A complementation analysis of mobilization deficient mutants of the plasmid ColE1

The existence conditions for bacterial plasmids: Theory and reality

Bacteria abound with conjugative and nonconjugative plasmids that often carry genes determining a number of environmental adaptations. Plasmids may also encode genes that enable them to transmit themselves infectiously to new host cells, by conjugation or mobilization. The question of whether plasmids can be maintained in a bacterial community as parasitic DNA, that is, while conferring a selective disadvantage to their host, serves as a basic hypothesis in theoretical studies of the population biology of plasmids. The conditions necessary for the establishment and maintenance of plasmids have been determined analytically for the simplest possible models. Based on these a priori conditions, on some reconsiderations and extensions of these models, and on recent estimates of transfer rates of liquid and surface bacterial populations, it will be argued that within a bacterial population, a parasitic lifestyle is unlikely for most naturally occurring plasmids. This result raises anew the problem of how cryptic plasmids are maintained and why plasmids encode costly and elaborate genes for horizontal transfer.

Mobilization of closely related plasmids pUB110 and pBC16 by Bacillus plasmid pXO503 requires trans-acting open reading frame beta

Genetic analysis of the closely related nonconjugative plasmids pUB110 and pBC16 has demonstrated that the open reading frame beta (ORF-beta) region in pUB110 and the corresponding homologous region in pBC16 are essential for mobilization of these plasmids by pLS20 or its derivatives. Deletions in this region or insertions that interrupted ORF-beta severely impaired or eliminated the mobilization of pUB110::pUC18 and pBC16::pUC18 hybrids. In contrast, a hybrid in which pUC18 was inserted into pBC16 at a point outside ORF-beta transferred at a frequency comparable to that of intact pUB110 or pBC16 (10(-4) transcipients per donor cell). The defect of most transfer-deficient (Mob-) hybrid plasmids could be complemented by an intact sister plasmid (i.e., pBC16 for pUB110::pUC18 Mob- hybrids). The inability to complement certain constructs suggested that the origin of transfer might be located in an area 5' to ORF-beta. Furthermore, cloning the region 5' to ORF-beta onto a nonmobilizable pC194::pUC18 construct resulted in a hybrid plasmid, pUCCoriTBC16, that could be mobilized with complementation. These results indicate that mobilization of pUB110 and pBC16 by conjugative helper plasmids requires ORF-beta in trans and at least one other region, including the RSA sequence, which presumably functions as an origin of transfer, in cis.

Mobilization of the relaxable Staphylococcus aureus plasmid pC221 by the conjugative plasmid pGO1 involves three pC221 loci

The Staphylococcus aureus plasmid pC221, a 4.6-kilobase multicopy chloramphenicol resistance plasmid that forms plasmid-protein relaxation complexes, was mobilized for transfer by the conjugative plasmid pGO1. Two open reading frames on the pC221 genome, now designated mobA and mobB, as well as a cis-acting locus, the putative oriT, were shown to be in involved in pC221 mobilization. The mobA (but not mobB) and oriT loci were required for pC221 relaxation, and relaxation was necessary but not sufficient for pC221 mobilization by pGO1. oriT was cloned onto a pE194 derivative and complemented in trans for both relaxation and mobilization. Mobilization of relaxable plasmids in S. aureus appears to be analogous to mobilization by donation observed in gram-negative bacteria.

Structure and nucleotide sequence of the region encoding the mobilization proteins of plasmid CloDF13

Mobilization of the non-conjugative plasmid CloDF13 requires both gene products of a conjugative plasmid and CloDF13-encoded information. About 30% of the CloDF13 genome is involved in plasmid transfer. The CloDF13 mobilization region comprises sequences acting in cis (bom, basis of mobilization) as well as protein-coding sequences (mob). Here we present the nucleotide sequence of the genes encoding the CloDF13 mobilization proteins. We confirmed the previous genetic data that the plasmid CloDF13 encodes two proteins involved in plasmid mobilization. The information for these proteins, designated B and C having Mrs of 57,890 and 15,870, respectively, is located within one operon directed by a promoter at 94% of the CloDF13 genome. The gene encoding the smaller protein is located distally within this operon. Transcription proceeds counter-clockwise and is terminated beyond gene C, although it can not be excluded that attenuation of the transcript occurs in the intergenic region. The role of the CloDF13 mobilization proteins in plasmid transfer will be discussed.

