Cooperative binding of initiator protein to replication origin conferred by single amino acid substitution.

The replication initiator protein pi of plasmid R6K binds seven 22 bp direct repeats (DR) in the gamma origin. The pi protein also binds to an inverted repeat (IR) in the operator of its own gene, pir, which lies outside the gamma origin sequences. A genetic system was devised to select for pi protein mutants which discriminate between IR and DR (York et al., Gene (Amst.) 116, 7-12, 1992; York and Filutowicz, J. Biol. Chem. 268, 21854-21861, 1993). From this selection the mutant pi S87N protein was isolated which is deficient in repressing the pir gene's expression because it cannot bind to IR at the pir gene operator. Remarkably, we discovered that pi S87N binds to DR cooperatively under conditions where wt pi binds independently. Moreover, the pi S87N is more active as a replication initiator in vivo when supplied at the same level as wt pi. Quantitative binding assays showed that both wt pi and pi S87N bind a DNA fragment containing a single DR unit with a similar affinity (Kd = 0.3 x 10(-12) M). Thus, cooperativity of pi S87N is most likely achieved through altered interactions between promoters bound at adjacent DR units.     

Binding of purified wild-type and mutant pi initiation proteins to a replication origin region of plasmid R6K

The three replication origins of the antibiotic resistance plasmid R6K require for their activity in Escherichia coli a DNA segment containing seven 22 base-pair direct repeats and a plasmid-encoded initiation protein (pi). The pi protein functions in the negative control of R6K replication, in addition to its requirement for the initiation of replication. Construction of a plasmid containing the pi structural gene (pir) downstream from the inducible pR promoter of bacteriophage lambda provided high levels of production of pi protein in E. coli. The pi protein was purified and shown to possess general DNA binding properties with a preference for DNA fragments containing the gamma origin of replication, the operator region of the pir gene and the R6K beta-origin region. Velocity sedimentation analysis indicates that the pi protein exists as a dimer in its native form. Agarose gel electrophoresis analysis of pi-gamma-origin complexes suggests that one pi dimer binds to each copy of the 22 base-pair direct repeats in the gamma origin region. Purified mutant pi protein obtained from a temperature-sensitive initiation mutant (pir 105-ts) exhibited temperature-sensitive binding activity to the gamma-origin region, whereas two mutant proteins exhibiting a high copy number phenotype were unaltered (pir104-cop) or slightly reduced (pir1-cop) in binding activity. The patterns of DNase I protection and enhancement were similar for the wild-type and mutant proteins examined.     

A single amino acid alteration in the initiation protein is responsible for the DNA overproduction phenotype of copy number mutants of plasmid R6K.

A novel type of high copy-number (cop) mutants of a mini-R6K plasmid were isolated. The mutations were mapped in the pir gene which encodes the pi initiation protein for plasmid R6K DNA replication. They resulted in an alteration by substitution of a single amino acid: threonine to isoleucine at the 108th position for the cop41, and proline to serine at the 113th position for the cop50, of the 305 amino acid pi protein. The cop41 mutation in the pi protein was found to be trans-dominant over the wild-type allele in the copy control of plasmid R6K. Moreover, it was shown that the altered pi protein was not overproduced in maxicells carrying this mutant plasmid and had a higher affinity to the repeated sequence which is present in the pir promoter region. Most likely the mutated pi protein also interacts more efficiently with the same repeated sequences, a target of pi, in the replication origin region and increases the frequency of the initiation event per cell division.     

Replication from one of the three origins of the plasmid R6K requires coupled expression of two plasmid-encoded proteins

The minimal beta-replicon of plasmid R6K contains an open reading frame for a 151-amino acid protein in addition to the seven 22-base pair direct nucleotide sequence repeats, the structural gene (pir) for the pi initiation protein, and the beta-origin sequence that have been shown to be required for replication activity. In this work, a site-specific mutation by linker insertion in this putative coding sequence, designated bis, resulted in a nonfunctional beta-replicon. The nonfunctional beta-replicon was complementable in trans and the protein coded by the bis sequence was detected in an immunoblot assay as a hybrid product from a bis-lac z fused gene. The bis gene is not required for a functional alpha or gamma origin replication origin of R6K. A site-specific mutation in the upstream pir gene was shown to lead to a loss of synthesis of the bis product and inactivation of the beta-replicon. Trans-complementation of this mutation for beta-replicon activity required the wild-type sequence of the pir gene joined to the intact bis sequence. These results indicate that the bis product is required for activity specifically of the beta-origin, and its synthesis is coupled in cis to the expression of pi protein from an unaltered pir gene.     

