Leading strand synthesis of R1 plasmid replication in vitro is primed by primase alone at a specific site downstream of oriR

Sequence of the R1 plasmid and comparison to F and R100

The R1 antibiotic resistance plasmid, originally discovered in a clinical Salmonella isolate in London, 1963, has served for decades as a key model for understanding conjugative plasmids. Despite its scientific importance, a complete sequence of this plasmid has never been reported. We present the complete genome sequence of R1 along with a brief review of the current knowledge concerning its various genetic systems and a comparison to the F and R100 plasmids. R1 is 97,566 nucleotides long and contains 120 genes. The plasmid consists of a backbone largely similar to that of F and R100, a Tn21-like transposon that is nearly identical to that of R100, and a unique 9-kb sequence that bears some resemblance to sequences found in certain Klebsiella oxytoca strains. These three regions of R1 are separated by copies of the insertion sequence IS1. Overall, the structure of R1 and comparison to F and R100 suggest a fairly stable shared conjugative plasmid backbone into which a variety of mobile elements have inserted to form an "accessory" genome, containing multiple antibiotic resistance genes, transposons, remnants of phage genes, and genes whose functions remain unknown.

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.

ATPase/helicase motif mutants of Escherichia coli PriA protein essential for recombination-dependent DNA replication

BACKGROUND

PriA protein, a DEXH-type helicase with C2C2 zinc-finger motifs, plays essential roles in RecA-dependent modes of Escherichia coli chromosomal DNA replication, namely inducible and constitutive stable DNA replication (iSDR and cSDR respectively, which may be initiated from a D-loop or R-loop structure), and in repair of double-stranded DNA breaks generated by various genotoxic agents or spontaneously during the course of DNA replication. However, the roles of ATPase/DNA helicase activities in functions of PriA are not well understood.

RESULTS

We have generated and characterized mutants of PriA protein carrying amino acid substitutions in its conserved ATPase/DNA helicase motifs, namely the Walker A, B and QXXGRXGR motifs. All these mutants were deficient in ATP hydrolysis and DNA helicase activities, but showed wild-type levels of D-loop DNA binding, except for the Walker B mutant which showed reduced DNA binding activity, suggesting that the helicase motifs are not directly involved in the DNA binding activity of PriA protein. They also rescued the low viability and UV-sensitivity of priA null cells. However, they did not rescue iSDR or cSDR-alternative modes of chromosomal DNA replication of the E. coli genome dependent on recombination functions-to the full extent.

CONCLUSIONS

ATPase/DNA helicase activities of PriA protein are required for full-level DNA synthesis in recombination-dependent modes of DNA replication in E. coli.

DNA binding of PriA protein requires cooperation of the N-terminal D-loop/arrested-fork binding and C-terminal helicase domains

PriA protein is essential for RecA-dependent DNA replication induced by stalled replication forks in Escherichia coli. PriA is a DEXH-type DNA helicase, ATPase activity of which depends on its binding to structured DNA including a D-loop-like structure. Here, we show that the N-terminal 181-amino acid polypeptide can form a complex with D-loop in gel shift assays and have identified a unique motif present in the N-terminal segment of PriA that plays a role in its DNA binding. We have also identified residues in the C terminus proximal helicase domain essential for D-loop binding. PriA proteins mutated in this domain do not bind to D-loop, despite the presence of the N-terminal DNA-binding motif. Those mutants that cannot bind to D-loop in vitro do not support a recombination-dependent mode of DNA replication in vivo, indicating that binding to a D-loop-like structure is essential for the ability of PriA to initiate DNA replication and repair from stalled replication forks. We propose that binding of the PriA protein to stalled replication forks requires proper configuration of the N-terminal fork-recognition and C-terminal helicase domains and that the latter may stabilize binding and increase binding specificity.

Change of plasmid DNA structure, hypermethylation, and Lon-proteolysis as steps in a replicative cascade

I have defined conditions under which RepFIC plasmid DNA can be maintained in a state of lowered helical density. In exponentially growing cultures, the DNA of lowered helical density is present in small amounts but never totally absent, suggesting that it is a normal variant of plasmid maintenance. It is fully methylated at frequent sites by dam-methyltransferase, some not previously recognized, further suggesting that the variant is a precursor of replication. The low-helical density plasmid is present in dam hosts, indicating that methylation is not essential for the change in helical density. The lowered helical density is stabilized in lon hosts, suggesting that Lon-protease may remove both the protein(s) that lower the helical density and the dam-methyltransferase after each round of replication.

