Plus-origin mapping of single-stranded DNA plasmid pE194 and nick site homologies with other plasmids.

Staphylococcus aureus plasmid pE194 manifests a natural thermosensitivity for replication and can be established in several species, both gram positive and gram negative, thus making it attractive for use as a delivery vector. Like most characterized plasmids of gram-positive bacteria, pE194 generates single-stranded DNA. The direction of pE194 replication is clockwise, as determined by the strandedness of free single-stranded DNA. Significant homology exists between a 50-base-pair sequence in the origin of pE194 and sequences present in plasmids pMV158 (Streptococcus agalactiae), pADB201 (Mycoplasma mycoides), and pSH71 (Lactococcus lactis). We used an initiation-termination reaction, in which pE194 initiates replication at its own origin and is induced to terminate at the related pMV158 sequence, to demonstrate that pE194 replicates by a rolling-circle mechanism; the initiation nick site was localized to an 8-base-pair sequence.     

DNA amplification occurs between the core region of replicationori + of the ts plasmid integrated in the chromosome and its analog in the bacterial genome

Integrated in theBacillus subtilis chromosome, hybrid plasmid pGG10 is capable of thermosensitive amplification. One amplification site corresponds to the core region of replicationori ⁺ of pE194, a component of pGG10; the other is a homologous region of theB. subtilis chromosome. A model of illegitimate amplification mediated by pE194 RepF is proposed.     

Replication and incompatibility properties of plasmid pE194 in Bacillus subtilis.

pE194, a 3.5-kilobase multicopy plasmid, confers resistance to the macrolide-lincosamide-streptogramin B antibiotics in Bacillus subtilis. By molecular cloning and deletion analysis we have identified a replication segment on the physical map of this plasmid, which consists of about 900 to 1,000 base pairs. This segment contains the replication origin. It also specifies a trans-acting function (rep) required for the stable replication of pE194 and a negatively acting copy control function which is the product of the cop gene. The target sites for the rep and cop gene products are also within this region. Two incompatibility determinants have been mapped on the pE194 genome and their properties are described. One (incA) resides within the replication region and may be identical to cop. incB, not located in the replication region, expresses incompatibility toward a copy control mutant (cop-6) but not toward the wild-type replicon.     

Replication in yeasts of plasmid pE194 from Staphylococcus aureus

The ability of the plasmid pE194 from S. aureus to serve as an autonomously replicating sequence (ARS) in yeast was shown. The hybrid plasmid pLD744 that contains pE194 and the yeast LEU2 gene sequences is unstable in yeast like other YRp-vectors: the mitotic stability of the pLD744 was as much as 1%. The plasmid pLD712 that differs from pLD744 by the existence of a centromeric sequence from the chromosome III of yeast Saccharomyces cerevisiae reveals about one order greater stability. The observation that there are some sequences in the primary structure of the pE194 which strongly conform to the ARS consensus in yeast inclines us to infer that the existence of ARS consensus on pE194 DNA is not sufficient for its effective replication in yeast.     

Replication termination for staphylococcal plasmids: plasmids pT181 and pC221 cross-react in the termination process.

We present data which indicate that (i) the origin of replication of plasmids pT181 and pC221 can also function as termination signals; (ii) termination of replication occurs when a round of replication initiated either by RepC at the pT181 origin or by RepD at the pC221 origin reaches either of these origins, proving that the two plasmids cross-react for termination of replication; and (iii) the replication initiated at the origin of another staphylococcal plasmid, pE194, does not terminate at the origin of pT181 or pC221, indicating the existence of a specific relationship between the initiation and termination of a replication event.     

