Lagging strand replication of rolling-circle plasmids: specific recognition of the ssoA-type origins in different gram-positive bacteria

Staphylococcus equorum plasmid pKS1030-3 encodes auxiliary biofilm formation and trans-acting gene mobilization systems

The foodborne bacterium Staphylococcus equorum strain KS1030 harbours plasmid pSELNU1, which encodes a lincomycin resistance gene. pSELNU1 undergoes horizontal transfer between bacterial strains, thus spreading antibiotic resistance. However, the genes required for horizontal plasmid transfer are not encoded in pSELNU1. Interestingly, a relaxase gene, a type of gene related to horizontal plasmid transfer, is encoded in another plasmid of S. equorum KS1030, pKS1030-3. The complete genome of pKS1030-3 is 13,583 bp long and encodes genes for plasmid replication, biofilm formation (the ica operon), and horizontal gene transfer. The replication system of pKS1030-3 possesses the replication protein-encoding gene repB, a double-stranded origin of replication, and two single-stranded origins of replication. The ica operon, relaxase gene, and a mobilization protein-encoding gene were detected in pKS1030-3 strain-specifically. When expressed in S. aureus RN4220, the ica operon and relaxase operon of pKS1030-3 conferred biofilm formation ability and horizontal gene transfer ability, respectively. The results of our analyses show that the horizontal transfer of pSELNU1 of S. equorum strain KS1030 depends on the relaxase encoded by pKS1030-3, which is therefore trans-acting. Genes encoded in pKS1030-3 contribute to important strain-specific properties of S. equorum KS1030. These results could contribute to preventing the horizontal transfer of antibiotic resistance genes in food.

Identification and Characterization of Novel SPHINX/BMMF-like DNA Sequences Isolated from Non-Bovine Foods

Sixteen novel circular rep-encoding DNA sequences with high sequence homologies to previously described SPHINX and BMMF sequences were isolated for the first time from non-bovine foods (pork, wild boar, chicken meat, Alaska pollock, pangasius, black tiger shrimp, apple, carrot, and sprouts from alfalfa, radish, and broccoli). The phylogenetic analysis of the full-length circular genomes grouped these together with previously described representatives of SPHINX/BMMF group 1 and 2 sequences (eight in each group). The characterization of genome lengths, genes present, and conserved structures confirmed their relationship to the known SPHINX/BMMF sequences. Further analysis of iteron-like tandem repeats of SPHINX/BMMF group 1-related genomes revealed a correlation with both full-length sequence tree branches as well as Rep protein sequence tree branches and was able to differentiate subtypes of SPHINX/BMMF group 1 members. For the SPHINX/BMMF group 2 members, a distinct grouping of sequences into two clades (A and B) with subgroups could be detected. A deeper investigation of potential functional regions upstream of the rep gene of the new SPHINX/BMMF group 2 sequences revealed homologies to the dso and sso regions of known plasmid groups that replicate via the rolling circle mechanism. Phylogenetic analyses were accomplished by a Rep protein sequence analysis of different ssDNA viruses, pCRESS, and plasmids with the known replication mechanism, as this yielded deeper insights into the relationship of SPHINX/BMMF group 1 and 2 Rep proteins. A clear relation of these proteins to the Rep proteins of plasmids could be confirmed. Interestingly, for SPHINX/BMMF group 2 members, the relationship to rolling circle replication plasmids could also be verified. Furthermore, a relationship of SPHINX/BMMF group 1 Rep proteins to theta-replicating plasmid Reps is discussed.

