The pAM beta 1 CopF repressor regulates plasmid copy number by controlling transcription of the repE gene

pSK41/pGO1-family conjugative plasmids of Staphylococcus aureus encode a cryptic repressor of replication

The majority of large multiresistance plasmids of Staphylococcus aureus utilise a RepA_N-type replication initiation protein, the expression of which is regulated by a small antisense RNA (RNAI) that overlaps the rep mRNA leader. The pSK41/pGO1-family of conjugative plasmids additionally possess a small (86 codon) divergently transcribed ORF (orf86) located upstream of the rep locus. The product of pSK41 orf86 was predicted to have a helix-turn-helix motif suggestive of a likely function in transcriptional repression. In this study, we investigated the effect of Orf86 on transcription of thirteen pSK41 backbone promoters. We found that Orf86 only repressed transcription from the rep promoter, and hence now redesignate the product as Cop. Over-expression of Cop in trans reduced the copy number of pSK41 mini-replicons, both in the presence and absence of rnaI. in vitro protein-DNA binding experiments with purified 6 × His-Cop demonstrated specific DNA binding, adjacent to, and partially overlapping the -35 hexamer of the rep promoter. The crystal structure of Cop revealed a dimeric structure similar to other known transcriptional regulators. Cop mRNA was found to result from "read-through" transcription from the strong RNAI promoter that escapes the rnaI terminator. Thus, PrnaI is responsible for transcription of two distinct negative regulators of plasmid copy number; the antisense RNAI that primarily represses Rep translation, and Cop protein that can repress rep transcription. Deletion of cop in a native plasmid did not appear to impact copy number, indicating a cryptic auxiliary role.

Plasmid Replicons for the Production of Pharmaceutical-Grade pDNA, Proteins and Antigens by Lactococcus lactis Cell Factories

The Lactococcus lactis bacterium found in different natural environments is traditionally associated with the fermented food industry. But recently, its applications have been spreading to the pharmaceutical industry, which has exploited its probiotic characteristics and is moving towards its use as cell factories for the production of added-value recombinant proteins and plasmid DNA (pDNA) for DNA vaccination, as a safer and industrially profitable alternative to the traditional Escherichia coli host. Additionally, due to its food-grade and generally recognized safe status, there have been an increasing number of studies about its use in live mucosal vaccination. In this review, we critically systematize the plasmid replicons available for the production of pharmaceutical-grade pDNA and recombinant proteins by L. lactis. A plasmid vector is an easily customized component when the goal is to engineer bacteria in order to produce a heterologous compound in industrially significant amounts, as an alternative to genomic DNA modifications. The additional burden to the cell depends on plasmid copy number and on the expression level, targeting location and type of protein expressed. For live mucosal vaccination applications, besides the presence of the necessary regulatory sequences, it is imperative that cells produce the antigen of interest in sufficient yields. The cell wall anchored antigens had shown more promising results in live mucosal vaccination studies, when compared with intracellular or secreted antigens. On the other side, engineering L. lactis to express membrane proteins, especially if they have a eukaryotic background, increases the overall cellular burden. The different alternative replicons for live mucosal vaccination, using L. lactis as the DNA vaccine carrier or the antigen producer, are critically reviewed, as a starting platform to choose or engineer the best vector for each application.

Plasmid Copy Number of pTRKH3 in Lactococcus lactis is Increased by Modification of the repDE Ribosome-Binding Site

Plasmids for DNA vaccination are exclusively produced in the Gram-negative Escherichia coli. One important drawback of this system is the presence of lipopolysaccharides. The generally recognized as safe Lactococcus lactis (L. lactis) would constitute a safer alternative for plasmid production. A key requirement for the establishment of a cost-effective L. lactis-based plasmid manufacturing is the availability of high-copy number plasmids. Unfortunately, the highest copy number reported in Gram-positive bacteria for the pAMβ1 replicon is around 100 copies. The purpose of this work is to engineer the repDE ribosome-binding site (RBS) of the pTRKH3 plasmid by site-directed mutagenesis in order to increase the plasmid copy number in L. lactis LMG19460 cells. The pTRKH3-b mutant is the most promising candidate, achieving 215 copies of plasmid per chromosome, a 3.5-fold increase when compared to the nonmodified pTRKH3, probably due to a stronger RBS sequence, a messenger RNA secondary structure that promotes the RepDE expression, an ideal intermediate amount of transcriptional repressors and the presence of a duplicated region that added an additional RBS sequence and one new in-frame start codon. pTRKH3-b is a promising high-copy number shuttle plasmid that will contribute to turn lactic acid bacteria into a safer and economically viable alternative as DNA vaccines producers.