Roles of a 106-bp origin enhancer and Escherichia coli DnaA protein in replication of plasmid R6K.

A dnaA 'null' strain could not support replication of intact plasmid R6K or derivatives containing combinations of its three replication origins (alpha, gamma, beta). DnaA binds in vitro to sites in two functionally distinct segments of the central gamma origin. The 277-bp core segment is common to all three origins and contains DnaA box 2, which cannot be deleted without preventing replication. Immediately to the left of the core lies the 106-bp origin enhancer, which contains DnaA box 1. When the origin enhancer is deleted, the core alone can still initiate replication if levels of wt pi protein are decreased or if copy-up pi mutant proteins are provided in trans. DnaA does not effect expression of R6K replication initiator protein pi, although several DnaA boxes were identified in the coding segment of the pir gene, which encodes pi. Together these data suggest that a single DnaA box, 2, is sufficient for initiation from the gamma origin and might be sufficient for initiation from the gamma origin and might be sufficient and required for the activity of the alpha and beta origins as well. Implications of the DnaA protein binding to two domains of the gamma origin and the role of the 106-bp origin enhancer in replication are discussed.     

Binding of DnaA protein to a replication enhancer counteracts the inhibition of plasmid R6K gamma origin replication mediated by elevated levels of R6K pi protein.

Replication of the gamma origin of Escherichia coli plasmid R6K requires pi protein, encoded by the R6K pir gene, and many host factors, including DnaA protein. Pi has dual roles, activating replication at low levels and inhibiting replication at high levels. The inhibitory function of pi is counteracted by integration host factor and a specific sequence of the origin called the enhancer. This 106-bp DNA segment contains a binding site for DnaA protein (DnaA box 1). In this study, we mutated this site to determine if it was required for the enhancer's function. Using gamma origin derivative plasmids with the DnaA box 1 altered or deleted, we show that this site is necessary to protect the origin against levels of wild-type pi protein that would otherwise inhibit replication. To show that the base substitutions in DnaA box 1 weakened the binding of DnaA, we developed a new application of the agarose gel retardation assay. This quick and easy assay has broad applicability, as shown in binding studies with DNA fragments carrying a different segment of the R6K origin, the chromosomal origin (oriC), or the pUC origin. The gel retardation assay suggests a stoichiometry of DnaA binding different from that deduced from other assays.     

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.     

Hexahistidine (His6)-tag dependent protein dimerization: a cautionary tale

Nickel nitrilotriacetic acid (Ni2+-NTA) immobilization of hexahistidine (His6) tagged proteins has become one of the most commonly used methods of affinity chromatography. Perhaps the greatest utility of this protein purification method stems from the general belief that His-tagged proteins (comprised of His6) are little affected in their activities or efficiencies, while alterations in specificity are unexpected. Although this is certainly true in many instances, we present a case in which the biochemical properties of proteins being studied were fundamentally altered due to the presence of His-tags. We carried out these studies using variants of the pi(30.5) protein of plasmid R6K, a DNA binding protein which negatively regulates plasmid replication. Pi(30.5) can bind DNA containing a target sequence (TGAGR) arranged either asymmetrically (direct repeats) in the gamma origin, or symmetrically in inverted half-repeats (IR's) in the operator of its own gene, pir. Importantly, dimers of pi protein bind to an IR; this property allows researchers to quickly assess whether different regulatory variants of pi proteins exhibit altered dimerization properties. For example, pi(30.5) containing a single amino-acid substitution, F107S (pi200(30.5)), has been shown to be monomeric in solution and dimers were not observed bound to IR's. Here we demonstrate that the presence of a His-tag partially restores the ability of pi200(30.5) to dimerize in solution and bind to an IR in dimeric form. This report sends an important message that (other) proteins containing His-tags may differ from their wild type counterparts in dimerization/oligomerization properties.     

Translational options for the pir gene of plasmid R6K: multiple forms of the replication initiator protein pi.

