Modulation of pPS10 host range by plasmid-encoded RepA initiator protein

Microbial evolution through horizontal gene transfer by mobile genetic elements

Mobile genetic elements (MGEs) are crucial for horizontal gene transfer (HGT) in bacteria and facilitate their rapid evolution and adaptation. MGEs include plasmids, integrative and conjugative elements, transposons, insertion sequences and bacteriophages. Notably, the spread of antimicrobial resistance genes (ARGs), which poses a serious threat to public health, is primarily attributable to HGT through MGEs. This mini-review aims to provide an overview of the mechanisms by which MGEs mediate HGT in microbes. Specifically, the behaviour of conjugative plasmids in different environments and conditions was discussed, and recent methodologies for tracing the dynamics of MGEs were summarised. A comprehensive understanding of the mechanisms underlying HGT and the role of MGEs in bacterial evolution and adaptation is important to develop strategies to combat the spread of ARGs.

Darwinian individuality of extrachromosomal genetic elements calls for population genetics tinkering

Plasmids are extrachromosomal genetic elements commonly found in prokaryotic (and sometime eukaryotic) cells. Small plasmids are often considered cryptic and their effect on the host is elusive, while large plasmids may encode functions that are essential for the host lifestyle and attain a secondary chromosome status. Plasmids are thus an important source of raw material for microbial genome evolution outside the mainstream of bacterial chromosomes. The discovery of plasmid-mediated antibiotic resistance led to extensive research on the contribution of plasmids to the environmental dimensions of antibiotic resistance and the evolution of plasmid-host interactions following the acquisition of plasmids encoding for antibiotic resistance. Recent experimental studies revealed the importance of intracellular plasmid diversity for plasmid-host interactions. Here we describe the evolutionary forces at play during plasmid evolution in a top-down approach: this includes the effect of processes at the level of the host population and the consideration of plasmids as Darwinian individuals within the host cell.

Mechanisms of Theta Plasmid Replication in Enterobacteria and Implications for Adaptation to Its Host

Plasmids are autonomously replicating sequences that help cells adapt to diverse stresses. Theta plasmids are the most frequent plasmid class in enterobacteria. They co-opt two host replication mechanisms: replication at oriC, a DnaA-dependent pathway leading to replisome assembly (theta class A), and replication fork restart, a PriA-dependent pathway leading to primosome assembly through primer extension and D-loop formation (theta classes B, C, and D). To ensure autonomy from the host's replication and to facilitate copy number regulation, theta plasmids have unique mechanisms of replication initiation at the plasmid origin of replication (ori). Tight plasmid copy number regulation is essential because of the major and direct impact plasmid gene dosage has on gene expression. The timing of plasmid replication and segregation are also critical for optimizing plasmid gene expression. Therefore, we propose that plasmid replication needs to be understood in its biological context, where complex origins of replication (redundant origins, mosaic and cointegrated replicons), plasmid segregation, and toxin-antitoxin systems are often present. Highlighting their tight functional integration with ori function, we show that both partition and toxin-antitoxin systems tend to be encoded in close physical proximity to the ori in a large collection of Escherichia coli plasmids. We also propose that adaptation of plasmids to their host optimizes their contribution to the host's fitness while restricting access to broad genetic diversity, and we argue that this trade-off between adaptation to host and access to genetic diversity is likely a determinant factor shaping the distribution of replicons in populations of enterobacteria.

Transcriptional Organization of the Stability Module of Broad-Host-Range Plasmid RA3, from the IncU Group

