Genes and sites involved in replication and incompatibility of an R100 plasmid derivative based on nucleotide sequence analysis

Calcium-responsive plasmid copy number regulation is dependent on discrete YopD domains in Yersinia pseudotuberculosis

Yersinia pathogenicity depends mainly on a Type III Secretion System (T3SS) responsible for translocating effector proteins into the eukaryotic target cell cytosol. The T3SS is encoded on a 70 kb, low copy number virulence plasmid, pYV. A key T3SS regulator, YopD, is a multifunctional protein and consists of discrete modular domains that are essential for pore formation and translocation of Yop effectors. In Y. pseudotuberculosis, the temperature-dependent plasmid copy number increase that is essential for elevated T3SS gene dosage and virulence is also affected by YopD. Here, we found that the presence of intracellular YopD results in increased levels of the CopA-RNA and CopB, two inhibitors of plasmid replication. Secretion of YopD leads to decreased expression of copA and copB, resulting in increased plasmid copy number. Moreover, using a systematic mutagenesis of YopD mutants, we demonstrated that the same discrete modular domains important for YopD translocation are also necessary for both the regulation of plasmid copy number as well as copA and copB expression. Hence, Yersinia has evolved a mechanism coupling active secretion of a plasmid-encoded component of the T3SS, YopD, to the regulation of plasmid replication. Our work provides evidence for the cross-talk between plasmid-encoded functions with the IncFII replicon.

Historical Events That Spawned the Field of Plasmid Biology

This chapter revisits the historical development and outcome of studies focused on the transmissible, extrachromosomal genetic elements called plasmids. Early work on plasmids involved structural and genetic mapping of these molecules, followed by the development of an understanding of how plasmids replicate and segregate during cell division. The intriguing property of plasmid transmission between bacteria and between bacteria and higher cells has received considerable attention. The utilitarian aspects of plasmids are described, including examples of various plasmid vector systems. This chapter also discusses the functional attributes of plasmids needed for their persistence and survival in nature and in man-made environments. The term plasmid biology was first conceived at the Fallen Leaf Lake Conference on Promiscuous Plasmids, 1990, Lake Tahoe, California. The International Society for Plasmid Biology was established in 2004 (www.ISPB.org).

Nucleotide sequence analysis of the enterotoxigenic Escherichia coli Ent plasmid

We report here the complete nucleotide sequence of pEntH10407 (65 147 bp), an enterotoxigenic Escherichia coli enterotoxin plasmid (Ent plasmid), which is self-transmissible at low frequency. Within the plasmid, we identified 100 open reading frames (ORFs) which could encode polypeptides. These ORFs included regions encoding heat-labile (LT) and heat-stable (STIa) enterotoxins, regions encoding tools for plasmid replication and an incomplete tra (conjugation) region. The LT and STIa region was located 13.5 kb apart and was surrounded by three IS1s and an IS600 in opposite reading orientations, indicating that the enterotoxin genes may have been horizontally transferred into the plasmid. We identified a single RepFIIA replication region (2.0 kb) including RepA proteins similar to RepA1, RepA2, RepA3 and RepA4. The incomplete tra region was made up of 17 tra genes, which were nearly identical to the corresponding genes of R100, and showed evidence of multiple insertions of ISEc8 and ISEc8-like elements. These data suggest that pEntH10407 has the mosaic nature characteristic of bacterial virulence plasmids, which contains information about its evolution. Although the tra genes might originally have rendered pEntH10407 self-transferable to the same degree as R100, multiple insertion events have occurred in the tra region of pEntH10407 to make it less mobile. Another self-transmissible plasmid might help pEntH10407 to transfer efficiently into H10407 strain. In this paper, we suggest another possibility: that the enterotoxigenic H10407 strain might be formed by auto-transfer of pEntH10407 at a low rate using the incomplete tra region.

Control of replication of plasmid R1: the intergenic region between copA and repA modulates the level of expression of repA

The RepA protein of plasmid R1 is rate-limiting for initiation of R1 replication. Its synthesis is mainly regulated by interactions of the antisense RNA, CopA, with the leader region of the RepA mRNA, CopT. This work describes the characterization of several mutants with sequence alterations in the intergenic region between the copA gene and the repA reading frame. The analysis showed that most of the mutations led both to a decrease in stability of maintenance of mini-R1 derivatives and to lowered repA expression assayed in translational repA-lacZ fusion constructs. Destruction of the copA gene and replacement of the upstream region by the tac promoter in the latter constructs indicated that these mutations per se alter the expression of repA. In addition, we show that particular mutations in this region can directly affect CopA-mediated control, either by changing the kinetics of interaction of CopA RNA with the RepA mRNA and/or by modifying the activity of the copA promoter. These data indicate the importance of the region analysed in the process that controls R1 replication.

Plasmid R1--replication and its control

Plasmid R1 is a low-copy-number plasmid belonging to the IncFII group. The genetics, biochemistry, molecular biology, and physiology of R1 replication and its control are summarised and discussed in the present communication. Replication of R1 starts at a unique origin, oriR1, and proceeds unidirectionally according to the Theta mode. Plasmid R1 replicates during the entire cell cycle and the R1 copies in the cell are members of a pool from which a plasmid copy at random is selected for replication. However, there is an eclipse period during which a newly replicated copy does not belong to this pool. Replication of R1 is controlled by an antisense RNA, CopA, that is unstable and formed constitutively; hence, its concentration is a measure of the concentration of the plasmid. CopA-RNA interacts with its complementary target, CopT-RNA, that is located upstream of the RepA message on the repA-mRNA. CopA-RNA post-transcriptionally inhibits translation of the repA-mRNA. CopA- and CopT-RNA interact in a bimolecular reaction which results in an inverse proportionality between the relative rate of replication (replications per plasmid copy and cell cycle) and the copy number; the number of replications per cell and cell cycle, n, is independent of the actual copy number in the individual cells, the so-called +n mode of control. Single base-pair substitutions in the copA/copT region of the plasmid genome may result in mutants that are compatible with the wild type. Loss of CopA activity results in (uncontrolled) so-called runaway replication, which is lethal to the host but useful for the production of proteins from cloned genes. Plasmid R1 also has an ancillary control system, CopB, that derepresses the synthesis of repA-mRNA in cells that happen to contain lower than normal number of copies. Plasmid R1, as other plasmids, form clusters in the cell and plasmid replication is assumed to take place in the centre of the cells; this requires traffic from the cluster to the replication factories and back to the clusters. The clusters are plasmid-specific and presumably based on sequence homology.

