first biochemical and structural characterization of a MOBT relaxase: the RelSt3 relaxase encoded by ICESt3 from Streptococcus thermophilus. We identified the oriT region of ICESt3 and demonstrated that RelSt3 is required for its conjugative transfer. The purified RelSt3 protein is a stable dimer that provides a Mn2+-dependent single-stranded endonuclease activity. Sequence comparisons of MOBT relaxases led to the identification of MOBT conserved motifs. These motifs, together with the construction of a 3D model of the relaxase domain of RelSt3, allowed us to determine conserved residues of the RelSt3 active site. The involvement of these residues in DNA nicking activity was demonstrated by targeted mutagenesis.

CONCLUSIONS

All together, this work argues in favor of MOBT being a full family of non-canonical relaxases. The biochemical and structural characterization of a MOBT member provides new insights on the molecular mechanism of conjugative transfer mediated by ICEs in Gram-positive bacteria. This could be a first step towards conceiving rational strategies to control gene transfer in these bacteria.

oriD structure controls RepD initiation during rolling-circle replication

Bacterial antibiotic resistance is often carried by circular DNA plasmids that are copied separately from the genomic DNA and can be passed to other bacteria, spreading the resistance. The chloramphenicol-resistance plasmid pC221 from Staphylococcus aureus is duplicated by a process called asymmetric rolling circle replication. It is not fully understood how the replication process is regulated but its initiation requires a plasmid-encoded protein called RepD that nicks one strand of the parent plasmid at the double-stranded origin of replication (oriD). Using magnetic tweezers to control the DNA linking number we found RepD nicking occurred only when DNA was negatively supercoiled and that binding of a non-nicking mutant (RepDY188F) stabilized secondary structure formation at oriD. Quenched-flow experiments showed the inverted complementary repeat sequence, ICRII, within oriD was most important for rapid nicking of intact plasmids. Our results show that cruciform formation at oriD is an important control for initiation of plasmid replication.

Replication of Staphylococcal Resistance Plasmids

The currently widespread and increasing prevalence of resistant bacterial pathogens is a significant medical problem. In clinical strains of staphylococci, the genetic determinants that confer resistance to antimicrobial agents are often located on mobile elements, such as plasmids. Many of these resistance plasmids are capable of horizontal transmission to other bacteria in their surroundings, allowing extraordinarily rapid adaptation of bacterial populations. Once the resistance plasmids have been spread, they are often perpetually maintained in the new host, even in the absence of selective pressure. Plasmid persistence is accomplished by plasmid-encoded genetic systems that ensure efficient replication and segregational stability during cell division. Staphylococcal plasmids utilize proteins of evolutionarily diverse families to initiate replication from the plasmid origin of replication. Several distinctive plasmid copy number control mechanisms have been studied in detail and these appear conserved within plasmid classes. The initiators utilize various strategies and serve a multifunctional role in (i) recognition and processing of the cognate replication origin to an initiation active form and (ii) recruitment of host-encoded replication proteins that facilitate replisome assembly. Understanding the detailed molecular mechanisms that underpin plasmid replication may lead to novel approaches that could be used to reverse or slow the development of resistance.

Force and twist dependence of RepC nicking activity on torsionally-constrained DNA molecules

Many bacterial plasmids replicate by an asymmetric rolling-circle mechanism that requires sequence-specific recognition for initiation, nicking of one of the template DNA strands and unwinding of the duplex prior to subsequent leading strand DNA synthesis. Nicking is performed by a replication-initiation protein (Rep) that directly binds to the plasmid double-stranded origin and remains covalently bound to its substrate 5′-end via a phosphotyrosine linkage. It has been proposed that the inverted DNA sequences at the nick site form a cruciform structure that facilitates DNA cleavage. However, the role of Rep proteins in the formation of this cruciform and the implication for its nicking and religation functions is unclear. Here, we have used magnetic tweezers to directly measure the DNA nicking and religation activities of RepC, the replication initiator protein of plasmid pT181, in plasmid sized and torsionally-constrained linear DNA molecules. Nicking by RepC occurred only in negatively supercoiled DNA and was force- and twist-dependent. Comparison with a type IB topoisomerase in similar experiments highlighted a relatively inefficient religation activity of RepC. Based on the structural modeling of RepC and on our experimental evidence, we propose a model where RepC nicking activity is passive and dependent upon the supercoiling degree of the DNA substrate.