The broad-host-range (BHR) conjugative plasmids have developed diverse adaptive mechanisms defining the range of their promiscuity. The BHR conjugative RA3 plasmid, the archetype of the IncU group, can transfer between, replicate in, and be maintained in representatives of Alpha-, Beta-, and Gammaproteobacteria Its stability module encompasses ten open reading frames (ORFs) apparently organized into five operons, all transcribed in the same direction from several strong promoters that are tightly regulated either by autorepressors or by global plasmid-encoded regulators. In this paper, we demonstrate that owing to an efficient RNA polymerase (RNAP) read-through, the transcription from the first promoter, orf02p, may continue through the whole module. Moreover, an analysis of mRNA produced from the wild-type (WT) stability module and its deletion variants deprived of particular internal transcription initiation sites reveals that in fact each operon may be transcribed from any upstream promoter, giving rise to multicistronic transcripts of variable length and creating an additional level of gene expression control by transcript dosage adjustment. The gene expression patterns differ among various hosts, indicating that promoter recognition, regulation, and the RNAP read-through mechanisms are modulated in a species-specific manner.IMPORTANCE The efficiently disseminating conjugative or mobilizable BHR plasmids play key roles in the horizontal spread of genetic information between closely related and phylogenetically distant species, which can be harmful from the medical, veterinary, or industrial point of view. Understanding the mechanisms determining the plasmid's ability to function in diverse hosts is essential to help limit the spread of undesirable plasmid-encoded traits, e.g., antibiotic resistance. The range of a plasmid's promiscuity depends on the adaptations of its transfer, replication, and stability functions to the various hosts. IncU plasmids, with the archetype plasmid RA3, are considered to constitute a reservoir of antibiotic resistance genes in aquatic environments; however, the molecular mechanisms determining their adaptability to a broad range of hosts are rather poorly characterized. Here, we present the transcriptional organization of the stability module and show that the gene transcript dosage effect is an important determinant of the stable maintenance of RA3 in different hosts.

Chromosome organization by a conserved condensin-ParB system in the actinobacterium Corynebacterium glutamicum

Higher-order chromosome folding and segregation are tightly regulated in all domains of life. In bacteria, details on nucleoid organization regulatory mechanisms and function remain poorly characterized, especially in non-model species. Here, we investigate the role of DNA-partitioning protein ParB and SMC condensin complexes in the actinobacterium Corynebacterium glutamicum. Chromosome conformation capture reveals SMC-mediated long-range interactions around ten centromere-like parS sites clustered at the replication origin (oriC). At least one oriC-proximal parS site is necessary for reliable chromosome segregation. We use chromatin immunoprecipitation and photoactivated single-molecule localization microscopy to show the formation of distinct, parS-dependent ParB-nucleoprotein subclusters. We further show that SMC/ScpAB complexes, loaded via ParB at parS sites, mediate chromosomal inter-arm contacts (as previously shown in Bacillus subtilis). However, the MukBEF-like SMC complex MksBEFG does not contribute to chromosomal DNA-folding; instead, this complex is involved in plasmid maintenance and interacts with the polar oriC-tethering factor DivIVA. Our results complement current models of ParB-SMC/ScpAB crosstalk and show that some condensin complexes evolved functions that are apparently uncoupled from chromosome folding.

The regulation of higher-order chromosome folding and segregation in bacteria is poorly understood. Here, Böhm et al. provide insights into the roles of DNA partitioning protein ParB and SMC condensin complexes in Corynebacterium glutamicum.

Plasmid-chromosome cross-talks

Plasmids can be acquired by recipient bacteria at a significant cost while conferring them advantageous traits. To counterbalance the costs of plasmid carriage, both plasmids and host bacteria have developed a tight regulatory network that may involve a cross-talk between the chromosome and the plasmids. Although plasmid regulation by chromosomal regulators is generally well known, chromosome regulation by plasmid has been far less investigated. Yet, a growing number of studies have highlighted an impact of plasmids on their host bacteria. Here, we describe the plasmid-chromosome cross-talk from the plasmid point of view. We summarize data about the chromosomal adaptive mutations generated by plasmid carriage; the impact of the loss of a domesticated plasmid or the gain of a new plasmid. Then, we present the control of plasmid-encoded regulators on chromosomal gene expression. The involvement of regulators homologous to chromosome-encoded proteins is illustrated by the H-NS-like proteins, and by the Rap-Phr system. Finally, plasmid-specific regulators of chromosomal gene expression are presented, which highlight the involvement of transcription factors and sRNAs. A comprehensive analysis of the mechanisms that allow a given plasmid to impact the chromosome of bacterium will help to understand the tight cross-talk between plasmids and the chromosome.

