Multiple pathways of copy control of gamma replicon of R6K: mechanisms both dependent on and independent of cooperativity of interaction of tau protein with DNA affect the copy number

Proteolysis in plasmid DNA stable maintenance in bacterial cells

Plasmids, as extrachromosomal genetic elements, need to work out strategies that promote independent replication and stable maintenance in host bacterial cells. Their maintenance depends on constant formation and dissociation of nucleoprotein complexes formed on plasmid DNA. Plasmid replication initiation proteins (Rep) form specific complexes on direct repeats (iterons) localized within the plasmid replication origin. Formation of these complexes along with a strict control of Rep protein cellular concentration, quaternary structure, and activity, is essential for plasmid maintenance. Another important mechanism for maintenance of low-copy-number plasmids are the toxin-antitoxin (TA) post-segregational killing (psk) systems, which prevent plasmid loss from the bacterial cell population. In this mini review we discuss the importance of nucleoprotein complex processing by energy-dependent host proteases in plasmid DNA replication and plasmid type II toxin-antitoxin psk systems, and draw attention to the elusive role of DNA in this process.

Iteron Plasmids

Iteron-containing plasmids are model systems for studying the metabolism of extrachromosomal genetic elements in bacterial cells. Here we describe the current knowledge and understanding of the structure of iteron-containing replicons, the structure of the iteron plasmid encoded replication initiation proteins, and the molecular mechanisms for iteron plasmid DNA replication initiation. We also discuss the current understanding of control mechanisms affecting the plasmid copy number and how host chaperone proteins and proteases can affect plasmid maintenance in bacterial cells.

Plasmid R6K replication control

The focus of this minireview is the replication control of the 39.9-kb plasmid R6K and its derivatives. Historically, this plasmid was thought to have a narrow host range but more recent findings indicate that its derivatives can replicate in a variety of enteric and non-enteric bacterial species (Wild et al., 2004). In the four-plus decades since it was first described, R6K has proven to be an excellent model for studies of plasmid DNA replication. In part this is because of its similarities to other systems in which replication is activated and regulated by Rep protein and iteron-containing DNA. However its apparent idiosynchracies have also added to its significance (e.g., independent and co-dependent replication origins, and Rep dimers that stably bind iterons). Here, we survey the current state of knowledge regarding R6K replication and place individual regulatory elements into a proposed homeostatic model with implications for the biological significance of R6K and its multiple origins of replication.

Investigations of pi initiator protein-mediated interaction between replication origins alpha and gamma of the plasmid R6K

A typical plasmid replicon of Escherichia coli, such as ori gamma of R6K, contains tandem iterons (iterated initiator protein binding sites), an AT-rich region that melts upon initiator-iteron interaction, two binding sites for the bacterial initiator protein DnaA, and a binding site for the DNA-bending protein IHF. R6K also contains two structurally atypical origins called alpha and beta that are located on either side of gamma and contain a single and a half-iteron, respectively. Individually, these sites do not bind to initiator protein pi but access it by DNA looping-mediated interaction with the seven pi-bound gamma iterons. The pi protein exists in 2 interconvertible forms: inert dimers and active monomers. Initiator dimers generally function as negative regulators of replication by promoting iteron pairing ("handcuffing") between pairs of replicons that turn off both origins. Contrary to this existing paradigm, here we show that both the dimeric and the monomeric pi are necessary for ori alpha-driven plasmid maintenance. Furthermore, efficient looping interaction between alpha and gamma or between 2 gamma iterons in vitro also required both forms of pi. Why does alpha-gamma iteron pairing promote alpha activation rather than repression? We show that a weak, transitory alpha-gamma interaction at the iteron pairs was essential for alpha-driven plasmid maintenance. Swapping the alpha iteron with one of gamma without changing the original sequence context that caused enhanced looping in vitro caused a significant inhibition of alpha-mediated plasmid maintenance. Therefore, the affinity of alpha iteron for pi-bound gamma and not the sequence context determined whether the origin was activated or repressed.