Genetic analysis of a lactococcal plasmid replicon

Summary The sequence and genetic organization was determined of the 2508 by lactococcal portion of pFX2, which was derived from a crypticLactococcus lactis subsp.lactis plasmid and used as the basis for construction of a series of lactococcal vectors. A lactococcal plasmid plus origin and two replication protein-coding regions (repA andrepB) were located. RepA has a helix-turn-helix motif, a geometry typical of DNA-binding proteins. RepB shows a high degree of homology to the plasmid replication initiation proteins from other gram-positive bacteria andMycoplasma. The transcribed inverted repeat sequence betweenrepA andrepB could form an attenuator to regulate pFX2 replication. Upstream of theori site, and in a region which was non-essential for replication, a 215 by sequence identical to the staphylococcal plasmid pE194 and carrying the RS_A site was identified. The genetic organization of this lactococcal plasmid replicon shares significant similarity with pE194 group plasmids.     

Nucleotide sequence and functional map of pE194, a plasmid that specifies inducible resistance to macrolide, lincosamide, and streptogramin type B antibodies.

pE194 is a small plasmid (isolated originally in Staphylococcus aureus) which confers erythromycin-inducible resistance to macrolide, lincosamide, and streptogramin type B (MLS) antibiotics. The nucleotide sequence of pE194 contains 3,728 base pairs (bp), corresponding to a molecular mass of 2.4 million daltons. By means of site-specific cleavage with restriction endonucleases and cloning resultant fragments, determinants of the two major biological functions of p E194, i.e., inducible MLS resistance and replication, could be localized and assigned to specific sequences in the plasmid. Restriction endonuclease TaqI cut pE194 at three sites. TaqI fragment A (1,443 bp) contained the determinant for inducible MLS resistance, whereas TaqI fragment B (1,354 bp) contained a determinant necessary for plasmid replication. Regulatory mutations resulting in constitutive expression of MLS resistance mapped in TaqI fragment A, whereas a mutation associated with elevated plasmid copy number was mapped in TaqI fragment B. Also mapping in TaqI fragment B was a plasmid replication determinant comprising two sets of inverted complementary repeat sequences, one of which spanned 124 bp and was adjacent to a second smaller set which was rich in guanine and cytosine residues. pE194 contained six open reading frames which were theoretically capable of coding for proteins with maximum molecular masses as follows (in daltons): A, 48,300; B, 29,200; C, 14,000; D, 13,900; E, 12,600; and F, 2,700. Insertion of plasmid pBR322 into the single PstI site located in frame A of pE194 resulted in a composite plasmid which could replicate in both Bacillus subtilis and Escherichia coli, suggesting that an intact polypeptide A is dispensable for both replication of pE194 and for MLS resistance. Frame B specified inducible MLS resistance, whereas frame F specified the putative peptide associated with the proposed B determinant translational attenuator. The extent to which frames C, D, and E, all contained in TaqI fragment B, were translated into polypeptide products is not known; however, a base change in frame E was found in a comparison between the high-copy-number mutant, cop-6, and the wild-type strains.     

Interference of plasmid pCM194 with lysogeny of bacteriophage SP02 in Bacillus subtilis.

Three observations indicated that the 2-megadalton chloramphenicol resistance plasmid pCM194 interferes with SP02 lysogeny of Bacillus subtilis. SP02 plaques formed on B. subtilis(pCM194) appeared almost clear, whereas plaques produced on plasmid-free or pUB110-containing cells contained large turbid centers. The number of phages spontaneously liberated by B. subtilis(SP02) was increased 10-fold or more when pCM194 was also present in the lysogens. Lastly, growth of B. subtilis(SP02, pCM194) for approximately 20 to 25 generations resulted in essentially complete loss of the prophage. This interference was not observed with pUB110 or pE194, and the pCM194 interference was not directed against B. subtilis temperate phage phi 105, which is unrelated to SP02. Lytic replication of SP02 appeared to be unaffected by pCM194. pCM194 interference with SP02 lysogeny was demonstrable in recombination-proficient strains and a recE mutant of B. subtilis. SP02 prophage which were noninducible due to the phage ind mutation were resistant to pCM194 interference. pCM194 interference was lost when the entire pCM194 molecule was joined at its unique HpaII site or at one of the two MboI sites to pUB110 or pUB110 derivatives. pBR322 joined to pCM194 at the same MboI site or at the HindIII site produced chimeras that retained the ability to interfere with SP02 lysogeny. A three-part plasmid constructed by joining pBR322 to pCM194 (at HindIII sites) and to pE194 (at PstI sites) was compatible with the SP02 prophage and showed a temperature-sensitive replication phenotype characteristic of the pE194 replicon. One explanation for the interference involves competition for a host component between an SP02 genome attempting to establish lysogeny and plasmids whose replication is directed by the pCM194 replicon.     