Compensatory mutations improve general permissiveness to antibiotic resistance plasmids

Horizontal gene transfer mediated by broad-host-range plasmids is an important mechanism of antibiotic resistance spread. While not all bacteria maintain plasmids equally well, plasmid persistence can improve over time, yet no general evolutionary mechanisms have emerged. Our goal was to identify these mechanisms and to assess if adaptation to one plasmid affects the permissiveness to others. We experimentally evolved Pseudomonas sp. H2 containing multidrug resistance plasmid RP4, determined plasmid persistence and cost using a joint experimental-modelling approach, resequenced evolved clones, and reconstructed key mutations. Plasmid persistence improved in fewer than 600 generations because the fitness cost turned into a benefit. Improved retention of naive plasmids indicated that the host evolved towards increased plasmid permissiveness. Key chromosomal mutations affected two accessory helicases and the RNA polymerase β-subunit. Our and other findings suggest that poor plasmid persistence can be caused by a high cost involving helicase-plasmid interactions that can be rapidly ameliorated.

Replisome Assembly at Bacterial Chromosomes and Iteron Plasmids

The proper initiation and occurrence of DNA synthesis depends on the formation and rearrangements of nucleoprotein complexes within the origin of DNA replication. In this review article, we present the current knowledge on the molecular mechanism of replication complex assembly at the origin of bacterial chromosome and plasmid replicon containing direct repeats (iterons) within the origin sequence. We describe recent findings on chromosomal and plasmid replication initiators, DnaA and Rep proteins, respectively, and their sequence-specific interactions with double- and single-stranded DNA. Also, we discuss the current understanding of the activities of DnaA and Rep proteins required for replisome assembly that is fundamental to the duplication and stability of genetic information in bacterial cells.

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.

Evolutionary Paths That Expand Plasmid Host-Range: Implications for Spread of Antibiotic Resistance

The World Health Organization has declared the emergence of antibiotic resistance to be a global threat to human health. Broad-host-range plasmids have a key role in causing this health crisis because they transfer multiple resistance genes to a wide range of bacteria. To limit the spread of antibiotic resistance, we need to gain insight into the mechanisms by which the host range of plasmids evolves. Although initially unstable plasmids have been shown to improve their persistence through evolution of the plasmid, the host, or both, the means by which this occurs are poorly understood. Here, we sought to identify the underlying genetic basis of expanded plasmid host-range and increased persistence of an antibiotic resistance plasmid using a combined experimental-modeling approach that included whole-genome resequencing, molecular genetics and a plasmid population dynamics model. In nine of the ten previously evolved clones, changes in host and plasmid each slightly improved plasmid persistence, but their combination resulted in a much larger improvement, which indicated positive epistasis. The only genetic change in the plasmid was the acquisition of a transposable element from a plasmid native to the Pseudomonas host used in these studies. The analysis of genetic deletions showed that the critical genes on this transposon encode a putative toxin-antitoxin (TA) and a cointegrate resolution system. As evolved plasmids were able to persist longer in multiple naïve hosts, acquisition of this transposon also expanded the plasmid's host range, which has important implications for the spread of antibiotic resistance.

RepA-WH1, the agent of an amyloid proteinopathy in bacteria, builds oligomeric pores through lipid vesicles

RepA-WH1 is a disease-unrelated protein that recapitulates in bacteria key aspects of human amyloid proteinopathies: i) It undergoes ligand-promoted amyloidogenesis in vitro; ii) its aggregates are able to seed/template amyloidosis on soluble protein molecules; iii) its conformation is modulated by Hsp70 chaperones in vivo, generating transmissible amyloid strains; and iv) causes proliferative senescence. Membrane disruption by amyloidogenic oligomers has been found for most proteins causing human neurodegenerative diseases. Here we report that, as for PrP prion and α-synuclein, acidic phospholipids also promote RepA-WH1 amyloidogenesis in vitro. RepA-WH1 molecules bind to liposomes, where the protein assembles oligomeric membrane pores. Fluorescent tracer molecules entrapped in the lumen of the vesicles leak through these pores and RepA-WH1 can then form large aggregates on the surface of the vesicles without inducing their lysis. These findings prove that it is feasible to generate in vitro a synthetic proteinopathy with a minimal set of cytomimetic components and support the view that cell membranes are primary targets in protein amyloidoses.