Unique properties of spacer acquisition by the type III-A CRISPR-Cas system

Type III CRISPR-Cas systems have a unique mode of interference, involving crRNA-guided recognition of nascent RNA and leading to DNA and RNA degradation. How type III systems acquire new CRISPR spacers is currently not well understood. Here, we characterize CRISPR spacer uptake by a type III-A system within its native host, Streptococcus thermophilus. Adaptation by the type II-A system in the same host provided a basis for comparison. Cas1 and Cas2 proteins were critical for type III adaptation but deletion of genes responsible for crRNA biogenesis or interference did not detectably change spacer uptake patterns, except those related to host counter-selection. Unlike the type II-A system, type III spacers are acquired in a PAM- and orientation-independent manner. Interestingly, certain regions of plasmids and the host genome were particularly well-sampled during type III-A, but not type II-A, spacer uptake. These regions included the single-stranded origins of rolling-circle replicating plasmids, rRNA and tRNA encoding gene clusters, promoter regions of expressed genes and 5′ UTR regions involved in transcription attenuation. These features share the potential to form DNA secondary structures, suggesting a preferred substrate for type III adaptation. Lastly, the type III-A system adapted to and protected host cells from lytic phage infection.

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

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

Dual role of the σ factor in primer RNA synthesis by bacterial RNA polymerase

Bacterial RNA polymerase (RNAP) serves as a primase during replication of single-stranded plasmids and filamentous phages. Primer RNA (prRNA) synthesis from the origin regions of these replicons depends on the σ factor that normally participates in promoter recognition. However, it was proposed that σ may not be required for origin recognition but is rather involved in RNA extension by RNAP. Here, by analyzing the natural replication origin of bacteriophage M13 and synthetic ssDNA templates, we show that interactions of σ with promoter-like motifs stabilize priming complexes and can control prRNA synthesis by trapping RNAP on the template. Thus, the σ factor is involved in both DNA recognition and RNA priming, unifying its functions in transcription initiation from double- and single-stranded templates.

Streptococcal group B integrative and mobilizable element IMESag-rpsI encodes a functional relaxase involved in its transfer

Streptococcus agalactiae or Group B Streptococcus (GBS) are opportunistic bacteria that can cause lethal sepsis in children and immuno-compromised patients. Their genome is a reservoir of mobile genetic elements that can be horizontally transferred. Among them, integrative and conjugative elements (ICEs) and the smaller integrative and mobilizable elements (IMEs) primarily reside in the bacterial chromosome, yet have the ability to be transferred between cells by conjugation. ICEs and IMEs are therefore a source of genetic variability that participates in the spread of antibiotic resistance. Although IMEs seem to be the most prevalent class of elements transferable by conjugation, they are poorly known. Here, we have studied a GBS-IME, termed IMESag-rpsI, which is widely distributed in GBS despite not carrying any apparent virulence trait. Analyses of 240 whole genomes showed that IMESag-rpsI is present in approximately 47% of the genomes, has a roughly constant size (approx. 9 kb) and is always integrated at a single location, the 3′-end of the gene encoding the ribosomal protein S9 (rpsI). Based on their genetic variation, several IMESag-rpsI types were defined (A–J) and classified in clonal complexes (CCs). CC1 was the most populated by IMESag-rpsI (more than 95%), mostly of type-A (71%). One CC1 strain (S. agalactiae HRC) was deep-sequenced to understand the rationale underlying type-A IMESag-rpsI enrichment in GBS. Thirteen open reading frames were identified, one of them encoding a protein (MobSag) belonging to the broadly distributed family of relaxases MOB_V1. Protein MobSag was purified and, by a newly developed method, shown to cleave DNA at a specific dinucleotide. The S. agalactiae HRC-IMESag-rpsI is able to excise from the chromosome, as shown by the presence of circular intermediates, and it harbours a fully functional mobilization module. Further, the mobSag gene encoded by this mobile element is able to promote plasmid transfer among pneumococcal strains, suggesting that MobSag facilitates the spread of IMESag-rpsI and that this spread would explain the presence of the same IMESag-rpsI type in GBS strains belonging to different CCs.