Origin and mode of replication of plasmids pE194 and pUB110

Replication of the multicopy antibiotic resistance plasmids pE194 and pUB110 has been studied in Bacillus subtilis. Based on electron microscopic analysis of replication intermediates and on evidence from deletants, we have determined that both plasmids replicate unidirectionally from fixed origins by a Θ mechanism. The location of these origins and the directions of replication have been determined relative to the physical maps. A cointegrate of pE194 and pUB110 has also been studied and evidence is presented from electron microscopy, temperature resistance, and copy number analysis that the cointegrate uses both parental replication origins.     

In vitro recognition of the replication origin of pLS1 and of plasmids of the pLS1 family by the RepB initiator protein.

Rolling-circle replication of plasmid pLS1 is initiated by the plasmid-encoded RepB protein, which has nicking-closing (site-specific DNA strand transferase) enzymatic activity. The leading-strand origin of pLS1 contains two regions, (i) the RepB-binding site, constituted by three directly repeated sequences (iterons or the bind region), and (ii) the sequence where RepB introduces the nick to initiate replication (the nic region). A series of plasmids, belonging to the pLS1 family, show features similar to those of pLS1 and have DNA sequences homologous to the pLS1 nic region. In addition, they all share homologies at the level of their Rep proteins. However, the bind regions of these plasmids are, in general, not conserved. We tested the substrate specificity of purified RepB of pLS1. The RepB protein has a temperature-dependent nicking-closing action on supercoiled pLS1, as well as on recombinant plasmid DNAs harboring the pLS1 nic region. The DNA strand transferase activity of pLS1-encoded RepB was also assayed on two plasmids of the pLS1 family, namely, pE194 and pFX2. DNAs from both plasmids were relaxed by RepB, provided they had a proper degree of supercoiling; i.e., it was necessary to modulate the supercoiling of pE194 DNA to achieve RepB-mediated DNA relaxation. Single-stranded oligonucleotides containing the nic regions of various plasmids belonging to the pLS1 family, including those of pE194 and pFX2, were substrates for RepB. In vitro, the RepB protein does not need to bind to the iterons for its nicking-closing activity.     

Yeast centromeric plasmids as shuttle vectors between Escherichia coli, Bacillus subtilis and Saccharomyces cerevisiae

A number of hybrid plasmids which can autonomously replicate in E. coli, B. subtilis and S. cerevisiae was constructed. Replication of these plasmids both in yeast and in B. subtilis starts on a sequences originating from Staphylococcus aureus plasmids pC194 and pE194. In yeast these hybrids are unstable like those yeast vectors which contain eukaryotic ARSs, but their stability has been increased by addition of yeast centromeric sequence. Both pC194 and pE194 DNAs contain sequences which reveal strong similarities with the yeast ARS consensus. Nevertheless the replication efficiences of these plasmids in yeast are different.     

Organization of the pE194 genome

Summary pE194 is a 3.5 kilobase erythromycin resistance plasmid which was originally isolated from Staphylococcus aureus and has been introduced into Bacillus subtilis. This plasmid specifies at least five polypeptides, detectable in minicell extracts, one of which (E3) is inducible by erythromycin and is required for the expression of erythromycin resistance. We have constructed a detailed restriction endonuclease cleavage site map of pE194, and have localized the DNA sequences which code for the five polypeptides on the map. Four of the five polypeptides (E2, 3, 4 and 5) are specified by a region of the genome which has half the coding capacity required if these proteins were specified by contiguous genes. The determinant of E3 inducibility is located in the same segment. Based on the deficiency in coding capacity and on additional evidence including peptide mapping, we suggest that either the genes for these four polypeptides overlap, and are read in the same frame, or that some of these proteins represent degradation products. The latter alternative appears less likely since E3 is regulated independently of the other three proteins. The fifth protein (E1) is probably transcribed in the opposite direction. Strand separation and hybridization experiments confirm that both strands are transcribed. Hybridization of labeled RNA from a plasmid-carrying strain to restriction fragments of pE194 reveals that the expected plasmid sequences are transcribed in vivo, as is a region of the genome which is near the replication origin and which does not specify any known polypeptide. The map locations of 3–4 RNA polymerase binding sites are presented. Two of them are found in the segm ent which is predicted to contain the E1 and the E2-5 promoters, and a third is in the region of the replication origin.     