Plasmid Rolling-Circle Replication

Plasmids are DNA entities that undergo controlled replication independent of the chromosomal DNA, a crucial step that guarantees the prevalence of the plasmid in its host. DNA replication has to cope with the incapacity of the DNA polymerases to start de novo DNA synthesis, and different replication mechanisms offer diverse solutions to this problem. Rolling-circle replication (RCR) is a mechanism adopted by certain plasmids, among other genetic elements, that represents one of the simplest initiation strategies, that is, the nicking by a replication initiator protein on one parental strand to generate the primer for leading-strand initiation and a single priming site for lagging-strand synthesis. All RCR plasmid genomes consist of a number of basic elements: leading strand initiation and control, lagging strand origin, phenotypic determinants, and mobilization, generally in that order of frequency. RCR has been mainly characterized in Gram-positive bacterial plasmids, although it has also been described in Gram-negative bacterial or archaeal plasmids. Here we aim to provide an overview of the RCR plasmids' lifestyle, with emphasis on their characteristic traits, promiscuity, stability, utility as vectors, etc. While RCR is one of the best-characterized plasmid replication mechanisms, there are still many questions left unanswered, which will be pointed out along the way in this review.

Historical Events That Spawned the Field of Plasmid Biology

This chapter revisits the historical development and outcome of studies focused on the transmissible, extrachromosomal genetic elements called plasmids. Early work on plasmids involved structural and genetic mapping of these molecules, followed by the development of an understanding of how plasmids replicate and segregate during cell division. The intriguing property of plasmid transmission between bacteria and between bacteria and higher cells has received considerable attention. The utilitarian aspects of plasmids are described, including examples of various plasmid vector systems. This chapter also discusses the functional attributes of plasmids needed for their persistence and survival in nature and in man-made environments. The term plasmid biology was first conceived at the Fallen Leaf Lake Conference on Promiscuous Plasmids, 1990, Lake Tahoe, California. The International Society for Plasmid Biology was established in 2004 (www.ISPB.org).

Structures of replication initiation proteins from staphylococcal antibiotic resistance plasmids reveal protein asymmetry and flexibility are necessary for replication

Antibiotic resistance in pathogenic bacteria is a continual threat to human health, often residing in extrachromosomal plasmid DNA. Plasmids of the pT181 family are widespread and confer various antibiotic resistances to Staphylococcus aureus. They replicate via a rolling circle mechanism that requires a multi-functional, plasmid-encoded replication protein to initiate replication, recruit a helicase to the site of initiation and terminate replication after DNA synthesis is complete. We present the first atomic resolution structures of three such replication proteins that reveal distinct, functionally relevant conformations. The proteins possess a unique active site and have been shown to contain a catalytically essential metal ion that is bound in a manner distinct from that of any other rolling circle replication proteins. These structures are the first examples of the Rep_trans Pfam family providing insights into the replication of numerous antibiotic resistance plasmids from Gram-positive bacteria, Gram-negative phage and the mobilisation of DNA by conjugative transposons.

Identification, characterization and preliminary X-ray diffraction analysis of the rolling-circle replication initiator protein from plasmid pSTK1

Antibiotic resistance in bacterial pathogens poses an ever-increasing risk to human health. In antibiotic-resistant strains of Staphylococcus aureus this resistance often resides in extra-chromosomal plasmids, such as those of the pT181 family, which replicate via a rolling-circle mechanism mediated by a plasmid-encoded replication initiation protein. Currently, there is no structural information available for the pT181-family Rep proteins. Here, the crystallization of a catalytically active fragment of a homologous replication initiation protein from the thermophile Geobacillus stearothermophilus responsible for the replication of plasmid pSTK1 is reported. Crystals of the RepSTK1 fragment diffracted to a resolution of 2.5 Å and belonged to space group P2₁2₁2₁.

Monomeric PcrA helicase processively unwinds plasmid lengths of DNA in the presence of the initiator protein RepD

The helicase PcrA unwinds DNA during asymmetric replication of plasmids, acting with an initiator protein, in our case RepD. Detailed kinetics of PcrA activity were measured using bulk solution and a single-molecule imaging technique to investigate the oligomeric state of the active helicase complex, its processivity and the mechanism of unwinding. By tethering either DNA or PcrA to a microscope coverslip surface, unwinding of both linear and natural circular plasmid DNA by PcrA/RepD was followed in real-time using total internal reflection fluorescence microscopy. Visualization was achieved using a fluorescent single-stranded DNA-binding protein. The single-molecule data show that PcrA, in combination with RepD, can unwind plasmid lengths of DNA in a single run, and that PcrA is active as a monomer. Although the average rate of unwinding was similar in single-molecule and bulk solution assays, the single-molecule experiments revealed a wide distribution of unwinding speeds by different molecules. The average rate of unwinding was several-fold slower than the PcrA translocation rate on single-stranded DNA, suggesting that DNA unwinding may proceed via a partially passive mechanism. However, the fastest dsDNA unwinding rates measured in the single-molecule unwinding assays approached the PcrA translocation speed measured on ssDNA.