Replication of Staphylococcal Resistance Plasmids

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

The qacC Gene Has Recently Spread between Rolling Circle Plasmids of Staphylococcus, Indicative of a Novel Gene Transfer Mechanism

Resistance of Staphylococcus species to quaternary ammonium compounds, frequently used as disinfectants and biocides, can be attributed to qac genes. Most qac gene products belong to the Small Multidrug Resistant (SMR) protein family, and are often encoded by rolling-circle (RC) replicating plasmids. Four classes of SMR-type qac gene families have been described in Staphylococcus species: qacC, qacG, qacJ, and qacH. Within their class, these genes are highly conserved, but qacC genes are extremely conserved, although they are found in variable plasmid backgrounds. The lower degree of sequence identity of these plasmids compared to the strict nucleotide conservation of their qacC means that this gene has recently spread. In the absence of insertion sequences or other genetic elements explaining the mobility, we sought for an explanation of mobilization by sequence comparison. Publically available sequences of qac genes, their flanking genes and the replication gene that is invariably present in RC-plasmids were compared to reconstruct the evolutionary history of these plasmids and to explain the recent spread of qacC. Here we propose a new model that explains how qacC is mobilized and transferred to acceptor RC-plasmids without assistance of other genes, by means of its location in between the Double Strand replication Origin (DSO) and the Single-Strand replication Origin (SSO). The proposed mobilization model of this DSO-qacC-SSO element represents a novel mechanism of gene mobilization in RC-plasmids, which has also been employed by other genes, such as lnuA (conferring lincomycin resistance). The proposed gene mobility has aided to the wide spread of clinically relevant resistance genes in Staphylococcus populations.

Plasmid Rolling-Circle Replication

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

Determination of Plasmid Segregational Stability in a Growing Bacterial Population

Bacterial plasmids are extensively used as cloning vectors for a number of genes for academic and commercial purposes. Moreover, attenuated bacteria carrying recombinant plasmids expressing genes with anti-tumor activity have shown promising therapeutic results in animal models of cancer. Equitable plasmid distribution between daughter cells during cell division, i.e., plasmid segregational stability, depends on many factors, including the plasmid copy number, its replication mechanism, the levels of recombinant gene expression, the type of bacterial host, and the metabolic burden associated with all these factors. Plasmid vectors usually code for antibiotic-resistant functions, and, in order to enrich the culture with bacteria containing plasmids, antibiotic selective pressure is commonly used to eliminate plasmid-free segregants from the growing population. However, administration of antibiotics can be inconvenient for many industrial and therapeutic applications. Extensive ongoing research is being carried out to develop stably-inherited plasmid vectors. Here, I present an easy and precise method for determining the kinetics of plasmid loss or maintenance for every ten generations of bacterial growth in culture.

Identification of a Single Strand Origin of Replication in the Integrative and Conjugative Element ICEBs1 of Bacillus subtilis

We identified a functional single strand origin of replication (sso) in the integrative and conjugative element ICEBs1 of Bacillus subtilis. Integrative and conjugative elements (ICEs, also known as conjugative transposons) are DNA elements typically found integrated into a bacterial chromosome where they are transmitted to daughter cells by chromosomal replication and cell division. Under certain conditions, ICEs become activated and excise from the host chromosome and can transfer to neighboring cells via the element-encoded conjugation machinery. Activated ICEBs1 undergoes autonomous rolling circle replication that is needed for the maintenance of the excised element in growing and dividing cells. Rolling circle replication, used by many plasmids and phages, generates single-stranded DNA (ssDNA). In many cases, the presence of an sso enhances the conversion of the ssDNA to double-stranded DNA (dsDNA) by enabling priming of synthesis of the second DNA strand. We initially identified sso1 in ICEBs1 based on sequence similarity to the sso of an RCR plasmid. Several functional assays confirmed Sso activity. Genetic analyses indicated that ICEBs1 uses sso1 and at least one other region for second strand DNA synthesis. We found that Sso activity was important for two key aspects of the ICEBs1 lifecycle: 1) maintenance of the plasmid form of ICEBs1 in cells after excision from the chromosome, and 2) stable acquisition of ICEBs1 following transfer to a new host. We identified sequences similar to known plasmid sso's in several other ICEs. Together, our results indicate that many other ICEs contain at least one single strand origin of replication, that these ICEs likely undergo autonomous replication, and that replication contributes to the stability and spread of these elements.