Broad-host-range Inc18 plasmids: Occurrence, spread and transfer mechanisms

Conjugative plasmid transfer is one of the major mechanisms responsible for the spread of antibiotic resistance and virulence genes. The incompatibility (Inc) 18 group of plasmids is a family of plasmids replicating by the theta-mechanism, whose members have been detected frequently in enterococci and streptococci. Inc18 plasmids encode a variety of antibiotic resistances, including resistance to vancomycin, chloramphenicol and the macrolide-lincosamide-streptogramine (MLS) group of antibiotics. These plasmids comprising insertions of Tn1546 were demonstrated to be responsible for the transfer of vancomycin resistance encoded by the vanA gene from vancomycin resistant enterococci (VRE) to methicillin resistant Staphylococcus aureus (MRSA). Thereby vancomycin resistant S. aureus (VRSA) were generated, which are serious multi-resistant pathogens challenging the health care system. Inc18 plasmids are widespread in the clinic and frequently have been detected in the environment, especially in domestic animals and wastewater. pIP501 is one of the best-characterized conjugative Inc18 plasmids. It was originally isolated from a clinical Streptococcus agalactiae strain and is, due to its small size and simplicity, a model to study conjugative plasmid transfer in Gram-positive bacteria. Here, we report on the occurrence and spread of Inc18-type plasmids in the clinic and in different environments as well as on the exchange of the plasmids among them. In addition, we discuss molecular details on the transfer mechanism of Inc18 plasmids and its regulation, as exemplified by the model plasmid pIP501. We finish with an outlook on promising approaches on how to reduce the emerging spread of antibiotic resistances.

Crosstalk between vertical and horizontal gene transfer: plasmid replication control by a conjugative relaxase

Horizontal gene transfer is a key process in the evolution of bacteria and also represents a source of genetic variation in eukaryotes. Among elements participating in gene transfer, thousands of small (<10 kb) mobile bacterial plasmids that replicate by the rolling circle mechanism represent a driving force in the spread of antibiotic resistances. In general, these plasmids are built as genetic modules that encode a replicase, an antibiotic-resistance determinant, and a relaxase that participates in their conjugative mobilization. Further, they control their relatively high copy number (∼30 copies per genome equivalent) by antisense RNAs alone or combined with a repressor protein. We report here that the MobM conjugative relaxase encoded by the promiscuous plasmid pMV158 participates in regulation of the plasmid copy number by transcriptional repression of the antisense RNA, thus increasing the number of plasmid molecules ready to be horizontally transferred (mobilization) and/or vertically inherited (replication). This type of crosstalk between genetic modules involved in vertical and horizontal gene flow has not been reported before.

DNA-Binding Proteins Regulating pIP501 Transfer and Replication

pIP501 is a Gram-positive broad-host-range model plasmid intensively used for studying plasmid replication and conjugative transfer. It is a multiple antibiotic resistance plasmid frequently detected in clinical Enterococcus faecalis and Enterococcus faecium strains. Replication of pIP501 proceeds unidirectionally by a theta mechanism. The minimal replicon of pIP501 is composed of the repR gene encoding the essential rate-limiting replication initiator protein RepR and the origin of replication, oriR, located downstream of repR. RepR is similar to RepE of related streptococcal plasmid pAMβ1, which has been shown to possess RNase activity cleaving free RNA molecules in close proximity of the initiation site of DNA synthesis. Replication of pIP501 is controlled by the concerted action of a small protein, CopR, and an antisense RNA, RNAIII. CopR has a dual function: It acts as transcriptional repressor at the repR promoter and, in addition, prevents convergent transcription of RNAIII and repR mRNA (RNAII), which indirectly increases RNAIII synthesis. CopR binds asymmetrically as a dimer at two consecutive binding sites upstream of and overlapping with the repR promoter. RNAIII induces transcriptional attenuation within the leader region of the repR mRNA (RNAII). Deletion of either control component causes a 10- to 20-fold increase of plasmid copy number, while simultaneous deletions have no additional effect. Conjugative transfer of pIP501 depends on a type IV secretion system (T4SS) encoded in a single operon. Its transfer host-range is considerably broad, as it has been transferred to virtually all Gram-positive bacteria including Streptomyces and even the Gram-negative Escherichia coli. Expression of the 15 genes encoding the T4SS is tightly controlled by binding of the relaxase TraA, the transfer initiator protein, to the operon promoter overlapping with the origin of transfer (oriT). The T4SS operon encodes the DNA-binding proteins TraJ (VirD4-like coupling protein) and the VirB4-like ATPase, TraE. Both proteins are actively involved in conjugative DNA transport. Moreover, the operon encodes TraN, a small cytoplasmic protein, whose specific binding to a sequence upstream of the oriT nic-site was demonstrated. TraN seems to be an effective repressor of pIP501 transfer, as conjugative transfer rates were significantly increased in an E. faecalis pIP501ΔtraN mutant.