Kinetic mechanism of initiation by RepD as a part of asymmetric, rolling circle plasmid unwinding

Some bacterial plasmids carry antibiotic resistance genes and replicate by an asymmetric, rolling circle mechanism, in which replication of the two strands is not concurrent. Initiation of this replication occurs via an initiator protein that nicks one DNA strand at the double-stranded origin of replication. In this work, RepD protein from the staphylococcal plasmid pC221 carries this function and allows PcrA helicase to bind and begin unwinding the plasmid DNA. This work uses whole plasmid constructs as well as oligonucleotide-based mimics of parts of the origin to examine the initiation reaction. It investigates the phenomenon that nicking, although required to open a single-stranded region at the origin and so allow PcrA to bind, is not required for another function of RepD, namely to increase the processivity of PcrA, allowing it to unwind plasmid lengths of DNA. A kinetic mechanism of RepD initiation is presented, showing rapid binding of the origin DNA. The rate of nicking varies with the structure of the DNA but can occur with a rate constant of >25 s(-1) at 30 °C. The equilibrium constant of the nicking reaction, which involves a transesterification to form a phosphotyrosine bond within the RepD active site, is close to unity.

Fluorescent biosensors to investigate helicase activity

ATP-driven translocation of helicases along DNA can be assayed in several ways. Reagentless biosensors, based on fluorophore-protein adducts, provide convenient ways for real-time assays of both the separation of dsDNA and the hydrolysis of ATP. Single-stranded DNA can be assayed using a modified single-stranded DNA-binding protein (SSB), and phosphate production during ATP hydrolysis can be measured by a modified phosphate-binding protein. Advantages and limitations of these approaches are compared with those of other types of measurements.

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

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

Visualizing helicases unwinding DNA at the single molecule level

DNA helicases are motor proteins that catalyze the unwinding of double-stranded DNA into single-stranded DNA using the free energy from ATP hydrolysis. Single molecule approaches enable us to address detailed mechanistic questions about how such enzymes move processively along DNA. Here, an optical method has been developed to follow the unwinding of multiple DNA molecules simultaneously in real time. This was achieved by measuring the accumulation of fluorescent single-stranded DNA-binding protein on the single-stranded DNA product of the helicase, using total internal reflection fluorescence microscopy. By immobilizing either the DNA or helicase, localized increase in fluorescence provides information about the rate of unwinding and the processivity of individual enzymes. In addition, it reveals details of the unwinding process, such as pauses and bursts of activity. The generic and versatile nature of the assay makes it applicable to a variety of DNA helicases and DNA templates. The method is an important addition to the single-molecule toolbox available for studying DNA processing enzymes.

The ATPase cycle of PcrA helicase and its coupling to translocation on DNA

The superfamily 1 bacterial helicase PcrA has a role in the replication of certain plasmids, acting with the initiator protein (RepD) that binds to and nicks the double-stranded origin of replication. PcrA also translocates single-stranded DNA with discrete steps of one base per ATP hydrolyzed. Individual rate constants have been determined for the DNA helicase PcrA ATPase cycle when bound to either single-stranded DNA or a double-stranded DNA junction that also has RepD bound. The fluorescent ATP analogue 2'(3')-O-(N-methylanthraniloyl)ATP was used throughout all experiments to provide a complete ATPase cycle for a single nucleotide species. Fluorescence intensity and anisotropy stopped-flow measurements were used to determine rate constants for binding and release. Quenched-flow measurements provided the kinetics of the hydrolytic cleavage step. The fluorescent phosphate sensor MDCC-PBP was used to measure phosphate release kinetics. The chemical cleavage step is the rate-limiting step in the cycle and is essentially irreversible and would result in the bound ATP complex being a major component at steady state. This cleavage step is greatly accelerated by bound DNA, producing the high activation of this protein compared to the protein alone. The data suggest the possibility that ADP is released in two steps, which would result in bound ADP also being a major intermediate, with bound ADP.P(i) being a very small component. It therefore seems likely that the major transition in structure occurs during the cleavage step, rather than P(i) release. ATP rebinding could then cause reversal of this structural transition. The kinetic mechanism of the PcrA ATPase cycle is very little changed by potential binding to RepD, supporting the idea that RepD increases the processivity of PcrA by increasing affinity to DNA rather than affecting the enzymatic properties per se.

PcrA helicase tightly couples ATP hydrolysis to unwinding double-stranded DNA, modulated by the initiator protein for plasmid replication, RepD

The plasmid replication initiator protein, RepD, greatly stimulates the ability of the DNA helicase, PcrA, to unwind plasmid lengths of DNA. Unwinding begins at oriD, the double-stranded origin of replication that RepD recognizes and covalently binds to initiate replication. Using a combination of plasmids containing oriD and oligonucleotide structures that mimic parts of oriD, the kinetics of DNA nicking and separation have been determined, along with the coupling ratio between base separation and ATP hydrolysis. At 30 °C, the rate of nicking is 1.0 s⁻¹, and translocation is ∼30 bp s⁻¹. During translocation, the coupling ratio is one ATP hydrolyzed per base pair separated, the same as the value previously reported for ATP hydrolyzed per base moved by PcrA along single-stranded DNA. The data suggest that processivity is high, such that several thousand base-pair plasmids are unwound by a single molecule of PcrA. In the absence of RepD, a single PcrA is unable to separate even short lengths (10 to 40 bp) of double stranded DNA.

