Characterization of putative rolling-circle plasmids from the Gram-negative bacterium Xylella fastidiosa and their use as shuttle vectors

This study was initiated to characterize a small Xylella fastidiosa (X. fastidiosa) plasmid and attempt to create a X. fastidosa/Escherichia coli shuttle vector that was stable in planta. Restriction enzyme analysis of a 1.3kb plasmid DNA from a grape-infecting strain of X. fastidiosa (UCLA) revealed the presence of three similar, but genetically distinct, plasmids, pUCLAs. Evidence that suggests the pUCLA plasmids replicate via a rolling-circle (RC) mechanism include: (i) the presence of ssDNA in X. fastidiosa cells; (ii) the presence of conserved motifs in the predicted ORF1 that are typical of initiator (Rep) proteins associated with RC replication; (iii) high amino acid identity between the putative Rep proteins of pUCLAs and Pf3, a filamentous bacteriophage of Pseudomonas aeruginosa that replicates by a RC mechanism; and (iv) the presence of a putative origin of replication upstream of ORF1 that has the potential to form secondary hairpin structures. One DNA motif present in pUCLA shared sequence similarity to known nicking sites in the origins of replication of other RC plasmids and phages. The shuttle vector, pXF001, successfully transformed grape X. fastidiosa strains and was found to be present as autonomous, structurally unchanged DNA molecules in X. fastidiosa. However, pXF001 was not stably maintained in X. fastidiosa without antibiotic selection.     

Characterization of a single-strand origin, ssoU, required for broad host range replication of rolling-circle plasmids

Single-stranded DNA (ssDNA) promoters are the key components of the single-strand origins (ssos) of replication of rolling-circle (RC) replicating plasmids. The recognition of this origin by the host RNA polymerase and the synthesis of a short primer RNA are critical for initiation of lagging-strand synthesis. This step is thought to be a limiting factor for the establishment of RC plasmids in a broad range of bacteria, because most of the ssos described are fully active only in their natural hosts. A special type of sso, the ssoU, is unique in the sense that it can be efficiently recognized in a number of different Gram-positive hosts. We have experimentally deduced the folded structure and characterized the ssDNA promoter present within the ssoU using P1 nuclease digestion and DNase I protection assays with the Bacillus subtilis and Staphylococcus aureus RNA polymerases. We have also identified the RNA products synthesized from this ssDNA promoter and mapped the initiation points of lagging-strand synthesis in vivo from ssoU-containing plasmids. Through gel mobility shift experiments, we have found that ssDNA containing the ssoU sequence can efficiently interact with the RNA polymerase from two different Gram-positive bacteria, S. aureus and B. subtilis. We have also realigned the narrow and broad host range sso sequences of RC plasmids, and found that they contain significant homology. Our data support the notion that the strength of the RNA polymerase-ssoU interaction may be the critical factor that confers the ability on the ssoU to be fully functional in a broad range of bacteria.     

Plasmid rolling-circle replication: recent developments

It is now well established that a large majority of small, multicopy plasmids of Gram-positive bacteria use the rolling-circle (RC) mechanism for their replication. Furthermore, the host range of RC plasmids now includes Gram-negative organisms as well as archaea. RC plasmids can be broadly classified into at least five families, individual members of which are spread among widely different bacteria. There is significant homology in the basic replicons of plasmids belonging to a particular family, and there is compelling evidence that such plasmids have evolved from common ancestors. Major advances have recently been made in our understanding of plasmid RC replication, including the characterization of the biochemical activities of the plasmid initiator proteins and their interaction with the double-strand origin, the domain structure of the initiator proteins and the molecular basis for the function of single-strand origins in plasmid lagging strand synthesis. Over the past several years, there has been a 'renaissance' in studies on RC replication as a result of the discovery that many plasmids replicate by this mechanism, and studies in the next few years are likely to reveal new and novel mechanisms used by RC plasmids for their regulated replication.     

