Regulation of DNA replication by iterons: an interaction between the ori2 and incC regions mediated by RepE-bound iterons inhibits DNA replication of mini-F plasmid in Escherichia coli.

In bacteria, plasmids and some DNA viruses, DNA replication is initiated and regulated by binding of initiator proteins to repetitive sequences. To understand the control mechanism we used the plasmid mini-F, whose copy number is stringently maintained in Escherichia coli, mainly by its initiator protein RepE and the incC region. The monomers of RepE protein bound to incC iterons, which exert incompatibility in trans and control the copy number of mini-F plasmid in cis. Many incompatibility defective mutants carrying mutations in their incC iterons had lost the affinity to bind to RepE, while one mutant retained high level binding affinity. The mutated incC mini-F plasmids lost the function to control the copy number. The copy number of the wild-type mini-F plasmid did not increase in the presence of excess RepE. These results suggested that the control of replication by incC iterons does not rely on their capacity to titrate RepE protein. Using a ligation assay, we found that RepE proteins mediated a cross-link structure between ori2 and incC, for which the dimerization domain of RepE and the structure of incC seem to be important. The structure probably causes inhibition of extra rounds of DNA replication initiation on mini-F plasmids, thereby keeping mini-F plasmid at a low copy number.     

The localized melting of mini-F origin by the combined action of the mini-F initiator protein (RepE) and HU and DnaA of Escherichia coli

Replication of mini-F plasmids requires the initiator protein RepE, which binds specifically to four iterons within the origin (ori2), as well as some host factors that are involved in chromosomal DNA replication. To understand the role of host factors and RepE in the early steps of mini-F DNA replication, we examined the effects of RepE and the Escherichia coli proteins DnaA and HU on the localized melting of ori2 DNA in a purified in vitro system. We found that the binding of RepE to an iteron causes a 50^° bend at or around the site of binding. RepE and HU exhibited synergistic effects on the localized melting within the ori2 region, as detected by sensitivity to the single-strand specific P1 endonuclease. This opening of duplex DNA occurred around the 13mer of ori2, whose sequence closely resembles the set of 13mers found in the chromosomal origin oriC. Further addition of DnaA to the reaction mixture increased the efficiency of melting and appeared to extend melting to the adjacent AT-rich region. Moreover, DNA melting with appreciably higher efficiencies was observed with mutant forms of RepE that were previously shown to be hyperactive both in DNA binding in vitro and in initiator activity in vivo. We propose that the binding of RepE to four iterons of ori2 causes bending at the sites of RepE binding and, with the assistance of HU, induces a localized melting in the 13mer region. The addition of DnaA extends melting to the AT-rich region, which could then serve as the entry site for the DnaB-DnaC complex, much as has been documented for oriC- dependent replication.     

The localized melting of mini-F origin by the combined action of the mini-F initiator protein (RepE) and HU and DnaA of Escherichia coli

 Replication of mini-F plasmids requires the initiator protein RepE, which binds specifically to four iterons within the origin (ori2), as well as some host factors that are involved in chromosomal DNA replication. To understand the role of host factors and RepE in the early steps of mini-F DNA replication, we examined the effects of RepE and the Escherichia coli proteins DnaA and HU on the localized melting of ori2 DNA in a purified in vitro system. We found that the binding of RepE to an iteron causes a 50^° bend at or around the site of binding. RepE and HU exhibited synergistic effects on the localized melting within the ori2 region, as detected by sensitivity to the single-strand specific P1 endonuclease. This opening of duplex DNA occurred around the 13mer of ori2, whose sequence closely resembles the set of 13mers found in the chromosomal origin oriC. Further addition of DnaA to the reaction mixture increased the efficiency of melting and appeared to extend melting to the adjacent AT-rich region. Moreover, DNA melting with appreciably higher efficiencies was observed with mutant forms of RepE that were previously shown to be hyperactive both in DNA binding in vitro and in initiator activity in vivo. We propose that the binding of RepE to four iterons of ori2 causes bending at the sites of RepE binding and, with the assistance of HU, induces a localized melting in the 13mer region. The addition of DnaA extends melting to the AT-rich region, which could then serve as the entry site for the DnaB-DnaC complex, much as has been documented for oriC- dependent replication. Received: 15 May 1996/Accepted: 11 July 1996     

