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

Recent advances in synthetic biology toolkits and metabolic engineering of Ralstonia eutropha H16 for production of value-added chemicals

Ralstonia eutropha H16, a facultative chemolithoautotrophic Gram-negative bacterium, demonstrates remarkable metabolic flexibility by utilizing either diverse organic substrates or CO2 as the sole carbon source, with H2 serving as the electron donor under aerobic conditions. The capacity of carbon and energy metabolism of R. eutropha H16 enabled development of synthetic biology technologies and strategies to engineer its metabolism for biosynthesis of value-added chemicals. This review firstly outlines the development of synthetic biology tools tailored for R. eutropha H16, including construction of expression vectors, regulatory elements, and transformation techniques. The availability of comprehensive omics data (i.e., transcriptomic, proteomic, and metabolomic) combined with the fully annotated genome sequence provides a robust genetic framework for advanced metabolic engineering. These advancements facilitate efficient reprogramming metabolic network of R. eutropha. The potential of R. eutropha as a versatile microbial platform for industrial biotechnology is further underscored by its ability to utilize a wide range of carbon sources for the production of value-added chemicals through both autotrophic and heterotrophic pathways. The integration of state-of-the-art genetic and genomic engineering tools and strategies with high cell-density fermentation processes enables engineered R. eutropha as promising microbial cell factories for optimizing carbon fluxes and expanding the portfolio of bio-based products.

Rep protein accommodates together dsDNA and ssDNA which enables a loop-back mechanism to plasmid DNA replication initiation

For DNA replication initiation in Bacteria, replication initiation proteins bind to double-stranded DNA (dsDNA) and interact with single-stranded DNA (ssDNA) at the replication origin. The structural-functional relationship of the nucleoprotein complex involving initiator proteins is still elusive and different models are proposed. In this work, based on crosslinking combined with mass spectrometry (MS), the analysis of mutant proteins and crystal structures, we defined amino acid residues essential for the interaction between plasmid Rep proteins, TrfA and RepE, and ssDNA. This interaction and Rep binding to dsDNA could not be provided in trans, and both are important for dsDNA melting at DNA unwinding element (DUE). We solved two crystal structures of RepE: one in a complex with ssDNA DUE, and another with both ssDNA DUE and dsDNA containing RepE-specific binding sites (iterons). The amino acid residues involved in interaction with ssDNA are located in the WH1 domain in stand β1, helices α1 and α2 and in the WH2 domain in loops preceding strands β1' and β2' and in these strands. It is on the opposite side compared to RepE dsDNA-recognition interface. Our data provide evidence for a loop-back mechanism through which the plasmid replication initiator molecule accommodates together dsDNA and ssDNA.

Iteron control of oriV function in IncP-1 plasmid RK2

Replication control of many plasmids is mediated by the balance between the positive and negative effects of Rep protein binding repeated sequences (iterons) associated with the replication origin, oriV. Negative control is thought to be mediated by dimeric Rep protein linking iterons in a process termed "handcuffing". The well-studied oriV region of RK2 contains 9 iterons arranged as a singleton (iteron 1), a group of 3 (iterons 2-4) and a group of 5 (iterons 5-9), but only iterons 5 to 9 are essential for replication. An additional iteron (iteron 10), oriented in the opposite direction, is also involved and reduces copy-number nearly two-fold. Since iterons 1 and 10 share an identical upstream hexamer (5' TTTCAT 3') it has been hypothesised that they form a TrfA-mediated loop facilitated by their inverted orientation. Here we report that contrary to the hypothesis, flipping one or other so they are in direct orientation results in marginally lower rather than higher copy-number. In addition, following mutagenesis of the hexamer upstream of iteron 10, we report that the Logo for the hexamer "upstream" of the regulatory iterons (1 to 4 and 10) differs from that of the essential iterons, suggesting functional differences in their interaction with TrfA.

Defining a novel domain that provides an essential contribution to site-specific interaction of Rep protein with DNA

An essential feature of replication initiation proteins is their ability to bind to DNA. In this work, we describe a new domain that contributes to a replication initiator sequence-specific interaction with DNA. Applying biochemical assays and structure prediction methods coupled with DNA–protein crosslinking, mass spectrometry, and construction and analysis of mutant proteins, we identified that the replication initiator of the broad host range plasmid RK2, in addition to two winged helix domains, contains a third DNA-binding domain. The phylogenetic analysis revealed that the composition of this unique domain is typical within the described TrfA-like protein family. Both in vitro and in vivo experiments involving the constructed TrfA mutant proteins showed that the newly identified domain is essential for the formation of the protein complex with DNA, contributes to the avidity for interaction with DNA, and the replication activity of the initiator. The analysis of mutant proteins, each containing a single substitution, showed that each of the three domains composing TrfA is essential for the formation of the protein complex with DNA. Furthermore, the new domain, along with the winged helix domains, contributes to the sequence specificity of replication initiator interaction within the plasmid replication origin.