Pre-amyloid oligomers of the proteotoxic RepA-WH1 prionoid assemble at the bacterial nucleoid

Upon binding to short specific dsDNA sequences in vitro, the N-terminal WH1 domain of the plasmid DNA replication initiator RepA assembles as amyloid fibres. These are bundles of single or double twisted tubular filaments in which distorted RepA-WH1 monomers are the building blocks. When expressed in Escherichia coli, RepA-WH1 triggers the first synthetic amyloid proteinopathy in bacteria, recapitulating some of the features of mammalian prion diseases: it is vertically transmissible, albeit non-infectious, showing up in at least two phenotypically distinct and interconvertible strains. Here we report B3h7, a monoclonal antibody specific for oligomers of RepA-WH1, but which does not recognize the mature amyloid fibres. Unlike a control polyclonal antibody generated against the soluble protein, B3h7 interferes in vitro with DNA-promoted or amyloid-seeded assembly of RepA-WH1 fibres, thus the targeted oligomers are on-pathway amyloidogenic intermediates. Immuno-electron microscopy with B3h7 on thin sections of E. coli cells expressing RepA-WH1 consistently labels the bacterial nucleoid, but not the large cytoplasmic aggregates of the protein. This observation points to the nucleoid as the place where oligomeric amyloid precursors of RepA-WH1 are generated, and suggests that, once nucleated by DNA, further growth must continue in the cytoplasm due to entropic exclusion.

Host range diversification within the IncP-1 plasmid group

Broad-host-range plasmids play a critical role in the spread of antibiotic resistance and other traits. In spite of increasing information about the genomic diversity of closely related plasmids, the relationship between sequence divergence and host range remains unclear. IncP-1 plasmids are currently classified into six subgroups based on the genetic distance of backbone genes. We investigated whether plasmids from two subgroups exhibit a different host range, using two IncP-1γ plasmids, an IncP-1β plasmid and their minireplicons. Efficiencies of plasmid establishment and maintenance were compared using five species that belong to the Alphaproteobacteria, Betaproteobacteria and Gammaproteobacteria. The IncP-1β plasmid replicated and persisted in all five hosts in the absence of selection. Of the two IncP-1γ plasmids, both were unable to replicate in alphaproteobacterial host Sphingobium japonicum, and one established itself in Agrobacterium tumefaciens but was very unstable. In contrast, both IncP-1γ minireplicons, which produced higher levels of replication initiation protein than the wild-type plasmids, replicated in all strains, suggesting that poor establishment of the native plasmids is in part due to suboptimal replication initiation gene regulation. The findings suggest that host ranges of distinct IncP-1 plasmids only partially overlap, which may limit plasmid recombination and thus result in further genome divergence.

Characterization of the replication origin of the myxobacterial self-replicative plasmid pMF1

Thus far, pMF1 is the only endogenous myxobacterial plasmid whose replication mechanism is unclear. In this study, we determined that the plasmid replicates via the theta-mode. The pMF1.14 gene, located in the pMF1.13-pMF1.15 operon (repABC), encodes an essential replication initiation protein that was predicted to have no typical DNA/protein binding motifs but contains rich disordered regions. The pMF1 replication-related essential cis-acting DNA region, approximate 370bp, was located within pMF1.14, and was found to contain several directly and inverted atypical repeats. The unique characteristics of the pMF1 replicon are suggested to be the reason for its strict narrow host range in Myxococcus cells.

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.

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.

Adaptive plasmid evolution results in host-range expansion of a broad-host-range plasmid

Little is known about the range of hosts in which broad-host-range (BHR) plasmids can persist in the absence of selection for plasmid-encoded traits, and whether this "long-term host range" can evolve over time. Previously, the BHR multidrug resistance plasmid pB10 was shown to be highly unstable in Stenotrophomonas maltophilia P21 and Pseudomonas putida H2. To investigate whether this plasmid can adapt to such unfavorable hosts, we performed evolution experiments wherein pB10 was maintained in strain P21, strain H2, and alternatingly in P21 and H2. Plasmids that evolved in P21 and in both hosts showed increased stability and decreased cost in ancestral host P21. However, the latter group showed higher variability in stability patterns, suggesting that regular switching between distinct hosts hampered adaptive plasmid evolution. The plasmids evolved in P21 were also equally or more stable in other hosts compared to pB10, which suggested true host-range expansion. The complete genome sequences of four evolved plasmids with improved stability showed only one or two genetic changes. The stability of plasmids evolved in H2 improved only in their coevolved hosts, not in the ancestral host. Thus a BHR plasmid can adapt to an unfavorable host and thereby expand its long-term host range.