Plasmid Replication Control by Antisense RNAs

Plasmids are selfish genetic elements that normally constitute a burden for the bacterial host cell. This burden is expected to favor plasmid loss. Therefore, plasmids have evolved mechanisms to control their replication and ensure their stable maintenance. Replication control can be either mediated by iterons or by antisense RNAs. Antisense RNAs work through a negative control circuit. They are constitutively synthesized and metabolically unstable. They act both as a measuring device and a regulator, and regulation occurs by inhibition. Increased plasmid copy numbers lead to increasing antisense-RNA concentrations, which, in turn, result in the inhibition of a function essential for replication. On the other hand, decreased plasmid copy numbers entail decreasing concentrations of the inhibiting antisense RNA, thereby increasing the replication frequency. Inhibition is achieved by a variety of mechanisms, which are discussed in detail. The most trivial case is the inhibition of translation of an essential replication initiator protein (Rep) by blockage of the rep-ribosome binding site. Alternatively, ribosome binding to a leader peptide mRNA whose translation is required for efficient Rep translation can be prevented by antisense-RNA binding. In 2004, translational attenuation was discovered. Antisense-RNA-mediated transcriptional attenuation is another mechanism that has, so far, only been detected in plasmids of Gram-positive bacteria. ColE1, a plasmid that does not need a plasmid-encoded replication initiator protein, uses the inhibition of primer formation. In other cases, antisense RNAs inhibit the formation of an activator pseudoknot that is required for efficient Rep translation.

Antisense-RNA mediated control of plasmid replication - pIP501 revisited

Over the past decade, a wealth of small noncoding RNAs (sRNAs) have been discovered in the genomes of almost all bacterial species, where they constitute the most abundant class of posttranscriptional regulators. These sRNAs are key-players in prokaryotic metabolism, stress response and virulence. However, the first bona-fide antisense RNAs had been found already in 1981 in plasmids, where they regulate replication or maintenance. Antisense RNAs involved in plasmid replication control - meanwhile investigated in depth for almost 35 years - employ a variety of mechanisms of action: They regulate primer maturation, inhibit translation of essential replication initiator proteins (Rep proteins) as well as leader peptides or the formation of activator pseudoknots required for efficient rep translation. Alternatively they attenuate transcription or translation of rep mRNAs. Some antisense RNAs collaborate with transcriptional repressors to ensure proper copy-number control. Here, I summarize our knowledge on replication control of the broad-host range plasmid pIP501 that was originally isolated from Streptococcus agalactiae. Plasmid pIP501 uses two copy number-control elements, RNAIII, a cis-encoded antisense RNA, and transcriptional repressor CopR. RNA III mediates transcription attenuation, a rather widespread concept that found its culmination in the recent discovery of riboswitches. A peculiarity of pIP501 is the unusual stability of RNA III, which requires a second function of CopR: CopR does not only repress transcription from the essential repR promoter, but also prevents convergent transcription between rep mRNA and RNAIII, thereby indirectly increasing the amount of RNAIII. The concerted action of these two control elements is necessary to prevent plasmid loss at dangerously low copy numbers.

Plasmid pSM19035, a model to study stable maintenance in Firmicutes

pSM19035 is a low-copy-number theta-replicating plasmid, which belongs to the Inc18 family. Plasmids of this family, which show a modular organization, are functional in evolutionarily diverse bacterial species of the Firmicutes Phylum. This review summarizes our understanding, accumulated during the last 20 years, on the genetics, biochemistry, cytology and physiology of the five pSM19035 segregation (seg) loci, which map outside of the minimal replicon. The segA locus plays a role both in maximizing plasmid random segregation, and in avoiding replication fork collapses in those plasmids with long inverted repeated regions. The segB1 locus, which acts as the ultimate determinant of plasmid maintenance, encodes a short-lived epsilon(2) antitoxin protein and a long-lived zeta toxin protein, which form a complex that neutralizes zeta toxicity. The cells that do not receive a copy of the plasmid halt their proliferation upon decay of the epsilon(2) antitoxin. The segB2 locus, which encodes two trans-acting, ParA- and ParB-like proteins and six cis-acting parS centromeres, actively ensures equal or roughly equal distribution of plasmid copies to daughter cells. The segC locus includes functions that promote the shift from the use of DNA polymerase I to the replicase (PolC-PolE DNA polymerases). The segD locus, which encodes a trans-acting transcriptional repressor, omega(2), and six cis-acting cognate sites, coordinates the expression of genes that control copy number, better-than-random segregation and partition, and assures the proper balance of these different functions. Working in concert the five different loci achieve almost absolute plasmid maintenance with a minimal growth penalty.