CyanoGate: A Modular Cloning Suite for Engineering Cyanobacteria Based on the Plant MoClo Syntax

Recent advances in synthetic biology research have been underpinned by an exponential increase in available genomic information and a proliferation of advanced DNA assembly tools. The adoption of plasmid vector assembly standards and parts libraries has greatly enhanced the reproducibility of research and the exchange of parts between different labs and biological systems. However, a standardized modular cloning (MoClo) system is not yet available for cyanobacteria, which lag behind other prokaryotes in synthetic biology despite their huge potential regarding biotechnological applications. By building on the assembly library and syntax of the Plant Golden Gate MoClo kit, we have developed a versatile system called CyanoGate that unites cyanobacteria with plant and algal systems. Here, we describe the generation of a suite of parts and acceptor vectors for making (1) marked/unmarked knock-outs or integrations using an integrative acceptor vector, and (2) transient multigene expression and repression systems using known and previously undescribed replicative vectors. We tested and compared the CyanoGate system in the established model cyanobacterium Synechocystis sp. PCC 6803 and the more recently described fast-growing strain Synechococcus elongatus UTEX 2973. The UTEX 2973 fast-growth phenotype was only evident under specific growth conditions; however, UTEX 2973 accumulated high levels of proteins with strong native or synthetic promoters. The system is publicly available and can be readily expanded to accommodate other standardized MoClo parts to accelerate the development of reliable synthetic biology tools for the cyanobacterial community.

Handcuffing reversal is facilitated by proteases and replication initiator monomers

Specific nucleoprotein complexes are formed strictly to prevent over-initiation of DNA replication. An example of those is the so-called handcuff complex, in which two plasmid molecules are coupled together with plasmid-encoded replication initiation protein (Rep). In this work, we elucidate the mechanism of the handcuff complex disruption. In vitro tests, including dissociation progress analysis, demonstrate that the dimeric variants of plasmid RK2 replication initiation protein TrfA are involved in assembling the plasmid handcuff complex which, as we found, reveals high stability. Particular proteases, namely Lon and ClpAP, disrupt the handcuff by degrading TrfA, thus affecting plasmid stability. Moreover, our data demonstrate that TrfA monomers are able to dissociate handcuffed plasmid molecules. Those monomers displace TrfA molecules, which are involved in handcuff formation, and through interaction with the uncoupled plasmid replication origins they re-initiate DNA synthesis. We discuss the relevance of both Rep monomers and host proteases for plasmid maintenance under vegetative and stress conditions.

Evolved plasmid-host interactions reduce plasmid interference cost

Antibiotic selection drives adaptation of antibiotic resistance plasmids to new bacterial hosts, but the molecular mechanisms are still poorly understood. We previously showed that a broad-host-range plasmid was poorly maintained in Shewanella oneidensis, but rapidly adapted through mutations in the replication initiation gene trfA1. Here we examined if these mutations reduced the fitness cost of TrfA1, and whether this was due to changes in interaction with the host's DNA helicase DnaB. The strains expressing evolved TrfA1 variants showed a higher growth rate than those expressing ancestral TrfA1. The evolved TrfA1 variants showed a lower affinity to the helicase than ancestral TrfA1 and were no longer able to activate the helicase at the oriV without host DnaA. Moreover, persistence of the ancestral plasmid was increased upon overexpression of DnaB. Finally, the evolved TrfA1 variants generated higher plasmid copy numbers than ancestral TrfA1. The findings suggest that ancestral plasmid instability can at least partly be explained by titration of DnaB by TrfA1. Thus under antibiotic selection resistance plasmids can adapt to a novel bacterial host through partial loss of function mutations that simultaneously increase plasmid copy number and decrease unfavorably high affinity to one of the hosts' essential proteins.

Functional amyloids as inhibitors of plasmid DNA replication

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

Sequence-specific interactions of Rep proteins with ssDNA in the AT-rich region of the plasmid replication origin

The DNA unwinding element (DUE) is a sequence rich in adenine and thymine residues present within the origin region of both prokaryotic and eukaryotic replicons. Recently, it has been shown that this is the site where bacterial DnaA proteins, the chromosomal replication initiators, form a specific nucleoprotein filament. DnaA proteins contain a DNA binding domain (DBD) and belong to the family of origin binding proteins (OBPs). To date there has been no data on whether OBPs structurally different from DnaA can form nucleoprotein complexes within the DUE. In this work we demonstrate that plasmid Rep proteins, composed of two Winged Helix domains, distinct from the DBD, specifically bind to one of the strands of ssDNA within the DUE. We observed nucleoprotein complexes formed by these Rep proteins, involving both dsDNA containing the Rep-binding sites (iterons) and the strand-specific ssDNA of the DUE. Formation of these complexes required the presence of all repeated sequence elements located within the DUE. Any changes in these repeated sequences resulted in the disturbance in Rep-ssDNA DUE complex formation and the lack of origin replication activity in vivo or in vitro.

