Expression and regulation of the RepA protein of the RepFIB replicon from plasmid P307.

The control of RepFIB replication appears to rely on the interaction between an initiator protein (RepA) and two sets of DNA repeat elements located on either side of the repA gene. Limited N-terminal sequence information obtained from a RepA:beta-galactosidase fusion protein indicates that although the first residue of RepA is methionine, the initiation of translation of RepA occurs from a CTG codon rather than from the predicted GTG codon located further downstream. Overexpressed RepA in trans is capable of repressing a repA:lacZ fusion plasmid in which the expression of the fusion protein is under the control of the repA promoter. The repA promoter has been located functionally by testing a series of repA:lacZ fusion plasmids. Both in vivo genetic tests and in vitro DNA-binding studies indicate that repA autoregulation can be achieved by RepA binding to one or more repeat elements which overlap the repA promoter sequence.     

Replication of Enterococcus faecalis pheromone-responding plasmid pAD1: location of the minimal replicon and oriV site and RepA involvement in initiation of replication

The hemolysin-determining plasmid pAD1 is a member of a widely disseminated family of highly conjugative elements commonly present in clinical isolates of Enterococcus faecalis. The determinants repA, repB, and repC, as well as adjacent iteron sequences, are believed to play important roles in pAD1 replication and maintenance. The repA gene encodes an initiator protein, whereas repB and repC encode proteins related to stability and copy number. The present study focuses specifically on repA and identifies a replication origin (oriV) within a central region of the repA determinant. A small segment of repA carrying oriV was able to support replication in cis of a plasmid vector otherwise unable to replicate, if an intact RepA was supplied in trans. We demonstrate that under conditions in which RepA is expressed from an artificial promoter, a segment of DNA carrying only repA is sufficient for stable replication in E. faecalis. We also show that RepA binds specifically to oriV DNA at several sites containing inverted repeat sequences (i.e., IR-1) and nonspecifically to single-stranded DNA, and related genetic analyses confirm that these sequences play an important role in replication. Finally, we reveal a relationship between the internal structure of RepA and its ability to recognize oriV. An in-frame deletion within repA resulting in loss of 105 nucleotides, including at least part of oriV, did not eliminate the ability of the altered RepA protein to initiate replication using an intact origin provided in trans. The relationship of RepA to other known initiator proteins is also discussed.     

Heat shock proteins DnaJ, DnaK, and GrpE stimulate P1 plasmid replication by promoting initiator binding to the origin.

Binding of the P1-encoded protein RepA to the origin of P1 plasmid replication is essential for initiation of DNA replication and for autoregulatory repression of the repA promoter. Previous studies have shown defects in both initiation and repression in hosts lacking heat shock proteins DnaJ, DnaK, and GrpE and have suggested that these proteins play a role in the RepA-DNA binding required for initiation and repression. In this study, using in vivo dimethyl sulfate footprinting, we have confirmed the roles of the three heat shock proteins in promoting RepA binding to the origin. The defects in both activities could be suppressed by increasing the concentration of wild-type RepA over the physiological level. We also isolated RepA mutants that were effective initiators and repressors without requiring the heat shock proteins. These data suggest that the heat shock proteins facilitate both repression and initiation by promoting only the DNA-binding activity of RepA. In a similar plasmid, F, initiator mutants that confer heat shock protein independence for replication were also found, but they were defective for repression. We propose that the initiator binding involved in repression and the initiator binding involved in initiation are similar in P1 but different in F.     

Effects of mutations in the repA gene of plasmid Rts1 on plasmid replication and autorepressor function.

We constructed a system in which wild-type RepA or RepAcop1 protein was supplied in trans in various amounts to coexisting mini-Rts1 plasmids by clones of the repA or repAcop1 gene under the control of the native promoter with or without its operator sequence. RepAcop1 protein which contains a single amino acid substitution (Arg-142 to Lys) within its 288 amino acids could initiate the replication of the mini-Rts1 plasmid efficiently at both 37 and 42 degrees C even if it was supplied in excess. In contrast, excess wild-type RepA inhibited plasmid replication at 37 degrees C but supported replication at 42 degrees C. Therefore, it appears that the initiator activity of RepA is not related to the incompatibility phenotype associated with an excess of RepA protein. An immunoblot analysis revealed that neither RepA nor RepAcop1 synthesis was temperature sensitive and that both were autogenously regulated to a similar extent because of the presence of an operator located immediately upstream of the promoter. Two mutant RepA proteins, each of which contains a 4-amino-acid insertion in the middle of the protein, maintained the autorepressor and incompatibility activities but lost the ori(Rts1)-activating function.     

Excess intracellular concentration of the pSC101 RepA protein interferes with both plasmid DNA replication and partitioning.

RepA, a plasmid-encoded gene product required for pSC101 replication in Escherichia coli, is shown here to inhibit the replication of pSC101 in vivo when overproduced 4- to 20-fold in trans. Unlike plasmids whose replication is prevented by mutations in the repA gene, plasmids prevented from replicating by overproduction of the RepA protein were lost rapidly from the cell population instead of being partitioned evenly between daughter cells. Removal of the partition (par) locus increased the inhibitory effect of excess RepA on replication, while host and plasmid mutations that compensate for the absence of par, or overproduction of the E. coli DnaA protein, diminished it. A repA mutation (repA46) that elevates pSC101 copy number almost entirely eliminated the inhibitory effect of RepA at high concentration and stimulated replication when the protein was moderately overproduced. As the RepA protein can exist in both monomer and dimer forms, we suggest that overproduction promotes RepA dimerization, reducing the formation of replication initiation complexes that require the RepA monomer and DnaA; we propose that the repA46 mutation alters the ability of the mutant protein to dimerize. Our discovery that an elevated intracellular concentration of RepA specifically impedes plasmid partitioning implies that the RepA-containing complexes initiating pSC101 DNA replication participate also in the distribution of plasmids at cell division.     

