DNA bending of pSC101 ori induced by Rep,a replication initiator protein and IHF

Purified Rep (or RepA) protein, a replication initiator of plasmid pSC101, is present almost solely in the dimer form, and its binding activity for the directly repeated sequences (iterons) in the replication origin (ori) is very low. When Rep protein was treated with guanidine hydrochloride followed by renaturation, it was shown to bind to the iterons with very high efficiency. A gel shift experiment suggested that guanidine-treated Rep bound to iterons as a monomer form. The Rep monomer bound noncooperatively to the three iterons and induced bending of the DNA helix axis in the same direction (about 100 degrees ). The configuration of the IHF box that is a binding site of another DNA bending protein IHF, the three iterons and an AT-rich region between these sequences was important for efficient bending of the ori region. Furthermore, a mutant Rep protein (Rep(IHF)) which can support the plasmid replication in IHF-deficient host cells was purified, and it was found that affinity of the Rep(IHF) monomer for iterons was similar to that of wild-type Rep and bent DNA only 14 degrees more strongly than did the wild-type Rep. Rep(IHF)-dependent plasmid replication, however, required both enhancer regions, par and IR-1, in addition to "core ori" as a minimal essential ori, whereas only one of these two enhancers was necessary for wild-type Rep-dependent replication. How Rep(IHF) can support plasmid replication in the absence of IHF is discussed.     

AT-rich region and repeated sequences - the essential elements of replication origins of bacterial replicons

Repeated sequences are commonly present in the sites for DNA replication initiation in bacterial, archaeal, and eukaryotic replicons. Those motifs are usually the binding places for replication initiation proteins or replication regulatory factors. In prokaryotic replication origins, the most abundant repeated sequences are DnaA boxes which are the binding sites for chromosomal replication initiation protein DnaA, iterons which bind plasmid or phage DNA replication initiators, defined motifs for site-specific DNA methylation, and 13-nucleotide-long motifs of a not too well-characterized function, which are present within a specific region of replication origin containing higher than average content of adenine and thymine residues. In this review, we specify methods allowing identification of a replication origin, basing on the localization of an AT-rich region and the arrangement of the origin's structural elements. We describe the regularity of the position and structure of the AT-rich regions in bacterial chromosomes and plasmids. The importance of 13-nucleotide-long repeats present at the AT-rich region, as well as other motifs overlapping them, was pointed out to be essential for DNA replication initiation including origin opening, helicase loading and replication complex assembly. We also summarize the role of AT-rich region repeated sequences for DNA replication regulation.     

Negative control of plasmid pSC101 replication by increased concentrations of both initiator protein and iterons

Increased intracellular concentrations of the initiator protein Rep (or RepA) interfere with pSC101 DNA replication, and mutated Rep proteins that result in an increase in plasmid copy numbers do not inhibit the replication. A rep mutant (rep(inh)) defective in the inhibitory activity was isolated and found to be a new high copy number mutant. The inhibitory function of Rep was enhanced by the coexistence of directly repeated sequences (DR; iterons) in the replication origin region (ori), but not by the inverted repeat sequences (IR) in ori and the rep promoter. This synergistic effect of Rep and DR sequences for the replication inhibition was dependent on their intracellular concentrations. Considering that DR sequences are the specific binding sites of the Rep monomer form, the Rep monomer-DR complex might be responsible for the inhibition of the plasmid replication. Furthermore, the Rep monomer in the crude cell extracts facilitated dimerization of DR DNA fragments by DNA ligase. Neither synergistic inhibitory function with DR nor Rep mediated dimerization of DR DNA was observed in high copy number mutant Rep proteins. The role of the Rep-iteron complex in the copy number control of pSC101 is discussed.     

Two alternative structures can be formed by IHF protein binding to the plasmid R6K gamma origin.