RK2 plasmid dynamics in Caulobacter crescentus cells--two modes of DNA replication initiation

Undisturbed plasmid dynamics is required for the stable maintenance of plasmid DNA in bacterial cells. In this work, we analysed subcellular localization, DNA synthesis and nucleoprotein complex formation of plasmid RK2 during the cell cycle of Caulobacter crescentus. Our microscopic observations showed asymmetrical distribution of plasmid RK2 foci between the two compartments of Caulobacter predivisional cells, resulting in asymmetrical allocation of plasmids to progeny cells. Moreover, using a quantitative PCR (qPCR) method, we estimated that multiple plasmid particles form a single fluorescent focus and that the number of plasmids per focus is approximately equal in both swarmer and predivisional Caulobacter cells. Analysis of the dynamics of TrfA-oriV complex formation during the Caulobacter cell cycle revealed that TrfA binds oriV primarily during the G1 phase, however, plasmid DNA synthesis occurs during the S and G2 phases of the Caulobacter cell cycle. Both in vitro and in vivo analysis of RK2 replication initiation in C. crescentus cells demonstrated that it is independent of the Caulobacter DnaA protein in the presence of the longer version of TrfA protein, TrfA-44. However, in vivo stability tests of plasmid RK2 derivatives suggested that a DnaA-dependent mode of plasmid replication initiation is also possible.

Roles of long and short replication initiation proteins in the fate of IncP-1 plasmids

Broad-host-range IncP-1 plasmids generally encode two replication initiation proteins, TrfA1 and TrfA2. TrfA2 is produced from an internal translational start site within trfA1. While TrfA1 was previously shown to be essential for replication in Pseudomonas aeruginosa, its role in other bacteria within its broad host range has not been established. To address the role of TrfA1 and TrfA2 in other hosts, efficiency of transformation, plasmid copy number (PCN), and plasmid stability were first compared between a mini-IncP-1β plasmid and its trfA1 frameshift variant in four phylogenetically distant hosts: Escherichia coli, Pseudomonas putida, Sphingobium japonicum, and Cupriavidus necator. TrfA2 was sufficient for replication in these hosts, but the presence of TrfA1 enhanced transformation efficiency and PCN. However, TrfA1 did not contribute to, and even negatively affected, long-term plasmid persistence. When trfA genes were cloned under a constitutive promoter in the chromosomes of the four hosts, strains expressing either both TrfA1 and TrfA2 or TrfA1 alone, again, generally elicited a higher PCN of an IncP1-β replicon than strains expressing TrfA2 alone. When a single species of TrfA was produced at different concentrations in E. coli cells, TrfA1 maintained a 3- to 4-fold higher PCN than TrfA2 at the same TrfA concentrations, indicating that replication mediated by TrfA1 is more efficient than that by TrfA2. These results suggest that the broad-host-range properties of IncP-1 plasmids are essentially conferred by TrfA2 and the intact replication origin alone but that TrfA1 is nonetheless important to efficiently establish plasmid replication upon transfer into a broad range of hosts.

The RNA chaperone, Hfq, controls two luxR-type regulators and plays a key role in pathogenesis and production of antibiotics in Serratia sp. ATCC 39006

Serratia sp. ATCC 39006 (S39006) is a Gram-negative bacterium that is virulent in plant (potato) and animal (Caenorhabditis elegans) models. It produces two secondary metabolite antibiotics, a prodigiosin and a carbapenem, and the exoenzymes, pectate lyase and cellulase. A complex regulatory network that includes quorum sensing (QS) controls production of prodigiosin. While many aspects of the regulation of the metabolites and exoenzymes are well understood, the potential role in this network of the RNA chaperone Hfq and dependent small regulatory RNAs has not been characterized. Hfq is an RNA chaperone involved in post-transcriptional regulation that plays a key role in stress response and virulence in diverse bacterial species. To explore whether Hfq-dependent processes might contribute to the regulation of antibiotic production we constructed an S39006 Δhfq mutant. Production of prodigiosin and carbapenem was abolished in this mutant strain, while production of the QS signalling molecule, butanoyl homoserine lactone (BHL), was unaffected. Using transcriptional fusions, we found that Hfq regulates the QS response regulators, SmaR and CarR. Additionally, exoenzyme production and swimming motility were decreased in a Δhfq mutant, and virulence was attenuated in potato and C. elegans models. These results suggest that an Hfq-dependent pathway is involved in the regulation of virulence and secondary metabolite production in S39006.

An efficient stress-free strategy to displace stable bacterial plasmids

A key stage in determining the phenotype(s) conferred by a plasmid is its displacement, or 'curing,' to create a plasmid-free strain. However, many plasmids are very stable, not only because they contain multiple replicons, but also because they can encode post-segregational killing systems that reduce the viability of plasmid-free segregants. We have developed an efficient curing strategy that involves combining key regions of the replicons and the post-segregational killing loci into an unstable cloning vector carrying sacB, which confers sensitivity to sucrose. Targeting plasmids of both the F family of Escherichia coli and the broad-host-range IncP-1 family, we demonstrated displacement of susceptible resident plasmids from all clones tested. Growth on sucrose allowed the isolation of many clones without either plasmid. This strategy is highly efficient and avoids the stress of inducing and surviving the effects of post-segregational killing systems or other lethal gene products.