Mobile genetic elements facilitate movement of genes, including those conferring antibiotic resistance and other traits, between bacteria. Integrative and conjugative elements (ICEs) are a large family of mobile genetic elements that are typically found integrated in the chromosome of their host bacterium. Under certain conditions (e.g., DNA damage, high cell density, stationary phase) an ICE excises from the host chromosome to form a circle. A linear single strand of ICE DNA can be transferred to an appropriate recipient through the ICE-encoded conjugation machinery. In addition, following excision from the chromosome, at least some (perhaps most) ICEs undergo autonomous rolling circle replication, a mechanism used by many plasmids and phages. Rolling circle replication generates single-stranded DNA (ssDNA). We found that ICEBs1, from Bacillus subtilis, contains at least two regions that enable conversion of ssDNA to double-stranded DNA. At least one of these regions functions as an sso (single strand origin of replication). ICEBs1 Sso activity was important for the ability of transferred ICEBs1 to be acquired by recipients and for the ability of ICEBs1 to replicate autonomously after excising from its host’s chromosome. We identified putative sso's in several other ICEs, indicating that Sso activity is likely important for the replication, stability and spread of these elements.

Bringing them together: plasmid pMV158 rolling circle replication and conjugation under an evolutionary perspective

Rolling circle-replicating plasmids constitute a vast family that is particularly abundant in, but not exclusive of, Gram-positive bacteria. These plasmids are constructed as cassettes that harbor genes involved in replication and its control, mobilization, resistance determinants and one or two origins of lagging strand synthesis. Any given plasmid may contain all, some, or just only the replication cassette. We discuss here the family of the promiscuous streptococcal plasmid pMV158, with emphasis on its mobilization functions: the product of the mobM gene, prototype of the MOBV relaxase family, and its cognate origin of transfer, oriT. Amongst the subfamily of MOBV1 plasmids, three groups of oriT sequences, represented by plasmids pMV158, pT181, and p1414 were identified. In the same subfamily, we found four types of single-strand origins, namely ssoA, ssoU, ssoW, and ssoT. We found that plasmids of the rolling-circle Rep_2 family (to which pMV158 belongs) are more frequently found in Lactobacillales than in any other bacterial order, whereas Rep_1 initiators seemed to prefer hosts included in the Bacillales order. In parallel, MOBV1 relaxases associated with Rep_2 initiators tended to cluster separately from those linked to Rep_1 plasmids. The updated inventory of MOBV1 plasmids still contains exclusively mobilizable elements, since no genes associated with conjugative transfer (other than the relaxase) were detected. These plasmids proved to have a great plasticity at using a wide variety of conjugative apparatuses. The promiscuous recognition of non-cognate oriT sequences and the role of replication origins for lagging-strand origin in the host range of these plasmids are also discussed.

Distribution of small native plasmids in Streptococcus pyogenes in India

Complete characterization of a Streptococcus pyogenes population from a defined geographic region comprises information on the plasmids that circulate in these bacteria. Therefore, we determined the distribution of small plasmids (<5kb) in a collection of 279 S. pyogenes isolates from India, where diversity of strains and incidence rates of S. pyogenes infections are high. The collection comprised 77 emm-types. For plasmid detection and discrimination, we developed PCRs for different plasmid replication initiation protein genes, the putative repressor gene copG and bacteriocin genes dysA and scnM57. Plasmid distribution was limited to 13 emm-types. Co-detection analysis using aforementioned PCRs revealed four distinct plasmid sub-types, two of which were previously unknown. Representative plasmids pA852 and pA996 of the two uncharacterized plasmid sub-types were sequenced. These two plasmids could be assigned to the pMV158 and the pC194/pUB110 family of rolling-circle plasmids, respectively. The majority of small plasmids found in India belonged to the two newly characterized sub-types, with pA852- and pA996-like plasmids amounting to 42% and 22% of all detected plasmids, respectively. None of the detected plasmids coded for a known antibiotic resistance gene. Instead, all of the four plasmid sub-types carried known or potential bacteriocin genes. These genes may have influence on the evolutionary success of certain S. pyogenes genotypes. Notably, pA852-like plasmids were found in all isolates of the most prevalent emm-type 11.0. Together, a priori fitness of this genotype and increased fitness due to the acquired plasmids may have rendered type emm11.0 successful and caused the prevalence of pA852-like plasmids in India.