Vectors for Lactobacilli and other Gram-positive bacteria based on the minimal replicon of pRV500 from Lactobacillus sakei

The low-copy-number plasmid pRV500, belonging to the pUCL287 group of theta-type plasmids, was previously isolated from Lactobacillus sakei and characterized. We show here that the replicon of this plasmid enables replication also in Enterococcus faecalis and Bacillus subtilis but not in Lactococcus lactis. A 1.25 kb region encompassing the iterons and the repA gene was sufficient for replication, copy-number control and relative stable maintenance in L. sakei. Functional implications of host or plasmid-borne factors in the maintenance of pUCL287-type plasmids are discussed. The minimal replicon from pRV500 was fused to pBluescript for constructing the shuttle E. coli/lactobacilli cloning vector pRV610. pRV610 enables the white/blue lacZ alpha-complementation in E. coli. The cassettes for selection (erythromycin resistance) and replication (iterons and repA gene) are each bordered by unique restriction sites for easy replacement if needed. Derivatives in which chloramphenicol or tetracycline resistance replaced erythromycin resistance were constructed. In order to allow inducible gene expression, a copper-inducible promoter was placed on the pRV613 derivative. Expression of the downstream reporter gene lacZ was shown to be induced by 30 microM CuSO(4).

Improvement of a nisin-inducible expression vector for use in lactic acid bacteria

The plasmid pMSP3535 is a popular vector for nisin-inducible expression of heterologous genes in lactic acid bacteria. However, the maximum protein expression level achievable with pMSP3535 is relatively low. In an effort to increase expression we modified pMSP3535 to create a high expression variant termed pMSP3535H2. Modifications included removal of a small NisA peptide fragment from the P nisA promoter and addition of a bidirectional transcription terminator. In addition the plasmid copy number was increased by replacing the pMSP3535 copy number control region with that of a high copy variant of the same replicon. As a result of these modifications, expression of two target proteins, the green fluorescent protein and the Escherichia coli antigen intimin, increased 5.0- and 7.5-fold, respectively. The increased range of inducible expression achieved with pMSP3535H2 will facilitate molecular studies in a range of lactic acid bacteria.

Construction and evaluation of food-grade vectors for Lactococcus lactis using aspartate aminotransferase and alpha-galactosidase as selectable markers

AIMS

We report development of two food-grade cloning vectors for Lactococcus lactis, which utilize either a lactococcal aspartate aminotransferase gene (aspC), or Bifidobacterium longumalpha-galactosidase gene (aglL) as selectable markers.

METHODS AND RESULTS

The theta-replicon of lactococcal plasmid, pW563, was combined with aspC and a multiple cloning site. When electroporated into L. lactis JLS400 (AspC-), the resulting vector, pSUW611 (3.9 kbp), restores ability of the mutant to grow in milk thus allowing for selection of the transformants. The vector is stable during 100 generations of nonselective growth (0.2% loss per generation). The second vector, pSUW711 (5.1 kbp), was constructed by exchanging aspC with aglL under the control of usp45 promoter. Lactococcus lactis transformed with pSUW711 produced distinctive colonies within 48-72 h on melibiose-containing plates. Expression of two Lactobacillus helveticus peptidases was attempted using these new vehicles. Introduction of pepN on pSUW611 and pSUW711 into L. lactis led to a sixfold, or 27-fold increase in aminopeptidase activity, respectively. However, no changes in endopeptidase activity were recorded upon transformation with pSUW611 carrying pepO2 under control of three different promoters. Attempts were also made to construct high copy variants of pSUW711.

CONCLUSIONS

The aspC and aglL can be employed as food-grade genetic markers for L. lactis. The vectors, pSUW611 and pSUW711, were successfully used to express Lact. helveticus PepN in L. lactis.

SIGNIFICANCE AND IMPACT OF THE STUDY

Two novel food-grade vectors were developed which provide simple and convenient selection and maintenance in L. lactis.

Distinctive genetic features exhibited by the Y-family DNA polymerases in Bacillus subtilis

Translesional DNA polymerases form a large family of structurally related proteins, known as the Y-polymerases. Bacillus subtilis encodes two Y-polymerases, referred herewith as Pol Y1 and Pol Y2. Pol Y1 was expressed constitutively and did not mediate UV mutagenesis. Pol Y1 overexpression increased spontaneous mutagenesis. This effect depended on Pol Y1 polymerase activity, Pol Y1 interaction with the beta-clamp, and did not require the presence of the RecA protein. In addition, Pol Y1 overexpression delayed cell growth at low temperature. The growth delay was mediated by Pol Y1 interaction with the beta-clamp but not by its polymerase activity, suggesting that an excess of Pol Y1 in the cell could sequester the beta-clamp. In contrast, Pol Y2 was expressed during the SOS response, and, in its absence, UV-induced mutagenesis was abolished. Upon Pol Y2 overproduction, both UV-induced and spontaneous mutagenesis were stimulated, and both depended on the Pol Y2 polymerase activity. However, UV mutagenesis did not appear to require the interaction of Pol Y2 with the beta-clamp whereas spontaneous mutagenesis did. In addition, Pol Y2-mediated spontaneous mutagenesis required the presence of RecA. Together, these results show that the regulation and the genetic requirements of the two B. subtilis Y-polymerases are different, indicating that they fulfil distinct biological roles. Remarkably, Pol Y1 appears to exhibit a mutator activity similar to that of Escherichia coli Pol IV, as well as an E. coli UmuD-related function in growth delay. Pol Y2 exhibits an E. coli Pol V-like mutator activity, but probably acts as a single polypeptide to bypass UV lesions. Thus, B. subtilis Pol Y1 and Pol Y2 exhibit distinctive features from the E. coli Y-polymerases, indicating that different bacteria have adapted different solutions to deal with the lesions in their genetic material.