Fluorescent single-stranded DNA binding protein as a probe for sensitive, real-time assays of helicase activity

The formation and maintenance of single-stranded DNA (ssDNA) are essential parts of many processes involving DNA. For example, strand separation of double-stranded DNA (dsDNA) is catalyzed by helicases, and this exposure of the bases on the DNA allows further processing, such as replication, recombination, or repair. Assays of helicase activity and probes for their mechanism are essential for understanding related biological processes. Here we describe the development and use of a fluorescent probe to measure ssDNA formation specifically and in real time, with high sensitivity and time resolution. The reagentless biosensor is based on the ssDNA binding protein (SSB) from Escherichia coli, labeled at a specific site with a coumarin fluorophore. Its use in the study of DNA manipulations involving ssDNA intermediates is demonstrated in assays for DNA unwinding, catalyzed by DNA helicases.

Characterization of the pTZ2162 encoding multidrug efflux gene qacB from Staphylococcus aureus

The plasmid-borne multidrug efflux gene qacB is widely distributed in methicillin-resistant Staphylococcus aureus (MRSA). We analyzed the complete nucleotide sequence of the plasmid pTZ2162 (35.4 kb) encoding qacB. The plasmid pTZ2162 contains 47 ORFs and four copies of IS257 (designated IS257A to D). The 24.7-kb region of pTZ2162, which excluding the region flanked by IS257A and IS257D, is 99.9% identical to pN315 carried by MRSA N315. However, the repA-like region of pTZ2162 was divided into two ORFs, ORF46 and ORF47. Functional analysis with the pUC19-based vector pTZN03 showed that both ORF46 and ORF47 were essential for the replication of pTZ2162 and ORF1 is required for the stable maintenance of pTZ2162 in S. aureus. When pTZ2162 was searched for evidence of mobile elements, an 8-bp duplicated sequence (GATAAAGA) was existed at the left boundary of IS257A and the right boundary of IS257D. Therefore, the 10.7-kb region between IS257A and IS257D in pTZ2162 has the potential to act as a transposon. In addition to qacB, the pTZ2162 transposon-like element contains a novel fosfomycin resistance determinant fosD and an aminoglycoside resistance determinant aacA-aphD. This transposon-like element appears to have translocated into the beta-lactamase gene blaZ. Our data suggest that qacB is transferred between MRSA as a multiple antibiotic resistance transposon.

Directional loading and stimulation of PcrA helicase by the replication initiator protein RepD

The replication initiator protein RepD recruits the Bacillus PcrA helicase directly onto the (-) strand of the plasmid replication origin oriD. The 5'-phosphate group at the nick is essential for loading, suggesting that it is the RepD covalently linked to the 5'-phosphate group at the nick that loads the helicase onto the oriD. The products of the unwinding reaction were visualised by atomic force microscopy (AFM) and monitored in real time by fluorescence spectroscopy. RepD remains associated with PcrA and stimulates processive directional unwinding of the plasmid at approximately 60 bp s(-1). In the absence of RepD, PcrA retains the ability to bind to a pre-nicked oriD, but engages the 3' end of the nick and translocates 3'-5' along the (+) strand in a poorly processive fashion. Our data provide a unique insight into the recruitment of PcrA-like helicases to DNA-nick sites and the processive translocation of the PcrA motor as a component of the plasmid replication apparatus.

Interactions between the RepB initiator protein of plasmid pMV158 and two distant DNA regions within the origin of replication

Plasmids replicating by the rolling circle mode usually possess a single site for binding of the initiator protein at the origin of replication. The origin of pMV158 is different in that it possesses two distant binding regions for the initiator RepB. One region was located close to the site where RepB introduces the replication-initiating nick, within the nic locus; the other, the bind locus, is 84 bp downstream from the nick site. Binding of RepB to the bind locus was of higher affinity and stability than to the nic locus. Contacts of RepB with the bind and nic loci were determined through high-resolution footprinting. Upon binding of RepB, the DNA of the bind locus follows a winding path in its contact with the protein, resulting in local distortion and bending of the double-helix. On supercoiled DNA, simultaneous interaction of RepB with both loci favoured extrusion of the hairpin structure harbouring the nick site while causing a strong DNA distortion around the bind locus. This suggests interplay between the two RepB binding sites, which could facilitate loading of the initiator protein to the nic locus and the acquisition of the appropriate configuration of the supercoiled DNA substrate.