Escherichia coli integration host factor (IHF) contributes to the regulation of R6K plasmid copy number by counteracting the inhibitory activity of the plasmid-encoded replication protein pi. Two IHF-binding sites (ihf1 and ihf2) flank seven iterons in the origin which bind pi protein. As previously shown by electron microscopy, IHF can compact a large segment of the R6K gamma origin DNA, encompassing site ihf1, an AT-rich domain containing ihf1, and some of the seven iterons located downstream of ihf1. We termed this phenomenon IHF-mediated DNA folding. This folding requires a high IHF concentration, and the region of the origin (replication enhancer) located to the left of the AT-rich domain. However, site ihf2 is not necessary in forming the folded structure. As reported here, IHF binding to ihf2 can be detected in gel mobility shift assays only if the leftmost enhancer region is absent. Sites ihf1 and ihf2 each contain two consensus IHF sequences. Site-directed mutagenesis was performed to determine which sequences are recognized by IHF protein and which sites are involved in forming the various gamma origin-IHF complexes. Finally, we define the boundaries of protection from DNaseI digestion when IHF is bound to ihf2. We propose a model in which IHF protein bound to ihf1, in the absence of the enhancer region, facilitates IHF binding to ihf2.     

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.     

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.     

Characterization of the oriI and oriII Origins of Replication in Phage-Plasmid P4

In the Escherichia coli phage-plasmid P4, two partially overlapping replicons with bipartite ori sites coexist. The essential components of the oriI replicon are the alpha and cnr genes and the ori1 and crr sites; the oriII replicon is composed of the alpha gene, with the internal ori2 site, and the crr region. The P4 alpha protein has primase and helicase activities and specifically binds type I iterons, present in ori1 and crr. Using a complementation test for plasmid replication, we demonstrated that the two replicons depend on both the primase and helicase activities of the alpha protein. Moreover, neither replicon requires the host DnaA, DnaG, and Rep functions. The bipartite origins of the two replicons share the crr site and differ for ori1 and ori2, respectively. By deletion mapping, we defined the minimal ori1 and ori2 regions sufficient for replication. The ori1 site was limited to a 123-bp region, which contains six type I iterons spaced regularly close to the helical periodicity, and a 35-bp AT-rich region. Deletion of one or more type I iterons inactivated oriI. Moreover, insertion of 6 or 10 bp within the ori1 region also abolished replication ability, suggesting that the relative arrangement of the iterons is relevant. The ori2 site was limited to a 36-bp P4 region that does not contain type I iterons. In vitro, the alpha protein did not bind ori2. Thus, the alpha protein appears to act differently at the two origins of 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.     

Open strands adjacent to iterons promote the binding of the replication initiator protein (Rep) of pSC101 to the unit sequence of the iterons in vitro

The purified dimeric form of the Rep protein, a replication initiator protein of the plasmid pSC101, has a low affinity for repeated sequences, iterons, in the replication origin of the plasmid, and higher affinities for two inverted repeats in the operator region of the rep gene resulting in its functioning as an autorepressor. Studies of binding to various synthetic DNA have established that Rep can bind to duplex iteron-sequence carrying open (non-complementary) strands at one end proximal to the rep gene. Open strands at the opposite end of the iteron have no effect on Rep-binding. One open strand seems to be required in a sequence-specific fashion. A randomly sequenced duplex DNA with the open strands cannot bind to Rep but can function as a significant competitor. This suggests that Rep has some affinity for the open strands and forms a stable complex with the adjacent iteron. The mutated Rep protein, Rep1, which causes an increase in the plasmid copy number in vivo, has equally high affinity for the iteron with the open strands as wild type Rep, though it has a lower affinity for the inverted repeats than the wild type. The Rep dimer might bind to these DNA sequences with different modes.     

Two enhancer elements for DNA replication of pSC101, par and a palindromic binding sequence of the Rep protein.

The minimal replication origin (ori) of the plasmid pSC101 has been previously defined as an approximately 220-bp region by using plasmids defective in the par region, which is a cis-acting determinant of plasmid stability. This ori region contains the DnaA binding sequence, three repeated sequences (iterons), and an inverted repeat (IR) element (IR-1), one of the binding sites of an initiator protein, Rep (or RepA). In the present study, we show that plasmids containing par can replicate at a nearly normal copy number in the absence of IR-1 but still require a region (the downstream region) between the third iteron and IR-1. Because par is dispensable in plasmids retaining IR-1, par and IR-1 can compensate each other for efficient replication. The region from the DnaA box to the downstream region can support DNA replication at a reduced frequency, and it is designated "core-ori." Addition of either IR-1 or par to core-ori increases the copy number of the plasmid up to a nearly normal level. However, the IR-1 element must be located downstream of the third iteron (or upstream of the rep gene) to enhance replication of the plasmid, while the par region, to which DNA gyrase can bind, functions optimally regardless of its location. Furthermore, the enhancer activity of IR-1 is dependent on the helical phase of the DNA double helix, suggesting that the Rep protein bound to IR-1 stimulates the activation of ori via its interaction with another factor or factors capable of binding to individual loci within ori.     