Intergeneric transfer of the Enterococcus faecalis plasmid pIP501 to Escherichia coli and Streptomyces lividans and sequence analysis of its tra region

The nucleotide sequence of the transfer (tra) region of the multiresistance broad-host-range Inc18 plasmid pIP501 was completed. The 8629-bp DNA sequence encodes 10 open reading frames (orf), 9 of them are possibly involved in pIP501 conjugative transfer. The putative pIP501 tra gene products show highest similarity to the respective ORFs of the conjugative Enterococcus faecalis plasmids pRE25 and pAMbeta1, and the Streptococcus pyogenes plasmid pSM19035, respectively. ORF7 and ORF10 encode putative homologues of type IV secretion systems involved in transport of effector molecules from pathogens to host cells and in conjugative plasmid transfer in Gram-negative (G-) bacteria. pIP501 mobilized non-selftransmissible plasmids such as pMV158 between different E. faecalis strains and from E. faecalis to Bacillus subtilis. Evidence for the very broad-host-range of pIP501 was obtained by intergeneric conjugative transfer of pIP501 to a multicellular Gram-positive (G+) bacterium, Streptomyces lividans, and to G- Escherichia coli. We proved for the first time pIP501 replication, expression of its antibiotic resistance genes as well as functionality of the pIP501 tra genes in S. lividans and E. coli.

Transcriptional repressor CopR: the structured acidic C terminus is important for protein stability

The transcriptional repressor CopR is one of the two copy-number control components of plasmid pIP501. CopR binds as a dimer at two consecutive major grooves on the same face of the DNA. Previously, equilibrium dissociation constants of CopR dimers and the CopR-DNA complex and the intracellular CopR concentration were calculated. Amino acid residues involved in DNA binding and dimerization were determined. Here, we provide a detailed analysis of the acidic C terminus of CopR. A series of C-terminally truncated CopR mutants were analysed with regard to activity and half-life in vivo and DNA binding, dimerization, structure and stability in vitro. The last 29 amino acid residues of CopR were not essential for DNA binding and dimerization but for protein stability. However, whereas CopDelta20 was, in spite of drastically shortened half-life, still 100 % active in vivo, CopDelta24 and CopDelta27 retained only 20 % activity. In vivo stability could be restored only partially by adding a C-terminal tail previously shown to stabilize the lambda repressor N terminus. However, substitution of seven Glu residues by Lys within the last 20 residues drastically reduced half-life. Our results clearly demonstrate that the acidic C terminus is important for the stability of CopR. Using CD-measurements we show that the C terminus of CopR is structured.

Transcriptional repressor CopR: amino acids involved in forming the dimeric interface

Plasmid pIP501 encoded transcriptional repressor CopR is one of the two regulators of plasmid copy number. It acts as a transcriptional repressor at the essential repR promoter. Furthermore, CopR prevents convergent transcription from the repR and the antisense promoter, thereby indirectly increasing the amount of antisense-RNA, the second regulatory component. CopR binds as a dimer to a nearly palindromic operator with the consensus sequence 5'CGTG. Previously, a CopR structural model was built and used to identify amino acids involved in DNA binding. These data showed that CopR is a HTH protein belonging to the lambda repressor superfamily and allowed the identification of two amino acids involved in specific DNA recognition. Here, we describe site-directed mutagenesis in combination with EMSA, dimerization studies using sedimentation equilibrium, and CD measurements to verify the model predictions concerning amino acids involved in dimerization. With this approach, the dimeric interface could be located between amino acids I44 and L62. F5 located at the N-terminus is additionally required for proper folding, and could, therefore, not be unequivocally assigned to the dimeric interface. CD measurements at protein concentrations well below K(Dimer) revealed that the monomer of CopR is folded.

A study of the CopF repressor of plasmid pAMbeta1 by phage display

We studied DNA binding of a transcriptional repressor, CopF, displayed on a filamentous phage. Mutagenesis of a putative helix-turn-helix motif of CopF and of certain bases of the operator abolished the protein-DNA interaction, establishing the elements involved in CopF function and showing that phage display can be used to study repressor proteins.