Characterization, sequence and mode of replication of plasmid pNB2 from the thermophilic bacterium Clostridium thermosaccharolyticum

 The 1882-bp nucleotide sequence of the cryptic plasmid pNB2 isolated from the thermophilic bacterium Clostridium thermosaccharolyticum was determined. pNB2 DNA has very low GC content (27%) and may serve as a model for studying the modes of maintenance and replication of AT-rich DNA under conditions of thermophilic growth. The plasmid sequence revealed three open reading frames (ORFs) which would encode polypeptides of 289, 68 and 59 amino acids, respectively, and these proteins were synthesized in E. coli extracts primed with the plasmid. We found that the product of ORF289 may be initiated at the non-ATG start codon, TTG, and has similarities with the conserved motifs of Rep proteins encoded by rolling circle (RC) plasmids of the pC194/pUB110 family. Southern hybridization analysis of lysates of C. thermosaccharolyticum cells harboring pNB2 revealed single-stranded intermediates, suggesting that this plasmid is able to replicate in clostridial cells via the RC mechanism. The most significant similarities are found between pNB2 Rep protein and the Rep proteins of three RC plasmids of the pC194 family (pTB913, pBC1 and pST1) isolated from thermophilic bacteria. Comparative analysis of these Rep proteins showed that despite the significant level of divergence, these Rep proteins share a high degree of similarity in the regions of five well-known conserved domains of RC Rep proteins and fall into two groups in accordance with the similarities found in their active sites. Received: 25 April 1996 / Accepted: 20 June 1996     

Characterization,sequence and mode of replication of plasmid pNB2 from the thermophilic bacterium Clostridium thermosaccharolyticum

The 1882-bp nucleotide sequence of the cryptic plasmid pNB2 isolated from the thermophilic bacterium Clostridium thermosaccharolyticum was determined. pNB2 DNA has very low GC content (27%) and may serve as a model for studying the modes of maintenance and replication of AT-rich DNA under conditions of thermophilic growth. The plasmid sequence revealed three open reading frames (ORFs) which would encode polypeptides of 289, 68 and 59 amino acids, respectively, and these proteins were synthesized in E. coli extracts primed with the plasmid. We found that the product of ORF289 may be initiated at the non-ATG start codon, TTG, and has similarities with the conserved motifs of Rep proteins encoded by rolling circle (RC) plasmids of the pC194/pUB110 family. Southern hybridization analysis of lysates of C. thermosaccharolyticum cells harboring pNB2 revealed single-stranded intermediates, suggesting that this plasmid is able to replicate in clostridial cells via the RC mechanism. The most significant similarities are found between pNB2 Rep protein and the Rep proteins of three RC plasmids of the pC194 family (pTB913, pBC1 and pST1) isolated from thermophilic bacteria. Comparative analysis of these Rep proteins showed that despite the significant level of divergence, these Rep proteins share a high degree of similarity in the regions of five well-known conserved domains of RC Rep proteins and fall into two groups in accordance with the similarities found in their active sites.     

Non-replicative helicases at the replication fork

Reactivation of stalled or collapsed replication forks is an essential process in bacteria. Restart systems operate to restore the 5'-->3' replicative helicase, DnaB, to the lagging-strand template. However, other non-replicative 3'-->5' helicases play an important role in the restart process as well. Here we examine the DNA-binding specificity of three of the latter group, PriA, Rep, and UvrD. Only PriA and Rep display structure-specific fork binding. Interestingly, their specificity is opposite: PriA binds a leading-strand fork, presumably reflecting its restart activity in directing loading of DnaB to the lagging-strand template. Rep binds a lagging-strand fork, presumably reflecting its role in partially displacing Okazaki fragments that originate near the fork junction. This activity is necessary for generating a single-stranded landing pad for DnaB. While UvrD shows little structure-specificity, there is a slight preference for lagging-strand forks, suggesting that there might be some redundancy between Rep and UvrD and possibly explaining the observed synthetic lethality that occurs when mutations in the genes encoding these two proteins are combined.     

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.     