Peripheral sequences of the Serratia entomophila pADAP virulence-associated region

Some strains of the Enterobacteriaceae Serratia entomophila and Serratia proteamaculans cause amber disease in the grass grub, Costelytra zealandica (Coleoptera: Scarabaeidae), an important pasture pest in New Zealand. The genes responsible for this disease reside on a large, 155-kb plasmid designated amber disease-associated plasmid (pADAP). Herein, we report the DNA sequencing of approximately 50 kb upstream and 10 kb downstream of the virulence-encoding region. Based on similarity with proteins in the current databases, and potential ribosome-binding sites, 63 potential ORFs were determined. Eleven of these ORFs belong to a type IV pilus cluster (pilL-V) and a further eight have similarities to the translated products of the plasmid transfer traH-N genes of the plasmid R64. In addition, a degenerate 785-nt direct repeat flanks a 44.7-kb region with the potential to encode three Bacillus subtilis Yee-type proteins, a fimbrial gene cluster, the sep virulence-associated genes and several remnant IS elements.

Novel type of fimbriae encoded by the large plasmid of sorbitol-fermenting enterohemorrhagic Escherichia coli O157:H(-)

Sorbitol-fermenting (SF) enterohemorrhagic Escherichia coli (EHEC) O157:H(-) have emerged as important causes of diarrheal diseases and the hemolytic-uremic syndrome in Germany. In this study, we characterized a 32-kb fragment of the plasmid of SF EHEC O157:H(-), pSFO157, which differs markedly from plasmid pO157 of classical non-sorbitol-fermenting EHEC O157:H7. We found a cluster of six genes, termed sfpA, sfpH, sfpC, sfpD, sfpJ, and sfpG, which mediate mannose-resistant hemagglutination and the expression of fimbriae. sfp genes are similar to the pap genes, encoding P-fimbriae of uropathogenic E. coli, but the sfp cluster lacks homologues of genes encoding subunits of a tip fibrillum as well as regulatory genes. The major pilin, SfpA, despite its similarity to PapA, does not cluster together with known PapA alleles in a phylogenetic tree but is structurally related to the PmpA pilin of Proteus mirabilis. The putative adhesin gene sfpG, responsible for the hemagglutination phenotype, shows significant homology neither to papG nor to other known sequences. Sfp fimbriae are 3 to 5 nm in diameter, in contrast to P-fimbriae, which are 7 nm in diameter. PCR analyses showed that the sfp gene cluster is a characteristic of SF EHEC O157:H(-) strains and is not present in other EHEC isolates, diarrheagenic E. coli, or other Enterobacteriaceae. The sfp gene cluster is flanked by two blocks of insertion sequences and an origin of plasmid replication, indicating that horizontal gene transfer may have contributed to the presence of Sfp fimbriae in SF EHEC O157:H(-).

A transposon carrying the gene mphB for macrolide 2'-phosphotransferase II

The mphB gene for macrolide 2'-phosphotransferase II is located on two plasmids, pTZ3721 and pTZ3723, in Escherichia coli BM2506. We examined translocation of mphB that originated from pTZ3721. The transposable element carrying mphB is 39 kb long and has a Tn21-like transposition module at one end and a Tn1721-like transposition module at other. The structure of the transposition modules of this element resembles that of Tn2610. However, the gene arrangement of the internal region on the transposon carrying mphB was reverse to that of Tn2610. The nucleotide sequences of both terminal regions suggested that the inversion of the DNA fragment occurred between the res sites by resolvase-mediated recombination.

Complete DNA sequence and structural analysis of the enteropathogenic Escherichia coli adherence factor plasmid

The complete nucleotide sequence and organization of the enteropathogenic Escherichia coli (EPEC) adherence factor (EAF) plasmid of EPEC strain B171 (O111:NM) were determined. The EAF plasmid encodes two known virulence-related operons, the bfp operon, which is composed of genes necessary for biosynthesis of bundle-forming pili, and the bfpTVW (perABC) operon, composed of regulatory genes required for bfp transcription and also for transcriptional activation of the eae gene in the LEE pathogenicity island on the EPEC chromosome. The 69-kb EAF plasmid, henceforth designated pB171, contains, besides the bfp and bfpTVW (perABC) operons, potential virulence-associated genes, plasmid replication and maintenance genes, and many insertion sequence elements. Of the newly identified open reading frames (ORFs), two which comprise a single operon had the potential to encode proteins with high similarity to a C-terminal region of ToxB whose coding sequence is located on pO157, a large plasmid harbored by enterohemorrhagic E. coli. Another ORF, located between the bfp and bfpTVW operons, showed high similarity with trcA, a bfpT-regulated chaperone-like protein gene of EPEC. Two sites were found to be putative replication regions: one similar to RepFIIA of p307 or F, and the other similar to RepFIB of R100 (NR1). In addition, we identified a third region that contains plasmid maintenance genes. Insertion elements were scattered throughout the plasmid, indicating the mosaic nature of the EAF plasmid and suggesting evolutionary events by which virulence genes may have been obtained.

Plasmid maintenance functions of the large virulence plasmid of Shigella flexneri

The large virulence plasmid pMYSH6000 of Shigella flexneri contains a replicon and a plasmid maintenance stability determinant (Stb) on adjacent SalI fragments. The presence of a RepFIIA replicon on the SalI C fragment was confirmed, and the complete sequence of the adjacent SalI O fragment was determined. It shows homology to part of the transfer (tra) operon of the F plasmid. Stb stabilizes a partition-defective P1 miniplasmid in Escherichia coli. A 1.1-kb region containing a homolog of the F trbH gene was sufficient to confer stability. However, the trbH open reading frame could be interrupted without impairing stability. Deletion analysis implicated the involvement of two small open reading frames, STBORF1 and STBORF2, that fully overlap trbH in the opposite direction. These open reading frames are closely related to the vagC and vagD genes of the Salmonella dublin virulence plasmid and to open reading frame pairs in the F trbH region and in the chromosomes of Dichelobacter nodosus and Haemophilus influenzae. Stb appears to promote better-than-random distribution of plasmid copies and is a plasmid incompatibility determinant. The F homolog does not itself confer stability but exerts incompatibility against the activity of the Stb system. Stb is likely to encode either an active partition system or a postsegregational killing system. It shows little similarity to previously studied plasmid stability loci, but the genetic organization of STBORF1 and STBORF2 resembles that of postsegregational killing mechanisms.

