Specific interaction between the initiator protein (Rep) and origin of plasmid ColE2-P9

The replication initiator protein (Rep) of plasmid ColE2-P9 (ColE2) is multifunctional. We are interested in how Rep binds to the origin (Ori) to perform various functions. We used the wild type and variants of Rep to study the Rep-Ori interaction by both in vitro and in vivo approaches, including biochemical analyses of protein-DNA interactions and an in vivo replication assay. We identified three regions (I, II, and III) of Rep, located in the C-terminal half, and three corresponding binding sites (I, II, and III) in Ori which are important for Rep-Ori interaction. We showed that region I, containing a putative helix-turn-helix motif, is necessary and sufficient for specific Ori recognition, interacting with site I of the origin DNA from the major groove. Region II interacts with site II of the origin DNA, from the adjacent minor groove in the left half of Ori, and region III interacts with site III, next to the template sequence for primer synthesis, which is one and one-half turn apart from site I on the opposite surface of the origin DNA. A putative linker region located between the two DNA binding domains (regions II and III) was identified, which might provide Rep an extended conformation suitable for binding to the two separate sites in Ori. Based on the results presented in this paper, we propose a model for Rep-Ori interaction in which Rep binds to Ori as a monomer.     

Distinct functions of the two specificity determinants in replication initiation of plasmids ColE2-P9 and ColE3-CA38

The plasmid ColE2-P9 Rep protein specifically binds to the cognate replication origin to initiate DNA replication. The replicons of the plasmids ColE2-P9 and ColE3-CA38 are closely related, although the actions of the Rep proteins on the origins are specific to the plasmids. The previous chimera analysis identified two regions, regions A and B, in the Rep proteins and two sites, alpha and beta, in the origins as specificity determinants and showed that when each component of the region A-site alpha pair and the region B-site beta pair is derived from the same plasmid, plasmid DNA replication is efficient. It is also indicated that the replication specificity is mainly determined by region A and site alpha. By using an electrophoretic mobility shift assay, we demonstrated that region B and site beta play a critical role for stable Rep protein-origin binding and, furthermore, that 284-Thr in this region of the ColE2 Rep protein and the corresponding 293-Trp of the ColE3 Rep protein mainly determine the Rep-origin binding specificity. On the other hand, region A and site alpha were involved in the efficient unwinding of several nucleotide residues around site alpha, although they were not involved in the stable binding of the Rep protein to the origin. Finally, we discussed how the action of the Rep protein on the origin involving these specificity determinants leads to the plasmid-specific replication initiation.     

The Rep protein binding elements of the plasmid ColE2-P9 replication origin

The plasmid ColE2-P9 (ColE2) origin (32bp) is specifically recognized by the plasmid-specified Rep protein that initiates DNA replication. The ColE2 origin is divided into at least three functional subregions (I, II, and III), and three sites (a, b, and c) found in subregions I and II play important roles in Rep protein binding. We performed SELEX experiments of plasmid ColE2 to determine the optimal sequences for specific binding of the Rep protein. From these experiments, we obtained a common 16-bp sequence (5'-TGAGACCANATAAGCC-3'), which corresponds to about one half of the minimal ColE2 origin and contains sites a and b. Gel mobility shift assays using single-point mutant origins and the Rep protein further indicated that high affinity sequence-specific recognition by the Rep protein requires sites a, b, and c, but that mutations in site c were less disruptive to this recognition than those in sites a and b.     

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.     

Rolling-circle replication of an animal circovirus genome in a theta-replicating bacterial plasmid in Escherichia coli

A bacterial plasmid containing 1.75 copies of double-stranded porcine circovirus (PCV) DNA in tandem (0.8 copy of PCV type 1 [PCV1], 0.95 copy of PCV2) with two origins of DNA replication (Ori) yielded three different DNA species when transformed into Escherichia coli: the input construct, a unit-length chimeric PCV1(Rep)/PCV2(Cap) genome with a composite Ori but lacking the plasmid vector, and a molecule consisting of the remaining 0.75 copy PCV1(Cap)/PCV2(Rep) genome with a different composite Ori together with the bacterial plasmid. Replication of the input construct was presumably via the theta replication mechanism utilizing the ColE(1) Ori, while characteristics of the other two DNA species, including a requirement of two PCV Oris and the virus-encoded replication initiator Rep protein, suggest they were generated via the rolling-circle copy-release mechanism. Interestingly, the PCV-encoded Rep' protein essential for PCV DNA replication in mammalian cells was not required in bacteria. The fact that the Rep' protein function(s) can be compensated by the bacterial replication machinery to support the PCV DNA replication process echoes previous suggestions that circular single-stranded DNA animal circoviruses, plant geminiviruses, and nanoviruses may have evolved from prokaryotic episomal replicons.     