Folded DNA in action: hairpin formation and biological functions in prokaryotes

Structured forms of DNA with intrastrand pairing are generated in several cellular processes and are involved in biological functions. These structures may arise on single-stranded DNA (ssDNA) produced during replication, bacterial conjugation, natural transformation, or viral infections. Furthermore, negatively supercoiled DNA can extrude inverted repeats as hairpins in structures called cruciforms. Whether they are on ssDNA or as cruciforms, hairpins can modify the access of proteins to DNA, and in some cases, they can be directly recognized by proteins. Folded DNAs have been found to play an important role in replication, transcription regulation, and recognition of the origins of transfer in conjugative elements. More recently, they were shown to be used as recombination sites. Many of these functions are found on mobile genetic elements likely to be single stranded, including viruses, plasmids, transposons, and integrons, thus giving some clues as to the manner in which they might have evolved. We review here, with special focus on prokaryotes, the functions in which DNA secondary structures play a role and the cellular processes giving rise to them. Finally, we attempt to shed light on the selective pressures leading to the acquisition of functions for DNA secondary structures.

Lagging-strand DNA replication origins are required for conjugal transfer of the promiscuous plasmid pMV158

The promiscuous streptococcal plasmid pMV158 is mobilizable by auxiliary plasmids and replicates by the rolling-circle mechanism in a variety of bacterial hosts. The plasmid has two lagging-strand origins, ssoA and ssoU, involved in the conversion of single-stranded DNA intermediates into double-stranded plasmid DNA during vegetative replication. Transfer of the plasmid also would involve conversion of single-stranded DNA molecules into double-stranded plasmid forms in the recipient cells by conjugative replication. To test whether lagging-strand origins played a role in horizontal transfer, pMV158 derivatives defective in one or in both sso's were constructed and tested for their ability to colonize new hosts by means of intra- and interspecies mobilization. Whereas either sso supported transfer between strains of Streptococcus pneumoniae, only plasmids that had an intact ssoU could be efficiently mobilized from S. pneumoniae to Enterococcus faecalis. Thus, it appears that ssoU is a critical factor for pMV158 promiscuity and that the presence of a functional sso plays an essential role in plasmid transfer.

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

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

Small rolling circle plasmids in Bacillus subtilis and related species: Organization, distribution, and their possible role in host physiology

Bacillus subtilis and related species (Bacillus licheniformis, Bacillus pumilus, Bacillus amyloliquefaciens, and Bacillus mojavensis) represent a group of bacteria largely studied and widely employed by industry. Small rolling circle replicating plasmids of this group of bacteria have been intensively studied as they represent a convenient model for genetic research and for the construction of molecular tools for the genetic modification of their hosts. Through the computational analysis of the available plasmid sequences to date, the first part of this review focuses on the main stages that the present model for rolling circle replication involves, citing the research data which helped to elucidate the mechanism by which these molecules replicate. Analysis of the distribution and phylogeny of the small RC plasmids inside the Bacillus genus is then considered, emphasizing the low level of diversity observed among these plasmids through the in silico analysis of their organization and the sequence divergence of their replication module. Finally, the parasitic vs. mutualistic nature of small rolling circle plasmids is briefly discussed.