Plasmid copy-number control and better-than-random segregation genes of pSM19035 share a common regulator

Transcription initiation of the copy-number control and better-than-random segregation genes of the broad-host-range and low-copy-number plasmid pSM19035 are subjected to repression by the autoregulated pSM19035-encoded omega product in Bacillus subtilis cells. The promoters of the copS (Pcop1 and Pcop2), delta (Pdelta), and omega (Pomega) genes have been mapped. These promoters are embedded in a set of either seven copies of a 7-bp direct repeat or in a block consisting of two 7-bp direct repeats and one 7-bp inverted repeat; the blocks are present either two or three times. The cooperative binding of omega protein to the repeats on the Pcop1, Pcop2, Pdelta, and Pomega promoters represses transcription initiation by a mechanism that does not exclude sigma(A)RNAP from the promoters. These results indicate that omega protein regulates plasmid maintenance by controlling the copy number on the one hand and by regulating the amount of proteins required for better-than-random segregation on the other hand.

Regulation of expression of the Lactococcus lactis histidine operon

In Lactococcus lactis, the his operon contains all the genes necessary for histidine biosynthesis. It is transcribed from a unique promoter, localized 300 bp upstream of the first gene. The region corresponding to the untranslated 5' end of the transcript, named the his leader region, displays the typical features of the T box transcriptional attenuation mechanism which is involved in the regulation of many amino acid biosynthetic operons and tRNA synthetase genes in gram-positive bacteria. Here we describe the regulation of transcription of the his operon by the level of histidine in the growth medium. In the absence of histidine, two transcripts are present. One covers the entire operon, while the other stops at a terminator situated about 250 bp downstream of the transcription start point. DNA sequences implicated in regulation of the his operon were identified by transcriptional fusion with luciferase genes and site-directed mutagenesis. In addition to the previously defined sequences necessary for effective T-box-mediated regulation, new essential regions were identified. Eighteen percent of the positions of the his leader region were found to differ in seven distantly related strains of L. lactis. Analysis of the variable positions supports the folding model of the central part of the his leader region. Lastly, in addition to the T-box-mediated regulation, the operon is regulated at the level of initiation of transcription, which is repressed in the presence of histidine. An operator site, necessary for full repression, overlaps the terminator involved in the T box attenuation mechanism. The functionality of the operator is altered on plasmids with low and high copy numbers, suggesting that supercoiling may play a role in the expression of the his operon. The extents of regulation at the levels of initiation and attenuation of transcription are 6- to 8-fold and 14-fold, respectively. Together, the two levels of control allow a 120-fold range of regulation of the L. lactis operon by histidine.

Plasmid pIP501 encoded transcriptional repressor CopR binds to its target DNA as a dimer

The CopR protein is one of the two regulators of pIP501 copy number. It acts as transcriptional repressor at the essential repR promoter pII. Previously, we found that CopR contacts two consecutive major grooves (site I and site II) on the same face of the DNA. In spite of identical sequence motifs in these sites, neighboring bases were contacted differently. Furthermore, we showed that CopR can dimerize in solution. We demonstrate by two independent methods that CopR binds the DNA as a dimer. We present data that suggest that the sigmoidal CopR-DNA binding curve published previously is the result of two coupled equilibria: dimerization of CopR monomers and CopR dimer-DNA binding. A KD-value of 1.44(+/-0.49)x10(-6) M for CopR dimers was determined by analytical ultracentrifugation. Based on this value and the binding curve, the equilibrium dissociation constant K2 for the CopR-DNA complex was calculated to be 4(+/-1. 3)x10(-10) M. Quantitative Western blot analysis was used to determine the intracellular concentration of CopR in Bacillus subtilis. This value, 20x10(-6) to 30x10(-6) M, is 10 to 20-fold higher than the equilibrium constant for dimer dissociation, suggesting that CopR binds in vivo as a preformed dimer.

Transcription-driven DNA replication of plasmid pAMbeta1 in Bacillus subtilis

pAMbeta1 is a plasmid isolated from Enterococcus faecalis which replicates in Bacillus subtilis by a unidirectional theta mechanism. It has been shown previously that initiation of pAMbeta1 replication requires a plasmid-encoded protein (RepE) and a short origin and is carried out by the host DNA polymerase I. It is not known which primer is used by this polymerase for initiating replication. Here, we report that a transcription fork passing through the origin is a limiting factor for plasmid replication. Transcription that activates the origin is initiated at the repE promoter and is thus regulated by the plasmid copy-number control system. Two lines of evidence suggest that the transcription generates the primer for the DNA polymerase I. First, the transcription must start upstream from the origin and progress in the direction of replication to be effective. Second, 3' ends of RNA transcripts initiated upstream of the origin map within the origin, provided that the Rep protein and an intact origin are present. This is the first report for simultaneous requirement of a transcription fork, a replication protein and the DNA polymerase I in initiation of DNA replication.