Structural and functional organization of ColE2 and ColE3 replicons

Summary The complete nucleotide sequences of the 1.5 kb regions of ColE2 and ColE3 plasmids containing the segments sufficient for autonomous replication have been determined. They are quite homologous (greater than 90%), indicating that these two plasmids share common mechanisms of initiation of replication and its regulation. An open reading frame with a coding capacity for a protein of about 300 amino acids is present in both ColE2 and ColE3 and it actually specifies the Rep (for replication) protein, which is the plasmid specific trans-acting factor required for autonomous replication. The amino acid sequences of the Rep proteins of ColE2 and ColE3 are quite homologous (greater than 90%). The cis-acting sites (origins) where replication initiates in the presence of the trans-acting factors consist of 32 bp for ColE2 and 33 bp for ColE3. They are the smallest of all the prokaryotic replication origins so far reported. They are nonhomologous only at two positions, one of which, a deletion of a single nucleotide in ColE2 (or an insertion in ColE3), determines the plasmid specificity in interaction of the origins with the Rep proteins. Both plasmids carry a region with an identical nucleotide sequence and the one in ColE2, the IncA region, has been shown to express incompatibility against both ColE2 and ColE3. These results indicate that these plasmids share a common IncA determinant. A possibility that a small antisense RNA is involved in copy number control and incompatibility (IncA function) was suggested.     

Replication initiator protein mRNA of ColE2 plasmid and its antisense regulator RNA are under the control of different degradation pathways

Replication of the ColE2 plasmid requires a plasmid-coded initiator protein (Rep). Rep expression is controlled by antisense RNA (RNAI) against the Rep mRNA at a translational step. In this paper, we examined the effects of host RNA degradation enzymes on the degradation process of the Rep mRNA and its degradation intermediates especially those carrying the 5' untranslated region. We showed that the Rep mRNA is subjected to complex degradation pathways involving at least RNase I, RNase II, RNase III, RNase E, RNase G and PNPase. RNase II acts as a major exoribonuclease and PNPase plays a minor role. We also showed that the PcnB (polyA polymerase I) plays only a minor role in the Rep mRNA degradation process. The RNA degradation pathways of the Rep mRNA and RNAI of the ColE2 plasmid are quite different. Based on these results, we speculate that the ColE2 Rep mRNA and RNAI are endowed with individual RNA half lives required for the efficient copy number control by being subjected to different RNA degradation systems.     

Comparative analysis of the replicon regions of eleven ColE2-related plasmids.

The incA gene product of ColE2-P9 and ColE3-CA38 plasmids is an antisense RNA that regulates the production of the plasmid-coded Rep protein essential for replication. The Rep protein specifically binds to the origin and synthesizes a unique primer RNA at the origin. The IncB incompatibility is due to competition for the Rep protein among the origins of the same binding specificity. We localized the regions sufficient for autonomous replication of 15 ColE plasmids related to ColE2-P9 and ColE3-CA38 (ColE2-related plasmids), analyzed their incompatibility properties, and determined the nucleotide sequences of the replicon regions of 9 representative plasmids. The results suggest that all of these plasmids share common mechanisms for initiation of DNA replication and its control. Five IncA specificity types, 4 IncB specificity types, and 9 of the 20 possible combinations of the IncA and IncB types were found. The specificity of interaction of the Rep proteins and the origins might be determined by insertion or deletion of single nucleotides and substitution of several nucleotides at specific sites in the origins and by apparently corresponding insertion or deletion and substitution of amino acid sequences at specific regions in the C-terminal portions of the Rep proteins. For plasmids of four IncA specificity types, the nine-nucleotide sequences at the loop regions of the stem-loop structures of antisense RNAs are identical, suggesting an evolutionary significance of the sequence. The mosaic structures of the replicon regions with homologous and nonhomologous segments suggest that some of them were generated by exchanging functional parts through homologous recombination.     

Primer RNA synthesis by plasmid-specified Rep protein for initiation of ColE2 DNA replication.

Initiation of in vitro ColE2 DNA replication requires the plasmid-specified Rep protein and DNA polymerase I but not RNA polymerase and DnaG primase. The ColE2 Rep protein binds specifically to the origin where replication initiates. Leading-strand synthesis initiates at a unique site in the origin and lagging-strand DNA synthesis terminates at another unique site in the origin. Here we show that the primer RNA for leading-strand synthesis at the origin has a unique structure of 5'-ppApGpA. We reconstituted the initiation reaction of leading-strand DNA synthesis by using purified proteins, the ColE2 Rep protein, Escherichia coli DNA polymerase I and SSB, and we showed that the ColE2 Rep protein is a priming enzyme, primase, which is specific for the ColE2 origin. The ColE2 Rep protein is unique among other primases in that it recognizes the origin region and synthesizes the primer RNA at a fixed site in the origin region. Specific requirement for ADP as a substrate and its direct incorporation into the 5' end of the primer RNA are also unique properties of the ColE2 Rep protein.     