Mosaic plasmids and mosaic replicons: evolutionary lessons from the analysis of genetic diversity in IncFII-related replicons

The alpha replicons of the multi-replicon plasmids pGSH500 and pLV1402 have been characterized by DNA sequence analysis. Analysis of the DNA sequence of a 3672 bp HIN:dIII fragment from pFDT100, which contains the pGSH500 alpha replicon, revealed similarity to a number of replicons belonging to, or related to, those of the IncFII family. The replicon region contains copA, tapA, repA and oriR, and replication initiation and termination sites are related to those from the IncFII replicon of R1. A copB gene was found to lie upstream of the HIN:dIII site in the parental plasmid pGSH500. Downstream of oriR, a 707 bp region shows 72.6% identity to a region of the Escherichia coli chromosome at 43.3', suggesting this region of pGSH500 may have been incorporated into the plasmid during a past chromosomal recombination event. Oligonucleotide primers homologous to consensus regions in the copB and repA genes, and the oriR regions from a number of IncFII-related replicons were used to amplify replication regions from pLV1402. Analysis of the amplified regions has shown the presence of copB, copA, tapA and repA genes. Phylogenetic analysis of Rep protein sequences from the RepFIIA family of antisense-control-regulated replicons revealed the presence of three distinct subgroups of Rep proteins. Comparative analysis of DNA and protein sequences from members of the RepFIIA family provides evidence supporting the roles of both non-selective divergence in co-integrate (multi-replicon) plasmids and Chi-mediated-recombination in replicon evolution, and in particular, that such processes may have been widespread in the evolution of the RepFIIA family.

Escherichia coli and Bacillus subtilis PriA proteins essential for recombination-dependent DNA replication: involvement of ATPase/helicase activity of PriA for inducible stable DNA replication

The E. coli PriA protein, a DEXH-type DNA helicase with unique zinc finger-like motifs interrupting the helicase domains, is an essential component of the phiX174-type primosome and plays critical roles in RecA-dependent inducible and constitutive stable DNA replication (iSDR and cSDR, respectively) as well as in recombination-dependent repair of double-stranded DNA breaks. B. subtilis PriA (BsPriA) protein contains the conserved helicase domains as well as zinc finger-like motifs with 34% overall identity with the E. coli counterpart. We overexpressed and purified BsPriA and examined its biochemical properties. BsPriA binds specifically to both n'-pas (primosome assembly site) and D-loop and hydrolyzes ATP in the presence of n'-pas albeit with a specific activity about 30% of that of E. coli PriA. However, it is not capable of supporting n'-pas-dependent replication in vitro, nor is it able to support ColE1-type plasmid replication in vivo which requires the function of the phiX174-type primosome. We also show that a zinc finger mutant is not able to support recombination-dependent DNA replication, as measured by the level of iSDR after a period of thymine starvation, nor wild-type level of growth, cell morphology and UV resistance. Unexpectedly, we discovered that an ATPase-deficient mutant (K230D) is not able to support iSDR to a full extent, although it can restore normal growth rate and UV resistance as well as non-filamentous morphology in priA1::kan mutant. K230D was previously reported to be fully functional in assembly of the phiX174-type primosome at a single-stranded n'-pas. Our results indicate that ATP hydrolysis/ helicase activity of PriA may be specifically required for DNA replication from recombination intermediates in vivo.