Shifts in the host range of a promiscuous plasmid through parallel evolution of its replication initiation protein

The ability of bacterial plasmids to adapt to novel hosts and thereby shift their host range is key to their long-term persistence in bacterial communities. Promiscuous plasmids of the incompatibility group P (IncP)-1 can colonize a wide range of hosts, but it is not known if and how they can contract, shift or further expand their host range. To understand the evolutionary mechanisms of host range shifts of IncP-1 plasmids, an IncP-1β mini-replicon was experimentally evolved in four hosts in which it was initially unstable. After 1000 generations in serial batch cultures under antibiotic selection for plasmid maintenance (kanamycin resistance), the stability of the mini-plasmid dramatically improved in all coevolved hosts. However, only plasmids evolved in Shewanella oneidensis showed improved stability in the ancestor, indicating that adaptive mutations had occurred in the plasmid itself. Complete genome sequence analysis of nine independently evolved plasmids showed seven unique plasmid genotypes that had various kinds of single mutations at one locus, namely, the N-terminal region of the replication initiation protein TrfA. Such parallel evolution indicates that this region was under strong selection. In five of the seven evolved plasmids, these trfA mutations resulted in a significantly higher plasmid copy number. Evolved plasmids were found to be stable in four other naive hosts, but could no longer replicate in Pseudomonas aeruginosa. This study shows that plasmids can specialize to a novel host through trade-offs between improved stability in the new host and the ability to replicate in a previously permissive host.

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.

Replication and conjugative mobilization of broad host-range IncQ plasmids

The IncQ plasmids have a broader host-range than any other known replicating element in bacteria. Studies on the replication and conjugative mobilization of these plasmids, which have mostly been focused on the nearly identical RSF1010 and R1162, are summarized with a view to understanding how this broad host-range is achieved. Several significant features of IncQ plasmids emerge from these studies: (1) initiation of replication, involving DnaA-independent activation of the origin and a dedicated primase, is strictly host-independent. (2) The plasmids can be conjugatively mobilized by a variety of different type IV transporters, including those engaged in the secretion of proteins involved in pathogenesis. (3) Stability is insured by a combination of high copy-number and modulated gene expression to reduce metabolic load.

Conformation of a plasmid replication initiator protein affects its proteolysis by ClpXP system

Proteins from the Rep family of DNA replication initiators exist mainly as dimers, but only monomers can initiate DNA replication by interaction with the replication origin (ori). In this study, we investigated both the activation (monomerization) and the degradation of the broad-host-range plasmid RK2 replication initiation protein TrfA, which we found to be a member of a class of DNA replication initiators containing winged helix (WH) domains. Our in vivo and in vitro experiments demonstrated that the ClpX-dependent activation of TrfA leading to replicationally active protein monomers and mutations affecting TrfA dimer formation, result in the inhibition of TrfA protein degradation by the ClpXP proteolytic system. These data revealed that the TrfA monomers and dimers are degraded at substantially different rates. Our data also show that the plasmid replication initiator activity and stability in E. coli cells are affected by ClpXP system only when the protein sustains dimeric form.

Specific mutations within the AT-rich region of a plasmid replication origin affect either origin opening or helicase loading

Prokaryotic and eukaryotic replicons possess a distinctive region containing a higher than average number of adenine and thymine residues (the AT-rich region) where, during the process of replication initiation, the initial destabilization (opening) of the double helix takes place. In many prokaryotic origins, this region consists of repeated 13-mer motifs whose function has not yet been specified. Here we identify specific mutations within the 13-mer sequences of the broad-host-range plasmid RK2 that can result in defective origin opening or that do not affect opening but induce defects in helicase loading. We also show that after the initial recruitment of helicase at the DnaA-box sequences of the plasmid origin, the helicase is translocated to the AT-rich region in a reaction requiring specific sequence of the 13-mers and appropriate facing of the origin motifs. Our results demonstrate that specific sequences within the AT-rich region of a replication origin are required for either origin opening or helicase loading.

Bacterial conjugation-based antimicrobial agents

A clear imperative exists to generate radically different antibacterial technologies that will reduce the usage of conventional chemical antibiotics. Here we trace one route into this new frontier of drug discovery, a concept that we call the bacterial conjugation-based technologies (BCBT). One of the objectives of the BCBT is to exploit plasmid biology for combating the rising tide of antibiotic-resistant bacteria. Specifically, the concept utilizes conjugationally delivered plasmids as antimicrobial agents, and it builds on the accumulated work of many scientists dating back to the discoveries of conjugation and plasmids themselves. Each of the individual components that comprise the approach has been demonstrated to be feasible. We discuss the properties of bacterial plasmids to be employed in BCBT.

Small deletion variants of the replication protein, pi, and their potential for over-replication-based antimicrobial activity

The emergence of multiply antibiotic-resistant microorganisms in the environment has become a serious public health threat. To address this, our lab has devised a methodology in which antimicrobial agents are transferred into unwanted cells using the process of bacterial conjugation. In the work described here, we pursued proteins that cause plasmid over-replication as potential antimicrobial agents. Our focus was on the pir-encoded pi protein of plasmid R6K that possesses both positive and negative functions in controlling gamma origin-based replication. We observed that three of four pir mutations examined, including two in-frame deletions, severely impaired negative plasmid-replication control. The resulting over-replication phenotype was particularly strong when a pir mutant was placed in cis to gamma origin. In conjugative mating experiments with several representatives of the family Enterobacteriaceae, the plasmids expressed postconjugational antimicrobial activity. The potential utility of a conjugation-based antimicrobial approach is discussed. Additionally, we describe the replication inhibitory function of a novel and useful Rep protein variant, pi*M36A;M38A, which binds iteron DNA exclusively as dimers.