Mechanism of origin activation by monomers of R6K-encoded pi protein

One recurring theme in plasmid duplication is the recognition of the origin of replication (ori) by specific Rep proteins that bind to DNA sequences called iterons. For plasmid R6K, this process involves a complex interplay between monomers and dimers of the Rep protein, pi, with seven tandem iterons of gamma ori. Remarkably, both pi monomers and pi dimers can bind to iterons, a new paradigm in replication control. Dimers, the predominant form in the cell, inhibit replication, while monomers facilitate open complex formation and activate the ori. Here, we investigate a mechanism by which pi monomers out-compete pi dimers for iteron binding, and in so doing activate the ori. With an in vivo plasmid incompatibility assay, we find that pi monomers bind cooperatively to two adjacent iterons. Cooperative binding is eliminated by insertion of a half-helical turn between two iterons but is diminished only slightly by insertion of a full helical turn between two iterons. These studies show also that pi bound to a consensus site promotes occupancy of an adjacent mutated site, another hallmark of cooperative interactions. pi monomer/iteron interactions were quantified using a monomer-biased pi variant in vitro with the same collection of two-iteron constructs. The cooperativity coefficients mirror the plasmid incompatibility results for each construct tested. pi dimer/iteron interactions were quantified with a dimer-biased mutant in vitro and it was found that pi dimers bind with negligible cooperativity to two tandem iterons.     

Control of F plasmid replication by a host gene: evidence for interaction of the mafA gene product of Escherichia coli with the mini-F incC region.

Replication of F (including mini-F) and some related plasmids is known to be specifically inhibited in mafA mutants of Escherichia coli K-12. We have now isolated and characterized mini-F mutants that can overcome the replication inhibition. Such plasmids, designated pom (permissive on maf), were obtained spontaneously or after mutagenesis with hydroxylamine or by transposon (Tn3) insertion. In addition to their ability to replicate in mafA mutant bacteria, the pom mutant plasmids exhibit an increased copy number and resistance to "curing" by acridine dye in the mafA+ host. In agreement with these results, Tn3-induced pom mutants were found to carry Tn3 inserted at the incC region of mini-F DNA, known to be involved in incompatibility, control of copy number, and sensitivity to acridine dye. Furthermore, three of the seven mini-F plasmids tested that carry Tn3 within the tandem repeat sequences of the incC region (previously isolated by other workers) exhibit all the phenotypes of pom plasmids, the ability to replicate in the mafA strain, and high copy number and acridine resistance in the mafA+ strain. The rest of the plasmids that contain Tn3 just outside the tandem repeats remain wild type in all these properties. These results strongly suggest that the putative mafA gene product of host bacteria controls mini-F replication through interaction with the incC region.     

Repetitive plasmid sequences generate DNA fingerprinting patterns in mammals

Bacterial plasmids with stringently regulated copy numbers have directly repeated DNA sequences, termed iterons, in the vicinity of their replication origins. These sequences bind a specific protein exerting a key role in the initiation of plasmid replication. Plasmids P1, pSC101 and RFS1010 have different iteron sequences and belong to three different incompatibility groups. Used as DNA probes each of these plasmids generates specific patterns in mammals similar to those obtained by the DNA fingerprinting technique. The iteron-containing regions were identified as the part of the plasmids responsible for those patterns by using polymerase chain reaction (PCR) amplified DNA segments that contained the iteron regions as probes.     

Crystal structure of a prokaryotic replication initiator protein bound to DNA at 2.6 A resolution.

The initiator protein (RepE) of F factor, a plasmid involved in sexual conjugation in Escherichia coli, has dual functions during the initiation of DNA replication which are determined by whether it exists as a dimer or as a monomer. A RepE monomer functions as a replication initiator, but a RepE dimer functions as an autogenous repressor. We have solved the crystal structure of the RepE monomer bound to an iteron DNA sequence of the replication origin of plasmid F. The RepE monomer consists of topologically similar N- and C-terminal domains related to each other by internal pseudo 2-fold symmetry, despite the lack of amino acid similarities between the domains. Both domains bind to the two major grooves of the iteron (19 bp) with different binding affinities. The C-terminal domain plays the leading role in this binding, while the N-terminal domain has an additional role in RepE dimerization. The structure also suggests that superhelical DNA induced at the origin of plasmid F by four RepEs and one HU dimer has an essential role in the initiation of DNA replication.     

Binding of RepE initiator protein to mini-F DNA origin (ori2). Enhancing effects of repE mutations and DnaJ heat shock protein.