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

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

Replication and control of circular bacterial plasmids

An essential feature of bacterial plasmids is their ability to replicate as autonomous genetic elements in a controlled way within the host. Therefore, they can be used to explore the mechanisms involved in DNA replication and to analyze the different strategies that couple DNA replication to other critical events in the cell cycle. In this review, we focus on replication and its control in circular plasmids. Plasmid replication can be conveniently divided into three stages: initiation, elongation, and termination. The inability of DNA polymerases to initiate de novo replication makes necessary the independent generation of a primer. This is solved, in circular plasmids, by two main strategies: (i) opening of the strands followed by RNA priming (theta and strand displacement replication) or (ii) cleavage of one of the DNA strands to generate a 3'-OH end (rolling-circle replication). Initiation is catalyzed most frequently by one or a few plasmid-encoded initiation proteins that recognize plasmid-specific DNA sequences and determine the point from which replication starts (the origin of replication). In some cases, these proteins also participate directly in the generation of the primer. These initiators can also play the role of pilot proteins that guide the assembly of the host replisome at the plasmid origin. Elongation of plasmid replication is carried out basically by DNA polymerase III holoenzyme (and, in some cases, by DNA polymerase I at an early stage), with the participation of other host proteins that form the replisome. Termination of replication has specific requirements and implications for reinitiation, studies of which have started. The initiation stage plays an additional role: it is the stage at which mechanisms controlling replication operate. The objective of this control is to maintain a fixed concentration of plasmid molecules in a growing bacterial population (duplication of the plasmid pool paced with duplication of the bacterial population). The molecules involved directly in this control can be (i) RNA (antisense RNA), (ii) DNA sequences (iterons), or (iii) antisense RNA and proteins acting in concert. The control elements maintain an average frequency of one plasmid replication per plasmid copy per cell cycle and can "sense" and correct deviations from this average. Most of the current knowledge on plasmid replication and its control is based on the results of analyses performed with pure cultures under steady-state growth conditions. This knowledge sets important parameters needed to understand the maintenance of these genetic elements in mixed populations and under environmental conditions.

Structure of the Escherichia coli primase/single-strand DNA-binding protein/phage G4oric complex required for primer RNA synthesis

Escherichia coli primase/SSB/single-stranded phage G4oric is a simple system to study how primase interacts with DNA template to synthesize primer RNA for initiation of DNA replication. By a strategy of deletion analysis and antisense oligonucleotide protection on small single-stranded G4oric fragments, we have identified the DNA sequences required for binding primase and the critical location of single-strand DNA-binding (SSB) protein. Together with the previous data, we have defined the structure of the primase/SSB/G4oric priming complex. Two SSB tetramers bind to the G4oric secondary structure, which dictates the spacing of 3' and 5' bound adjacent SSB tetramers and leaves SSB-free regions on both sides of the stem-loop structure. Two primase molecules then bind separately to specific DNA sequences in the 3' and 5' SSB-free G4oric regions. Binding of the 3' SSB tetramer, upstream of the primer RNA initiation site, is also necessary for priming. The generation of a primase-recognition target by SSB phasing at DNA hairpin structures may be applicable to the binding of initiator proteins in other single-stranded DNA priming systems. Novel techniques used in this study include antisense oligonucleotide protection and RNA synthesis on an SSB-melted, double-stranded DNA template.

Frpo: a novel single-stranded DNA promoter for transcription and for primer RNA synthesis of DNA replication

We describe a novel promoter for E. coli RNA polymerase that functions efficiently only in the form of single-stranded DNA. Derived from the leading region of F plasmid, single-stranded Frpo sequence directs RNA polymerase to initiate transcription at a specific site within Frpo, and this specific transcription is highly stimulated by SSB. Prior denaturation activates transcription from otherwise inactive duplex DNA containing Frpo. Since RNAs synthesized on SSB-coated single-stranded Frpo are efficiently elongated into DNA chains by DNA polymerase III holoenzyme, transcription at Frpo serves also for priming DNA replication. A mode of recognition by RNA polymerase of a unique secondary structure within Frpo is proposed, and possible roles of this novel single-stranded promoter in expression and replication during conjugal transfer of F plasmid are discussed.

Role of the RepA1 protein in RepFIC plasmid replication

Using a sensitive primer extension technique, we have carried out studies to localize the start site of replication of the replicon RepFIC. In the course of these studies, we have found evidence that supports the hypothesis that transcription is an integral component of the initiation of replication. On the basis of our findings, we suggest that the transcript is processed to act as a primer, and therefore we propose that the transcript has a dual role as primer of replication and mRNA for the RepA1 protein. We present a model, based on our evidence, for the initiation of replication of the replicon RepFIC. This model provides as well an alternative explanation for what has been called the cis action of RepA1, and we show that RepA1 may act in trans as well as in cis.