Inhibition of protein and RNA synthesis in Escherichia coli results in declustering of plasmid RK2

Multi-copy plasmids in Escherichia coli are not randomly distributed throughout the cell but are present as clusters of plasmid molecules that are localized at preferred cellular locations. A plasmid RK2 derivative (pZZ15) that can be tagged with a green fluorescent protein-LacI fusion protein normally exists as clusters that are localized at the mid- and quarter-cell positions. In this study the effect of the protein synthesis inhibitor, chloramphenicol, and the RNA synthesis inhibitor, rifampicin, on RK2 clustering and localization was examined. The addition of either inhibitor to exponentially growing E. coli cells carrying pZZ15 results in a displacement of the position and a declustering of this multi-copy plasmid indicating that continued protein synthesis and RNA synthesis are required for clustering and localization of this plasmid. It is likely that it is not just the process of transcription or translation that is important for clustering but rather some host or plasmid encoded factor(s) that is required.

Positioning and the specific sequence of each 13-mer motif are critical for activity of the plasmid RK2 replication origin

The minimal replication origin of the broad-host-range plasmid RK2, oriV, contains five iterons which are binding sites for the plasmid-encoded replication initiation protein TrfA, four DnaA boxes, which bind the host DnaA protein, and an AT-rich region containing four 13-mer sequences. In this study, 26 mutants with altered sequence and/or spacing of 13-mer motifs have been constructed and analysed for replication activity in vivo and in vitro. The data show that the replacement of oriV 13-mers by similar but not identical 13-mer sequences from Escherichia coli oriC inactivates the origin. In addition, interchanging the positions of the oriV 13-mers results in greatly reduced activity. Mutants with T/A substitutions are also inactive. Furthermore, introduction of single-nucleotide substitutions demonstrates very restricted sequence requirements depending on the 13-mer position. Only two of the mutants are host specific, functional in Pseudomonas aeruginosa but not in E. coli. Our experiments demonstrate considerable complexity in the plasmid AT-rich region architecture required for functionality. It is evident that low internal stability of this region is not the only feature contributing to origin activity. Our studies suggest a requirement for sequence-specific protein interactions within the 13-mers during assembly of replication complexes at the plasmid origin.

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.

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.

pi protein- and ATP-dependent transitions from 'closed' to 'open' complexes at the gamma ori of plasmid R6K

R6K-encoded pi protein can bind to the seven, 22 bp tandem iterons of the gamma origin. In this work, we use a variant of pi, His-pi.F107S, that is hyperactive in replication. In vitro, His-pi.F107S-dependent local DNA melting (open complex formation) occurs in the absence of host proteins (IHF/HU or DnaA) and it is positioned in the A + T-rich region adjacent to iterons. Experiments described here examine the effects of ATP, Mg2+ and temperature on the opening reaction. We show that the opening of the gamma origin can occur in the presence of ATP as well as AMP-PCP (a non-hydrolyzable ATP analog). This suggests that, for gamma origin, ATP hydrolysis may be unnecessary for open complex formation facilitated by His-pi.F107S. In the absence of ATP or Mg2+, His-pi.F107S yielded data suggestive of distortions in the iteron attributable to DNA bending rather than DNA melting. Our findings also demonstrate that ATP and pi stimulate open complex formation over a wide range of temperatures, but not at 0 degrees C. These and other results indicate that ATP and/or Mg2+ are not needed for His-pi.F107S binding to iterons and that ATP effects an allosteric change in the protein bound to gamma origin.

A specific region in the N terminus of a replication initiation protein of plasmid RK2 is required for recruitment of Pseudomonas aeruginosa DnaB helicase to the plasmid origin

Broad host range plasmid RK2 encodes two versions of its essential replication initiation protein, TrfA, using in-frame translational starts spaced 97 amino acids apart. The smaller protein, TrfA-33, is sufficient for plasmid replication in many bacterial hosts. Efficient replication in Pseudomonas aeruginosa, however, specifically requires the larger TrfA-44 protein. With the aim of identifying sequences of TrfA-44 required for stable replication of RK2 in P. aeruginosa, specific deletions and a substitution mutant within the N terminus sequence unique to TrfA-44 were constructed, and the mutant proteins were tested for activity. Deletion mutants were targeted to three of the four predicted helical regions in the first 97 amino acids of TrfA-44. Deletion of TrfA-44 amino acids 21-32 yielded a mutant protein, TrfA-44Delta2, that had lost the ability to bind and load the DnaB helicase of P. aeruginosa or Pseudomonas putida onto the RK2 origin in vitro and did not support stable replication of an RK2 mini-replicon in P. aeruginosa in vivo. A substitution of amino acid 22 within this essential region resulted in a protein, TrfA-44E22A, with reduced activity in vitro, particularly with the P. putida helicase. Deletion of amino acids 37-55 (TrfA-44Delta3) slightly affected protein activity in vitro with the P. aeruginosa helicase and significantly with the P. putida helicase, whereas deletion of amino acids 71-88 (TrfA-44Delta4) had no effect on TrfA activity in vitro with either helicase. These results identify regions of the TrfA-44 protein that are required for recruitment of the Pseudomonas DnaB helicases in the initiation of RK2 replication.

