Plasmids of the pT181 family show replication-specific initiator protein modification

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.

Sequence analysis of five endogenous plasmids isolated from Lactobacillus pentosus F03

Lactobacillus pentosus F03, a strain isolated from pig intestines in Taiwan, contains multiple endogenous plasmids. We isolated, completely sequenced, and characterized five of the plasmids present in L. pentosus F03 designated as pF03-1 (3282bp), pF03-2 (3293bp), pF03-3 (1787bp), pF03-4 (2138bp), and pF03-5 (1949bp). The replication types of these plasmids were predicted by comparing the features of the replicon nucleotides and the similarity of replication proteins with those of the plasmids of known replication types. The results of basic local alignment search tool analyses indicate that these plasmids, except for pF03-4, belong to different replicating plasmid families. According to replicon and initiator protein analyses, pF03-1, pF03-2, and pF03-3, were determined to belong respectively to the pMV158, pC194/pUB110, and pT181 families of rolling-circle replication plasmids. However, pF03-5 contains the typical features observed in the family of theta-replicating plasmids and belongs to the pUCL287 family of theta-replicating plasmids.

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.

Contrasting lifestyles of rolling-circle phages and plasmids

The rolling-circle mechanism of DNA replication is used by small prokaryotic genomes, such as single-stranded phages and plasmids. However, phages and plasmids have adapted the rolling-circle mechanism differently to suit their contrasting biological needs. The phi X174 phage uses a monomeric initiator protein catalytically, displays incomplete termination and recycles the initiator protein, in order to mass-produce phage progeny. By contrast, to control replication precisely, the pT181 plasmid uses a dimeric initiator protein stochiometrically, completes termination and inactivates the initiator after each replication cycle. The phi X174 phage and the pT181 plasmid represent paradigmatic adaptations of the rolling-circle mechanism and could provide models for other replicons.

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.

Rolling-circle replication of bacterial plasmids

Many bacterial plasmids replicate by a rolling-circle (RC) mechanism. Their replication properties have many similarities to as well as significant differences from those of single-stranded DNA (ssDNA) coliphages, which also replicate by an RC mechanism. Studies on a large number of RC plasmids have revealed that they fall into several families based on homology in their initiator proteins and leading-strand origins. The leading-strand origins contain distinct sequences that are required for binding and nicking by the Rep proteins. Leading-strand origins also contain domains that are required for the initiation and termination of replication. RC plasmids generate ssDNA intermediates during replication, since their lagging-strand synthesis does not usually initiate until the leading strand has been almost fully synthesized. The leading- and lagging-strand origins are distinct, and the displaced leading-strand DNA is converted to the double-stranded form by using solely the host proteins. The Rep proteins encoded by RC plasmids contain specific domains that are involved in their origin binding and nicking activities. The replication and copy number of RC plasmids, in general, are regulated at the level of synthesis of their Rep proteins, which are usually rate limiting for replication. Some RC Rep proteins are known to be inactivated after supporting one round of replication. A number of in vitro replication systems have been developed for RC plasmids and have provided insight into the mechanism of plasmid RC 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.

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

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

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.

The inactivated plasmid inititator protein RepC/RepC* may have a regulatory role

During replication of the plasmid pT181, the initiator protein RepC is modified by the addition of an oligodeoxynucleotide, giving rise to a new form, RepC*. Here we show that during in vitro replication, RepC* is radioactively labeled, suggesting that the source of the RepC* oligodeoxynucleotide is the newly synthesized pT181 DNA. The RepC/RepC* heterodimer retains its ability to bind the pT181 double-strand origin and, therefore, it may act as a competitive inhibitor of the RepC homodimer during replication.

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.

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

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

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.

The level of the pUB110 replication initiator protein is autoregulated, which provides an additional control for plasmid copy number

Plasmids control their copy number by limiting the amount of the initiator for DNA replication. The plasmid pUB110 initiator protein is termed RepU. Expression of the pUB110 repU gene is controlled by two antisense RNAs that interfere with repU mRNA translation. Genetic evidence suggests that Rep protein levels may be regulated by additional uncharacterized mechanisms. The repU gene product was radiolabeled and purified by monitoring the radioactive label. RepU overproduction was performed in cells containing the plasmid leading strand replication origin (dso), to allow for a putative inactivation of RepU. Polypeptides with apparent molecular masses of 42 (RepU*) and 39 (RepU) kDa were purified, both having the N-terminal sequence expected for the repU gene. The RepU/RepU* protein mixture bound specifically to dso. At low protein concentrations, about six RepU/RepU* protomers bound to the dso region. At higher concentrations, an extended nucleoprotein complex was formed. The promoter for the repU gene was localized downstream of the dso region. The results suggest that the extended RepU/RepU*-dso DNA complex interferes with repU promoter utilization. This provides an additional copy number control by limiting RepU concentration. Our results suggest that during replication the RepU protein might be converted into an inactive RepU-RepU* hetero-oligomer, further limiting the amount of RepU protein available for replication initiation.

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.