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.

Defined DNA sequences promote the assembly of a bacterial protein into distinct amyloid nanostructures

RepA, the replication initiator protein of Pseudomonas pPS10 plasmid, is made of two winged-helix (WH) domains. RepA dimers undergo a structural transformation upon binding to origin DNA sequences (iterons), resulting in monomerization and alpha-helix into beta-strand conversion. This affects the N-terminal domain (WH1) and generates a metastable intermediate. Here it is shown that the interaction of short dsDNA oligonucleotides, including iteron or operator RepA targets, with the isolated WH1 domain promotes the assembly of different nanostructures. These range from irregular aggregates to amyloid spheroids and fibers. Their intrinsic order inversely correlates with the extent of the transformation induced by each DNA sequence on RepA. However, DNA is not a constituent of the assembled fibers, in agreement with the protein-only principle for amyloid structure. Thus, the RepA-WH1 domain on DNA binding mimics the behavior of the mammalian prion protein. The stretch of amino acids responsible for WH1 aggregation has been identified, leading to the design of mutants with enhanced or reduced amyloidogenicity and the synthesis of a peptide that assembles into a cross-beta structure. RepA amyloid assemblies could have a role in the negative regulation of plasmid replication. This article underlines the potential of specific nucleic acid sequences in promoting protein amyloidogenesis at nearly physiological conditions.

Early Events in the Binding of the pPS10 Replication Protein RepA to Single Iteron and Operator DNA Sequences

RepA protein, encoded in the Pseudomonas pPS10 replicon, is a stable dimer in solution (dRepA), acting as a self-repressor of repA transcription through binding to an inverted repeat operator. However, RepA monomers (mRepA) are required to initiate plasmid replication upon binding to four directly repeated DNA sequences (iterons). RepA is composed of two winged-helix (WH) domains: C-terminal WH2 is the main DNA-binding domain (DBD) for both target sequences, whereas N-terminal WH1 acts as dimerization interface in dRepA, but becomes a second DBD in mRepA. On the basis of CD spectroscopy, hydrodynamics, X-ray crystallography and model building studies, we proposed previously that the activation of RepA initiator implies a large structural change in WH1, coupled to protein monomerization and interdomain compaction. Here, we report novel features in the process. Binding curves of RepA to an iteron, followed by fluorescence anisotropy in solution and by surface plasmon resonance on immobilized DNA, exhibit the profiles characteristic of transitions between three states. In contrast, RepA-R93C, a monomeric activated mutant, exhibits a single binding transition. This suggests the presence of an intermediate species in the iteron-induced dissociation and structural transformation of RepA. High concentrations of bovine serum albumin or ovalbumin (macromolecular crowding) enhance RepA affinity for an iteron in solution and, in gel mobility-shift assays, result in the visualization of novel protein-DNA complexes. RepA-induced DNA bending requires the binding of two WH domains: either both WH2 in dimers (operator) or WH1 plus WH2 in monomers (iteron).

IncP-9 replication initiator protein binds to multiple DNA sequences in oriV and recruits host DnaA protein

The minimal replicon from IncP-9 plasmid pM3, consisting of oriV and rep, is able to replicate in Pseudomonas putida but not in Escherichia coli, unless production of Rep protein is increased. The Rep protein, at 20kDa, is the smallest replication protein so far identified for a theta replicating plasmid. Rep was purified and shown to bind in three blocks across the oriV region that do not correlate with a single unique binding sequence. The block closest to rep is not necessary for oriV function. Rep forms at least two types of complex--one rendering the DNA entirely resistant to cleavage, the other occupying one side of the helix. No short segment of oriV showed the same affinity for Rep as the whole of oriV. The oriV region did not bind purified DnaA from E. coli, P. putida or P. aeruginosa but when Rep was present also, super-shifts were found with DnaA in a sequence-specific manner. Scrambling of the primary candidate DnaA box did not inactivate oriV but did increase the level of Rep required to activate oriV. The general pattern of Rep-DNA recognition sequences in oriV indicates that the IncP-9 system falls outside of the paradigms of model plasmids that have been well-studied to date.