Interaction of Escherichia coli primase with a phage G4ori(c)-E. coli SSB complex

We earlier reported that Escherichia coli single-stranded DNA-binding protein (SSB) bound in a fixed position to the stem-loop structure of the origin of complementary DNA strand synthesis in phage G4 (G4ori(c)), leaving stem-loop I and the adjacent 5' CTG 3', the primer RNA initiation site, as an SSB-free region (W. Sun and G. N. Godson, J. Biol. Chem. 268:8026-8039, 1993). Using a small 278-nucleotide (nt) G4ori(c) single-stranded DNA fragment that supported primer RNA synthesis, we now demonstrate by gel shift that E. coli primase can stably interact with the SSB-G4ori(c) complex. This stable interaction requires Mg2+ for specificity. At 8 mM Mg2+, primase binds to an SSB-coated 278-nt G4ori(c) fragment but not to an SSB-coated control 285-nt LacZ ss-DNA fragment. In the absence of Mg2+, primase binds to both SSB-coated fragments and gives a gel shift. T4 gene 32 protein cannot substitute for E. coli SSB in this reaction. Stable interaction of primase with naked G4ori(c). single-stranded DNA was not observed. DNase I and micrococcal nuclease footprinting, of both 5' and 3' 32P-labeled DNA, demonstrated that primase interacts with two regions of G4ori(c): one covering stem-loop I and the 3' sequence flanking stem-loop I which contains the pRNA initiation site and another located on the 5' sequence flanking stem-loop III.

Mechanisms of primer RNA synthesis and D-loop/R-loop-dependent DNA replication in Escherichia coli

In DNA replication, DNA chains are generally initiated from small pieces of ribonucleotides attached to DNA templates. These 'primers' are synthesized by various enzymatic mechanisms in Escherichia coli. Studies on primer RNA synthesis on single-stranded DNA templates containing specific 'priming signals' revealed the presence of two distinct modes, ie immobile and mobile priming. The former includes primer RNA synthesis by primase encoded by dnaG and by RNA polymerase containing a sigma 70 subunit. Priming is initiated at a specific site in immobile priming. Novel immobile priming signals were identified from various plasmid replicons, some of which function in initiation of the leading strand synthesis. The latter, on the other hands involves a protein complex, primosome, which contains DnaB, the replicative helicase for E coli chromosomal replication. Utilizing the energy fueled by ATP hydrolysis of DnaB protein, primosomes are able to translocate on a template DNA and primase synthesizes primer RNAs at multiple sites. Two distinct primosomes, DnaA-dependent and PriA-dependent, have been identified, which are differentially utilized for E coli chromosomal replication. Whereas DnaA-dependent primosome supports normal chromosomal replication from oriC, the PriA-dependent primosome functions in oriC-independent chromosomal replication observed in DNA-damaged cells or cells lacking RNaseH activity. In oriC-independent replication, PriA protein may recognize the D- or R-loop structure, respectively, to initiate assembly of a primosome which mediates primer RNA synthesis and replication fork progression.

Comparative analysis of functional and structural features in the primase-dependent priming signals, G sites, from phages and plasmids

The primase-dependent priming signals, G sites, are directly recognized by the Escherichia coli primase (dnaG gene product) and conduct the synthesis of primer RNAs. In nucleotide sequence and secondary structure, there is no striking resemblance between the phage- and plasmid-derived G sites, except for the limited sequence homology near the start position of primer RNA synthesis. In this study, we analyzed the structure and function of a G site of plasmid R100, G site (R100), and discovered the necessity of the coexistence of two domains (domains I and III), which contains blocks A, B, and C, which are nucleotide sequences highly conserved among the plasmid-derived G sites. However, neither the internal region, domain II, between domains I and III nor the potential secondary structure proposed by Bahk et al. (J. D. Bahk, N. Kioka, H. Sakai, and T. Komano, Plasmid 20:266-270, 1988) is essential for single-stranded DNA initiation activity. Furthermore, chimeric G sites constructed between a G site of phage G4, G site(G4), and G site(R100) maintained significant single-stranded DNA initiation activities. These results strongly suggest that phage- and plasmid-derived G sites have functionally equivalent domains. The primase-dependent priming mechanisms of phage- and plasmid-derived G sites are discussed.