Localization of the start sites of lagging-strand replication of rolling-circle plasmids from Gram-positive bacteria

A number of small, multicopy plasmids from Gram-positive bacteria replicate by an asymmetric rolling-circle mechanism. Previous studies with several of these plasmids have identified a palindromic sequence, SSO_A, that acts as the single-strand origin (SSO) for the replication of the lagging-strand DNA. Although not all the SSO_A sequences share ONA sequence homology, they are structurally very similar. We have used an in vitro system to study the lagging-strand replication of several plasmids from Gram-positive bacteria using the SSO_A sequences of pT181, pE194 and pSN2 as representative of three different groups of Staphylococcus aureus plasmids. In addition, we have investigated the lagging-strand replication of the pUB110 plasmid that contains an alternative single-strand origin, sso_u. Our results confirm that RNA polymerase is involved in lagging-strand synthesis from both SSO_A and ssou-type lagging-strand origins. Interestingly, while initiation of lagging-strand DNA synthesis of pUB110 occurred predominantly at a single position within sso_u, replication of pT181, pSN2 and pE194 plasmids initiated at multiple positions from SSO_A.     

ssDNA-dependent colocalization of adeno-associated virus Rep and herpes simplex virus ICP8 in nuclear replication domains

The subnuclear distribution of replication complex proteins is being recognized as an important factor for the control of DNA replication. Herpes simplex virus (HSV) single-strand (ss)DNA-binding protein, ICP8 (infected cell protein 8) accumulates in nuclear replication domains. ICP8 also serves as helper function for the replication of adeno-associated virus (AAV). Using quantitative 3D colocalization analysis we show that upon coinfection of AAV and HSV the AAV replication protein Rep and ICP8 co-reside in HSV replication domains. In contrast, Rep expressed by a recombinant HSV, in the absence of AAV DNA, displayed a nuclear distribution pattern distinct from that of ICP8. Colocal ization of Rep and ICP8 was restored by the reintroduction of single-stranded AAV vector genomes. In vitro, ICP8 displayed direct binding to Rep78. Single-stranded recombinant AAV DNA strongly stimulated this interaction, whereas double-stranded DNA was ineffective. Our findings suggest that ICP8 by its strong ssDNA-binding activity exploits the unique single-strandedness of the AAV genome to form a tripartite complex with Rep78 and AAV ssDNA. This novel mechanism for recruiting components of a functional replication complex directs AAV to subnuclear HSV replication compartments where the HSV replication complex can replicate the AAV genome.     

Sequence of plasmid pGT5 from the archaeon Pyrococcus abyssi: evidence for rolling-circle replication in a hyperthermophile.

The plasmid pGT5 (3,444 bp) from the hyperthermophilic archaeon Pyrococcus abyssi GE5 has been completely sequenced. Two major open reading frames with a good coding probability are located on the same strand and cover 85% of the total sequence. The larger open reading frame encodes a putative polypeptide which exhibits sequence similarity with Rep proteins of plasmids using the rolling-circle mechanism for replication. Upstream of this open reading frame, we have detected an 11-bp motif identical to the double-stranded origin of several bacterial plasmids that replicate via the rolling-circle mechanism. A putative single-stranded origin exhibits similarities both to bacterial primosome-dependent single-stranded initiation sites and to bacterial primase (dnaG) start sites. A single-stranded form of pGT5 corresponding to the plus strand was detected in cells of P. abyssi. These data indicate that pGT5 replicates via the rolling-circle mechanism and suggest that members of the domain Archaea contain homologs of several bacterial proteins involved in chromosomal DNA replication. Phylogenetic analysis of Rep proteins from rolling-circle replicons suggest that diverse families diverged before the separation of the domains Archaea, Bacteria, and Eucarya.     

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.     

The family of highly interrelated single-stranded deoxyribonucleic acid plasmids.

Many plasmids from gram-positive bacteria replicate via a single-stranded deoxyribonucleic acid (ssDNA) intermediate, most probably by a rolling-circle mechanism (these plasmids are referred to in this paper as ssDNA plasmids). Their plus and minus origins are physically separated, and replicative initiations are not simultaneous; it is this feature that allows visualization of ssDNA replication intermediates. The insertion of foreign DNA into an ssDNA plasmid may provoke a high frequency of deletions, changes of replicative products to high-molecular-weight forms, segregational loss, and decreased plasmid copy numbers. When an ssDNA plasmid is inserted into the chromosome, both deletions and amplifications may be induced. Both the mode of replication and the copy control mechanism affect the fate of inserted foreign material, usually selecting for its loss. Thus, after having tasted various morsels of DNA, the resulting plasmid stays trim. The features of the ssDNA plasmids seem to be beneficial for their viability and propagation, but not for their use as cloning vectors. However, plasmids replicating via ssDNA intermediates are being exploited to yield insights into the mechanisms of recombination and amplification.     