Role of RepB in the replication of plasmid pJB01 isolated from Enterococcus faecium JC1

The plasmid pJB01 (GenBank Accession No. AY425961) isolated from the pathogenic bacterium, Enterococcus faecium JC1, is 2235 base pairs in length and consists of a putative double-strand origin (dso), a single-strand origin, a counter-transcribed RNA, and three open reading frames. A comparison of a few replication factors and motifs, bind and nic regions, for replication initiation on the nucleotide sequence level revealed that it belongs to the pMV158 family among RC-replicating plasmids. A runoff DNA synthesis assay demonstrated that nicking occurred between G525 and A526, which is located on the internal loop of a putative secondary structure in the dso. Unlike all the other plasmids of the pMV158 family having two or three direct repeats, pJB01 has three non-tandem direct repeats of 5'-CAACAAA-3' separated by four nucleotides, as the RepB-binding site in the dso. Moreover, the nick site on the internal loop is located at 77 nucleotides upstream from the RepB-binding region. Irrespective of the structural difference of direct repeats from other members of the pMV158 family, we think, it is still a new member of this plasmid family. The introduction of mutations in conserved regions of RepB confirmed that RepB N-moiety is important for nicking/nick-closing activity. Within N-moiety, especially all of the motif R-III, the Y100 in R-IV and Y116 in R-V residues, played particularly critical roles in this activity, however, for its binding, both of the N- and C-moieties of RepB were needed.

Plasmid rolling-circle replication: highlights of two decades of research

This review provides a historical perspective of the major findings that contributed to our current understanding of plasmid rolling-circle (RC) replication. Rolling-circle-replicating (RCR) plasmids were discovered approximately 20 years ago. The first of the RCR plasmids to be identified were native to Gram-positive bacteria, but later such plasmids were also identified in Gram-negative bacteria and in archaea. Further studies revealed mechanistic similarities in the replication of RCR plasmids and the single-stranded DNA bacteriophages of Escherichia coli, although there were important differences as well. Three important elements, a gene encoding the initiator protein, the double strand origin, and the single strand origin, are contained in all RCR plasmids. The initiator proteins typically contain a domain involved in their sequence-specific binding to the double strand origin and a domain that nicks within the double strand origin and generates the primer for DNA replication. The double strand origins include the start-site of leading strand synthesis and contain sequences that are bound and nicked by the initiator proteins. The single strand origins are required for synthesis of the lagging strand of RCR plasmids. The single strand origins are non-coding regions that are strand-specific, and contain extensive secondary structures. This minireview will highlight the major findings in the study of plasmid RC replication over the past twenty years. Regulation of replication of RCR plasmids will not be included since it is the subject of another review.

DNA–Protein Interactions during the Initiation and Termination of Plasmid pT181 Rolling-Circle Replication

Initiation of DNA replication requires the generation of a primer at the origin of replication that can be utilized by a DNA polymerase for DNA synthesis. This can be accomplished by several means, including the synthesis of an RNA primer by a DNA primase or RNA polymerase, by nicking of one strand of the DNA to generate a free 3'-OH end that can be used as a primer, and by the utilization of the OH group present in an amino acid such as serine within an initiation protein as a primer. Furthermore, some single-stranded DNA genomes can utilize a snap-back 3'-OH end generated due to self-complementarity as a primer for DNA replication. The different modes of initiation require the generation of highly organized DNA-protein complexes at the origin that trigger the initiation of replication. A large majority of small, multicopy plasmids of Gram-positive bacteria and some of Gram-negative bacteria replicate by a rolling-circle (RC) mechanism (for previous reviews, see Refs.). More than 200 rolling-circle replicating (RCR) plasmids have so far been identified and, based on sequence homologies in their replication regions, can be grouped into approximately seven families (Refs., and http://www.essex.ac.uk/bs/staff/osborn/DPR-home.htm). This review will focus on plasmids of the pT181 family that replicate by an RC mechanism. So far, approximately 25 plasmids have been identified as belonging to this family based on the sequence homology in their double-strand origins (dsos) and the genes encoding the initiator (Rep) proteins. This review will highlight our current understanding of the structural features of the origins of replication, and the DNA-protein and protein-protein interactions that result in the generation of a replication-initiation complex that triggers replication. It will discuss the molecular events that result in the precise termination of replication once the leading-strand DNA synthesis has been completed. This review will also discuss the various biochemical activities of the initiator proteins encoded by the plasmids of the pT181 family and the mechanism of inactivation of the Rep activity after supporting one round of leading-strand replication. Finally, the review will outline the mechanism of replication of the lagging strand of the pT181 plasmid as well as the limited information that is available on the role of host proteins in pT181 leading- and lagging-strand replication.

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.

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.