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

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

A 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.

Structural changes in RepA, a plasmid replication initiator, upon binding to origin DNA

RepA protein is the DNA replication initiator of the Pseudomonas plasmid pPS10. RepA dimers bind to an inversely repeated operator sequence in repA promoter, thus repressing its own synthesis, whereas monomers bind to four directly repeated sequences (iterons) to initiate DNA replication. We had proposed previously that RepA is composed of two winged-helix (WH) domains, a structural unit also present in eukaryotic and archaeal initiators. To bind to the whole iteron sequence through both domains, RepA should couple monomerization to a conformational change in the N-terminal WH, which includes a leucine zipper-like sequence motif. We show for the first time that, by itself, binding to iteron DNA in vitro dissociates RepA dimers into monomers and alters RepA conformation, suggesting an allosteric effect. Furthermore, we also show that similar changes in RepA are promoted by mutations that substitute two Leu residues of the putative leucine zipper by Ala, destabilizing the hydrophobic core of the first WH. We propose that this mutant (RepA-2L2A) resembles a transient folding intermediate in the pathway leading to active monomers. These findings, together with the known activation of other Rep-type proteins by chaperones, are relevant to understand the molecular basis of plasmid DNA replication initiation.

Cooperative action of Escherichia coli ClpB protein and DnaK chaperone in the activation of a replication initiation protein

The Escherichia coli molecular chaperone protein ClpB is a member of the highly conserved Hsp100/Clp protein family. Previous studies have shown that the ClpB protein is needed for bacterial thermotolerance. Purified ClpB protein has been shown to reactivate chemically and heat-denatured proteins. In this work we demonstrate that the combined action of ClpB and the DnaK, DnaJ, and GrpE chaperones leads to the activation of DNA replication of the broad-host-range plasmid RK2. In contrast, ClpB is not needed for the activation of the oriC-dependent replication of E. coli. Using purified protein components we show that the ClpB/DnaK/DnaJ/GrpE synergistic action activates the plasmid RK2 replication initiation protein TrfA by converting inactive dimers to an active monomer form. In contrast, Hsp78/Ssc1/Mdj1/Mge1, the corresponding protein system from yeast mitochondria, cannot activate the TrfA replication protein. Our results demonstrate for the first time that the ClpB/DnaK/DnaJ/GrpE system is involved in protein monomerization and in the activation of a DNA replication factor.

ParE toxin encoded by the broad-host-range plasmid RK2 is an inhibitor of Escherichia coli gyrase

Broad-host-range plasmid RK2 encodes a post-segregational killing system, parDE, which contributes to the stable maintenance of this plasmid in Escherichia coli and many distantly related bacteria. The ParE protein is a toxin that inhibits cell growth, causes cell filamentation and eventually cell death. The ParD protein is a specific ParE antitoxin. In this work, the in vitro activities of these two proteins were examined. The ParE protein was found to inhibit DNA synthesis using an E. coli oriC supercoiled template and a replication-proficient E. coli extract. Moreover, ParE inhibited the early stages of both chromosomal and plasmid DNA replication, as measured by the DnaB helicase- and gyrase-dependent formation of FI*, a highly unwound form of supercoiled DNA. The presence of ParD prevented these inhibitory activities of ParE. We also observed that the addition of ParE to supercoiled DNA plus gyrase alone resulted in the formation of a cleavable gyrase-DNA complex that was converted to a linear DNA form upon addition of sodium dodecyl sulphate (SDS). Adding ParD before or after the addition of ParE prevented the formation of this cleavable complex. These results demonstrate that the target of ParE toxin activity in vitro is E. coli gyrase.

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.

DnaA box sequences as the site for helicase delivery during plasmid RK2 replication initiation in Escherichia coli

DnaA box sequences are a common motif present within the replication origin region of a diverse group of bacteria and prokaryotic extrachromosomal genetic elements. Although the origin opening caused by binding of the host DnaA protein has been shown to be critical for the loading of the DnaB helicase, to date there has been no direct evidence presented for the formation of the DnaB complex at the DnaA box site. For these studies, we used the replication origin of plasmid RK2 (oriV), containing a cluster of four DnaA boxes that bind DnaA proteins isolated from different bacterial species (Caspi, R., Helinski, D. R., Pacek, M., and Konieczny, I. (2000) J. Biol. Chem. 275, 18454-18461). Size exclusion chromatography, surface plasmon resonance, and electron microscopy experiments demonstrated that the DnaB helicase is delivered to the DnaA box region, which is localized approximately 200 base pairs upstream from the region of origin opening and a potential site for helicase entry. The DnaABC complex was formed on both double-stranded superhelical and linear RK2 templates. A strict DnaA box sequence requirement for stable formation of that nucleoprotein structure was confirmed. In addition, our experiments provide evidence for interaction between the plasmid initiation protein TrfA and the DnaABC prepriming complex, formed at DnaA box region. This interaction is facilitated via direct contact between TrfA and DnaB proteins.