Replication of mini-F plasmid in Escherichia coli requires the plasmid-encoded RepE initiator protein and a number of host factors and is regulated by interaction of RepE with specific sequences near the replication origin, ori2. We have examined DNA binding properties of several hyperactive mutant RepE proteins with single amino acid substitutions. Plasmids carrying these (repE) mutations, unlike the parental plasmid, can replicate in bacterial hosts lacking the heat shock sigma factor (sigma 32) or deficient in the DnaK, DnaJ, or GrpE heat shock protein. Using gel-retardation assays, the mutant RepE proteins were shown to bind the ori2 repeated sequences with much increased affinities compared to the wild type RepE, whereas they bound to the repE operator with slightly reduced affinities. These results agreed well with the properties of mutant RepE proteins studied in vivo and accounted for the high RepE initiator activities and the high copy numbers of mutant plasmids. In addition, the DnaJ heat shock protein was found to markedly enhance the binding of wild type RepE to ori2 or the operator. DnaK protein with or without ATP failed to show such enhancements. Thus, among the heat shock proteins required for mini-F replication, DnaJ appears to play a major role in RepE binding to ori2 and the operator, perhaps accompanied by RepE activation.     

Minimal essential origin of plasmid pSC101 replication: requirement of a region downstream of iterons.

The minimal replication origin (ori) of the plasmid pSC101 was defined as an about 220-bp region under the condition that the Rep (or RepA) protein, a plasmid-encoded initiator protein, was supplied in trans. The DnaA box is located at one end of ori, as in other plasmids, like mini-F and P1. The other border is a strong binding site (IR-1) of Rep which is palindromic sequence and lies in an about 50-bp region beyond the repeated sequences (iterons) in ori. This IR-1 is located just upstream of another strong Rep binding site (IR-2), the operator site of the structure gene of Rep (rep), but its function has not been determined. The present study shows that the IR-1 sequence capable of binding to Rep is essential for plasmid replication with a nearly normal copy number. Furthermore, a region between the third iteron and IR-1 is also required in a sequence-specific fashion, since some one-base substitution in this region inactivate the origin function. It is likely that the region also is a recognition site of an unknown protein. Three copy number mutations of rep can suppress any one-base substitution mutation. On the other hand, the sequence of a spacer region between the second and the third iterons, which is similar to that of the downstream region of the third iteron, can be changed without loss of the origin function. The requirement of the region downstream of iterons in pSC101 seems to be unique among iteron-driven plasmid replicons.     

Mini-F plasmid mutants able to replicate in Escherichia coli deficient in the DnaJ heat shock protein.

A subset of Escherichia coli heat shock proteins, DnaJ, DnaK, and GrpE, is required for mini-F plasmid replication, presumably at the step of functioning of the RepE initiator protein. We have isolated and characterized mini-F plasmid mutants that acquired the ability to replicate in the Escherichia coli dnaJ259. The mutant plasmids were found to replicate in any of dnaJ, dnaK, and grpE mutant hosts tested. In each case, the majority of the mutant plasmids carried a unique amino acid alteration in a localized region of repE coding sequence and showed an increased copy number, whereas the minority contained a common single base change (C to T) in the promoter/operator region and produced an increased amount of RepE. All RepE proteins with altered residues (between 92 and 134) exhibited increased initiator activities (hyperactive), and many showed reduced repressor activities as well, indicating that this region is important for the both major functions of RepE protein. These results together with evidence reported elsewhere indicate that the subset of heat shock proteins serves to activate RepE protein prior to or during its binding to the replication origin and that the mutant RepE proteins are active even in their absence. We also found that a C-terminal lesion (repE602) reduces the initiator activity particularly of some hyperactive mutant RepE proteins but does not affect the repressor activity. This finding suggests a functional interaction between the central and C-terminal regions of RepE in carrying out the initiator function.     

Different phenotypes of Walker-like A box mutants of ParA homolog IncC of broad-host-range IncP plasmids

The promiscuous IncPα plasmids RK2 and R995 encode a broad-host-range partition system, whose essential components include the incC and korB genes and a DNA site (O(B)) to which the korB product binds. IncC2, the smaller of the two incC products, is sufficient for stabilization of R995ΔincC. It is a member of the type Ia ParA family of partition ATPases. To better understand the role of ATP in partition, we constructed three alanine-substitution mutants of IncC2. Each mutation changed a different residue of the Walker-like ATP-binding and hydrolysis motif, including a lysine (K10) conserved solely among members of the ParA and MinD families. All three IncC2 mutants were defective in plasmid partition, but they differed from one another in other respects. The IncC2 T16A mutant, predicted to be defective in Mg2? coordination, was severely impaired in all activities tested. IncC2 K10A, predicted to be defective in ATP hydrolysis, mediated enhanced incompatibility with R995 derivatives. IncC2 K15A, predicted to be defective in ATP binding, exhibited two distinct incompatibility properties depending on the genotype of the target plasmid. When in trans to plasmids carrying a complementable incC deletion, IncC2 K15A caused dramatic plasmid loss, even at low levels of expression. In trans to wild-type R995 or to R995ΔincC carrying a functional P1 partition system, IncC2 K15A-mediated incompatibility was significantly less than that caused by wild-type IncC2. All three Walker-like A box mutants were also defective for the host toxicity that normally results from co-overexpression of incC and korB. The phenotypes of the mutants support a model in which nucleotide hydrolysis is required for separation of paired plasmid complexes and possible interaction with a host factor.     

