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.     

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.     

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.     

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.     

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.     

Initiation of unidirectional ColE2 DNA replication by a unique priming mechanism.

The ColE2 DNA can be replicated in an in vitro system consisting of a crude extract of Escherichia coli cells. DNA synthesis requires a plasmid-coded protein (Rep) and host DNA polymerase I but not host RNA polymerase. Replication starts at a fixed region containing the origin and proceeds unidirectionally. The leading- and lagging-strand DNA fragments synthesized around the origin were identified from early replicative intermediates. The 5' end of the leading-strand DNA fragment was mapped at a unique position in the minimal origin and carried RNA of a few residues. The results suggested that the initiation of the leading-strand DNA synthesis does not require the host DnaG protein. Thus the Rep protein itself seems to be a primase. Synthesis of the primer RNA at a fixed site in the origin region on a double-stranded DNA template is a unique property of the ColE2 Rep protein among other known primases. The 3' end of the lagging-strand DNA fragment was mapped at a unique position just at the end of the minimal origin region. Termination of the lagging-strand DNA fragment at that position seems to be the mechanism of the unidirectional replication of ColE2 plasmid.     

Functional analysis of cis- and trans-acting replication factors of porcine circovirus type 1

The replication proteins Rep and Rep' of porcine circovirus type 1 (PCV1) are both capable of introducing and resealing strand discontinuities at the viral origin of DNA replication in vitro underlying genome amplification by rolling-circle replication. The PCV1 origin of replication encompasses the minimal binding site (MBS) of the Rep and Rep' proteins and an inverted repeat with the potential to form a stem-loop. In this study, both elements of the PCV1 origin were demonstrated to be essential for viral replication in transfected cells. Furthermore, investigation of conserved amino acid motifs within Rep and Rep' proteins revealed that the mutation of motifs I, II, and III and of the GKS box interfered with viral replication. In vitro studies demonstrated that motifs I to III were essential for origin cleavage, while the GKS box was dispensable for the initiation of viral replication. A covalent link between Rep/Rep' and the DNA after origin cleavage was demonstrated, providing a mechanism for energy conservation for the termination of replication.     

A single-stranded region located downstream of the repeated sequence in the ori region of pSC101 is required for binding of the Rep protein in vitro.

Purified replication initiator protein (Rep) of plasmid pSC101 binds preferentially to two inverted repeats (IR) overlapping the promoter of its own structure gene, rep. However, the protein has much lower binding affinity for directly repeated (DR) sequences in the replication origin (ori) that are similar to the symmetric sequences. Exonuclease III (exo III) promotes in vitro binding of Rep to the origin repeats. In the present studies, DNA containing the DR sequences was degraded unidirectionally by exo III and then formed a complex with Rep. Analyses of DNA from the complex revealed that Rep bound to the DR sequences only when the degradation proceeded from the 3' end proximal to IR to the DR sequences, resulting in conversion of the duplex structure in a specific downstream region of DR into the single-stranded form. The degradation in the opposite direction had no effect on binding of Rep. These results suggest that a localized structural change of DNA adjacent to DR is required for Rep binding to double-stranded DR sequences. By contrast, exo III strikingly inhibited binding of Rep to DNA containing the IR sequences by introducing a single-stranded moiety into duplex IR sequences.     

Analysis of the herpes simplex virus type 1 OriS sequence: mapping of functional domains.

The herpes simplex virus type 1 (HSV-1) OriS region resides within a 90-bp sequence that contains two binding sites for the origin-binding protein (OBP), designated sites I and II. A third presumptive OBP-binding site (III) within OriS has strong sequence similarity to sites I and II, but no sequence-specific OBP binding has yet been demonstrated at this site. We have generated mutations in sites I, II, and III and determined their replication efficiencies in a transient in vivo assay in the presence of a helper virus. Mutations in any one of the sites reduced DNA replication significantly. To study the role of OriS sequence elements in site I and the presumptive site III in DNA replication, we have also generated a series of mutations that span from site I across the presumptive binding site III. These mutants were tested for their ability to replicate and for the ability to bind OBP by using gel shift analyses. The results indicate that mutations across site I drastically reduce DNA replication. Triple-base-pair substitution mutations that fall within the crucial OBP-binding domain, 5'-YGYTCGCACT-3' (where Y represents C or T), show a reduced level of OBP binding and DNA replication. Substitution mutations in site I that are outside this crucial binding sequence show a more detrimental effect on DNA replication than on OBP binding. This suggests that these sequences are required for initiation of DNA replication but are not critical for OBP binding. Mutations across the presumptive OBP-binding site III also resulted in a loss in efficiency of DNA replication. These mutations influenced OBP binding to OriS in gel shift assays, even though the mutated sequences are not contained within known OBP-binding sites. Replacement of the wild-type site III with a perfect OBP-binding site I results in a drastic reduction of DNA replication. Thus, our DNA replication assays and in vitro DNA-binding studies suggest that the binding of the origin sequence by OBP is not the only determining factor for initiation of DNA replication in vivo.     