A set of compatible tac promoter expression vectors

A series of expression vectors have been developed which all contain an identical expression cassette comprised of the lacIq gene, the tac promoter, a multiple cloning site (MCS) and a downstream transcriptional terminator. This cassette has been inserted into four distinct plasmid backbones, each of which is from a separate incompatibility group and carries a different drug resistance gene. Therefore, different combinations of these expression plasmids can be stably maintained together.

Comparative analysis of the replicon regions of eleven ColE2-related plasmids

The incA gene product of ColE2-P9 and ColE3-CA38 plasmids is an antisense RNA that regulates the production of the plasmid-coded Rep protein essential for replication. The Rep protein specifically binds to the origin and synthesizes a unique primer RNA at the origin. The IncB incompatibility is due to competition for the Rep protein among the origins of the same binding specificity. We localized the regions sufficient for autonomous replication of 15 ColE plasmids related to ColE2-P9 and ColE3-CA38 (ColE2-related plasmids), analyzed their incompatibility properties, and determined the nucleotide sequences of the replicon regions of 9 representative plasmids. The results suggest that all of these plasmids share common mechanisms for initiation of DNA replication and its control. Five IncA specificity types, 4 IncB specificity types, and 9 of the 20 possible combinations of the IncA and IncB types were found. The specificity of interaction of the Rep proteins and the origins might be determined by insertion or deletion of single nucleotides and substitution of several nucleotides at specific sites in the origins and by apparently corresponding insertion or deletion and substitution of amino acid sequences at specific regions in the C-terminal portions of the Rep proteins. For plasmids of four IncA specificity types, the nine-nucleotide sequences at the loop regions of the stem-loop structures of antisense RNAs are identical, suggesting an evolutionary significance of the sequence. The mosaic structures of the replicon regions with homologous and nonhomologous segments suggest that some of them were generated by exchanging functional parts through homologous recombination.

Control of ColE2 plasmid replication: regulation of Rep expression by a plasmid-coded antisense RNA

We isolated and characterized mutants of ColE2 with increased copy number (cop) and those with reduced sensitivity to the wild-type incA gene (inc). Both types of mutations were single-base substitutions in the incA region and simultaneously increased the plasmid copy number and reduced the inhibitory activity of the incA gene on ColE2 DNA replication. Most of the cop mutations also reduced sensitivity to the wild-type incA gene. These mutations were located in the region specifying the large stem-and-loop structures of RNA I and the 5' portion of the Rep mRNA. All these results indicate that RNA I interacts with the Rep mRNA and thereby inhibits expression of the Rep protein at a post-transcriptional step and that this is probably the only mechanism that controls the ColE2 Rep protein expression. It is suggested that only portions of the nucleotides in the loop region are involved in initial (kissing) interaction of these RNAs. The total level of rep gene expression in the host cells appears to be kept constant (at a level characteristic for each cop allele) irrespective of the actual plasmid copy number above a certain level, when rep gene expression is regulated by the incA gene on the same plasmid. These seem to be the basic mechanisms for the replication control of ColE2.

Control of replication of the Lactobacillus pentosus plasmid p353-2: evidence for a mechanism involving transcriptional attenuation of the gene coding for the replication protein

The synthesis of plasmid DNA and of RNA encoded by the replication protein gene (rep) of plasmid p353-2 of Lactobacillus pentosus was studied for the wild-type plasmid and for a mutant plasmid with a deletion in the 5' untranslated region of the rep gene. Plasmid p353-2 codes for two countertranscript RNAs (CT-RNA) of approximately 75 and 250 nucleotides transcribed from the 5' untranslated region of the rep gene, in opposite directions. In a mutant plasmid with a deletion of the promoter and part of the CT-RNA-encoding sequence which shows a 5- to 10-fold increase in copy number compared to the wild-type plasmid, no CT-RNA could be detected. In the wild-type plasmid more than 90% of transcription initiated at a promoter upstream of the rep gene is prematurely terminated to form a 190 nucleotide truncated RNA, whereas in the mutant plasmid nearly all transcripts reach a size (1100 nucleotides) corresponding to that of the rep gene. A model is presented for the role of CT-RNA in control of plasmid replication, similar to that previously presented for the staphylococcal plasmid pT181, involving a mechanism of transcriptional attenuation of rep RNA at a site just upstream of the rep gene.

Insertion and deletion mutations in the repA4 region of the IncFII plasmid NR1 cause unstable inheritance

Mutants of IncFII plasmid NR1 that have transposons inserted in the repA4 open reading frame (ORF) are not inherited stably. The repA4 ORF is located immediately downstream from the replication origin (ori). The repA4 coding region contains inverted-repeat sequences that are homologous to the terC inverted repeats located in the replication terminus of the Escherichia coli chromosome. The site of initiation of leading-strand synthesis for replication of NR1 is also located in repA4 near its 3' end. Transposon insertions between ori and the right-hand terC repeat resulted in plasmid instability, whereas transposon insertions farther downstream did not. Derivatives that contained a 35-bp frameshift insertion in the repA4 ORF were all stable, even when the frameshift was located very near the 5' end of the coding region. This finding indicates that repA4 does not specify a protein product that is essential for plasmid stability. Examination of mutants having a nest of deletions with endpoints in or near repA4 indicated that the 3' end of the repA4 coding region and the site of leading-strand initiation could be deleted without appreciable effect on plasmid stability. Deletion of the pemI and pemK genes, located farther downstream from repA4 and reported to affect plasmid stability, also had no detectable effect. In contrast, mutants from which the right-hand terC repeat, or both right- and left-hand repeats, had been deleted were unstable. None of the insertion or deletion mutations in or near repA4 affected plasmid copy number. Alteration of the terC repeats by site-directed mutagenesis had little effect on plasmid stability. Plasmid stability was not affected by a fus mutation known to inactivate the termination function. Therefore, it appears that the overall integrity of the repA4 region is more important for stable maintenance of plasmid NR1 than are any of the individual known features found in this region.