A rolling-circle miniplasmid of Xanthomonas campestris pv. glycines: the nucleotide sequence and its use as a cloning vector

The indigenous multicopy miniplasmid (pXG33) of Xanthomonas campestris pv. glycines was entirely sequenced and evaluated as a cloning vector for Xanthomonas. The pXG33 contains 1738 bp and the nucleotide sequence revealed a consensus nicking site (TGATA) described for the pC194 family of rolling-circle replicating (RCR) plasmids. This nicking site is embebbed in a region of high potential to form a number of stem-loop structures. The predicted protein (Rep) showed conserved amino acid residues and potential catalytic regions, containing conserved Tyr and Glu residues. These results indicate that pXG33 replicates by a rolling-circle mechanism. For use as a cloning vector for Xanthomonas, a fragment containing the kanamycin resistance gene (aphA) and the stabilization locus (parB) was inserted into pXG33. The new construct, of 3.4 kb, was designated pXG31. By deletion of the parB locus and using pBluescript KS(+) as an intermediate, pXG40 (2.8 kb), containing unique restriction sites for BamHI, EcoRI, SacI, and KpnI at the ends of the kanamycin resistance gene, was generated. Both constructs showed stability in Xanthomonas during 18 h of growth or 72 h of fermentation, high-copy number, and no interference with pathogenicity. pXG31 and pXG40, however, were incapable of duplication in Escherichia coli and a shuttle vector (pKX33) was constructed by inactivation of some restriction sites of pXG40 and ligation to the cloning vector pBluescript KS(+). pKX33 is nonconjugative, is multicopy, is of low molecular weight (5.7 kb), presents antibiotic resistance markers for ampicillin and kanamycin, has unique restriction sites for KpnI, SalI, EcoRV, EcoRI, BamHI, XbaI, and SacI, and can be used directly for sequencing with universal primers. It can be maintained in E. coli and several species and pathovars of Xanthomonas.

The active site of the rolling circle replication protein Rep75 is involved in site-specific nuclease, ligase and nucleotidyl transferase activities

The plasmid pGT5 from the hyperthermophilic archaeon Pyrococcus abyssi replicates via a rolling circle mechanism. The protein Rep75, encoded by this plasmid, exhibits a nicking-closing (NC) activity in vitro on single-stranded oligonucleotides containing the pGT5 double-stranded origin sequence. In addition, Rep75 catalyses a site-specific nucleotidyl terminal transferase (NTT) activity, e.g. it can transfer one AMP or dAMP (from ATP or dATP) to the 3'-OH of an oligonucleotide corresponding to the left part of the nicking site. The Rep75 sequence contains a motif similar to the active-site motifs of Rep proteins from the PhiX174/pC194 superfamily. We show here that the tyrosine present in this motif is indeed essential for DNA cleavage by Rep75, but is dispensable for its NTT activity. However, a nearby arginine, which is not required for DNA cleavage, is involved in both NTT and closing, indicating that the same active site is involved in the NC and NTT activities of Rep75. For both NTT and NC, the G residue in 3' of the nicking site is essential, whereas the A residue in 5' is dispensable for NC, despite its conservation in RC plasmids of the PhiX174/pC194 superfamily. The NTT and closing activities have an optimal temperature lower than the nicking activity. These data indicate that the three reactions catalysed by Rep75 can be uncoupled, although they share part of their mechanisms. Finally, we show that NC is inhibited by ATP or dATP at concentrations that promote NTT. We propose a model in which the NTT activity of Rep75 plays a role in the regulation of pGT5 replication in vivo.

An oligonucleotide inhibits oligomerization of a rolling circle initiator protein at the pT181 origin of replication

A large number of plasmids have been shown to replicate by a rolling circle (RC) mechanism. The initiators encoded by these plasmids have origin-specific, nicking-closing activity that is required for the initiation and termination of RC replication. Since the initiators of many RC plasmids are rate-limiting for replication, these proteins are usually inactivated after supporting one round of replication. In the case of the pT181 plasmid, inactivation of the initiator RepC protein occurs by the attachment of an oligonucleotide to its active tyrosine residue. We have generated the inactivated form of RepC, termed RepC*, in vitro and investigated the effects of attachment of the oligonucleotide on its various biochemical activities. Our results demonstrate that while RepC* is inactive in nicking-closing and replication activities due to the blockage of its active tyrosine residue, it is competent in origin DNA binding and DNA religation activities. We have investigated the oligomeric state of RepC and RepC* and found that RepC exists as a dimer in solution and can oligomerize on the DNA. We have generated heterodimers in vitro between the wild-type and epitope-tagged RepC proteins. In electrophoretic mobility shift experiments, the initiator heterodimers generated a novel DNA-protein complex, demonstrating that it binds to DNA as a dimer. We have shown that a DNA binding mutant of RepC can be targeted to the origin in the presence of the wild-type protein primarily through a protein-protein interaction. Interestingly, RepC* is defective in its ability to oligomerize on the DNA. RepC* inhibited the DNA binding and replication activity of wild-type RepC to only a very limited extent, suggesting that it may play only a minor regulatory role in replication in vivo. Based on these and earlier results, we propose a model for the role of RepC during the initiation and termination of pT181 RC replication.

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.