Negative regulation of pPS10 plasmid replication: origin pairing by zipping-up DNA-bound RepA monomers

In many plasmid replicons of gram-negative bacteria, Rep protein dimers are transcriptional self-repressors of their genes, whereas monomers are initiators of DNA replication. Switching between both functions implies conformational remodelling of Rep, and is promoted by Rep binding to the origin DNA repeats (iterons) or chaperones. Rep proteins play another key role: they bridge together two iteron DNA stretches, found either on the same or on different plasmid molecules. These so-called, respectively, 'looped' and 'handcuffed' complexes are thought to be negative regulators of plasmid replication. Although evidence for Rep-dependent plasmid handcuffing has been found in a number of replicons, the structure of these Rep-DNA assemblies is still unknown. Here, by a combination of proteomics, electron microscopy, genetic analysis and modelling, we provide insight on a possible three-dimensional structure for two handcuffed arrays of the iterons found at the origin of pPS10 replicon. These are brought together in parallel register by zipping-up DNA-bound RepA monomers. We also present evidence for a distinct role of RepA dimers in DNA looping. This work defines a new regulatory interface in Rep proteins.

Crystal structure of pi initiator protein-iteron complex of plasmid R6K: implications for initiation of plasmid DNA replication

We have determined the crystal structure of a monomeric biologically active form of the pi initiator protein of plasmid R6K as a complex with a single copy of its cognate DNA-binding site (iteron) at 3.1-A resolution. The initiator belongs to the family of winged helix type of proteins. The structure reveals that the protein contacts the iteron DNA at two primary recognition helices, namely the C-terminal alpha4' and the N-terminal alpha4 helices, that recognize the 5' half and the 3' half of the 22-bp iteron, respectively. The base-amino acid contacts are all located in alpha4', whereas the alpha4 helix and its vicinity mainly contact the phosphate groups of the iteron. Mutational analyses show that the contacts of both recognition helices with DNA are necessary for iteron binding and replication initiation. Considerations of a large number of site-directed mutations reveal that two distinct regions, namely alpha2 and alpha5 and its vicinity, are required for DNA looping and initiator dimerization, respectively. Further analysis of mutant forms of pi revealed the possible domain that interacts with the DnaB helicase. Thus, the structure-function analysis presented illuminates aspects of initiation mechanism of R6K and its control.

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.

Role of pi dimers in coupling ("handcuffing") of plasmid R6K's gamma ori iterons

One proposed mechanism of replication inhibition in iteron-containing plasmids (ICPs) is "handcuffing," in which the coupling of origins via iteron-bound replication initiator (Rep) protein turns off origin function. In minimal R6K replicons, copy number control requires the interaction of plasmid-encoded pi protein with the seven 22-bp iterons of the gamma origin of replication. Like other related Rep proteins, pi exists as both monomers and dimers. However, the ability of pi dimers to bind iterons distinguishes R6K from most other ICPs, where only monomers have been observed to bind iterons. Here, we describe experiments to determine if monomers or dimers of pi protein are involved in the formation of handcuffed complexes. Standard ligation enhancement assays were done using pi variants with different propensities to bind iterons as monomers or dimers. Consistent with observations from several ICPs, a hyperreplicative variant (pi.P106L(wedge)F107S) exhibits deficiencies in handcuffing. Additionally, a novel dimer-biased variant of pi protein (pi.M36A(wedge)M38A), which lacks initiator function, handcuffs iteron-containing DNA more efficiently than does wild-type pi. The data suggest that pi dimers mediate handcuffing, supporting our previously proposed model of handcuffing in the gamma ori system. Thus, dimers of pi appear to possess three distinct inhibitory functions with respect to R6K replication: transcriptional autorepression of pi expression, in cis competition (for origin binding) with monomeric activator pi, and handcuffing-mediated inhibition of replication in trans.

Multiple homeostatic mechanisms in the control of P1 plasmid replication

Many organisms control initiation of DNA replication by limiting supply or activity of initiator proteins. In plasmids, such as P1, initiators are limited primarily by transcription and dimerization. However, the relevance of initiator limitation to plasmid copy number control has appeared doubtful, because initiator oversupply increases the copy number only marginally. Copy number control instead has been attributed to initiator-mediated plasmid pairing ("handcuffing"), because initiator mutations to handcuffing deficiency elevates the copy number significantly. Here, we present genetic evidence of a role for initiator limitation in plasmid copy number control by showing that autorepression-defective initiator mutants also can elevate the plasmid copy number. We further show, by quantitative modeling, that initiator dimerization is a homeostatic mechanism that dampens active monomer increase when the protein is oversupplied. This finding implies that oversupplied initiator proteins are largely dimeric, partly accounting for their limited ability to increase copy number. A combination of autorepression, dimerization, and handcuffing appears to account fully for control of P1 plasmid copy number.