Suppression of replication-deficient mutants of IncFII plasmid NR1 can occur by two different mechanisms that increase expression of the repA1 gene

Replication-proficient (Rep+) revertants were isolated from mutants of IncFII plasmid NR1 that were replication defective (Rep-). The parental Rep- plasmids contained a mutation that inactivated promoter PE for transcription of RNA-E, a trans-acting repressor of translation of the essential RepA1 replication initiation protein of NR1. The PE mutation also introduced a nonsense codon into a leader peptide gene that precedes and slightly overlaps the repA1 translation initiation site in the mRNA. This reduced the rate of synthesis of RepA1 by uncoupling its translation from that of the leader peptide. The reduced rate of RepA1 synthesis was responsible for the Rep- phenotype. All Rep+ revertants retained the PE mutation and contained second-site mutations responsible for suppression of the Rep- phenotype. One Rep+ revertant contained a second mutation adjacent to the Shine-Dalgarno sequence of repA1. Another Rep+ revertant contained a mutation in the repA2 gene, which encodes the trans-acting repressor of transcription of repA1. By using translational lacZ gene fusions, it was found that both kinds of suppressor mutation increased the expression of repA1 to a level sufficient to support replication. In both cases, the synthesis of RepA1 remained uncoupled from that of the leader peptide. The Shine-Dalgarno mutation increased the rate of leader peptide-independent translation of repA1 mRNA and also reduced the sensitivity of repA1 mRNA to inhibition by RNA-E. The repA2 mutation inactivated the RepA2 repressor and increased the rate of transcription of repA1 mRNA. The translational lacZ gene fusions were used to assess the range of regulation of expression of repA1 provided by each of the RNA-E and RepA2 regulatory circuits. By constructing miniplasmids that contained various combinations of the mutations, the contributions of the RNA-E and RepA2 regulatory circuits were assessed with respect to control of plasmid copy number and stable inheritance. Plasmids that lacked either circuit were less stable than wild-type plasmids.

Characterization of a replicon of the moderately promiscuous plasmid, pGSH5000, with features of both the mini-replicon of pCU1 and the ori-2 of F

The dominant, polA1-independent replicon of pGSH500, rep beta (1.8 kb), consists of a cis-acting oriV region of 245 bp; a repB gene that is essential for autonomous replication and 18, 30 to 36 bp iterons which constitute the inc/cop region. The molecular organization of rep beta resembles that of mini-pCU1 (IncN). Furthermore, there is a 58% identity between the Rep proteins of these replicons. RepB also shows a 31% identity with RepE of mini-F. In addition, an 80% identity over 200 bp was identified between the cis-acting beta oriV region and the equivalent region of ori-2 (mini-F). Replicons with deletions of repB could be complemented by Rep (pCU1) and RepE (mini-F) in trans, supporting the hypothesis that rep beta is a natural hybrid between a pCU1-like and F-like replicon.

Expression of the repA1 gene of IncFII plasmid NR1 is translationally coupled to expression of an overlapping leader peptide

Examination of a group of mutants of plasmid NR1 that had lost the expression of IncFII plasmid incompatibility (Inc-) revealed a group that had also lost replication proficiency (Rep-). These mutants were obtained from plasmids in which the NR1 replication control region was present in a cointegrate with plasmid pBR322. Whereas the wild-type parental cointegrate plasmid was capable of replicating in a polA host owing to the PolA independence of NR1 replication, the mutants were not able to transform a polA host. Losses of both expression of IncFII plasmid incompatibility and replication proficiency were found to result from the same single base-pair substitution in four independently isolated Inc- Rep- mutants. The mutation inactivates promoter PE for the transcription of RNA-E, a trans-acting repressor of translation of the essential RepA1 replication initiation protein of NR1. Although the loss of RNA-E synthesis had been expected to increase the expression of repA1, the efficiency of translation of repA1 mRNA from these mutants was at least 100-fold lower than that from the wild type, as revealed by repA1-lacZ translational fusions. The PE mutation introduced a stop codon into a 24-amino-acid reading frame that precedes the repA1 gene and terminates just 2 bp downstream from the repA1 start codon. This putative leader peptide was also expressed in a lacZ translational fusion, and its expression was reduced by a factor of 10(4) by the PE mutation. The expression of the leader peptide and the expression of repA1 were regulated by RNA-E. These results suggest that the expression of repA1 is coupled to the translation of the leader peptide and that the repression of repA1 translation by RNA-E may occur via inhibition of the translation of the leader peptide.

Comparative analysis of the replication regions of IncB, IncK, and IncZ plasmids

Minireplicons from the I-complex plasmids R387 (IncK) and pIE545 (IncZ) were constructed, and the nucleotide sequences of their replication regions were compared with that of the B plasmid, pMU720. The coding sequence of the putative replication protein, RepA, of each plasmid was located. RepA of K and B plasmids were homologous, whereas RepA of Z resembled RepA1 of FII plasmid. Sequences upstream of RepA were conserved in the three I-complex plasmids. Group B and Z plasmids were incompatible.

Nucleotide sequence of the replication region from the Mycobacterium-Escherichia coli shuttle vector pEP2

The replication region derived from the Corynebacterium diphtheriae-Escherichia coli plasmid pNG2 was sequenced. This 1.85-kb segment contains a single origin of DNA replication, one major open reading frame and shares no sequence homology with previously described plasmids.

Organization of the replication control region of plasmid ColIb-P9

We identified a 1,845-base-pair sequence that contains essential information for the autonomous replication and regulation of the 93-kilobase-pair IncI alpha group ColIb-P9 plasmid. Biochemical and genetic analyses revealed that this sequence specifies at least two structural genes, designated repZ and inc. The repZ gene encodes a protein with a molecular weight of 39,000, which probably functions as an initiator for the ColIb-P9 replicon. The inc gene that phenotypically governs the incompatibility encodes an RNA with a size of about 70 bases. This small RNA acts in trans to repress the expression of repZ, thereby functioning to maintain a constant copy number of the ColIb-P9 replicon in host cells.