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.

Mutational analysis of the specific priming signal essential for DNA replication of the broad host-range plasmid RSF1010

To analyze the RSF1010-specific priming mechanism, a library of randomly mutagenized ssiA sequences was constructed by chemical synthesis using mixed nucleotide phosphoramidites. Synthetic ssiA sequences with the single base-substitutions were assayed for the SSI activity in E. coli JM109 expressing RepB' primase. It was demonstrated that the activity of ssiA was damaged markedly by single base-substitutions within the possible stem-loop structure and its 3'-flanking region. It is conceivable that these domains are critical in recognition and primer synthesis by RepB' primase.

Roles of the G site and phi X174-type primosome assembly site in priming of leading-strand synthesis: initiation by a mobile primosome and replication-fork arrest by RepA protein bound to oriR

Bacterial replicons often contain single-strand initiation sequences (ssi) such as a G site (a sequence recognized by a dnaG-encoded primase for the synthesis of primer RNA) and a primosome assembly site (pas) near the DNA replication origin (ori). The R1 plasmid contains a G site downstream from oriR, which serves for the priming of the leading-strand synthesis of this plasmid. On the other hand, the F, R6K and Rts1 plasmids carry pas at similar locations relative to the respective ori. In order to assess the functional significance of these pas, R1 plasmid derivatives carrying an n'-pas (phi X174-type pas) in place of the G site were constructed and their replication properties were examined in vitro. Deletion of the G site in the R1 plasmid resulted in a nearly 80% reduction of total DNA synthesis in vitro, which was recovered to the wild-type (wt) level by inserting the G4 complementary ori. Furthermore, insertion of an n'-pas on the leading-strand template restored the in vitro replicative activity to a level 70% of wt. This recovery was dependent on the assembly of the phi X174-type primosome, which efficiently primed leading-strand synthesis and moved toward the oriR. However, the R1 plasmid derivative containing the n'-pas replicated unidirectionally in vitro, probably due to the anti-helicase activity of the RepA protein bound to oriR, which was shown by helicase assays using partial heteroduplexes as substrates.(ABSTRACT TRUNCATED AT 250 WORDS)

Differential binding of wild-type and a mutant RepA protein to oriR sequence suggests a model for the initiation of plasmid R1 replication

DNA replication of the enterobacterial plasmid R1 is initiated by RepA protein. We have developed a new procedure for the purification of RepA from inclusion bodies, which involves CHAPS-mediated solubilization. This method has been also used for the thermosensitive mutant protein RepA2623. The nucleoprotein complexes obtained with both proteins and oriR, the origin of replication, are studied in this paper. DNaseI and hydroxyl-radical footprinting suggest the presence in oriR of two sites with different affinity for RepA separated by eight helical turns. The pattern of hypersensitive sites in the footprints indicates that the oriR sequence, when complexed with RepA, is curved. The binding of RepA molecules to oriR is co-operative and this co-operativity is defective in the thermosensitive protein. Band-shift analysis of RepA-oriR complexes revealed the existence of a species with an anomalously high electrophoretic mobility that appears after formation of the first RepA-oriR complex and requires the sequential interaction of RepA with its two distal binding sites. These features lead us to propose that protein-protein interactions between RepA bound to both distal sites could be responsible for oriR looping. This model represents a novel mechanism that results in activation of an origin in a replicon that does not contain iterons.

Characterization of the minimal origin required for replication of the streptococcal plasmid pIP501 in Bacillus subtilis