Inhibition of a naturally occurring rolling-circle replicon in derivatives of the theta-replicating plasmid pIP501

The mechanisms ensuring regulation of DNA replication in genomes containing multiple replicons are poorly understood. In this report, we addressed this question by analysing in Bacillus subtilis the replication of a derivative of the promiscuous plasmid pIP501 that carries a rolling-circle and a theta replicon. Genetic analyses revealed that the rolling-circle replicon is strongly inhibited in the derivative and that inhibition requires three elements involved in theta replication: the replication origin, the initiator RepR protein and strong transcription of the repR gene. Inhibition is, however, independent of DNA synthesis at the theta origin. We conclude that rolling-circle inhibition is caused by an inhibitory signal encoded by the theta replicon and propose that the signal is composed, at least, of the RepR protein bound to its cognate origin.

Dual function of the copR gene product of plasmid pIP501

Replication of plasmid pIP501 is regulated at a step subsequent to transcription initiation by an antisense RNA (RNAIII) and transcriptionally by a repressor protein, CopR. Previously, it had been shown that CopR binds to a 44-bp DNA fragment upstream of and overlapping the repR promoter pII. Subsequently, we found that high-copy-number pIP501 derivatives lacking copR and low-copy-number derivatives containing copR produced the same intracellular amounts of RNAIII. This suggested a second, hitherto-unknown function of CopR. In this report, we show that CopR does not affect the half-life of RNAIII. Instead, we demonstrate in vivo that, in the presence of both pII and pIII, CopR provided in cis or in trans causes an increase in the intracellular concentration of RNAIII and that this effect is due to the function of the protein rather than its mRNA. We suggest that, in the absence of CopR, the increased (derepressed) RNAII transcription interferes, in cis, with initiation of transcription of RNAIII (convergent transcription), resulting in a lower RNAIII/plasmid ratio. When CopR is present, the pII promoter is repressed to >90%, so that convergent transcription is mostly abolished and RNAIII/plasmid ratios are high. The hypothesis that RNAII transcription influences promoter pIII through induced changes in DNA supercoiling is supported by the finding that the gyrase inhibitor novobiocin affects the accumulation of both sense and antisense RNA. The dual role of CopR in repression of RNAII transcription and in prevention of convergent transcription is discussed in the context of replication control of pIP501.

Plasmid pIP501 encoded transcriptional repressor CopR binds asymmetrically at two consecutive major grooves of the DNA

Replication of the streptococcal plasmid pIP501 is regulated by the CopR protein and an antisense-RNA (RNAIII). CopR acts as transcriptional repressor at the essential repR promoter pII by binding to inverted repeat IR1 upstream of pII. To further characterize the interaction of CopR with its target, footprinting studies were performed. Methylation interference identified three guanine bases (G240, G242 and G251) in the top strand and two (G252 and G254) in the bottom strand contacted by CopR in the major groove of the DNA. Missing base interference revealed the contribution of the bases in the neighbourhood of these guanine bases to the specific DNA-protein contacts. Phosphate residues essential for CopR binding were determined by ethylation interference. The recognition sequence was localized at the centre of inverted repeat IR1. CopR contacts two consecutive major grooves (site I and II) on the same face of the DNA. Although the two sites share a common sequence motif, neighbouring bases are contacted differently. DNA fragments carrying single mutations in site I or II were analysed by band shift assays. Gel filtration and native gel electrophoresis demonstrated that CopR exists only as a dimer. A sigmoidal binding curve of CopR to its DNA target was observed and allowed the determination of the apparent dissociation constant K(D). The significance of the relatively high apparent K(D) for the role of CopR in pIP501 copy number regulation is discussed.

Plasmid vectors for gram-positive bacteria switching from high to low copy number

A set of vectors for Gram-positive bacteria was constructed with a new feature which enables the switching down of their copy number per cell. These vectors carry the replication region of pAM beta 1, containing a gene essential for replication, repE, and its regulator, copF. The latter gene was inactivated by inserting a linker into its unique KpnI site. Since copF downregulates the expression of repE, its inactivation leads to an increase in the plasmid copy number per cell. The original low copy state can be restored by removal of the linker via KpnI cleavage and ligation. The new replicon was used to build (i) vectors for studying gene regulation by transcriptional or translational fusion with the bacterial luciferase gene, (ii) vectors for gene expression, and (iii) cassettes of the replicon with different multiple cloning sites, which would facilitate construction of vectors for novel purposes.