DnaA protein is not essential for replication of IncFII plasmid NR1

By transformation of dnaA null mutant host cells that are suppressed either by an rnh mutation or by chromosomal integration of a mini-R1 plasmid, it was shown that replication of miniplasmids composed of the NR1 minimal replicon had no absolute dependence upon DnaA protein. In addition, the suppression of the dnaA null mutation by the integrated mini-R1, which is an IncFII relative of NR1, was found to be sensitive to the expression of IncFII-specific plasmid incompatibility. This suggests that the integrative suppression by mini-R1 is under the control of the normal IncFII plasmid replication circuitry. Although NR1 replication had no absolute requirement for DnaA, the copy numbers of NR1-derived miniplasmids were lower in dnaA null mutants, and the plasmids exhibited a much reduced stability of inheritance during subculture in the absence of selection. This suggests that DnaA protein may participate in IncFII plasmid replication in some auxiliary way, such as by increasing the efficiency of formation of an open initiation complex at the plasmid replication origin. Such an auxiliary role for DnaA in IncFII replication would be different from that for replication of most other plasmids examined, for which DnaA has been found to be either essential or unimportant.

Isolation and characterization of a conditional replication mutant of the antibiotic resistance factor R1 affected in the gene of the replication protein repA

In vitro mutagenesis with hydroxylamine of a ParD- miniderivative of R1, pAB174, yielded mutants that were less stable in the cell than pAB174. Some of these mutants had a thermosensitive phenotype. The replication of pAB2623, one of the thermosensitive mutants, was inhibited in the cell at the restrictive temperature of 42 degrees C. The efficiency of the RepA protein of pAB2623 to promote replication of R1 in an in vitro assay was greatly reduced. Sequence analysis indicated that the repA gene of pAB2623 contains, close to its 3' end, two GC-AT transitions, separated by a single base, that change two consecutive codons of the gene. These results indicate that the phenotype of the mutant is the consequence of a mutated RepA protein and is consistent with the requirement of RepA for the in vivo replication of this plasmid.

Killing of Escherichia coli cells modulated by components of the stability system ParD of plasmid R1

The proteins P10 and P12 have been shown to be gene products of a new stability system, ParD, of plasmid R1. It is now shown that an R1 miniplasmid, pAB112, carrying a trans-complementable amber mutation in the gene of the P10 protein, is lethal for the host in the absence of suppression. This lethal effect is suppressed in a supF background and also by deletions in pAB112 that affect the gene of the P12 protein. These data indicate that the P12 protein has a lethal effect on the host and that this effect is neutralized by the P10 protein. The possibility that the stabilization conferred by the ParD system could be due to a counterselection, mediated by P12, of cells that lose the plasmid at cell division, is discussed.

Unidirectional replication of plasmid R100

We isolated a 284 base-pair BamHI fragment of plasmid R100 that supports initiation of replication of a plasmid regardless of the orientation of the fragment. Analysis of the specific radioactivity of restriction fragments from 32P-labeled replication intermediates synthesized in vitro shows that replication of the plasmid carrying the 284 base-pair fragment is unidirectional. The direction of replication depends on the orientation of the fragment present in the plasmid. The 5' ends of the leading-strand DNA formed in the early stage of replication were mapped to a region downstream from the 284 base-pair fragment in the direction of replication. The lagging-strand DNA products were also identified and their 3' ends mapped to unique sites within the 284 base-pair fragment causing unidirectional replication of R100.

Core sequence of two separable terminus sites of the R6K plasmid that exhibit polar inhibition of replication is a 20 bp inverted repeat

The DNA replication terminus (terR) of the R6K plasmid located on a 216 bp Alul fragment (Alu216) can block progress of the DNA replication fork. We previously developed an electrophoresis assay that allows detection of terminus activity on any DNA fragment cloned in the pUC vector. For precise identification of terR, we tested Alu216, its subfragments, and synthetic oligonucleotides by this assay. We found terR to be composed of a pair of separable sites, terR1 and terR2, each of which can block the DNA replication fork traveling in a specific but not the opposite direction. Both terR sites were composed of 22 nucleotides containing the repeated 20 bp sequence 5'-TAGTTACAACAC(A or T) CAA(G or T) AGA-3', located 73 bp apart in the inverted position of Alu216. A DNA homology search suggested that the R6K plasmid and the E. coli chromosome share a common termination system.

In-vivo studies on the cis-acting replication initiator protein of IncFII plasmid NR1

Using segment-directed mutagenesis, a temperature-sensitive mutant of the gene that encodes the cis-acting RepA1 initiation protein of the IncFII plasmid NR1 was isolated. The mutant protein was unable to promote initiation of plasmid replication in vivo at 42 degrees C. Both the wild-type and the mutant repA1 genes were cloned separately into the high-expression vector plasmid pAS1. In these pAS1-repA1 derivatives, the transcription of the repA1 gene was under the control of the lambda PL promoter, which was regulated by the temperature-sensitive lambda cI857 repressor protein. The translation initiation of the repA1 mRNA from these derivatives was mediated by the lambda cII Shine-Dalgarno sequence and initiation codon. The yield of 33,000 Mr RepA1 protein detected on SDS/polyacrylamide gels from Escherichia coli cells containing the pAS1-repA1 derivatives was dependent upon whether the newly synthesized RepA1 was capable of interacting in cis with the downstream NR1 replication origin on the cloned DNA fragment. Mutations in the repA1 gene or deletions of the cis origin region dramatically increased the detectable yield of RepA1 protein. Deletion of the NR1 origin region from the pAS1 derivative containing the wild-type repA1 gene enabled the cis-acting RepA1 protein to complement partially the temperature-sensitive repA1 mutant in trans, to increase the copy number in trans of plasmids that contained the NR1 replicon, and to help NR1 derivatives overcome plasmid incompatibility. The trans effects of RepA1 provided by the pAS1-repA1 derivatives that retained the origin in cis were much less significant. RepA1 provided in trans also stimulated the replication of plasmids carrying cloned copies of the NR1 replication origin region regardless of whether the origin was transcribed from an upstream promoter.