A rolling circle replication initiator protein with a nucleotidyl-transferase activity encoded by the plasmid pGT5 from the hyperthermophilic archaeon Pyrococcus abyssi

The plasmid pGT5 from the hyperthermophilic archaeon Pyrococcus abyssi presents similarities to plasmids from the pC194 family that replicate by the rolling circle mechanism. These plasmids encode a replication initiator protein, which activates the replication origin by nicking one of the two DNA strands. The gene encoding the putative Rep protein of pGT5 (Rep75) has been cloned and overexpressed in Escherichia coli, and the recombinant protein has been purified to homogeneity. Rep75 exhibits a highly thermophilic nicking-closing activity in vitro on single-stranded oligonucleotides containing the putative double-stranded replication origin sequence of pGT5. Gel shift analyses on single-stranded oligonucleotides indicate that Rep75 recognizes the single-stranded DNA region upstream of the nicking site via non-covalent interaction and remains covalently linked to the 5'-phosphate of the downstream fragment after nicking. Besides these expected activities, Rep75 contains a dATP (and ATP) terminal transferase activity at the 3'-OH extremity of the nicking site, which had not been reported previously for proteins of this type. Rep75, which is the first replication initiator protein characterized in an archaeon, offers an attractive new model for the study of rolling circle replication.

How rolling circle plasmids control their copy number

Rolling circle DNA replication is inherently continuous and unregulated. This 'go-for-broke' strategy works well for lytic phages but is suicidal for plasmids that must coexist with their host. Plasmids have consequently evolved elaborate copy number control systems that operate at the transcriptional, translational and post-translational levels.

Double-stranded origin nicking and replication initiation are coupled in the replication of a rolling circle plasmid, pT181

The Staphylococcus aureus rolling circle plasmid pT181 initiator RepC is modified by the addition of an oligodeoxynucleotide, giving rise to a new form, RepC*. RepC/RepC* heterodimer is an inhibitor of replication. However, in order to act effectively, the initiator/inhibitor protein must be stable. We show here that RepC is stable for at least 90 min, which enables it to function effectively as an inhibitor of replication. This finding also allowed us to carry out the two stages in pT181 replication sequentially: first, binding/nicking of the double-strand origin (DSO) by the pT181-encoded RepC, followed by initiation/elongation by the host cell's DNA replication apparatus. The results demonstrate that these two stages in pT181 replication are functionally coupled and that interruptions in this continuous process generate relaxed pT181 DNA that cannot be used as a template for replication.

Initiation of replication of plasmid pMV158: mechanisms of DNA strand-transfer reactions mediated by the initiator RepB protein

The initiator RepB protein of the rolling circle-replicating plasmid pMV158 has nicking-closing (topoisomerase I-like) activities on supercoiled DNA. RepB is also able to perform a strand-transfer reaction on a single-stranded DNA substrate that contains its target. Several attempts at capturing covalent protein-DNA intermediates were made to identify the mechanism of RepB-mediated activity. Whereas RepB did not generate stable complexes with its target DNA, employment of single-stranded oligonucleotides containing a chiral phosphorothioate in the target DNA allowed us to follow the process of RepB-mediated strand-transfer reaction. This reaction occurred through a number of even steps because the chirality of the phosphorothioate at the reaction site was retained after RepB-mediated strand transfer. This finding suggests the existence of a covalent intermediate during the strand-transfer reaction between the protein and its target DNA. By site-directed mutagenesis at the codon for Tyr99 of RepB, and purification and assay of activity of the mutant protein variants, we showed that the Tyr99 residue is involved in the nucleophilic attack of RepB to its cognate DNA.

Modification of the plasmid initiator protein RepC active site during replication

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. His-tagged 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.

Mechanisms of initiation and termination reactions in conjugative DNA processing. Independence of tight substrate binding and catalytic activity of relaxase (TraI) of IncPalpha plasmid RP4

The relaxase (TraI) of plasmid RP4 (IncPalpha) plays a key role in initiation and termination of transfer DNA replication during conjugative transmission of the plasmid. TraI functions as a DNA strand transferase that cleaves a unique phosphodiester bond at nic of the transfer origin. The cleavage reaction consists in a reversible transesterification that leads to transfer of the 5' phosphoryl at nic to the hydroxyl group of TraI Tyr-22. Hence, cleavage results in the covalent attachment of TraI to the 5' terminus of the plasmid strand destined for transfer. To investigate the protein's ability to function in a "second cleavage" reaction proposed to terminate rolling circle mode transfer DNA replication, single-stranded oligonucleotides containing the nic region were immobilized at their 3' ends on magnetic beads and cleaved by TraI. The resulting covalent TraI-oligonucleotide adducts were active in the joining reaction but unable to cleave oligonucleotides containing an intact nic region, indicating that second cleavage probably requires a TraI dimer, since a monomer is insufficient. The covalently attached oligonucleotide determines the affinity of the relaxase for the 3' terminus of the T-strand. To further the biochemical characterization of TraI-catalyzed reactions, we used specific TraI mutants, showing that amino acid residues in each relaxase motif are involved in substrate binding. To uncouple substrate binding and cleaving-joining, we applied partially biotinylated TraI mutant proteins that were immobilized to magnetic beads. Using this approach we could demonstrate that tight DNA substrate binding and cleaving-joining are independent processes. Enhanced topoisomerase activity of some TraI mutants was correlated with low specific substrate binding affinity in conjunction with high cleaving-joining activity.