Plasmid rolling-circle replication: highlights of two decades of research

This review provides a historical perspective of the major findings that contributed to our current understanding of plasmid rolling-circle (RC) replication. Rolling-circle-replicating (RCR) plasmids were discovered approximately 20 years ago. The first of the RCR plasmids to be identified were native to Gram-positive bacteria, but later such plasmids were also identified in Gram-negative bacteria and in archaea. Further studies revealed mechanistic similarities in the replication of RCR plasmids and the single-stranded DNA bacteriophages of Escherichia coli, although there were important differences as well. Three important elements, a gene encoding the initiator protein, the double strand origin, and the single strand origin, are contained in all RCR plasmids. The initiator proteins typically contain a domain involved in their sequence-specific binding to the double strand origin and a domain that nicks within the double strand origin and generates the primer for DNA replication. The double strand origins include the start-site of leading strand synthesis and contain sequences that are bound and nicked by the initiator proteins. The single strand origins are required for synthesis of the lagging strand of RCR plasmids. The single strand origins are non-coding regions that are strand-specific, and contain extensive secondary structures. This minireview will highlight the major findings in the study of plasmid RC replication over the past twenty years. Regulation of replication of RCR plasmids will not be included since it is the subject of another review.     

Characterization of two small cryptic plasmids from Pseudomonas sp. strain S-47

Two small cryptic plasmids, p47L and p47S, identified in Pseudomonas sp. S-47 were characterized by determination of DNA sequences and physical and functional maps. They are 3084 and 1782 bp in length, respectively, with GC contents of 63.55 and 65.21%. The detection of single-strand DNAs of both plasmids indicates that they replicate by a rolling-circle mechanism. The deduced polypeptide encoded by the rep gene of p47L is homologous with Rep proteins of plasmids belonging to the pIJ101/pJV1 family, which are known to replicate by the rolling-circle mechanism. Despite containing a homologous signature with Rep proteins of rolling-circle replicating (RCR) plasmids in the pT181 family, the Rep of p47S lacks significant homology with Rep proteins of this family and is missing a region similar to the family's replication origin (dso). Based on the rep sequence comparisons, p47L falls into a previously defined plasmid family whereas p47S defines a new family of RCR plasmid.     

Molecular analysis of two rolling-circle replicating cryptic plasmids, pBMYdx and pBMY1, from the soil gram-positive Bacillus mycoides

Two cryptic plasmids of two environmental strains of the soil Bacillus mycoides were cloned and sequenced. They are of a small size (3377 and 3476 bp) and carry regions homologous to double- and single-strand origins of replication of rolling-circle replication modules. In addition, both plasmids have ORFs with homologies with Mob and Rep proteins, in the same relative position and orientation. While dso- and sso-like sequences are similar in pBMY1 and pBMYdx, the putative Mob and Rep proteins are not homologous between the two but show similarity with Mob and Rep proteins of different bacterial plasmids.     

Bacteriophage T4 helicase loader protein gp59 functions as gatekeeper in origin-dependent replication in vivo