Microcin B17, a novel tool for preparation of maxicells: identification of polypeptides encoded by the IncFII minireplicon pMccB17

The DNA replication inhibitor peptide microcin B17 is shown to be a useful tool for preparing Escherichia coli maxicells. To illustrate its usefulness, we have identified polypeptides synthesized from pMccB17 and R100 IncFII miniplasmids. After comparing the respective polypeptides and the miniplasmid restriction maps, we concluded that these plasmids share extensive homology in the basic replicon but are different for an adjacent region (parD) that is involved in plasmid stability and maintenance.

Transcriptional pausing in a region important for plasmid NR1 replication control

The results of in vitro single-round transcription experiments indicated that RNA polymerase pauses during transcription of the leader region that precedes the repA1 gene of IncFII plasmid NR1. Transcription initiated at either of the two transcription promoter sites of the repA1 gene, which encodes the essential replication initiation protein of NR1, was observed to pause in this region. Pausing was specifically enhanced by addition of NusA protein, an Escherichia coli transcription accessory factor. Northern blot RNA-DNA hybridization analysis of repA1 mRNA synthesized in vivo revealed RNA species that had lengths equivalent to those of the in vitro-paused intermediates. The steady-state rate of in vivo repA1 mRNA transcription downstream from the pause sites (measured by quantitative hybridization of pulse-labeled RNA to DNA probes complementary to different segments of repA1 mRNA) was not appreciably affected, which suggests that the pause sites do not promote premature termination of transcription. The pause sites were located between the target sequence within the leader region of the mRNA that interacts with a 91-base countertranscript and the beginning of the repA1 coding sequence. Because the countertranscript is an inhibitor of translation of repA1 mRNA, transcriptional pausing in this region may be an important feature of the regulation of RepA1 synthesis, which is the mechanism by which plasmid NR1 controls its replication.

Identification of components of a new stability system of plasmid R1, ParD, that is close to the origin of replication of this plasmid

We provide evidence that a mutation which derepresses an autoregulated system that is located in the vicinity of the basic replicon of R1, stabilizes the ParA- and ParB- miniplasmid of R1 pKN1562, without increasing its copy number. The system, which we have called ParD, maps inside the 1.45-kb PstI-EcoRI fragment that is adjacent to the origin of replication of the plasmid. Two proteins whose expression is coordinated are components of the system. The sequence of the PstI-EcoRI fragment was obtained. The wild-type ParD system determines in cis a basal but detectable stability.

Role of replication in IS102-mediated deletion formation

Intramolecular transposition produces replicon dissociation in a bireplicon; this reaction is homologous to the well-characterized IS-associated deletions in the case of a monoreplicon. However the frequencies at which these two reactions occur differ by a factor of more than 10(2) in favor of deletion formation. This raises the question of how these deletions occur. We show that the presence of a productive replication on the fragment to be deleted interferes with deletion formation. Our results also suggest that the deleted fragment is not degraded during deletion formation.

Identification and expression of a copy number control gene in the IncFIII hemolytic plasmid pSU316

A DNA fragment carrying both the IncFIII determinant and a copy number control gene of the hemolytic plasmid pSU316 has been cloned in pBR322. Deletion derivatives of the hybrid plasmid generated by Bal 31 digestion, which no longer exhibit the IncFIII phenotype, fall into two complementation groups when tested against a pSU316 miniplasmid derivative. Type 1 mutants exhibit the copy number control (Cop+) phenotype whereas type 2 mutants do not. Restriction analysis of type 1 and type 2 mutants allowed us to locate the cop gene of pSU316 in a 700-base-pair fragment adjacent to the IncFIII determinant. Plasmid expression in a minicell system suggests that the product of the cop gene of pSU316 could be a 13,000-dalton protein.

Nucleotide sequence analysis of RepFIC, a basic replicon present in IncFI plasmids P307 and F, and its relation to the RepA replicon of IncFII plasmids

RepFIC is a basic replicon of IncFI plasmid P307 which is located within a 3.09-kilobase SmaI fragment. The nucleotide sequence of this region has been determined and shown to be homologous with the RepFIIA replicon of IncFII plasmids. The two replicons share three homologous regions, HRI, HRII, and HRIII, which are flanked by two nonhomologous regions, NHRI and NHRII. A comparison of coding regions reveals that the two replicons have several features in common. RepFIC, like RepFIIA, codes for a repA2 protein with its amino-terminal codons in HRI and its carboxy-terminal codons in NHRI. Although the codons for the repA1 proteins are located in NHRII, the DNA region containing a putative promoter, ribosomal binding site, and initiation codons is located in HRII. This region also codes for an inc RNA. There are nine base-pair differences between the inc RNA of RepFIIA and that of RepFIC, and as a result, RepFIC and RepFIIA replicons are compatible. An EcoRI fragment from the F plasmid which shows homology with RepFIC of P307 has also been sequenced. This fragment contains only a portion of RepFIC, including the genes for the putative repA2 protein and inc RNA. The region coding for a putative repA1 protein is interrupted by the transposon Tn1000 and shows no homology with the repA1 region of RepFIIA and RepFIC of P307. Our comparative and structural analyses suggest that RepFIC and RepFIIA, although different, have a similar replication mechanism and thus can be assigned to the same replicon family, which we designate the RepFIIA family.

Regulation of IncFII plasmid DNA replication. A quantitative model for control of plasmid NR1 replication in the bacterial cell division cycle

A quantitative model for the regulation of replication of the low copy number IncFII plasmid NR1 in the Escherichia coli cell division cycle has been developed. The initiation of NR1 replication requires a cis-acting initiator protein whose synthesis is regulated by several mechanisms. The NR1 regulatory processes include co-operative protein-protein interactions in the formation of an active transcription repressor, the interaction of repressor with a rightward operator site in the control of transcription of the initiator gene, and the interaction of an inhibitor RNA transcript with the initiator mRNA in the control of translation of the initiation protein. A statistical thermodynamic model was used to predict probable configurations of the regulatory processes in a single growing cell. These probabilities were coupled by a kinetic model to the events of the cell cycle, such as initiation of mRNA transcription and protein translation, and the initiation of plasmid DNA replication. Parameter values were chosen so that the simulated values for plasmid copy number and the intracellular concentrations of repressor protein and mRNA agreed with experimentally determined estimates. A number of different copy number mutants that have altered one or another of the regulatory processes were simulated by the model. The contributions of each of the regulatory processes toward the overall stability of inheritance of plasmid NR1 in a population of cells in culture were examined. These simulations predict a very stable pattern of inheritance for plasmid NR1 despite its low copy number, in agreement with experimental observation.