Countertranscript-driven attenuation system of the pAM beta 1 repE gene

The plasmid-encoded RepE protein is absolutely essential and rate-limiting for replication of the promiscuous plasmid pAM beta 1 originating from Enterococcus faecalis. We previously showed that the rep gene is transcribed from a promoter that is negatively regulated (approximately 10-fold reduction) by the CopF repressor. In this report, we show that this transcription is decreased a further approximately 10-times by a countertranscript-driven transcriptional attenuation system. Extensive mutagenesis revealed that this system operates by a mechanism similar to that previously described for the unrelated repC gene of plasmid pT181.

An unusually long-lived antisense RNA in plasmid copy number control: in vivo RNAs encoded by the streptococcal plasmid pIP501

The main regulator of pIP501 replication is an antisense RNA (RNAIII) that induces transcriptional attenuation of the essential RNAII. Previous studies identified the termination point in vivo and demonstrated attenuation in vitro. This in vivo analysis confirms the appearance of attenuated RNAII dependent on RNAIII. Half-lives and intracellular levels of RNAII and RNAIII were determined: in a Bacillus subtilis cell harboring a wild-type pIP501 plasmid, approximately 50 molecules RNAII and 1000 to 2000 molecules of RNAIII were measured, respectively. The half-life of RNAII was in the range of that of other target RNAs, whereas that of RNAIII (approximately 30 minutes) was unusually long, representing a so far unprecedented case of a metabolically stable antisense RNA regulating plasmid copy number. Long antisense RNA half-life is predicted to yield sluggish control and instability of maintenance. We propose a model for how plasmid pIP501 may avoid this problem by using both the repressor CopR and the antisense RNAIII for control. Four stem-loop mutants of RNAII/RNAIII with elevated copy numbers were characterized for in vitro antisense/target RNA binding, RNAIII half-life, incompatibility, and attenuation in vivo. Two classes were found: interaction mutants and half-life mutants. The former suggest a key function for loop LIII of RNAIII as recognition loop in the primary steps of RNAII/RNAIII interaction.

Molecular tools for the study of transcriptional regulation in Bacillus anthracis

Bacillus anthracis produces two toxins composed of three proteins. Genetic tools were constructed to study the regulation of toxin synthesis. They included transcriptional fusions with various reporter genes, in replicative and integrative vectors. The reporter gene xylE, encoding catechol 2,3-dioxygenase, may be valuable for screening of strong promoters, as expression of the gene can be visualized directly and the studies of regulation in B. anthracis. Therefore, transcriptional fusions between a lacZ reporter gene and the toxin genes were constructed. Experiments with a multicopy plasmid in trans suggested that the transcriptional activator(s) of the toxin genes were not titrated. B. anthracis strains, which contain pXO1 carrying multiple copies of fusions, were analysed. Expression of the reporter gene was proportional to the fusion copy number. Indeed, single integration of a suicide plasmid can be distinguished from multiple integration according to the level of resistance to an appropriate antibiotic. Finally, recombination in B. anthracis was found to be very efficient (approximately 10(-2) recombinants per transconjugant cell.

Characterization of the replication region of the Bacillus subtilis plasmid pLS20: a novel type of replicon

A 3.1 kb fragment of the large (approximately 55 kb) Bacillus subtilis plasmid pLS20 containing all the information for autonomous replication was cloned and sequenced. In contrast to the parental plasmid, derived minireplicons were unstably maintained. Using deletion analysis the fragment essential and sufficient for replication was delineated to 1.1 kb. This 1.1 kb fragment is located between two divergently transcribed genes, denoted orfA and orfB, neither of which is required for replication. orfA shows homology to the B.subtilis chromosomal genes rapA (spoOL, gsiA) and rapB (spoOP). The 1.1 kb fragment, which is characterized by the presence of several regions of dyad symmetry, contains no open reading frames of more than 85 codons and shows no similarity with other known plasmid replicons. The structural organization of the pLS20 minimal replicon is entirely different from that of typical rolling circle plasmids from Gram-positive bacteria. The pLS20 minireplicons replicate in polA5 and recA4 B.subtilis strains. Taken together, these results strongly suggest that pLS20 belongs to a new class of theta replicons.

The copR gene product of plasmid pIP501 acts as a transcriptional repressor at the essential repR promoter

The amount of the rate-limiting replication initiator protein RepR of plasmid pIP501 is negatively controlled by an antisense RNA (RNAIII) and a dispensable protein (CopR). Deletions or mutations in either component cause a 10-20-fold copy number increase. RNAIII induces transcription attenuation of the repR mRNA; the mode of CopR action remained unclear. To test the function of CopR, transcriptional fusions of promoters pI, pII and pIII with lacZ were integrated into the Bacillus subtilis chromosome. CopR and/or RepR were supplied in trans, and LacZ synthesis measured. The results show that CopR represses the repR promoter pII. Neither CopR nor RepR autoregulate their promoters. Gel mobility shift assays indicate that CopR binds to a 44 bp DNA fragment comprising the inverted repeat upstream of pII.