Characterization and application of a rolling-circle-type plasmid from Cupriavidus taiwanensis

Two small cryptic plasmids, pTJ86-1 and pTJ86-2, identified in Cupriavidus taiwanensis strain TJ86, were detected and characterized. Complete sequencing of pTJ86-1 and pTJ86-2 revealed these plasmids to be 2221 and 2229bp in length with a GC content of 61.7% and 61.6%, respectively. Both plasmids harbored four open reading frames (ORF1, 2, 3 and 4). Only the predicted ORF1 gene product of both plasmids (436 amino acids) was homologous to Rep proteins previously identified on plasmids replicated using a rolling-circle replication (RCR). A double-stranded origin (DSO) of replication, highly conserved in the group III (cluster III) RCR plasmids, was identified and located immediately upstream of this putative Rep gene. In addition, both plasmids contained a putative single-stranded origin of replication (SSO) exhibiting similarity to the ssoA-type. Detection of single-stranded plasmid DNA by Southern analysis and S1 nuclease digestion confirmed that the cryptic plasmid replicated via an RCR mechanism. A potential shuttle vector, pS4-tet(R), was constructed by ligation of pTJ86-1 to the cloning vector pBluescript II SK(+) along with the insertion of a tetracycline-resistance (tet(R)) gene. It was successfully used for the transformation of genera Burkholderia and Cupriavidus.

Dysgalacticin: a novel, plasmid-encoded antimicrobial protein (bacteriocin) produced by Streptococcus dysgalactiae subsp. equisimilis

Dysgalacticin is a novel bacteriocin produced by Streptococcus dysgalactiae subsp. equisimilis strain W2580 that has a narrow spectrum of antimicrobial activity directed primarily against the principal human streptococcal pathogen Streptococcus pyogenes. Unlike many previously described bacteriocins of Gram-positive bacteria, dysgalacticin is a heat-labile 21.5 kDa anionic protein that kills its target without inducing lysis. The N-terminal amino acid sequence of dysgalacticin [Asn-Glu-Thr-Asn-Asn-Phe-Ala-Glu-Thr-Gln-Lys-Glu-Ile-Thr-Thr-Asn-(Asn)-Glu-Ala] has no known homologue in publicly available sequence databases. The dysgalacticin structural gene, dysA, is located on the indigenous plasmid pW2580 of strain W2580 and encodes a 220 aa preprotein which is probably exported via a Sec-dependent transport system. Natural dysA variants containing conservative amino acid substitutions were also detected by sequence analyses of dysA elements from S. dysgalactiae strains displaying W2580-like inhibitory profiles. Production of recombinant dysgalacticin by Escherichia coli confirmed that this protein is solely responsible for the inhibitory activity exhibited by strain W2580. A combination of in silico secondary structure prediction and reductive alkylation was employed to demonstrate that dysgalacticin has a novel structure containing a disulphide bond essential for its biological activity. Moreover, dysgalacticin displays similarity in predicted secondary structure (but not primary amino acid sequence or inhibitory spectrum) with another plasmid-encoded streptococcal bacteriocin, streptococcin A-M57 from S. pyogenes, indicating that dysgalacticin represents a prototype of a new class of antimicrobial proteins.

Deletion of pT181-like sequence in an smr-encoding mosaic plasmid harboured by a persistent bovine Staphylococcus warneri strain

OBJECTIVES

The aim was to study the persistence and characteristics of Staphylococcus warneri strains resistant to quaternary ammonium compounds (QACs), including sequencing and analysis of two plasmids proved to carry the smr gene.

METHODS

During a 3.5 year period quarter milk samples were collected on three occasions from all lactating cows in a dairy herd. The samples were screened with regard to QAC-resistant bacteria using a selective medium. Thirty randomly selected QAC-resistant S. warneri were typed by PFGE and subjected to plasmid isolation and analysis followed by gene detection using PCR. Two smr-containing plasmids in S. warneri isolates were sequenced.

RESULTS

All isolates from the initial collection of quarter milk contained smr residing on a 5.8 kb plasmid (pSW174), which contained regions with high similarities to various plasmids, including pT181, pSK108 and pPI-2. The pT181-like sequence was flanked by 148 bp direct repeats, denoted ISLE49, with high similarity to previously reported sequences of approximately 148 bp, including ISLE39 flanking the insertion sequence IS257 in methicillin-resistant Staphylococcus aureus. All isolates from subsequent collections of quarter milk harboured a smaller smr-containing plasmid (pSW49). Sequence analyses revealed pSW49 (3552 bp) to be an in-part deleted version of pSW174 (5767 bp).