Improvement of pCOR plasmid copy number for pharmaceutical applications

Production of pharmaceutical-grade plasmid DNA is becoming important as the demand for clinical batches is steadily growing. pCOR plasmids have been specifically designed and used for gene delivery into humans, and have been produced by high cell-density fermentation with a yield of 100 mg/l. This yield could probably be increased as long as the release specifications of bulk plasmid remain the same, particularly in terms of plasmid sequence. We report here the use of genetic approaches in Escherichia coli to increase the copy number of pCOR. The bacterial gene encoding the pi initiator-protein, which plays a pivotal role in pCOR replication, was mutagenized. A fluorescence-based screening methodology in E. coli was used to identify novel copy-up mutations. A particular combination of copy-up mutations translated into a 3-5-fold increase in monomer pCOR plasmid DNA per biomass unit.

Twenty years of the pPS10 replicon: insights on the molecular mechanism for the activation of DNA replication in iteron-containing bacterial plasmids

This review focuses on the contributions of the Pseudomonas replicon pPS10 to understanding the initiation of DNA replication in iteron-containing plasmids from Gram-negative bacteria. Dimers of the pPS10 initiator protein (RepA) repress repA transcription by binding to the two halves of an inverted repeat operator. RepA monomers are the active initiator species that bind to four directly repeated sequences (iterons). pPS10 initiator was the first Rep protein whose domains were defined (two "winged-helix," WH modules) and their binding sites were identified at each half of the iteron repeat. This was confirmed by the crystal structure of the monomer of a homologous initiator (RepE from F plasmid) bound to iteron DNA. The recently solved structure of the dimeric N-terminal domain (WH1) of pPS10 RepA, when compared to the RepE monomer, shows that upon dimer dissociation an alpha-helix at WH1 C-terminus becomes part of an interdomain beta-sheet. In solution, the iteron sequence, by itself, can induce the same kind of structural transformation in RepA. This seems to alter the package of both WH domains to adapt their DNA reading heads (HTH motifs) to the distinct spacing between half repeats in iterons and operator. Based on biochemical and spectroscopic work, structural and functional similarities were proposed between RepA and archaeal/eukaryal initiators. This was independently confirmed by the crystal structure of the archaeal initiator Cdc6. Characterization of mutants, either in pPS10 or in the Escherichia coli chromosome, has provided some evidence on a WH1-mediated interaction between RepA and the chromosomal initiator DnaA that results in a broadened-host range.

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 conformational switch between transcriptional repression and replication initiation in the RepA dimerization domain

Plasmids are natural vectors for gene transfer. In Gram-negative bacteria, plasmid DNA replication is triggered when monomers of an initiator protein (Rep) bind to direct repeats at the origin sequence. Rep dimers, which are inactive as initiators, bind to an inverse repeat operator, repressing transcription of the rep gene. Rep proteins are composed of N-terminal dimerization and C-terminal DNA-binding domains. Activation of Rep is coupled to dimer dissociation, converting the dimerization domain into a second origin-binding module. Although the structure of the monomeric F plasmid initiator (mRepE) has been determined, the molecular nature of Rep activation remains unknown. Here we report the crystal structure of the dimeric N-terminal domain of the pPS10 plasmid initiator (dRepA). dRepA has a winged-helix fold, as does its homologous domain in mRepE. However, dimerization transforms an interdomain loop and beta-strand (monomeric RepE) into an alpha-helix (dimeric RepA). dRepA resemble the C terminus of eukaryotic and archaeal Cdc6, giving clues to the phylogeny of DNA replication initiators.

Origin pairing ('handcuffing') as a mode of negative control of P1 plasmid copy number

In one family of bacterial plasmids, multiple initiator binding sites, called iterons, are used for initiation of plasmid replication as well as for the control of plasmid copy number. Iterons can also pair in vitro via the bound initiators. This pairing, called handcuffing, has been suggested to cause steric hindrance to initiation and thereby control the copy number. To test this hypothesis, we have compared copy numbers of isogenic miniP1 plasmid monomer and dimer. The dimer copy number was only one-quarter that of the monomer, suggesting that the higher local concentration of origins in the dimer facilitated their pairing. Physical evidence consistent with iteron-mediated pairing of origins preferentially in the dimer was obtained in vivo. Thus, origin handcuffing can be a mechanism to control P1 plasmid replication.