Structure and function of the F plasmid genes essential for partitioning

The F plasmid in Escherichia coli has its own partition mechanism controlled by the sopA and sopB genes, and by the cis-acting sopC region. The DNA sequence of the entire partition region and its flanking regions is described here. Two large open reading frames coding for 43,700 Mr and 35,400 Mr proteins correspond to sopA and sopB, respectively. The sopB reading frame is located immediately downstream from the sopA reading frame. Twelve 43 base-pair direct repeats exist in the sopC region without any spacer regions, and one pair of seven base-pair inverted repeats exists in each of the direct repeats. Analysis of deletions in the sopC region showed that the direct repeats play an important role in plasmid partition and IncD incompatibility. IncG incompatibility is exhibited by pBR322 derivatives carrying the sopB gene alone. When compared with the partition genes parA and parB of plasmid P1, homology in amino acid sequence was found between the SopA protein of F and the ParA protein of P1, and also between SopB protein of F and ParB protein of P1. In addition, homology was found between Rep proteins of F and P1.

Complete nucleotide sequence of the topA gene encoding Escherichia coli DNA topoisomerase I

The nucleotide sequence of a 4071 base-pair long segment containing the gene topA encoding Escherichia coli DNA topoisomerase I and its flanking regions has been determined. The gene encodes a total of 864 amino acids from the ATG start to a TAA termination codon, of which the first f-Met appears to be removed after translation; the calculated molecular weight of the translated protein is 97,413. Mapping of promoters by deletion of sequences upstream from the ATG initiation codon indicates the existence of at least two promoters that direct transcription into topA.

Characterization of the gene products produced in minicells by pSM1, a derivative of R100

At least ten polypeptides larger than 6 kilodaltons (K) are produced in minicells from the miniplasmid pSM1 in vivo. pSM1 (5804 bp) is a small derivative of the drug resistance plasmid R100 (ca. 90 kb) and carries the R100 essential replication region as well as some non-essential functions. Cloned restriction fragments of pSM1 and plasmids with deletions within pSM1 sequences were used to assign eight of the ten observed polypeptides to specific coding regions of pSM1. Two of these polypeptides were identified as RepA1 and RepA2, proteins encoded by the essential replication region of pSM1/R100. The nucleotide sequence consisting of 885 bp outside the essential replication region is presented here. This sequence contains an open reading frame, orf4, for a protein 22.9 K in size, and one of the pSM1-encoded polypeptides was identified as the orf4 gene product. Five additional polypeptides were shown to be the products of other open reading frames mapping outside the essential replication region. Specific functions have been assigned to four of these polypeptides and tentatively to the fifth.

Enhanced instability of IncFII basic replicon by the polA mutation

IncFII plasmids consisting of a basic replicon and of an additional fragment(s) unrelated to plasmid maintenance were all less stable in polA1 than in its wild type. Reversion to UV-resistance recovered stability and vice versa. UV irradiation promoted instability in polA1 cells. Larger plasmids showed a greater instability and a fewer number of copies in a same host. Surprisingly, polA1 cells with Tn3 on the plasmid showed a higher ampicillin resistance than the wild type, apparently suggesting that the polA1 mutation increases the copy number. The size-dependency of instability was less marked in polA1 than in its parent. Comparison of the generation times has suggested a detrimental effect exerted by a basic replicon in polA1 hosts.

Cloning, mapping, and sequencing of plasmid R100 traM and finP genes

The fertility control gene finP, the transfer gene traM, and the transfer origin, oriT, of plasmid R100 were isolated on a single 1.2-kilobase EcoRV fragment and were then subcloned as HaeIII fragments. The sequence of the 754-base-pair finP-containing fragment is reported here. In addition to the finP gene, the sequence includes all but two bases of the R100 traM open reading frame and apparently all of the leader mRNA sequence and amino end of the traJ gene of R100. The sequence contains two open reading frames which encode small proteins on the opposite strand from the traM and traJ genes. It also shows two sets of inverted repeats that have the characteristics of transcription terminators. One set is positioned as if it was the traM terminator, and the other set, which is downstream from the first, sits in the middle of the leader mRNA sequence for traJ. On the bottom strand, this inverted repeat has the structure of a rho-independent terminator. Other less-stable inverted repeats overlap this second terminator in the same way as is seen in attenuation sequences, and the two separate small open reading frames on the bottom strand also totally overlap the stem of the rho-independent terminator, suggesting that their translation would cause shifting of termination to the bottom strand homolog of the putative traM terminator. The finP gene product was not identified, but the gene was mapped to the sequence which contains the traJ gene. It either overlaps traJ or is antisense to it.

Incompatibility repressor in a RepA-like replicon of the IncFI plasmid ColV2-K94

The replication region Rep1 of the IncFI plasmid ColV2-K94 was cloned on self-replicating restriction fragments. Rep1 was structurally and functionally homologous to the RepA replicon of IncFII R plasmids. Despite this close relationship, these two replication systems were compatible with each other. The nucleotide sequence of the copA incompatibility-replication control gene of Rep1 was determined and compared with the copA sequence of RepA. Six base changes were found in a 24-base-pair span of the copA gene; these may result in the formation of a new, more stable, 49-base stem-loop structure in the potential CopA RNA repressor molecule. We postulate that these alterations weaken the interaction between RNA transcripts of the Rep1 and RepA replicons.

