Organization of the replication control region of plasmid ColIb-P9.

We identified a 1,845-base-pair sequence that contains essential information for the autonomous replication and regulation of the 93-kilobase-pair IncI alpha group ColIb-P9 plasmid. Biochemical and genetic analyses revealed that this sequence specifies at least two structural genes, designated repZ and inc. The repZ gene encodes a protein with a molecular weight of 39,000, which probably functions as an initiator for the ColIb-P9 replicon. The inc gene that phenotypically governs the incompatibility encodes an RNA with a size of about 70 bases. This small RNA acts in trans to repress the expression of repZ, thereby functioning to maintain a constant copy number of the ColIb-P9 replicon in host cells.     

Role of leader peptide synthesis in repZ gene expression of the ColIb-P9 plasmid

The frequency of replication initiation of the ColIb-P9 plasmid depends on the level of repZ expression, which has been shown to be negatively regulated by inc RNA, the approximately 70-base-long product of the inc gene. To further understand the regulatory mechanism of repZ gene expression, we isolated mutants defective in ColIb-P9 replication using a lambda:ColIb-P9 hybrid phage. Among six mutants isolated, one amber mutant, rep57, failed to synthesize the RepZ protein. The mutation occurred in the repZ leader sequence that encodes a 29-amino-acid reading frame, designated as repY. We also isolated mutants that suppressed the rep57 phenotype. These mutations were single base insertions between the repY initiation codon and the rep57 mutation site and resulted not only in a frame shift of repY but also in the formation of repY-repZ fusions without changing the amino acid sequence of RepZ. Thus, repY is not directly involved in the replication reaction but rather functions as a positive regulator for repZ expression. We propose that repZ expression is coupled with repY translation, which acts to disrupt a secondary structure sequestering the repZ translation initiation signal. The positive and negative regulations of repZ expression were discussed. The other mutants were mapped in repZ, confirming that repZ is essential for ColIb-P9 replication.     

Copy number control of IncIalpha plasmid ColIb-P9 by competition between pseudoknot formation and antisense RNA binding at a specific RNA site.

Replication of a low-copy-number IncIalpha plasmid ColIb-P9 depends on expression of the repZ gene encoding the replication initiator protein. repZ expression is negatively controlled by the small antisense Inc RNA, and requires formation of a pseudoknot in the RepZ mRNA consisting of stem-loop I, the Inc RNA target, and a downstream sequence complementary to the loop I. The loop I sequence comprises 5'-rUUGGCG-3', conserved in many prokaryotic antisense systems, and was proposed to be the important site of copy number control. Here we show that the level of repZ expression is rate-limiting for replication and thus copy number, by comparing the levels of repZ expression and copy number from different mutant ColIb-P9 derivatives defective in Inc RNA and pseudoknot formation. Kinetic analyses using in vitro transcribed RNAs indicate that Inc RNA binding and the pseudoknot formation are competitive at the level of initial base paring to loop I. This initial interaction is stimulated by the presence of the loop U residue in the 5'-rUUGGCG-3' motif. These results indicate that the competition between the two RNA-RNA interactions at the specific site is a novel regulatory mechanism for establishing the constant level of repZ expression and thus copy number.     

The plasmid ColIb-P9 antisense Inc RNA controls expression of the RepZ replication protein and its positive regulator repY with different mechanisms.

The autonomous replication region of plasmid ColIb-P9 contains repZ encoding the RepZ replication protein, and inc and repY as the negative and positive regulators of repZ translation, respectively. inc encodes the antisense Inc RNA, and repY is a short open reading frame upstream of repZ. Translation of repY enables repZ translation by inducing formation of a pseudoknot containing stem-loop I, which base pairs with the sequence preceding the repZ start codon. Inc RNA inhibits both repY translation and formation of the pseudoknot by binding to the loop I. To investigate control of repY expression by Inc RNA, we isolated a number of mutations that express repY in the presence of Inc RNA. One class of mutations delete a part of another stem-loop (II), which derepresses repY expression by initiating translation at codon 10 (GUG), located within this structure. Point mutations in stem-loop II can also derepress repY translation, and the introduction of compensatory base-changes restores control of repY translation. These results not only indicate that suppressing a cryptic start codon by secondary structure is important for maintaining the translational control of repZ but also demonstrate that the position of start site for repY translation is critical for its control by Inc RNA. Thus, Inc RNA controls repY translation by binding in the vicinity of the start codon, in contrast to the control of repZ expression at the level of loop-loop interaction.     

Structural analysis of late intermediate complex formed between plasmid ColIb-P9 Inc RNA and its target RNA. How does a single antisense RNA repress translation of two genes at different rates?