A mutational hot spot in the incompatibility gene incC of mini-F plasmid

The incC incompatibility locus of the mini-F plasmid is also a replication control locus. We have selected and sequenced six independent incC mutations. Each mutation causes a partial loss of incompatibility. All mutations are GC----AT transitions. Five of six mutations occur in the same base pair located at coordinate 46.070 kb; the sixth mutation occurs in an adjacent base pair at 46.069 kb. Both mutational sites are in a hexanucleotide sequence common to several origins of replication.     

Direct repeats of the F plasmid incC region express F incompatibility

The nucleotide sequence of the incompatibility region incC, located at 45.8--46.4 kb on the F plasmid map, was determined. This region consists of 543 bp and contains sufficient information to code for only two small polypeptides of 34 and 30 amino acids each. Deletion of the ATG start codons for these two polypeptides has no effect on expression of incC incompatibility. A prominent feature of this sequence is the presence of five 22 bp direct repeats. A 58 bp segment of the incC region that contains two of these direct repeats was inserted into plasmid pACYC184, which is compatible with the F plasmid. The pACYC184 plasmid containing the direct-repeat sequences now expresses incompatibility with the F'lac plasmid and replication-proficient derivatives of the mini-F plasmid.     

Interactions of plasmid-encoded replication initiation proteins with the origin of DNA replication in the broad host range plasmid RK2

The TrfA proteins, encoded by the broad host range plasmid RK2, are required for replication of this plasmid in a variety of Gram-negative bacteria. Two TrfA proteins, 33 and 44 kDa in molecular mass (designated TrfA-33 and TrfA-44, respectively), are expressed from the trfA gene of RK2 through the use of two alternative in-frame start codons within the same open reading frame. The two proteins have been purified from Escherichia coli to near homogeneity as a mixture of wild-type TrfA-44/33, as TrfA-33 alone and as a functional variant form of TrfA-44, designated TrfA-44(98L), which contains a leucine in place of the TrfA-33 methionine start codon. Cross-linking experiments demonstrated that TrfA-33 can multimerize in solution. By using gel mobility shift and DNase I footprinting techniques the binding properties of TrfA-33, TrfA-44(98L), and TrfA-44/33 to the origin of replication of plasmid RK2 were analyzed. All three protein preparations were able to bind very specifically to the cluster of five direct repeats (iterons) contained in the minimal origin of replication. Each protein preparation produced a ladder of TrfA/minimal oriV complexes of decreasing electrophoretic mobility. The DNase I protection pattern on the five iterons was identical for all three protein preparations and extended from the beginning of the first iteron to 5 base pairs upstream of the fifth iteron. Studies on the affinity of the proteins for DNA fragments containing one, two, or all five iterons of the origin revealed a strong preference of TrfA protein for DNA containing at least two iterons. To study the stability of TrfA.DNA complexes, association and dissociation rates of TrfA-33 and DNA fragments with one, two, or five iterons were measured. This analysis showed that unlike complexes involving two or five iterons the TrfA/one iteron complexes were highly unstable, suggesting some form of cooperativity between proteins or iterons in the formation of stable complexes and/or the requirement of specific sequences bordering the iterons at the RK2 origin of replication for the stabilization of TrfA/DNA complexes.     

The partition (par) locus of pSC101 is an enhancer of plasmid incompatibility

The incompatibitity that pSC101-derived plasmids express toward each other is mediated by directly repeated sequences (iterons) located near the plasmid's replication origin. We report here that the pSC101 par locus, which stabilizes plasmid inheritance in dividing cell populations and alters DNA superheliclty, can function as a cis-acting enhancer of incompatibility, which we show is determined jointly by the copy number of the plasmid and the number of iterons per copy. A single synthetic 32 bp iteron sequence carried by the pUC19 plasmid confers strong pSC101-specific incompatibility in the absence of any other pSC101 sites but requires the par locus to express strong incompatibility when carried by a lower-copy-number plasmid. We propose a model by which the par locus can enchance the apparently antagonistic processes of incompatibility and pSC101 DNA replication while concurrently facilitating plasmid distribution during cell division.