Incompatibility mutants of IncFII plasmid NR1 and their effect on replication control

DNA from the replication control region of plasmid NR1 or of the Inc- copy mutant pRR12 was cloned into a pBR322 vector plasmid. These pBR322 derivatives were mutagenized in vitro with hydroxylamine and transformed into Escherichia coli cells that harbored either NR1 or pRR12. After selection for the newly introduced pBR322 derivatives only, those cells which retained the unselected resident NR1 or pRR12 plasmids were examined further. By this process, 134 plasmids with Inc- mutations in the cloned NR1 or pRR12 DNA were obtained. These mutants fell into 11 classes. Two of the classes had plasmids with deletions or insertions in the NR1 DNA and were not examined further. Plasmids with apparent point mutations were classified by examining (i) their ability to reconstitute a functional NR1-derived replicon (Rep+ or Rep-), (ii) the copy numbers of the Rep+ reconstituted replicons, (iii) the cross-reactivity of incompatability among the various mutant classes and parental plasmids, and (iv) the trans effects of the mutants on the copy number and stable inheritance of a coresident plasmid.

DNA-protein interactions during replication of genetic elements of bacteria

Specific interactions of DNA with proteins are required for both the replication of deoxyribonucleic acid proper and its regulation. Genetic elements of bacteria, their extrachromosomal elements in particular, represent a suitable model system for studies of these processes at the molecular level. In addition to replication enzymes (DNA polymerases), a series of other protein factors (e.g. topoisomerases, DNA unwinding enzymes, and DNA binding proteins) are involved in the replication of the chromosomal, phage and plasmid DNA. Specific interactions of proteins with DNA are particularly important in the regulation of initiation of DNA synthesis. Association of DNAs with the cell membrane also plays an important role in their replication in bacteria.

Transcription of the replication control region of the IncFII R-plasmid NR1 in vitro and in vivo

The minimal replicon of the 90,000 base-pair IncFII R plasmid NR1 consists of a 2700 base-pair region of the DNA. Minireplicator plasmids consisting of the 2700 base-pair minimal replicon plus a 2200 base-pair region coding for chloramphenicol acetyltransferase (cat) were used as templates for in vitro transcription. Six RNA transcripts were synthesized from these templates in vitro. We have determined the directions of transcription and the approximate sites of initiation and termination of each of the in vitro RNA transcripts. One RNA transcript was synthesized from the cat gene, while the other five were transcribed from the minimal replicon. Four of the RNA transcripts also were identified by quantitative hybridization of RNA synthesized in vivo from these minireplicator plasmids. The strengths of the promoters for the RNA transcripts were estimated by the relative rates of transcription both in vitro and in vivo. Transcription from convergent promoters reduced the rate of RNA synthesis in vivo in both directions. In vivo, a significant fraction of the cat mRNA was extended past its in vitro termination point. Transcription of mutants that have altered plasmid copy number and/or incompatibility properties also were examined. The possible roles of each of the transcripts as mRNA and their involvement in regulation of DNA replication are discussed.

Identification of a gene, tir of R100, functionally homologous to the F3 gene of F in the inhibition of RP4 transfer

We detected a gene of R100 functionally homologous to the F3 gene of F in the inhibition of RP4 transfer. Using in vitro recombinant DNA techniques, we located the gene, designated tir, in a 0.9 kb region, 2,392-3,293 in the nucleotide sequence coordinate of R100. From the DNA sequence analysis of R100 (Ohtsubo unpublished results), a coding frame of polypeptides, whose molecular weight is estimated to be 24.1 kilodaltons (kd), was inferred to be the region tir. Furthermore, we showed that tir could not repress expression of the F3 gene.

Analysis of the individual regulatory components of the IncFII plasmid replication control system

Replication of the IncFII plasmid NR1 is controlled by regulating the amount of synthesis of the repA1 initiator protein at both the transcriptional and translational levels. We have examined mutations which have altered each of these levels of regulation, resulting in different plasmid copy numbers. The genes which encode each of the individual wild-type or mutant regulatory components from the replication control region of NR1 have been cloned independently into pBR322 vectors, and their effects in trans, either individually or in various combinations, on plasmid incompatibility, stability, copy number, and repA1 gene expression have been defined.

Regulation of transcription of the repA1 gene in the replication control region of IncFII plasmid NR1 by gene dosage of the repA2 transcription repressor protein

Transcription of the repA1 gene of the IncFII plasmid NR1 is initiated at two promoters in the replication control region. Transcription from the upstream promoter is constitutive at a low level, whereas transcription from the downstream promoter is regulated. The 5' end of the constitutively synthesized transcript also encodes the transcription repressor protein for the regulated downstream promoter. Therefore, the level of the repressor protein in the cell is gene dosage dependent. Using both lac gene fusions and quantitative hybridization methods, we have determined the in vivo relationship between the rate of transcription from the regulated promoter and the repressor protein concentration as a function of gene dosage. At the wild-type copy number of NR1, transcription from the regulated promoter is 96% repressed, but substantial derepression occurs when the copy number falls below the normal value. At or above the normal plasmid copy number, the basal level of repA1 mRNA is provided by transcription from the constitutive upstream promoter.

Incompatibility and IncFII plasmid replication control

The DNA coding for replication control and incompatibility of the plasmid NR1 serves as a template in vivo and in vitro for RNA transcription in both directions. In the rightward direction, RNA synthesis begins from 2 different promoters, one of which is regulated and the other constitutive. In vivo, each of these transcripts is more than 1,000 nucleotides long, terminating near the estimated site for the origin of replication. These transcripts serve as messenger RNA for several proteins. One protein (repA1) is required for replication and another (repA2) serves as the repressor for the regulated rightward promoter. RNA synthesis in the leftward direction is constitutive and produces a single transcript of 91 nucleotides which is complementary in sequence to the rightward transcripts. This small transcript is the incompatibility product which regulates the replication of the plasmid. When the intracellular concentration of the small transcript is experimentally varied, the rate of translation of the rightward transcripts and the rate of initiation of replication (plasmid copy number) vary inversely to its concentration. The mode of action of this inhibitor RNA is likely to be formation of an RNA-RNA duplex with the rightward transcripts, thereby inhibiting the translation which would produce the required replication protein. The probability that a rightward transcript will escape interaction with the small RNA molecules and thus allow replication to initiate can be predicted from the laws of mass action based on base-stacking free energies for the likely sequences of initial contact. The estimated intracellular RNA concentrations, based on quantitative hybridization experiments, are agreement with those predicted from the calculated equilibrium constants for duplex formation.