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.     

Insertion and amplification of foreign genes in the Lactococcus lactis subsp. lactis chromosome

The plasmid pE194 is unable to replicate in Lactococcus lactis subsp. lactis (formerly Streptococcus lactis). When linked to resident bacteriophage sequences, pE194 was able to integrate into the L. lactis subsp. lactis chromosome either by Campbell-like recombination or by double crossing over with deletion. Integration occurred into the DNA of the prophage and prevented its multiplication. When a selective pressure was applied to an integrant in which pE194 was flanked by two direct repeats of prophage fragment, amplification of pE194 and the prophage fragment was observed. The pE194 copy number was assessed at six to nine, and amplification was stable upon growth under nonselective conditions.     

Plasmid replication stimulates DNA recombination in Bacillus subtilis

The effects of plasmid replication on the frequency of homologous recombination have been investigated. For that purpose Bacillus subtilis strains that carry in their chromosome directly repeated DNA sequences, and an integrated copy of plasmid pE194 either proximal or distal to the repeats, were constructed. The repeat consists either of 3.9 X 10(3) base pBR322 sequences or 2.1 X 10(3) base B. subtilis chromosomal sequences. As plasmid pE194 is naturally thermosensitive for replication, the activity of the replicon could be regulated. Recombination between the repeated sequences was infrequent (about 10(-4) per generation) when the integrated plasmid did not replicate. It was 20 to 450 times higher when the plasmid was allowed to replicate, provided that the repeats were in the proximity of the plasmid. These results show that plasmid replication stimulates DNA recombination.     

Insertion and amplification of foreign genes in the Lactococcus lactis subsp. lactis chromosome.

The plasmid pE194 is unable to replicate in Lactococcus lactis subsp. lactis (formerly Streptococcus lactis). When linked to resident bacteriophage sequences, pE194 was able to integrate into the L. lactis subsp. lactis chromosome either by Campbell-like recombination or by double crossing over with deletion. Integration occurred into the DNA of the prophage and prevented its multiplication. When a selective pressure was applied to an integrant in which pE194 was flanked by two direct repeats of prophage fragment, amplification of pE194 and the prophage fragment was observed. The pE194 copy number was assessed at six to nine, and amplification was stable upon growth under nonselective conditions.     

Lactobacillus hilgardii plasmid pLAB1000 consists of two functional cassettes commonly found in other gram-positive organisms.

A Lactobacillus hilgardii plasmid, pLAB1000, was studied to understand the organization of autonomous replicons from lactobacilli. Two cassettes could be identified. First, the replication region consisted of a sequence coding for a replication protein (Rep) and its corresponding target site, similar to those from plasmids pUB110, pC194 (Staphylococcus aureus), pFTB14, pBAA1 (Bacillus sp.), and pLP1 (Lactobacillus sp.). Sequence analysis indicated the possible synthesis of an antisense RNA that might regulate Rep production. The results also suggested that pLAB1000 replicates via a single-stranded DNA intermediate, and a putative lagging-strand initiation site was found that had similarities to those of alpha 3, St-1, and G4 isometric bacteriophages. The second cassette of pLAB1000 consisted of a sequence coding for a putative mobilization protein (Mob) and its corresponding RSA site. This cassette was similar to those found in pT181, pUB110, pE194 (S. aureus), and pG12 (Bacillus sp.), and it was found to be conserved among different Lactobacillus plasmid replicons. The origin and evolution of these functional cassettes are also discussed.