The RepA protein of plasmid pSC101 controls Escherichia coli cell division through the SOS response

Although plasmid copy number varies widely among different plasmid species, normally copy number is maintained within a narrow range for any given plasmid. Such copy number control has been shown to occur by regulation of the rate of plasmid DNA replication. Here we report a novel mechanism by which the pSC101 plasmid also can detect an imbalance between the cellular level of its replication protein, RepA, and plasmid-borne RepA binding sites to inhibit bacterial DNA replication and delay host cell division when RepA is in relative excess. We show that delayed cell division occurs by RepA-mediated induction of the SOS response and can be reversed by over-expression of the host DNA primase, DnaG. The effects of RepA excess are prevented by introducing a surfeit of RepA binding sites. The mechanism reported here may help to limit variation in plasmid copy number and allow repopulation of cells with plasmids when copy number falls--potentially pre-empting plasmid loss in cultures of dividing cells.

Monomer/dimer ratios of replication protein modulate the DNA strand-opening in a replication origin

DNA opening is an essential step in the initiation of replication via the Cairns mode of replication. The opening reaction was investigated in a gamma ori system by using hyperactive variants of plasmid R6K-encoded initiator protein, pi. Reactivity to KMnO4 (indicative of opening) within gamma ori DNA occurred in both strands of a superhelical template upon the combined addition of wt pi, DnaA and integration host factor (IHF), each protein known to specifically bind gamma ori. IHF, examined singly, enhanced reactivity to KMnO4. The IHF-dependent reactive residues, however, are distinct from those dependent on pi (wt and hyperactive variants). Remarkably, the DNA helix opening does not require IHF and/or DnaA when hyperactive variants of pi were used instead of wt protein. We present three lines of evidence consistent with the hypothesis that DNA strand separation is facilitated by pi monomers despite the fact that both monomers and dimers of the protein can bind to iterons (pi binding sites). Taken together, our data suggest that pi elicits its ability to modulate plasmid copy number at the DNA helix-opening step.

A pot-pourri of plasmid paradoxes: effects of a second copy

Bacterial plasmids are exemplary subjects for study, being conveniently isolated, dissected, reassembled, and introduced into various hosts. Their versatility and power make them eminently worthy of our attention. In what follows I consider some consequences of simply doubling the dosage of particular plasmid genes or of forming a plasmid dimer. These consequences can be perverse, paradoxical, or informative. They bear on questions of cell viability, copy number limitation, clonal homogeneity, check-point control, and the recovery of mutants. They have relevance to biotechnology, evolution and medicine. In reviewing these effects, my motivation is largely to share my enthusiasm for certain kinds of biological narratives, the nature of which is best left for the reader to discern.

Control of plasmid DNA replication by iterons: no longer paradoxical

Replication origins of a family of bacterial plasmids have multiple sites, called iterons, for binding a plasmid-specific replication initiator protein. The iteron-initiator interactions are essential for plasmid replication as well as for inhibition of plasmid over-replication. The inhibition increases with plasmid copy number and eventually shuts plasmid replication off completely. The mechanism of inhibition appears to be handcuffing, the coupling of origins via iteron-bound initiators that block origin function. The probability of a trans-reaction such as handcuffing is expected to increase with plasmid copy number and diminish with increases in cell volume, explaining how the copy number can be maintained in a growing cell. Control is also exerted at the level of initiator synthesis and activation by chaperones. We propose that increases in active initiators promote initiation by overcoming handcuffing, but handcuffing dominates when the copy number reaches a threshold. Handcuffing should be ultrasensitive to copy number, as the negative control by iterons can be stringent (switch-like).

Separate roles of Escherichia coli replication proteins in synthesis and partitioning of pSC101 plasmid DNA

We report here that the Escherichia coli replication proteins DnaA, which is required to initiate replication of both the chromosome and plasmid pSC101, and DnaB, the helicase that unwinds strands during DNA replication, have effects on plasmid partitioning that are distinct from their functions in promoting plasmid DNA replication. Temperature-sensitive dnaB mutants cultured under conditions permissive for DNA replication failed to partition plasmids normally, and when cultured under conditions that prevent replication, they showed loss of the entire multicopy pool of plasmid replicons from half of the bacterial population during a single cell division. As was observed previously for DnaA, overexpression of the wild-type DnaB protein conversely stabilized the inheritance of partition-defective plasmids while not increasing plasmid copy number. The identification of dnaA mutations that selectively affected either replication or partitioning further demonstrated the separate roles of DnaA in these functions. The partition-related actions of DnaA were localized to a domain (the cell membrane binding domain) that is physically separate from the DnaA domain that interacts with other host replication proteins. Our results identify bacterial replication proteins that participate in partitioning of the pSC101 plasmid and provide evidence that these proteins mediate plasmid partitioning independently of their role in DNA synthesis.