The antisense Inc RNA encoded by the IncIalpha ColIb-P9 plasmid replicon controls the translation of repZ encoding the replication initiator and its leader peptide repY at different rates with different mechanisms. The initial loop-loop base pairing between Inc RNA and the target in the repZ mRNA leader inhibits formation of a pseudoknot required for repZ translation. A subsequent base pairing at the 5' leader of Inc RNA blocks repY translation. To delineate the molecular basis for the differential control, we analyzed the intermediate complexes formed between RepZ mRNA and Inc RNA(54), a 5'-truncated Inc RNA derivative. We found that the initial base pairing at the loops transforms into a more stable intermediate complex by its propagation in both directions. The resulting extensive base pairing indicates that the inhibition of the pseudoknot formation is established at this stage. Furthermore, the region of extensive base pairing includes bases different in related plasmids showing different incompatibility. Thus, the observed extensive base pairing is important for determining the incompatibility of the low-copy-number plasmids. We discuss the evolution of replication control systems found in IncIalpha, IncB, and IncFII group plasmids.     

Structural and functional features of cis-acting sequences in the basic replicon of plasmid ColIb-P9.

We have structurally and functionally analyzed the cis-elements essential for ColIb-P9 plasmid DNA replication. The putative oriV region encompassed a region of 172 base pairs (bp) located 152 bp downstream of the repZ gene. A typical dnaA box found in this region proved nonessential for the DNA replication of ColIb-P9. The ssi signal of ColIb-P9 is a homologue of the G-sites of R1 and R100 plasmids. Deletion of the G-site led to 1.5-fold reduction of the copy number, suggesting that although this G-site is not essential, it is important for efficient ColIb-P9 DNA replication. In addition, the ColIb-P9 replicon is highly and extensively homologous with the P307 (RepFIC) replicon, and highly homologous with the R100 (RepFIIA) replicon around the G-site region. These facts imply a common ancestry from which the plasmids have evolved.     

Polyadenylation can regulate ColE1 type plasmid copy number independently of any effect on RNAI decay by decreasing the interaction of antisense RNAI with its RNAII target

Replication of ColE1-type plasmids is regulated by RNAI, an antisense RNA that interacts with the replication pre-primer, RNAII. Exonucleolytic attack at the 3' end of RNAI is impeded in pcnB mutant bacteria, which lack poly(A) polymerase I-the principal RNA polyadenylase of E. coli; this leads to accumulation of an RNAI decay intermediate (RNAI(-5)) and dramatic reduction of the plasmid copy number. Here, we report that polyadenylation can also affect RNAI-mediated control of plasmid DNA replication by inhibiting interaction of RNAI(-5) with RNAII. We show that mutation of the host pcnB gene profoundly affects the plasmid copy number, even under experimental conditions that limit the effects of polyadenylation on RNAI(-5) decay. Moreover, poly(A) tails interfere with RNAI/RNAII interaction in vitro without producing any detectable alteration of RNAI secondary structure. Our results establish the existence of a previously undetected mechanism by which RNA polyadenylation can control plasmid copy number.     

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.     

Arginine-rich RNA binding domain and protein scaffold domain of RNase E are important for degradation of RNAI but not for that of the Rep mRNA of the ColE2 plasmid

Expression of the replication initiator protein (Rep) of the ColE2 plasmid is controlled by antisense RNA (RNAI). Therefore alterations in processes and/or rates of degradation of these two RNAs would affect the Rep expression. Here, we have shown that the arginine-rich RNA binding domain (ARRBD) of RNase E is important for the initial endoribonucleolytic cleavage of RNAI but dispensable for the endoribonucleolytic cleavages of the Rep mRNA. We have also shown that the protein scaffold domain of RNase E is important for successive exoribonucleolytic degradation of RNAI, suggesting involvement of RhlB, but dispensable for that of the Rep mRNA. Such differences in the initiation and successive steps of degradation between RNAI and the Rep mRNA might be important in determining their individual degradation efficiencies required for a quick response to the changes in the plasmid copy number.     

Maintenance of pBR322-derived plasmids without functional RNAI

pBR322-derived plasmids that lack the bla gene and 40% of the gene for the replication inhibitor, RNAI, have been constructed. Since the RNAI gene totally overlaps with the gene for the replication primer, RNAII, this primer is similarly defective and also lacks its normal promoter. The primer is presumed to by synthesized either from the counter-tet promoter (plasmid pCL59) or from an inserted lacUV5 promoter (plasmid pCL59-65). Based mainly on the observation that the plasmid Rom protein, which normally assists in the RNAI/RNAII interaction, has no effect on the replication of the RNAI/RNAII-defective plasmids, we suggest that the defective RNAI is not functional while the defective RNAII primer, although less efficient, still allows plasmid replication. The defective plasmids are fully compatible with the intact parent plasmid, indicating that they do not share a common control of replication. In the absence of antibiotics, the bacteria lose the defective plasmid, beginning after 80 generations; under the same conditions, the parent plasmid is retained even after 140 generations. During exponential growth of their host, the number of defective plasmids in a culture increases exponentially with a doubling time either smaller or greater than that of the host cell growth, depending on the growth medium and, in the case of pCL59-65, on the presence or absence of lac inducer IPTG. As a result of these differences in host cell growth and plasmid replication, the plasmids are either gradually diluted out or their copy number continually increases. This shows that, without RNAI, plasmid replication is uncoupled from the host cell growth and not, as usual, adjusted to it. It also implies that the RNAI mechanism is the only means of replication control for ColE1-type plasmids that senses and adjusts the copy number; limiting host factors cannot provide a back-up control to stabilize copy numbers.