Identification of a plasmid-coded protein required for initiation of ColE2 DNA replication.

The product of the rep gene of ColE2 is required for initiation of ColE2 DNA replication. The rep gene was placed under the control of the promoters, PL and PR, and the heat-labile cl857 repressor of bacteriophage lambda. The Rep protein was identified as a 35 Kd protein by the maxicell method in combination with heat-induced expression. The protein was efficiently expressed from these promoters in unirradiated cells and accumulated up to a few per cent of the total cellular proteins. It was partially purified (about 80% pure) and its properties examined. The amino acid sequence of the amino terminal portion of the partially purified protein agreed well with that predicted from the nucleotide sequence of the rep gene. One of the characteristic features of the rep gene is frequent usage of rare codons, especially those for arginine. The protein specifically stimulated replication of ColE2 DNA but not that of ColE3 DNA in crude cell extracts of Escherichia coli. Specific binding of the protein to plasmid DNA containing the origin region of ColE2 was demonstrated by the filter binding method. Neither endonuclease activity nor topoisomerase activity was detected by using ColE2 DNA.     

The effects of RNA degradation enzymes on antisense RNAI controlling ColE2 plasmid copy number

Replication of the ColE2 plasmid requires a plasmid-coded initiator protein (Rep). Rep expression is controlled by antisense RNA (RNAI), which prevents the Rep mRNA translation. In this paper, we examined the effects of RNA degradation enzymes on the degradation pathways of RNAI of the ColE2 plasmid. In the DeltapcnB strain lacking the poly(A) polymerase I (PAP I) the RNAI degradation intermediate (RNAI(*)) accumulates much more than that in the wt strain. RNAI(*) is produced by the RNase E cleavage. RNase II and PNPase are involved in further degradation of RNAI(*) and PAP I is necessary for efficient degradation. The degradation process of ColE2 RNAI is similar to those of R1 CopA RNA and ColE1 RNAI, although the nucleotide sequences and fine secondary structures of these three RNAs are different. ColE2 RNAI is cleaved at multiple positions in the 5' end region by RNase E. The degradation pathway of ColE2 RNAI shown here is quite different from that of the ColE2 Rep mRNA which we have previously reported. In the DeltapcnB strain used for RNA analysis the copy number of the ColE2 plasmid decreases to about a half as compared with that in the isogenic wt strain.     

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.     

Replication of ColE2 and ColE3 plasmids In vitro replication dependent on plasmid-coded proteins

Summary We developed an in vitro replication system for ColE2 and ColE3 plasmids using cell extracts prepared from bacteria with or without these plasmids. DNA synthesis depended on host DNA polymerase I and was sensitive to rifampicin and chloramphenicol. Preincubation of the extracts with plasmid DNA, however, allowed replication of template DNA added subsequently in a plasmid-specific manner in the presence of rifampicin and chloramphenicol. The plasmid-specified trans-acting factor(s) was detected in cell extracts from bacteria carrying a recombinant plasmid with the region of ColE2 or ColE3 encoding the Rep protein. The plasmid-specified factor(s) consisted at least in part of protein, probably the Rep protein. In vitro replication started within a region of ColE2 or ColE3 containing the smallest cis-acting segment essential for in vivo replication and proceeded in a fixed direction.     

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.     

Essential elements in the coding region of mRNA for translation of ColE2 Rep protein

Translation initiation of mRNA encoding the plasmid-specified initiator protein (Rep) required for initiation of the ColE2 plasmid DNA replication is fairly efficient in Escherichia coli despite the absence of a canonical Shine-Dalgarno sequence. Although a GA cluster sequence exists upstream the initiation codon, its activity as the SD sequence has been shown to be very inefficient. Deletion analyses have shown that there are sequences important for the Rep translation in the regions upstream the GA cluster sequence and downstream the initiation codon. To further define regions important for translation of the Rep mRNA, a set of the ColE2 rep genes bearing single-base substitution mutations in the coding region near the initiation codon was generated and their translation activities examined. We showed that translation of the Rep mRNA was reduced by some of these mutations in a region ranging at least 70 nucleotides from the initiation codon in the coding region, indicating the presence of translation enhancer(s) outside the translation initiation region which is covered by the ribosome bound to the initiation codon. Some of them seem to be essential and specific for translation of the ColE2 Rep mRNA due to the absence of a canonical SD sequence.     

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.     

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.