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

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

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).

Interactions of DnaA proteins from distantly related bacteria with the replication origin of the broad host range plasmid RK2

Replication initiation of the broad host range plasmid RK2 requires binding of the host-encoded DnaA protein to specific sequences (DnaA boxes) at its replication origin (oriV). In contrast to a chromosomal replication origin, which functionally interacts only with the native DnaA protein of the organism, the ability of RK2 to replicate in a wide range of Gram-negative bacterial hosts requires the interaction of oriV with many different DnaA proteins. In this study we compared the interactions of oriV with five different DnaA proteins. DNase I footprint, gel mobility shift, and surface plasmon resonance analyses showed that the DnaA proteins from Escherichia coli, Pseudomonas putida, and Pseudomonas aeruginosa bind to the DnaA boxes at oriV and are capable of inducing open complex formation, the first step in the replication initiation process. However, DnaA proteins from two Gram-positive bacteria, Bacillus subtilis and Streptomyces lividans, while capable of specifically interacting with the DnaA box sequences at oriV, do not bind stably and fail to induce open complex formation. These results suggest that the inability of the DnaA protein of a host bacterium to form a stable and functional complex with the DnaA boxes at oriV is a limiting step for plasmid host range.

Role of bacterial chaperones in DNA replication

Studies on the involvement of chaperone proteins in DNA replication have been limited to a few replication systems, belonging primarily to the prokaryotic world. The insights gained from these studies have substantially contributed to our understanding of the eukaryotic DNA replication process as well. The finding that molecular chaperones can activate some initiation proteins before DNA synthesis has led to the more general suggestion that molecular chaperones can influence the DNA-binding activity of many proteins, including transcriptional factors involved in cell regulatory systems. The DnaK/DnaJ/GrpE molecular chaperone system became a paradigm of our understanding of fundamental processes, such as protein folding, translocation, selective proteolysis and autoregulation of the heat-shock response. Studies on the Clp ATPase family of molecular chaperones will help to define the nature of signals involved in chaperone-dependent proteins' refolding and the degradation of misfolded proteins.

Host-dependent requirement for specific DnaA boxes for plasmid RK2 replication

The replication origin of the broad-host-range plasmid RK2, oriV, contains four DnaA boxes, which bind the DnaA protein isolated from Escherichia coli. Using a transformation assay, mutational analysis of these boxes showed a differential requirement for replication in different Gram-negative bacteria. DnaA boxes 3 and 4 were required in E. coli and Pseudomonas putidabut not as strictly in Azotobacter vinelandii and not at all in P. aeruginosa. In vitro replication results using an extract prepared from E. coli demonstrated that the activity of origin derivatives containing mutations in boxes 3 or 4 or a deletion of all four DnaA boxes could be restored by the addition of increasing amounts of purified DnaA protein. High levels of DnaA protein in the presence of the TrfA protein also resulted in the stimulation of open complex formation and DnaB helicase loading on oriV, even in the absence of the four DnaA boxes. These observations at least raise the possibility that an alternative mechanism of initiation of oriV is being used in the absence of the four DnaA boxes and that this mechanism may be similar to that used in P. aeruginosa, which does not require these four DnaA boxes for replication.

A critical DnaA box directs the cooperative binding of the Escherichia coli DnaA protein to the plasmid RK2 replication origin

The requirement of DnaA protein binding for plasmid RK2 replication initiation the Escherichia coli was investigated by constructing mutations in the plasmid replication origin that scrambled or deleted each of the four upstream DnaA boxes. Altered origins were analyzed for replication activity in vivo and in vitro and for binding to the E. coli DnaA protein using a gel mobility shift assay and DNase I footprinting. Most strikingly, a mutation in one of the boxes, box 4, abolished replication activity and eliminated stable DnaA protein binding to all four boxes. Unlike DnaA binding to the E. coli origin, oriC, DnaA binding to two of the boxes (boxes 4 and 3) in the RK2 origin, oriV, is cooperative with box 4 acting as the "organizer" for the formation of the DnaA-oriV nucleoprotein complex. Interestingly, the inversion of box 4 also abolished replication activity, but did not result in a loss of binding to the other boxes. However, DnaA binding to this mutant origin was no longer cooperative. These results demonstrate that the sequence, position, and orientation of box 4 are crucial for cooperative DnaA binding and the formation of a nucleoprotein structure that is functional for the initiation of replication.