Bacteriophage T4 initiates origin-dependent replication via an R-loop mechanism in vivo. During in vitro reactions, the phage-encoded gp59 stimulates loading of the replicative helicase, gp41, onto branched intermediates, including origin R-loops. However, although gp59 is essential for recombination-dependent replication from D-loops, it does not appear to be required for origin-dependent replication in vivo. In this study, we have analyzed the origin-replicative intermediates formed during infections that are deficient in gp59 and other phage replication proteins. During infections lacking gp59, the initial replication forks from two different T4 origins actively replicated both leading- and lagging-strands. However, the retrograde replication forks from both origins were abnormal in the gp59-deficient infections. The lagging-strand from the initial fork was elongated as a new leading-strand in the retrograde direction without lagging-strand synthesis, whereas in the wild-type, leading- and lagging-strand synthesis appeared to be coupled. These results imply that gp59 inhibits the polymerase holoenzyme in vivo until the helicase-primase (gp41-gp61) complex is loaded, and we thereby refer to gp59 as a gatekeeper. We also found that all origin-replicative intermediates were absent in infections deficient in the helicase gp41 or the single-strand-binding protein gp32, regardless of whether gp59 was present or absent. These results argue that replication from the origin in vivo is dependent on both the helicase and single-strand-binding protein and demonstrate that the strong replication defect of gene 41 and 32 single mutants is not caused by gp59 inhibition of the polymerase.     

Molecular Analysis of Two Rolling-Circle Replicating Cryptic Plasmids, pBMYdx and pBMY1, from the Soil Gram-Positive Bacillus mycoides

Two cryptic plasmids of two environmental strains of the soil Bacillus mycoides were cloned and sequenced. They are of a small size (3377 and 3476 bp) and carry regions homologous to double- and single-strand origins of replication of rolling-circle replication modules. In addition, both plasmids have ORFs with homologies with Mob and Rep proteins, in the same relative position and orientation. While dso- and sso-like sequences are similar in pBMY1 and pBMYdx, the putative Mob and Rep proteins are not homologous between the two but show similarity with Mob and Rep proteins of different bacterial plasmids.     

Minireplicon from pBtoxis of Bacillus thuringiensis subsp. israelensis

A 2.2-kb fragment containing a replicon from pBtoxis, the large plasmid that encodes the insecticidal endotoxins of Bacillus thuringiensis subsp. israelensis, was identified, cloned, and sequenced. This fragment contains cis elements, including iterons, found in replication origins of other large plasmids and suggests that pBtoxis replicates by a type A theta mechanism. Two genes, pBt156 and pBt157, encoding proteins of 54.4 kDa and 11.8 kDa, respectively, were present in an operon within this minireplicon, and each was shown by deletion analysis to be essential for replication. The deduced amino acid sequences of the 54.4-kDa and 11.8-kDa proteins showed no substantial homology with known replication (Rep) proteins. However, the 54.4-kDa protein contained a conserved FtsZ domain, and the 11.8 kDa protein contained a helix-turn-helix motif. As FtsZ proteins have known functions in bacterial cell division and the helix-turn-helix motif is present in Rep proteins, it is likely that these proteins function in plasmid replication and partitioning. The minireplicon had a copy number of two or three per chromosome equivalent in B. thuringiensis subsp. israelensis but did not replicate in B. cereus, B. megaterium, or B. subtilis. A plasmid constructed to synthesize large quantities of the Cry11A and Cyt1A endotoxins demonstrated that this minireplicon can be used to engineer vectors for cry and cyt gene expression.     

Molecular analysis of pDL10 from Acidianus ambivalens reveals a family of related plasmids from extremely thermophilic and acidophilic archaea.

The 7598-bp plasmid pDL10 from the extremely thermophilic, acidophilic, and chemolithoautotrophic Archaeon Acidianus ambivalens was sequenced. It contains 10 open reading frames (ORFs) organized in five putative operons. The deduced amino acid sequence of the largest ORF (909 aa) showed similarity to bacterial Rep proteins known from phages and plasmids with rolling-circle (RC) replication. From the comparison of the amino acid sequences, a novel family of RC Rep proteins was defined. The pDL10 Rep protein shared 45-80% identical residues with homologous protein genes encoded by the Sulfolobus islandicus plasmids pRN1 and pRN2. Two DNA regions capable of forming extended stem-loop structures were also conserved in the three plasmids (48-69% sequence identity). In addition, a putative plasmid regulatory protein gene (plrA) was found, which was conserved among the three plasmids and the conjugative Sulfolobus plasmid pNOB8. A homolog of this gene was also found in the chromosome of S. solfataricus. Single-stranded DNA of both pDL10 strands was detected with a mung bean nuclease protection assay using PCR detection of protected fragments, giving additional evidence for an RC mechanism of replication.