CONCLUSIONS

The IS-associated elements found in this study may have a wider role in the integration and excision of DNA sequences in staphylococci than previously reported. The mosaic plasmid structure based on genetic elements of various origins contributes to further knowledge on the flexibility of smr-encoding plasmids.

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.

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

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

Complete sequence and structural organization of pFL5 and pFL7, two cryptic plasmids from Bacillus licheniformis

The complete nucleotide sequences of two plasmids, pFL5 and pFL7, isolated from soil bacteria, Bacillus licheniformis FL5 and FL7, have been determined. The plasmids pFL5 and pFL7 were analyzed and found to be 9150 and 7853 bp in size with a G+C content of 41.0 and 43.6 mol%, respectively. Computer assisted analysis of sequence data revealed 11 possible ORFs in pFL5, four of which could be assigned no function from homology searches. Instead, eight putative ORFs were identified in pFL7, two of which appeared to have no biological function. All the ORFs were preceded by a ribosome binding site. The ORFs 9.5 and 6.7, each of 340 amino acids, were postulated to encode a replication protein similar to known replication proteins of rolling circle replicons, particularly those of the pC194 family. The structural organization of the two pFL plasmids is similar to the pTA plasmids family, with only a few putative coding regions that cannot be attributed to these plasmid backbone genes. In contrast to pTA plasmids, the majority of the genes have an orientation of transcription opposite to the direction of replication. The identified probable sso sequences seem to belong to a different group of those found in Bacillus plasmids; in fact, a significant level of homology was found with ssoA group sequences. These plasmids seem to be related to plasmids identified within the Bacillus subtilis group, confirming the low-level diversity among these replicons.

Structural and functional analysis of pt38, a 2.9kb plasmid of Streptococcus thermophilus yogurt strain

The cryptic plasmid pt38 (2911 bp) of Streptococcus thermophilus ST2783, a strain isolated from Bulgarian yogurt, was subcloned and sequenced. Five ORFs (ORF1 to ORF5) were identified, although putative transcription initiation and termination signals, and Shine-Dalgarno sequence could only be localized for three of them (ORF1, ORF2, and ORF5). ORF2 would specify a 142-amino acid protein sharing a high degree of homology with plasmid-born low-molecular-weight heat stress proteins described in a variety of S. thermophilus strains. On the other hand, ORF1 would encode a 311-residue protein, which was found to be almost identical to the putative Rep proteins of previously sequenced S. thermophilus rolling circle-replicating plasmids. Intracellular single-stranded pt38 DNA was detected, showing that, in fact, the plasmid replicates via a rolling circle mechanism. A putative double-strand origin with significant homology to that of pC194, and a ssoA-type single-strand origin were also identified on the nucleotide sequence of pt38. A DNA region that can be transcribed into a small RNA (ctRNA) complementary to the leader segment of the rep (ORF1) mRNA is proposed to be involved in the control of plasmid replication. In vitro synthesis of this ctRNA was observed, and this constitutes the first report on the existence of such antisense RNAs, likely acting as regulatory elements, in S. thermophilus plasmids.

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

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

Biochemical characterization of the Staphylococcus aureus PcrA helicase and its role in plasmid rolling circle replication

Previous genetic studies have suggested that a putative chromosome-encoded helicase, PcrA, is required for the rolling circle replication of plasmid pT181 in Staphylococcus aureus. We have overexpressed and purified the staphylococcal PcrA protein and studied its biochemical properties in vitro. Purified PcrA helicase supported the in vitro replication of plasmid pT181. It had ATPase activity that was stimulated in the presence of single-stranded DNA. Unlike many replicative helicases, PcrA was highly active as a 5' --> 3' helicase and had a weaker 3' --> 5' helicase activity. The RepC initiator protein encoded by pT181 nicks at the origin of replication and becomes covalently attached to the 5' end of the DNA. The 3' OH end at the nick then serves as a primer for displacement synthesis. PcrA helicase showed an origin-specific unwinding activity with supercoiled plasmid pT181 DNA that had been nicked at the origin by RepC. We also provide direct evidence for a protein-protein interaction between PcrA and RepC proteins. Our results are consistent with a model in which the PcrA helicase is targeted to the pT181 origin through a protein-protein interaction with RepC and facilitates the movement of the replisome by initiating unwinding from the RepC-generated nick.