An essential iteron-binding protein required for plasmid R1162 replication induces localized melting within the origin at a specific site in AT-rich DNA.

The R1162-encoded protein RepIB is essential for replication of the plasmid and binds specifically to iterons within the replicative origin. The protein causes the localized melting of DNA (determined by sensitivity to P1 nuclease) at a site within the AT-rich region of the origin, about 60 bp from the iteron binding sites and separated from them by a GC-rich tract. Point mutations have been isolated in the AT-rich DNA. These mutations interfere with origin activity and also prevent the protein-induced sensitivity to P1. A second-site suppressor of one of these mutations maps in the repIb gene and restores both origin function and sensitivity to P1. The results suggest a specific interaction between RepIB and origin DNA at a position distant from its primary binding site.     

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     

Replication regulation of Vibrio cholerae chromosome II involves initiator binding to the origin both as monomer and as dimer

The origin region of Vibrio cholerae chromosome II (chrII) resembles plasmid origins that have repeated initiator-binding sites (iterons). Iterons are essential for initiation as well as preventing over-initiation of plasmid replication. In chrII, iterons are also essential for initiation but over-initiation is prevented by sites called 39-mers. Both iterons and 39-mers are binding sites of the chrII specific initiator, RctB. Here, we have isolated RctB mutants that permit over-initiation in the presence of 39-mers. Characterization of two of the mutants showed that both are defective in 39-mer binding, which helps to explain their over-initiation phenotype. In vitro, RctB bound to 39-mers as monomers, and to iterons as both monomers and dimers. Monomer binding to iterons increased in both the mutants, suggesting that monomers are likely to be the initiators. We suggest that dimers might be competitive inhibitors of monomer binding to iterons and thus help control replication negatively. ChrII replication was found to be dependent on chaperones DnaJ and DnaK in vivo. The chaperones preferentially improved dimer binding in vitro, further suggesting the importance of dimer binding in the control of chrII replication.     

Sequence-specific interactions of Rep proteins with ssDNA in the AT-rich region of the plasmid replication origin

The DNA unwinding element (DUE) is a sequence rich in adenine and thymine residues present within the origin region of both prokaryotic and eukaryotic replicons. Recently, it has been shown that this is the site where bacterial DnaA proteins, the chromosomal replication initiators, form a specific nucleoprotein filament. DnaA proteins contain a DNA binding domain (DBD) and belong to the family of origin binding proteins (OBPs). To date there has been no data on whether OBPs structurally different from DnaA can form nucleoprotein complexes within the DUE. In this work we demonstrate that plasmid Rep proteins, composed of two Winged Helix domains, distinct from the DBD, specifically bind to one of the strands of ssDNA within the DUE. We observed nucleoprotein complexes formed by these Rep proteins, involving both dsDNA containing the Rep-binding sites (iterons) and the strand-specific ssDNA of the DUE. Formation of these complexes required the presence of all repeated sequence elements located within the DUE. Any changes in these repeated sequences resulted in the disturbance in Rep-ssDNA DUE complex formation and the lack of origin replication activity in vivo or in vitro.     

The ColE2-P9 Rep protein binds to the origin DNA as a monomer

The Rep proteins of some plasmid replicons have two functions. Dimers bind to the operator sequences acting as auto-repressors, whereas monomers bind to the iterons to initiate replication of DNA. The ColE2 Rep proteins are present mostly in a dimeric form with some multimers larger than dimers in solution, while the form of Rep binding to Ori is not known. We used an EMSA-based method to determine the molecular weight of Rep in the Rep-Ori complex. The result suggested that Rep binds to Ori as a monomer. In addition, the result of EMSA using the Rep protein fused with the maltose binding protein and the His6-tag also supported this conclusion. We proposed that dimerization of Rep might probably be involved in keeping the copy number of the ColE2 plasmid at the normal low level by limiting the amount of active monomeric forms of Rep in the host cell.     