The autogenously controlled pir gene of plasmid R6K was believed to encode a single polypeptide that plays multiple roles in the plasmid's biology. We have isolated an opal (op) mutant at the 18th codon of the pir coding frame which does not totally abolish translation of pir mRNA. In extracts of cells containing this mutation two translational products (35 kDa and 30.2 kDa) have been detected. We propose that the 35-kDa polypeptide produced by the pir18 op mutation contains Trp substituted for Arg18 as the result of an opal readthrough. Translation, which results in the 30.2-kDa polypeptide, originates downstream from the UGA stop signal created by the mutation. Moreover, we realize now that the 30.2-kDa polypeptide is also produced in cells containing a wild-type (wt) pir gene. The shorter variant of the pi protein lacks replication initiation and inhibition functions, as well as autorepressor activity in vivo. We also show that an in-frame fusion of seven N-terminal codons of the trpE gene with a pir gene lacking the first two codons produces two polypeptides which replace the 35-kDa pi protein and are of similar molecular weight. Thus, at least three options exist in the translation of the wt pir mRNA. Start codons are most likely at codon positions 1, 6 or 7, and 36 or 38. Each of these five AUG codons is preceded by a consensus ribosome-binding site (RBS).     

Integration host factor of Escherichia coli reverses the inhibition of R6K plasmid replication by pi initiator protein.

Integration host factor (IHF) protein is the only host-encoded protein known to bind and to affect replication of the gamma origin of Escherichia coli plasmid R6K. We examined the ability of R6K origins to replicate in cells lacking either of the two subunits of IHF. As shown previously, the gamma origin cannot replicate in IHF-deficient cells. However, this inability to replicate was relieved under the following conditions: underproduction of the wild-type pi replication protein of R6K or production of normal levels of mutant pi proteins which exhibit relaxed replication control. The copy number of plasmids containing the primary R6K origins (alpha and beta) is substantially reduced in IHF-deficient bacteria. Furthermore, replication of these plasmids is completely inhibited if the IHF-deficient strains contain a helper plasmid producing additional wild-type pi protein. IHF protein has previously been shown to bind to two sites within the gamma origin. These sites flank a central repeat segment which binds pi protein. We propose a model in which IHF binding to its sites reduces the replication inhibitor activity of pi protein at all three R6K origins.     

Monomer/dimer ratios of replication protein modulate the DNA strand-opening in a replication origin

DNA opening is an essential step in the initiation of replication via the Cairns mode of replication. The opening reaction was investigated in a gamma ori system by using hyperactive variants of plasmid R6K-encoded initiator protein, pi. Reactivity to KMnO4 (indicative of opening) within gamma ori DNA occurred in both strands of a superhelical template upon the combined addition of wt pi, DnaA and integration host factor (IHF), each protein known to specifically bind gamma ori. IHF, examined singly, enhanced reactivity to KMnO4. The IHF-dependent reactive residues, however, are distinct from those dependent on pi (wt and hyperactive variants). Remarkably, the DNA helix opening does not require IHF and/or DnaA when hyperactive variants of pi were used instead of wt protein. We present three lines of evidence consistent with the hypothesis that DNA strand separation is facilitated by pi monomers despite the fact that both monomers and dimers of the protein can bind to iterons (pi binding sites). Taken together, our data suggest that pi elicits its ability to modulate plasmid copy number at the DNA helix-opening step.     

Altered (copy-up) forms of initiator protein pi suppress the point mutations inactivating the gamma origin of plasmid R6K.

The R6K gamma origin core contains the P2 promoter, whose -10 and -35 hexamers overlap two of the seven binding sites for the R6K-encoded pi protein. Two mutations, P2-201 and P2-203, which lie within the -35 region of P2, are shown to confer a promoter-down phenotype. We demonstrate here that these mutations prevent replication of a gamma origin core plasmid. To determine whether or not the reduced promoter activity caused by these mutations is responsible for their effect on replication, we generated two new mutations (P2-245-6-7 and P2-246) in the -10 hexamer of the P2 promoter. Although these new mutations inhibit P2 activity as much as the P2-201 and P2-203 mutations, they do not prevent replication of the gamma origin core. Therefore, activity of the P2 promoter does not appear to be required for replication. We also show that the inability of the gamma origin to function in the presence of the P2-201 and P2-203 mutations is reversed by the hyperactive variants of pi protein called copy-up pi. This suppression occurs despite the fact that in vivo dimethyl sulfate methylation protection patterns of the gamma origin iterons are identical in cells producing wild-type pi and those producing copy-up pi variants. We discuss how the P2-201 and P2-203 mutations could inhibit replication of the gamma origin core and what mechanisms might allow the copy-up pi mutants to suppress this deficiency.     

Activation of distant replication origins in vivo by DNA looping as revealed by a novel mutant form of an initiator protein defective in cooperativity at a distance.