Participation of the Escherichia coli heat shock proteins DnaJ, DnaK, and GrpE in autorepression of the P1 plasmid repA promoter

The replicon of the low copy number plasmid P1 uses the three Escherichia coli heat shock proteins DnaJ, DnaK, and GrpE for the efficient initiation of its DNA replication. The only P1-encoded protein required for plasmid replication is the initiator, RepA. Binding of RepA to the origin also represses the promoter for the repA gene, which is located within the origin. We found that repression is incomplete in E. coli strains with mutations in the dnaJ, dnaK, or grpE genes. Since there is no decrease in RepA concentration in the mutant strains, the mutations are likely to affect the protein-DNA or protein-protein reactions required for repression, thereby decreasing RepA binding at its promoter. We also showed that the deficit in repression can be overcome by providing excess RepA, implying that the mechanism of repression is not altered in the mutant strains. Since repression requires RepA binding to the origin, a binding deficit might account for the replication defect in the heat shock mutants.     

Importance of structural differences between complementary RNA molecules to control of replication of an IncB plasmid.

Replication of the IncB miniplasmid pMU720 is dependent on the expression of repA, the gene encoding replication initiator protein RepA. Binding of a small antisense RNA (RNAI) to its complementary target (stem-loop I [SLI]) in the RepA mRNA prevents the participation of SLI in the formation of a pseudoknot that is an enhancer of translation of this mRNA. Thus, RNAI regulates the frequency of replication of pMU720 by controlling the efficiency of translation of the RepA mRNA. Mutational analysis of the two seven-base complementary sequences involved in formation of the pseudoknot showed that only the five central bases of each were critical for the formation of the pseudoknot. Physical analysis of SLI showed that despite the complete complementarity of its sequence to that of RNAI, the structures of the two molecules are different. The most prominent difference between the two structures is the presence of a 4-base internal loop immediately below the hairpin loop of SLI but not that of RNAI. Closure of this internal loop in SLI resulted in a 40-fold reduction in repA expression and loss of sensitivity of the residual expression to inhibition by RNAI. By contrast, repA expression was largely unaffected by the closure of a lower internal loop whose presence in SLI and RNAI is essential for effective interaction between these two molecules. These results suggest that the interaction of SLI with the distal pseudoknot bases is fundamentally different from the RNAI-SLI binding interaction and that the differences in structure between RNAI and SLI are necessary to allow SLI to be able to efficiently bind RNAI and to participate in pseudoknot formation.     

Function of the N-terminal half of RepA in activation of Rts1 ori.

The RepA protein of the Rts1 plasmid, consisting of 288 amino acids, is a trans-acting protein essential for replication. A mutant repA gene, repA delta C143, carrying a deletion that removed the 143 C-terminal amino acids of RepA, could transform, but at a low frequency, an Escherichia coli polA strain, JG112, when repA delta C143 was cloned into pBR322 with Rts1 ori in the natural configuration. The transformation was less efficient without the dyad DnaA box in the ori region, and no transformation occurred at 42 degrees C, characteristic of Rts1 replication. A fusion of the 3'-terminal half of repA of the P1 plasmid to repA delta C143 yielded a pBR322 chimeric plasmid that contained Rts1 ori through hybrid (Rts1-P1) repA. This plasmid was maintained much more stably in JG112 at 37 degrees C. At 42 degrees C, however, it was quite unstable. The overproduced hybrid RepA protein showed interference with mini-Rts1 replication in trans and also exhibited an autorepressor function, although both activities were decreased. These findings suggest that the N-terminal half of the RepA molecule of Rts1 is involved in the activation of the replication origin.     

Importance of the C terminus of plasmid Rts1 RepA protein for replication and incompatibility of the plasmid.

RepA protein, essential for replication of plasmid Rts1, was found to bind in vivo immediately upstream of the repA promoter in studies with mini-Rts1 derivatives with deletions in the upstream region of repA. We constructed another series of repA mutants that would encode RepA derivatives containing oligopeptide substitutions in place of the carboxyl-terminal six amino acids. These modified RepA proteins could not activate ori (Rts1) at all and showed various degrees of incompatibility, or no incompatibility, toward a mini-Rts1 plasmid. These results suggest that the carboxyl-terminal six (or fewer) amino acids of RepA are important for exerting replication and incompatibility functions. One of the RepA derivatives, which showed an evident incompatibility without initiating replication, was examined for its ability to repress the repA gene.     

Analysis of elements involved in pseudoknot-dependent expression and regulation of the repA gene of an IncL/M plasmid

Replication of the IncL/M plasmid pMU604 is controlled by a small antisense RNA molecule (RNAI), which, by inhibiting the formation of an RNA pseudoknot, regulates translation of the replication initiator protein, RepA. Efficient translation of the repA mRNA was shown to require the translation and correct termination of the leader peptide, RepB, and the formation of the pseudoknot. Although the pseudoknot was essential for the expression of repA, its presence was shown to interfere with the translation of repB. The requirement for pseudoknot formation could in large part be obviated by improving the ribosome binding region of repA, either by replacing the GUG start codon by AUG or by increasing the spacing between the start codon and the Shine-Dalgarno sequence (SD). The spacing between the distal pseudoknot sequence and the repA SD was shown to be suboptimal for maximal expression of repA.