Exonuclease III promotes in vitro binding of the replication initiator protein of plasmid pSC101 to the repeated sequences in the ori region

Purified Rep protein, a replication initiator protein of plasmid pSC101, has less binding affinity for the direct repeats (DR) in the replication origin region (ori) than that for the inverted repeats (IR) in the promoter region of the structure gene of Rep (rep) (Sugiura, S. et al. (1990) J. Biochem. 107, 369-376). We found a protein factor that promotes binding of purified Rep to the DR sequence in the cell extract of Escherichia coli. In the presence of the factor, DNA fragments containing the DR sequence can form a specific DNA-protein complex by the addition of low concentrations of Rep. On the contrary, IR-containing DNA loses its binding activity for Rep by preincubation with the factor. We purified extensively the factor and identified it as exonuclease III (exo III). Enzymatic action of the factor or authentic exo III at 37 degrees C is necessary for binding of Rep to DR-DNA. This binding of Rep to duplex DNA treated with exo III is DR-sequence specific. Since Rep cannot bind to the single stranded DR sequence, the present finding suggests that partial single-stranded regions around the DR sequence are required for binding of Rep.     

Anatomy of the replication origin of plasmid ColE2-P9

The plasmid ColE2-P9 origin is a 32-bp region which is specifically recognized by the plasmid-specified Rep protein to initiate DNA replication. We analyzed the structural and functional organization of the ColE2 origin by using various derivatives carrying deletions and single-base-pair substitutions. The origin may be divided into three subregions: subregion I, which is important for stable binding of the Rep protein; subregion II, which is important for binding of the Rep protein and for initiation of DNA replication; and subregion III, which is important for DNA replication but apparently not for binding of the Rep protein. The Rep protein might recognize three specific DNA elements in subregions I and II. The relative transformation frequency of the autonomously replicating plasmids carrying deletions in subregion I is lower, and nevertheless the copy numbers of these plasmids in host bacteria are higher than those of the wild-type plasmid. Efficient and stable binding of the Rep protein to the origin might be important for the replication efficiency to be at the normal (low) level. Subregion II might be essential for interaction with the catalytic domain of the Rep protein for primer RNA synthesis. The 8-bp sequence across the border of subregions II and III, including the primer sequence, is conserved in the (putative) origins of many plasmids, the putative Rep proteins of which are related to the ColE2-P9 Rep protein. Subregion III might be required for a step that is necessary after Rep protein binding has taken place.     

In vitro recognition of the replication origin of pLS1 and of plasmids of the pLS1 family by the RepB initiator protein.

Rolling-circle replication of plasmid pLS1 is initiated by the plasmid-encoded RepB protein, which has nicking-closing (site-specific DNA strand transferase) enzymatic activity. The leading-strand origin of pLS1 contains two regions, (i) the RepB-binding site, constituted by three directly repeated sequences (iterons or the bind region), and (ii) the sequence where RepB introduces the nick to initiate replication (the nic region). A series of plasmids, belonging to the pLS1 family, show features similar to those of pLS1 and have DNA sequences homologous to the pLS1 nic region. In addition, they all share homologies at the level of their Rep proteins. However, the bind regions of these plasmids are, in general, not conserved. We tested the substrate specificity of purified RepB of pLS1. The RepB protein has a temperature-dependent nicking-closing action on supercoiled pLS1, as well as on recombinant plasmid DNAs harboring the pLS1 nic region. The DNA strand transferase activity of pLS1-encoded RepB was also assayed on two plasmids of the pLS1 family, namely, pE194 and pFX2. DNAs from both plasmids were relaxed by RepB, provided they had a proper degree of supercoiling; i.e., it was necessary to modulate the supercoiling of pE194 DNA to achieve RepB-mediated DNA relaxation. Single-stranded oligonucleotides containing the nic regions of various plasmids belonging to the pLS1 family, including those of pE194 and pFX2, were substrates for RepB. In vitro, the RepB protein does not need to bind to the iterons for its nicking-closing activity.