Mobilization of the non-conjugative plasmid RSF1010: a genetic and DNA sequence analysis of the mobilization region

The entire region required for mobilization of the non-conjugative plasmid RSF1010 has been cloned into a mobilization-deficient pBR322 derivative. The segment of DNA cloned was approximately 1.8 kb and included the origin of conjugal DNA transfer (oriT). The DNA sequence of the mobilization region has been determined, and revealed the presence of several overlapping reading frames. The isolation and mapping of both Tn1725 and BamH1-linker insertions and comparison with the DNA sequence data has allowed the identification of three genes required for mobilization. Two of these genes are overlapping and encode proteins of 16 kDa and greater than 65 kDa (although the truncated protein is functional, the gene extends outside the region cloned). The third gene is transcribed in the opposite direction. Promoters capable of transcribing these genes were located by S1 mapping in the inter-cistronic region between these divergently transcribed genes. The oriT site is located in this region, and the transcriptional patterns observed for mob+ and mob- plasmids implied that the promoters may be regulated by two of the mobilization proteins binding to the oriT site.

Polar mobilization of the Escherichia coli chromosome by the ColE1 transfer origin

Mobilization of the plasmid ColE1 from cells containing a conjugative plasmid (such as F) requires the synthesis of ColE1 mob proteins, and the presence, in cis, of bom (basis of mobility), a region of ColE1 containing the origin of transfer (oriT). The process of ColE1 transfer is thought to resemble that of the conjugative plasmid F, although the plasmids share little sequence homology. In F, conjugation is preceded by a strand-specific nicking event at oriT. The nicked strand is then conducted to the recipient with the 5' end leading. This is believed also to occur with ColE1, but direct biochemical confirmation has been precluded by its small size (6.65 kb). To test this hypothesis genetically, a novel method, using a lambda dv-based vector, has been devised to site-specifically integrate bom (or any other cloned sequence) into the chromosome of Escherichia coli. When provided with suitable mobilizing plasmids, such strains were found to transfer the chromosome in a polar way. From these data, the orientation of transfer of ColE1 was deduced and shown to be analogous to F.

Identification of ColE1 DNA sequences that direct single strand-to-double strand conversion by a phi X174 type mechanism

A DNA single-strand initiation sequence, named rriA (called rri-1 previously), was detected in the origin region (Hae II fragment E) of the ColE1 plasmid [Nomura, N. & Ray, D. S. (1980) Proc. Natl. Acad. Sci. USA 77, 6566-6570]. Another site, called rriB, has been found on the opposite strand of Hae II fragment C. Both rriA and rriB (i) direct conversion of chimeric M13 phage single-stranded DNA to parental replicative form DNA in vivo by a rifampicin-resistant mechanism that is dependent on the dnaG and dnaB gene products, (ii) provide effector sites of dATP hydrolysis by primosomal protein n', and (iii) require the same primosomal proteins as phi X174 DNA for directing the in vitro conversion that rriA is the DNA sequence that determines the mechanism of lagging strand synthesis of ColE1 DNA and that the mechanism of discontinuous synthesis involves the primosomal proteins utilized in the in vitro conversion of phi X174 single strands to the double-stranded replicative form.