Stabilization of the relaxosome and stimulation of conjugal transfer are genetically distinct functions of the R1162 protein MobB

MobB is a small protein encoded by the broad-host-range plasmid R1162 and required for efficient mobilization of its DNA during conjugation. The protein was shown previously to stabilize the relaxosome, the complex of plasmid DNA and mobilization proteins at the origin of transfer (oriT). We have generated in-frame mobB deletions that specifically inactivate the stabilizing effect of MobB while still allowing a high rate of transfer. Thus, MobB has two genetically distinct functions in transfer. The effect of another deletion, extending into mobA, indicates that both functions require a specific region of MobA protein that is distinct from the nicking-ligating domain. The mobB mutations that specifically affected stability also resulted in poor growth of cells, due to increased transcription from the promoters adjacent to oriT. The effects of the mutations could be suppressed not only by full-length MobB provided in trans, as expected, but also by additional copies of oriT, cloned in pBR322. In addition, in the presence of MobA both the full-length and truncated forms of MobB stimulated recombination between oriT-containing plasmids. We propose a model in which MobB regulates expression of plasmid genes by altering the stability of the relaxosome, in a manner that involves the coupling of plasmid molecules.

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

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

Assemblies of replication initiator protein on symmetric and asymmetric DNA sequences depend on multiple protein oligomerization surfaces

The pi35.0 protein of plasmid R6K regulates transcription and replication by binding a DNA sequence motif (TGAGR) arranged either asymmetrically into 22 bp direct repeats (DRs) in the gamma origin, or symmetrically into inverted half-repeats (IRs) in the operator of its own gene, pir. The binding patterns of the two natural forms of the pi protein and their heterodimers revealed that the predominant species, pi35.0 (35.0 kDa), can bind to a single copy of the DR as either a monomer or a dimer while pi30.5 (30.5 kDa) binds only as a dimer. We demonstrate that only one subunit of a pi35.0 dimer makes specific contact with DNA. Electron microscopic (EM) analysis of the nucleoprotein complexes formed by pi35.0 and DNA fragments containing all seven DRs revealed coupled ("hand-cuffed") DNA molecules that are aligned in a parallel orientation. Antiparallel orientations of the DNA were not observed. Thus, hand-cuffing depends on a highly ordered oligomerization of pi35.0 in such structures. The pi protein (pi35.0, pi30.5) binds to an IR as a dimer or heterodimer but not as a monomer. Moreover, a single amino acid residue substitution, F200S (pir200), introduced into pi30.5 severely destabilizes dimers of this protein in solution and concomitantly prevents binding of this protein to the IR. This mutation also changes the stability of pi35.0 dimers but it does not change the ability of pi35.0 to bind IRs. To explain these observations we propose that the diverse interactions of pi variants with DNA are controlled by multiple surfaces for protein oligomerization.

Replication of R6K gamma origin in vitro: discrete start sites for DNA synthesis dependent on pi and its copy-up variants

The regulation of the plasmid R6K gamma origin (gamma ori) is accomplished through the ability of the pi protein to act as an initiator and inhibitor of replication. Hyperactive variants of this protein, called copy-up pi, allow four to tenfold increases of gamma ori plasmid DNA in vivo. The higher activity of copy-up pi variants could be explained by an increase in the initiator function, a decrease in the inhibitor activity, or a derepression of a more efficient mechanism of replication that can be used by wt pi (pi35. 0) only under certain conditions. We have compared the replication activities of wt pi35.0 and copy-up pi mutants in vitro, and analyzed the replication products. It is shown that copy-up variants are several-fold more active than wt pi35.0 in replication. This appears to be due to enhanced specific replication activity of copy-up mutants rather than elevated fractions of protein proficient in DNA binding. Furthermore, biochemical complementation revealed that pi200 (copy-up) is dominant over wt pi35.0. The elevated activity of copy-up pi is not caused by an increased rate of replisome assembly as inferred from in vitro replication assays in which the lag periods observed were similar to that of wt pi35.0. Moreover, only one round of semiconservative, unidirectional replication occurred in all the samples analyzed indicating that copy-up pi proteins do not initiate multiple rounds of DNA synthesis. Rather, a larger fraction of DNA template replicates in the presence of copy-up pi as determined by electron microscopy. Two clusters of discrete DNA synthesis start sites are mapped by primer extension near the stability (stb) locus of the gamma ori. We show that the start sites are the same in the presence of wt pi35.0 or copy-up proteins. This comparative analysis suggests that wt pi35.0 and copy-up variants utilize fundamentally similar mechanism(s) of replication priming.

Mechanistic studies of initiator-initiator interaction and replication initiation

Unlike the chromosome of Escherichia coli that needs only one replication initiator protein (origin recognition protein) called DnaA, many plasmid replicons require dual initiators: host-encoded DnaA and a plasmid-encoded origin recognition protein, which is believed to be the major determinant of replication control. Hitherto, the relative mechanistic roles of dual initiators in DNA replication were unclear. Here, we present the first evidence that DnaA communicates with the plasmid-encoded pi initiator of R6K and contacts the latter at a specific N-terminal region. Without this specific contact, productive unwinding of plasmid ori gamma and replication is abrogated. The results also show that DnaA performs different roles in host and plasmid replication as revealed by the finding that the ATP-activated form of DnaA, while indispensable for oriC replication, was not required for R6K replication. We have analyzed the accessory role of the DNA bending protein, integration host factor (IHF), in promoting initiator-origin interaction and have found that IHF significantly enhances the binding of DnaA to its cognate site. Collectively, the results further advance our understanding of replication initiation.