By using deletional analysis the origin of replication, oriR, of the streptococcal plasmid pIP501 in Bacillus subtilis has been mapped at a position immediately downstream of the repR gene. Determination of both the right and left border of oriR allowed the definition of a sequence of a maximum of 52 nucleotides which theoretically constitutes the minimal origin of replication. Recently, the start point of leading-strand synthesis of the closely related plasmid pAM beta 1 has been mapped at a position which is located exactly in the middle of this sequence (Bruand et al., 1991). The function of oriR did not depend on its location downstream of the repR gene. Translocation of oriR-containing fragments to other regions of the plasmid proved to be possible. The smallest translocated fragment that still reconstituted autonomous replication was 72bp in size. This fragment was also active in directing the replication of an Escherichia coli plasmid in B. subtilis when the RepR protein was supplied in trans from a repR gene integrated into the host chromosome. The transformation efficiency of plasmids carrying translocated oriR fragments showed a certain dependence on the fragment length and orientation. The DNA sequence of oriR included an inverted repeat, both branches of which appeared to be essential for oriR function. The repeats of oriR shared sequence similarity with a repeat located upstream of promoter pII, which has been suggested to be involved in autoregulation of repR expression.

Enriched sources of Escherichia coli replication proteins. The dnaG primase is a zinc metalloprotein

Primase, the product of the Escherichia coli dnaG gene, is the enzyme responsible for RNA primer synthesis on both template strands at replication forks during chromosomal DNA synthesis. The dnaG gene was modified by replacement of the natural ribosome-binding site with one complementary to the 3' end of 16S rRNA, and then inserted downstream of tandem bacteriophage lambda PR and PL promoters in the pUC9-derived vector pCE30. Following thermal induction of transcription, the resulting plasmid pPL195 directed synthesis of primase activity to levels corresponding to approx. 120,000 molecules per cell. The overproduced protein was soluble and was readily purified in high yield (31 mg per 1 of culture). Purified primase was monomeric, was fully active in priming replication at the bacteriophage G4 complementary strand origin, and was shown to contain 0.92 +/- 0.08 g atom of tightly-bound zinc per mol of protein. Potential zinc-binding amino-acid residues near the N-terminus of the protein were identified. Although a mutant primase lacking 27 amino acid residues from the N-terminus was partly soluble, it was completely inactive.

Identification of eleven single-strand initiation sequences (ssi) for priming of DNA replication in the F, R6K, R100 and ColE2 plasmids

Based on the ability to complement the poor growth of an M13 phage derivative lacking the complementary strand origin, eleven single-strand initiation sequences (ssi) for DNA replication are identified in the F, R6K, R100 and ColE2 plasmids. Six of them were from F, two from near the gamma and alpha origins (ori) of R6K, two from the vicinity of the basic replicon of R100 and one from near the ori of ColE2. They can be classified into two groups based on the morphology of the plaques and the length of nucleotide (nt) sequences required for ssi activity; one group that gives rise to larger and clearer plaques and can be reduced to nearly 100 nt (seven out of eleven), and another that generates smaller and less clear plaques and requires more than 200 nt for full activity (four out of eleven). Sequence homology is detected among some members from both groups. The possible biological roles of the ssi are discussed.

Specificity of recognition sequence for Escherichia coli primase

We have surveyed the frequency of each of 64 trinucleotide permutations at every nucleotide frame located from 1 to 15 nucleotides upstream of primer RNA-DNA transition sites mapped within a 1.5 kb region of the bacteriophage lambda genome and a 1.4 kb region of the Escherichia coli genome. We have demonstrated that in both systems initiation of DNA synthesis strongly correlates with a CAG sequence located 11 nucleotides upstream of the DNA start sites. Based on the examination of various reports of the priming reaction catalyzed by E. coli primase in vivo and in vitro, we propose that (i) E. coli primase itself recognizes a 3'GTC 5' sequence on the template strand, (ii) DnaB helicase releases the specificity of E. coli primase and, (iii) the consensus recognition sequence for E. coli primase associated with DnaB helicase is 3'PuPyPy 5'.

Plasmid Co1IB contains an ssi signal close to the replication origin

Taking advantage of the plaque morphology method, we identified a single-strand initiation (ssi) signal in plasmid pSM32, a mini-Co1Ib plasmid. This ssi signal was situated in the 350-nt HaeIII segment of the 1.8-kb S7 fragment, and located nearly 400 nt downstream of the origin of DNA replication. Introduction of the ssi signal into a mutant of filamentous phage M13 lacking oric resulted in restoration of phage growth and RFI DNA synthesis. Interestingly, DNA homology studies showed that the nucleotide sequence of the ssi signal was extremely homologous with that of the "G4-type" ssi signal in plasmid R100.