We have isolated mutants of the pi initiator protein of the plasmid R6K that are defective in DNA looping in vitro but retain their normal DNA binding affinity for the primary binding sites (iterons) at the gamma origin/enhancer. One such looping defective mutant called R6 was determined to be a proline to leucine change at position 46 near the N terminus of the pi protein. Using a set of genetic assays that discriminate between the activation of the gamma origin/enhancer from those of the distantly located alpha and beta origins, we show that the looping defective initiator protein fails to activate the alpha and beta origins but derepresses initiation from the normally silent gamma origin in vivo. The results conclusively prove that DNA looping is required to activate distant replication origins located at distances of up to 3 kb from the replication enhancer.     

Structure-based functional analysis of the replication protein of plasmid R6K: key amino acids at the pi/DNA interface

In previous work, we characterized the bases in an iteron of plasmid R6K that are important for the binding of pi protein monomers and dimers. Here we investigate the following six amino acids of pi, encoded by pir, hypothesized to be important for DNA contact: Ser71, Try74, Gly131, Gly211, Arg225, and Arg254.     

Bacterial expression system with tightly regulated gene expression and plasmid copy number

A new Escherichia coli host/vector system has been engineered to allow tight and uniform modulation of gene expression and gamma origin (ori) plasmid copy number. Regulation of gamma ori plasmid copy number is achieved through arabinose-inducible expression of the necessary Rep protein, pi, whose gene was integrated into the chromosome of the host strain under control of the P(BAD) promoter. gamma ori replication can be uniformly modulated over 100-fold by changing the concentration of l-arabinose in the growth medium. This strain avoids the problem of all-or-nothing induction of P(BAD) because it is deficient in both arabinose uptake and degradation genes. Arabinose enters the cell by a mutant LacY transporter, LacYA177C, which is expressed from the host chromosome. Although this strain could be compatible with any gamma ori plasmid, we describe the utility of a gamma ori expression vector that allows especially tight regulation of gene expression. With this host/vector system, it is possible to independently modulate gene expression and gene dosage, facilitating the cloning and overproduction of toxic gene products. We describe the successful use of this system for cloning a highly potent toxin, Colicin E3, in the absence of its cognate immunity protein. This system could be useful for cloning genes encoding other potent toxins, screening libraries for potential toxins, and maintaining any gamma ori vector at precise copy levels in a cell.     

Mechanistic studies of initiator-initiator interaction and replication initiation.

Unlike the chromosome of Escherichia coli that needs only one replication initiator protein (origin recognition protein) called DnaA, many plasmid replicons require dual initiators: host-encoded DnaA and a plasmid-encoded origin recognition protein, which is believed to be the major determinant of replication control. Hitherto, the relative mechanistic roles of dual initiators in DNA replication were unclear. Here, we present the first evidence that DnaA communicates with the plasmid-encoded pi initiator of R6K and contacts the latter at a specific N-terminal region. Without this specific contact, productive unwinding of plasmid ori gamma and replication is abrogated. The results also show that DnaA performs different roles in host and plasmid replication as revealed by the finding that the ATP-activated form of DnaA, while indispensable for oriC replication, was not required for R6K replication. We have analyzed the accessory role of the DNA bending protein, integration host factor (IHF), in promoting initiator-origin interaction and have found that IHF significantly enhances the binding of DnaA to its cognate site. Collectively, the results further advance our understanding of replication initiation.     

A DNA segment conferring stable maintenance on R6K gamma-origin core replicons.

The plasmid R6K gamma origin consists of two adjacent modules, the enhancer and the core, and requires R6K initiator protein pi for replication. While the core alone can replicate at a low level of wild-type pi protein, we show here that host cells do not stably maintain core plasmids. The presence of the enhancer segment confers stable inheritance on core plasmids without a significant change in average plasmid copy number. Deletions and site-directed mutagenesis indicated that the stability of core plasmids is not mediated by binding sites or consensus sequences in the enhancer for DnaA, pi protein, gyrase, Fis, or Dcm methylase. Proper segregation of core plasmids requires only the R6K stb or stability-related region, which includes the 20-bp segment of the 100-bp enhancer adjacent to the core. The use of the pi 116 mutant protein, which increases plasmid copy number fourfold, does not stabilize core plasmids lacking the enhancer. We also show that at an elevated level of wild-type pi, the gamma-origin plasmid is unstable, even in the presence of the enhancer. We discuss the differences and similarities between the R6K stability system and those found in other plasmids.