Functional domains of Rts1 and P1 RepA proteins for initiation of replication

Rts1 RepA and P1 RepA are trans-acting proteins essential for initiation of replication of Rts1 and P1 plasmids, respectively. We recently found that P1 RepA bound in vitro to the Rts1 replication origin as strongly as Rts1 RepA and activated the origin in vivo. However, the ori activation was quite inefficient. This study shows that by replacing a small region of P1 RepA with the corresponding region of Rts1 RepA, the efficiency of Rts1 ori activation increased markedly. Interestingly, the same subregion of P1 RepA was found to be important for in vivo activation of the P1 origin. Thus, a region essential for efficient activation of the replication origin was assigned to the P1 RepA molecule as well as to the Rts1 RepA molecule. The region was distinct from a domain necessary for in vitro binding to the origin, although both regions were required for in vivo activation of the respective origin.

Protein domains and conformational changes in the activation of RepA, a DNA replication initiator

RepA is the DNA replication initiator protein of the Pseudomonas plasmid pPS10. RepA has a dual function: as a dimer, it binds to an inversely-repeated sequence acting as a repressor of its own synthesis; as a monomer, RepA binds to four directly-repeated sequences to constitute a specialized nucleoprotein complex responsible for the initiation of DNA replication. We have previously shown that a Leucine Zipper-like motif (LZ) at the N-terminus of RepA is responsible for protein dimerization. In this paper we characterize the existence in RepA of two protein globular domains C-terminal to the LZ. We propose that dissociation of RepA dimers into monomers results in a conformational change from a compact arrangement of both domains, competent for binding to the operator, to an extended species that is suited for iteron binding. This model establishes the structural basis for the activation of DNA replication initiators in plasmids from Gram-negative bacteria.

Role of the EBNA-1 protein in pausing of replication forks in the Epstein-Barr virus genome

We have previously shown that replication forks stall at a family of repeated sequences (FR) within the Epstein-Barr virus latent origin of replication oriP, both in a small plasmid and in the intact Epstein-Barr virus genome. Each of the 20 repeated sequences within the FR contains a binding site for Epstein-Barr nuclear antigen 1 (EBNA-1), the only viral protein required for latent replication. We showed that the EBNA-1 protein enhances the accumulation of paused replication forks at the FR. In this study, we have investigated a series of truncated EBNA-1 proteins to determine the portion of the EBNA-1 protein that is responsible for pausing of forks at the FR. Two-dimensional agarose gel electrophoresis was performed on the products of in vitro replication reactions in the presence of full-length EBNA-1 or proteins with various deletions to assess the extent of fork pausing at the FR. We conclude that a portion of the DNA binding domain is important for fork pausing. We also present evidence indicating that phosphorylation of the EBNA-1 protein or EBNA-1-truncated derivatives is not essential for pausing. To investigate the mechanism of EBNA-1-mediated pausing of replication forks, we asked whether EBNA-1 could inhibit the DNA unwinding activity of replicative helicases. We found that EBNA-1, when bound to the FR, inhibits DNA unwinding in vitro by SV40 T antigen and Escherichia coli dnaB helicases in an orientation-independent manner.

The replication initiator protein pi of the plasmid R6K specifically interacts with the host-encoded helicase DnaB

The replication initiator protein pi of plasmid R6K is known to interact with the seven iterons of the gamma origin/enhancer and activate distant replication origins alpha and beta (ori alpha and ori beta) by pi-mediated DNA looping. Here we show that pi protein specifically interacts in vitro with the host-encoded helicase DnaB. The site of interaction of pi on DnaB has been localized to a 37-aa-long region located between amino acids 151 and 189 of DnaB. The surface of pi that interacts with DnaB has been mapped to the N-terminal region of the initiator protein between residues 1 and 116. The results suggest that during initiation of replication, the replicative helicase DnaB is first recruited to the gamma enhancer by the pi protein. In a subsequent step, the helicase probably gets delivered from ori gamma to ori alpha and ori beta by pi-mediated DNA looping.