Plasmid rolling-circle replication: recent developments

It is now well established that a large majority of small, multicopy plasmids of Gram-positive bacteria use the rolling-circle (RC) mechanism for their replication. Furthermore, the host range of RC plasmids now includes Gram-negative organisms as well as archaea. RC plasmids can be broadly classified into at least five families, individual members of which are spread among widely different bacteria. There is significant homology in the basic replicons of plasmids belonging to a particular family, and there is compelling evidence that such plasmids have evolved from common ancestors. Major advances have recently been made in our understanding of plasmid RC replication, including the characterization of the biochemical activities of the plasmid initiator proteins and their interaction with the double-strand origin, the domain structure of the initiator proteins and the molecular basis for the function of single-strand origins in plasmid lagging strand synthesis. Over the past several years, there has been a 'renaissance' in studies on RC replication as a result of the discovery that many plasmids replicate by this mechanism, and studies in the next few years are likely to reveal new and novel mechanisms used by RC plasmids for their regulated replication.

A functional lagging strand origin does not stabilize plasmid pMV158 inheritance in Escherichia coli

Plasmid rolling circle replication generates single-stranded DNA intermediates. The intracellular amount of these molecules depends upon the efficiency of the conversion of single-stranded into double-stranded plasmid forms, that is, the functionality of the lagging strand origin (sso). The broad-host-range streptococcal plasmid pMV158 harbors two different ssos, both of which function efficiently in Streptococcus pneumoniae but poorly in Escherichia coli. Plasmid pMV158 is stably inherited in the pneumococcal host, but it is unstable in E. coli. A pMV158 derivative lacking its two ssos is unstable in both strains. We have cloned into this derivative the coliphage f1 lagging strand origin. Whereas the f1 sso was fully functional in E. coli, it did not show any activity in S. pneumoniae, a bacteria closely related to the pMV158 natural host. The presence of the f1 sso did not stabilize pMV158 inheritance in either the gram-positive or the gram-negative host.

Characterization of a single-strand origin, ssoU, required for broad host range replication of rolling-circle plasmids

Single-stranded DNA (ssDNA) promoters are the key components of the single-strand origins (ssos) of replication of rolling-circle (RC) replicating plasmids. The recognition of this origin by the host RNA polymerase and the synthesis of a short primer RNA are critical for initiation of lagging-strand synthesis. This step is thought to be a limiting factor for the establishment of RC plasmids in a broad range of bacteria, because most of the ssos described are fully active only in their natural hosts. A special type of sso, the ssoU, is unique in the sense that it can be efficiently recognized in a number of different Gram-positive hosts. We have experimentally deduced the folded structure and characterized the ssDNA promoter present within the ssoU using P1 nuclease digestion and DNase I protection assays with the Bacillus subtilis and Staphylococcus aureus RNA polymerases. We have also identified the RNA products synthesized from this ssDNA promoter and mapped the initiation points of lagging-strand synthesis in vivo from ssoU-containing plasmids. Through gel mobility shift experiments, we have found that ssDNA containing the ssoU sequence can efficiently interact with the RNA polymerase from two different Gram-positive bacteria, S. aureus and B. subtilis. We have also realigned the narrow and broad host range sso sequences of RC plasmids, and found that they contain significant homology. Our data support the notion that the strength of the RNA polymerase-ssoU interaction may be the critical factor that confers the ability on the ssoU to be fully functional in a broad range of bacteria.