Characterization of the theta-type plasmid pCD3.4 from Carnobacterium divergens, and modulation of its host range by RepA mutation

The complete nucleotide sequence of the 3475 bp plasmid pCD3.4 from Carnobacterium divergens LV13, which encodes the bacteriocin divergicin A, was determined. Nucleotide sequence, deletion and complementation analyses revealed the presence of a trans-acting replication protein, RepA, and DNA sequences involved in plasmid replication and copy-number control. The DNA region preceding the repA gene probably contains the origin of replication. This sequence includes four and a half direct repeats (iterons) of 22 bp, to which RepA is thought to bind, and an AT-rich region containing a 12 bp repeat, at which initiation of DNA might occur. Further upstream of this sequence resides a fifth iteron required for optimal plasmid replication. The RepA protein shows homology to replication proteins of the pUCL287 subfamily of theta-type replicons. Two ORFs were found downstream of the repA gene that could be deleted without affecting replication and stability of the plasmid. pCD3.4 has a narrow host range, and could only be maintained in Carnobacterium spp.; however, a mutant of the plasmid was obtained that enabled the pCD3.4 replicon to replicate in Enterococcus faecium, but not in Carnobacterium spp. The mutation was located in the C-terminal region of the RepA protein, changing a proline into a serine. This is believed to be the first example of such plasmid-host-range modulation in Gram-positive bacteria.

Mechanisms of, and barriers to, horizontal gene transfer between bacteria

Bacteria evolve rapidly not only by mutation and rapid multiplication, but also by transfer of DNA, which can result in strains with beneficial mutations from more than one parent. Transformation involves the release of naked DNA followed by uptake and recombination. Homologous recombination and DNA-repair processes normally limit this to DNA from similar bacteria. However, if a gene moves onto a broad-host-range plasmid it might be able to spread without the need for recombination. There are barriers to both these processes but they reduce, rather than prevent, gene acquisition.

Ability of IncP-9 plasmid pM3 to replicate in Escherichia coli is dependent on both rep and par functions

IncP-9 plasmids are common in Pseudomonas species and can be transferred to other Gram-negative eubacteria but tend not to be stably maintained outside their natural host genus. A 1.3 kb ori V-rep fragment from IncP-9 plasmid pM3 was sufficient for autonomous replication in Pseudomonas putida but not in Escherichia coli. Replication of ori V-rep in E. coli was restored when additional rep was provided in trans, suggesting that the replication defect resulted from insufficient rep expression from its natural promoter. A promoter deficiency in E. coli was confirmed by reporter gene assays, transcriptional start point mapping and mutation of the promoter recognition elements. Dissection of the pM3 mini-replicon, pMT2, showed that this replication deficiency in E. coli is suppressed by additional determinants from its par operon: ParB, which can be supplied in trans, and its target, the par operon promoter, required in cis to ori V-rep. We propose that ParB binding to its target either changes plasmid DNA and thus promoter conformation or by spreading or looping contacts RNAP at the rep promoter so that rep expression is sufficient to activate ori V.

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.

Plasmid P1 RepA Is Homologous to the F Plasmid RepE Class of Initiators

DNA replication of plasmid P1 requires a plasmid-encoded origin DNA-binding protein, RepA. RepA is an inactive dimer and is converted by molecular chaperones into an active monomer that binds RepA binding sites. Although the sequence of RepA is not homologous to that of F plasmid RepE, we found by using fold-recognition programs that RepA shares structural homology with RepE and built a model based on the RepE crystal structure. We constructed mutants in the two predicted DNA binding domains to test the model. As expected, the mutants were defective in P1 DNA binding. The model predicted that RepA binds the first half of the binding site through interactions with the C-terminal DNA binding domain and the second half through interactions with the N-terminal domain. The experiments supported the prediction. The model was further supported by the observation that mutants defective in dimerization map to the predicted subunit interface region, based on the crystal structure of pPS10 RepA, a RepE family member. These results suggest P1 RepA is structurally homologous to plasmid initiators, including those of F, R6K, pSC101, pCU1, pPS10, pFA3, pGSH500, Rts1, RepHI1B, RepFIB, and RSF1010.

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.