Copy-up mutants of the plasmid RK2 replication initiation protein are defective in coupling RK2 replication origins

The broad host range plasmid RK2 replicates and regulates its copy number in a wide range of Gram-negative bacteria. The plasmid-encoded trans-acting replication protein TrfA and the origin of replication oriV are sufficient for controlled replication of the plasmid in all Gram-negative bacteria tested. The TrfA protein binds specifically to direct repeat sequences (iterons) at the origin of replication. A replication control model, designated handcuffing or coupling, has been proposed whereby the formation of coupled TrfA-oriV complexes between plasmid molecules results in hindrance of origin activity and, consequently, a shut-down of plasmid replication under conditions of higher than normal copy number. Therefore, according to this model, the coupling activity of an initiation protein is essential for copy number control and a copy-up initiation protein mutant should have reduced ability to form coupled complexes. To test this model for plasmid RK2, two previously characterized copy-up TrfA mutations, trfA-254D and trfA-267L, were combined and the resulting copy-up double mutant TFrfA protein TrfA-254D/267L was characterized. Despite initiating runaway (uncontrolled) replication in vivo, the copy-up double-mutant TrfA protein exhibited replication kinetics similar to the wild-type protein in vitro. Purified TrfA-254D, TrfA-267L, and TrfA-254D/267L proteins were then examined for binding to the iterons and for coupling activity using an in vitro ligase-catalyzed multimerization assay. It was found that both single and double TrfA mutant proteins exhibited substantially reduced (single mutants) or barely detectable (double mutant) levels of coupling activity while not being diminished in their capacity to bind to the origin of replication. These observations provide direct evidence in support of the coupling model of replication control.

The dimer-dimer interaction surface of the replication terminator protein of Bacillus subtilis and termination of DNA replication

The replication terminator protein (RTP) of Bacillus subtilis causes polar fork arrest at replication termini by sequence-specific interaction of two dimeric proteins with the terminus sequence. The crystal structure of the RTP protein has been solved, and the structure has already provide valuable clues regarding the structural basis of its function. However, it provides little information as to the surface of the protein involved in dimer-dimer interaction. Using site-directed mutagenesis, we have identified three sites on the protein that appear to mediate the dimer-dimer interaction. Crystallographic analysis of one of the mutant proteins (Y88F) showed that its structure is unaltered when compared to the wild-type protein. The locations of the three sites suggested a model for the dimer-dimer interaction that involves an association between two beta-ribbon motifs. This model is supported by a fourth mutation that was predicted to disrupt the interaction and was shown to do so. Biochemical analyses of these mutants provide compelling evidence that cooperative protein-protein interaction between two dimers of RTP is essential to impose polar blocks to the elongation of both DNA and RNA chains.

Host growth temperature and a conservative amino acid substitution in the replication protein of pPS10 influence plasmid host range

pPS10 is a replicon isolated from Pseudomonas syringe pv. savastanoi that can be established at 37 degrees C efficiently in Pseudomonas aeruginosa but very inefficiently in Escherichia coli. The establishment of the wild-type pPS10 replicon in E. coli is favored at low temperatures (30 degrees C or below). RepA protein of pPS10 promotes in vitro plasmid replication in extracts from E. coli, and this replication depends on host proteins DnaA, DnaB, DnaG, and SSB. Mutant plasmids able to efficiently replicate in E. coli at 37 degrees C were obtained. Three of four mutants whose mutations were mapped show a conservative Ala-->Val change in the amino-terminal region of the replication protein RepA. Plasmids carrying this mutation maintain the capacity to replicate in P. aeruginosa and have a fourfold increase in copy number in this host. The mutation does not substantially alter the autoregulation mediated by RepA. These results show that the physiological conditions of the host as well as subtle changes in the plasmid replication protein can modulate the host range of the pPS10 replicon.

Analysis of functional domains of Rts1 RepA by means of a series of hybrid proteins with P1 RepA

The RepA protein of the plasmid Rts1, consisting of 288 amino acids, is a trans-acting protein essential for initiation of plasmid replication. To study the functional domains of RepA, hybrid proteins of Rts1 RepA with the RepA initiator protein of plasmid P1 were constructed such that the N-terminal portion was from Rts1 RepA and the C-terminal portion was from P1 RepA. Six hybrid proteins were examined for function. The N-terminal region of Rts1 RepA between amino acid residues 113 and 129 was found to be important for Rts1 ori binding in vitro. For activation of the origin in vivo, an Rts1 RepA subregion between residues 177 and 206 as well as the DNA binding domain was required. None of the hybrid initiator proteins activated the P1 origin. Both in vivo and in vitro studies showed, in addition, that a C-terminal portion of Rts1 RepA was required along with the DNA binding and ori activating domains to achieve autorepression, suggesting that the C-terminal region of Rts1 RepA is involved in dimer formation. A hybrid protein consisting of the N-terminal 145 amino acids of Rts1 and the C-terminal 142 amino acids from P1 showed strong interference with both Rts1 and P1 replication, whereas other hybrid proteins showed no or little effect on P1 replication.