Identification of the nicking tyrosine of geminivirus Rep protein

The replication initiator (Rep) proteins of geminiviruses perform a DNA cleavage and strand transfer reaction at the viral origin of replication. As a reaction intermediate, Rep proteins become covalently linked to the 5' end of the cleaved DNA. We have used tomato yellow leaf curl virus Rep protein for in vivo and in vitro analyses. Isolating a covalent peptide-nucleotide complex, we have identified the amino acid of Rep which mediates cleavage and links the protein to DNA. We show that tyrosine-103, located in a conserved sequence motif, initiates DNA cleavage and is the physical link between geminivirus Rep protein and its origin DNA.

In vitro recognition of the replication origin of pLS1 and of plasmids of the pLS1 family by the RepB initiator protein

Rolling-circle replication of plasmid pLS1 is initiated by the plasmid-encoded RepB protein, which has nicking-closing (site-specific DNA strand transferase) enzymatic activity. The leading-strand origin of pLS1 contains two regions, (i) the RepB-binding site, constituted by three directly repeated sequences (iterons or the bind region), and (ii) the sequence where RepB introduces the nick to initiate replication (the nic region). A series of plasmids, belonging to the pLS1 family, show features similar to those of pLS1 and have DNA sequences homologous to the pLS1 nic region. In addition, they all share homologies at the level of their Rep proteins. However, the bind regions of these plasmids are, in general, not conserved. We tested the substrate specificity of purified RepB of pLS1. The RepB protein has a temperature-dependent nicking-closing action on supercoiled pLS1, as well as on recombinant plasmid DNAs harboring the pLS1 nic region. The DNA strand transferase activity of pLS1-encoded RepB was also assayed on two plasmids of the pLS1 family, namely, pE194 and pFX2. DNAs from both plasmids were relaxed by RepB, provided they had a proper degree of supercoiling; i.e., it was necessary to modulate the supercoiling of pE194 DNA to achieve RepB-mediated DNA relaxation. Single-stranded oligonucleotides containing the nic regions of various plasmids belonging to the pLS1 family, including those of pE194 and pFX2, were substrates for RepB. In vitro, the RepB protein does not need to bind to the iterons for its nicking-closing activity.

Plasmid rolling circle replication and its control

This review summarises current information on rolling circle replicating plasmids originally isolated from Gram-positive bacteria with a low guanine and cytosine content in their DNA. It focuses on the peculiar biological features of these small, high copy number plasmids that replicate via an asymmetric RC mechanism. The regulation of plasmid copy number is also discussed.

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 to 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.

The tyrosine-6 hydroxyl of gamma delta resolvase is not required for the DNA cleavage and rejoining reactions

Site-specific recombinases of the resolvase and DNA invertase family all contain a tyrosine residue close to the N-terminus, and four residues away from a serine that has been implicated in catalysis of DNA strand breakage and reunion. To examine the role of this tyrosine in recombination, we have constructed a mutant of gamma delta resolvase in which the tyrosine (residue 6) is replaced by phenylalanine. Characterization of the Y6F mutant protein in vitro indicated that although it was highly defective in recombination, it could cleave DNA at the cross-over site, form a covalent resolvase-DNA complex and rejoin the cleaved cross-over site (usually restoring the parental site). These data rule out a direct role of the Tyr-6 hydroxyl as the nucleophile in the DNA cleavage reaction and strengthen the conclusion that this nucleophile is the nearby invariant serine residue, Ser-10. We conclude that Tyr-6 is essential for fully co-ordinated strand cleavage and exchange, but is dispensable for individual strand cleavage and religation reactions.

Specific nicking-closing activity of the initiator of replication protein RepB of plasmid pMV158 on supercoiled or single-stranded DNA

Asymmetric rolling circle replication of the promiscuous replicon pMV158 is initiated by the plasmid-encoded RepB protein. In vitro, purified RepB protein introduces a nick within the leading strand origin of replication by a nucleophylic attack on the phosphodiester bond at the dinucleotide GpA. Some changes within and around this dinucleotide were recognized by the protein. RepB nicked and closed supercoiled pMV158 DNA, having an optimum activity at 60 degrees C. We have imitated, in vitro, a process of rolling circle replication, since RepB was able to nick (initiation) and to covalently close (termination) single-stranded oligonucleotides containing the protein cleavage sequence. Covalent DNA-protein complexes were not found, indicating that RepB has unique features among plasmid-encoded proteins involved in rolling-circle replication or conjugative mobilization.