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.     

Identification of the replication-associated protein binding domain within the intergenic region of tomato leaf curl geminivirus.

The geminiviral replication-associated protein (Rep) is the only viral protein required for viral DNA replication. Tomato leaf curl virus (TLCV) Rep was expressed in Escherichia coli as a histidine-tagged fusion protein and purified to homogeneity in non-denaturing form. The fusion protein was used in in vitro binding experiments to identify the Rep-binding elements within the origin of replication of TLCV. Electrophoretic mobility shift assays demonstrated that the Rep binds specifically to a 120 bp fragment within the TLCV intergenic region. Fine resolution of the binding regions within the 120 bp fragment, using DNase I footprinting, demonstrated two footprints covering the sequences GCAATTGGTGTCTCTCAA and TGAATCGGTGTCTGGGG containing a direct repeat of the motif GGTGTCT (underlined). Our results suggest that the repeated motif is involved in virus-specific Rep-binding, but may not constitute the entire binding element. This is the first demonstration of geminivirus sequence elements involved in Rep-binding by direct protein-DNA interaction assays.     

HU protein binding to the replication origin of the rolling-circle plasmid pKYM enhances DNA replication

The RepK protein, which is encoded by the rolling-circle plasmid pKYM, binds to the PR I site in the pKYM DNA replication origin. We have identified HU as a protein that binds to the PR II and PR III sites in the replication-enhancing region which is downstream of PR I. DNA footprinting assays show that HU binds to these two sites only when RepK is bound to PR I, and that HU also enhances the binding of RepK to PR I. In vivo, pKYM was unable to transform an HU null strain. Two mutant RepK proteins, RepKW179Y, which contains a Trp-to-Tyr exchange at position 179, and RepKD277L, which contains an Asp-to-Leu mutation at residue 277, initiate DNA replication in vivo in the absence of HU. In vitro, these mutant RepK proteins form more stable complexes with the pKYM origin region than does the wild-type RepK protein. These results indicate that HU plays a role in the formation of a stable RepK-origin complex, which is required for the initiation of pKYM DNA replication. Received: 24 July 1996 / Accepted: 30 December 1996     

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.     

Characterization of the herpes simplex virus origin binding protein interaction with OriS.

The origin binding protein (OBP) of herpes simplex virus (HSV), which is essential for viral DNA replication, binds specifically to sequences within the viral replication origin(s) (for a review, see Challberg, M.D., and Kelly, T. J. (1989) Annu. Rev. Biochem. 58, 671-717). Using either a COOH-terminal OBP protein A fusion or the full-length protein, each expressed in Escherichia coli, we investigated the interaction of OBP with one HSV origin, OriS. Binding of OBP to a set of binding site variant sequences demonstrates that the 10-base pair sequence, 5' CGTTCGCACT 3', comprises the OBP-binding site. This sequence must be presented in the context of at least 15 total base pairs for high affinity binding, Ka = approximately 0.3 nM. Single base pair mutations in the central CGC sequence lower the affinity by several orders of magnitude, whereas a substitution at any of the other seven positions reduces the affinity by 10-fold or less. OBP binds with high affinity to duplex DNA containing mismatched base pairs. This property is exploited to analyze OBP binding to DNA heteroduplexes containing singly substituted mutant and wild-type DNA strands. For positions 2, 3, 5, 6, 7, 8, and 9, substitutions are tolerated on one or the other DNA strand, indicating that base-mediated interactions are limited to one base of each pair. For both Boxes I and II, these interactions are localized to one face of the DNA helix, forming a recognition surface in the major groove. In OriS, the 31 base pairs which separate Boxes I and II orient the two interaction surfaces to the same side of the DNA.     

Topography of simian virus 40 A protein-DNA complexes: arrangement of protein bound to the origin of replication.

DNA binding regions I, II, and III at the origin of replication have different arrangements of A protein (T antigen) recognition pentanucleotides. The A protein also protects each region from DNase in distinctly different patterns. Footprint and fragment assays led to the following conclusions: (i) in some cases a single recognition pentanucleotide is sufficient to direct the binding and accurate alignment of A protein on DNA; (ii) the A protein binds within isolated region I or II in a sequential process leading to multiple overlapping areas of DNase protection within each region; and (iii) the 23-base pair span of recognition sequences in region II allows binding and protection of a longer length of DNA than the 23-base pair span in region I. We propose a model of protein binding that addresses the problem of variations in the arrangement of pentanucleotides in regions I and II and explains the observed DNase protection patterns. The central feature of the model requires each protomer of A protein to bind to a pentanucleotide in a unique direction. The resulting orientation of protein would protect more DNA at the 5' end of the 5'-GAGGC-3' recognition sequence than at the 3' end. The arrangement of multiple protomers at the origin of simian virus 40 replication is discussed.