Read-through transcription from a derepressed Tn3 promoter affects ColE1 functions on a ColE1::Tn3 composite plasmid

Mutations in the repressor encoded by the transposon Tn3 tnpR gene lead to increased levels of expression of two gene products: the mutant repressor (TnpR-) and the Tn3 encoded transposase, TnpA (Heffron et al. 1978; Chou et al. 1979a). Derivatives of the ColE1::Tn3 composite plasmid, RSF2124, with mutant Tn3 repressor exhibited the expected elevated levels of transposition. Unexpectedly, hosts containing these tnpR- derivatives produced enhanced levels of the ColE1 encoded toxin, colicin E1. The gene for colicin E1 maps far (0.23-0.98 MU) from the Tn3 insertion point (0.73 MU) (Fig. 1). The colicin E1 overproduction phenotype, designated Eop-, was complemented in trans by wild type repressor gene product (TnpR+) to the wild type phenotype, Eop+. Hosts with RSF2124 derivatives which expressed high levels of both mutant repressor and mutant transposase (TnpR-, TnpA-) were Eop-. Hosts containing plasmids deleted for both tnpA and tnpR promoters were Eop+, while hosts with plasmids carrying a lac promoter substitution for the tnpA promoter were Eop-. These data support the idea that a cis-acting effect of increased transcription from the tnpA promoter into adjacent ColE1 DNA was the cause of colicin overproduction. Increased transcription activated a putative colicin augmentation function (caf) whose presence was required for the Eop- phenotype. Deletion mapping established that one boundary of the caf locus lies within 52 bases of the junction of the left end of Tn3 and ColE1 DNA. ColE1 DNA in this area contains an open reading frame which could encode either a 74 or a 63 residue protein (B. Polisky, unpublished DNA sequence data). The presence of increased levels of an mRNA transcript from this region and/or the increased expression of protein(s) from this transcript could result in an Eop- phenotype. Expression of the Eop- phenotype requires the presence of the host recE gene. Evidence is presented which suggests that the recA repressor, lexA protein, controls expression of the recE gene product, ExoVIII.

Selection and characterization of ColE1 plasmid mutants that exhibit altered stability and replication

This report describes a method for isolating mutants of plasmid ColE1 that exhibit unstable maintenance and altered replication characteristics. It also describes the initial characterization of four mutants isolated by that method. A chimeric plasmid, pHSG124, containing a ColE1 derivative and a temperature-sensitive replication derivative of pSC101 was mutagenized in vitro, using hydroxylamine. By adjusting the growth conditions of transformants containing the mutagenized chimeric deoxyribonucleic acid, it was possible to rapidly screen colonies and identify those that had a high probability of carrying ColE1 mutants that exhibit unstable maintenance. Of those mutants, some exhibited altered copy number or accumulated catenated structures. Evidence is presented which suggests that the mutations in three of the mutants are probably located in the HaeII A fragment of ColE1.

Structure and properties of the region of homology between plasmids pMB1 and ColE1

Physical maps of the two independently isolated Escherichia coli plasmids, pMB1 and ColE1, were prepared with 13 restriction endonucleases and compared. A 5.1 kilobase continuous region covering 55% of pMB1 and 75% of colE1 was found to have similar, but non-identical, restriction maps. The differences in the maps of this region probably arose by localized mutational events rather than by major sequence rearrangements. The F-factor was found to mobilize pMB1 efficiently for conjugal transfer. A region on pMB1 required for its F-mediated transfer was mapped. Results of our study combined with results of other investigators suggest that pMB1 and ColE1 share functional properties such as colicin production, colicin immunity, mode of replication, and mobilization by the F-factor, and that the sequences required to code these functions are contained within the 5.1 kilobase homologous region.

Plasmid cloning vectors that can be nicked at a unique site

We describe ColEl-type plasmids, with relaxed DNA replication, based on pMB9, and carrying the CmR determinant of R1, in addition to the TcR determinant of pMB9. One of the plasmids, pPH207, has unique sites for EcoRI, HindIII, BamI, SalI and HpaI. Insertion of foreign DNA into all but the last of these inactivates either the CmR or the TcR determinant. The original CmR TcR plasmid (pCM2) contains a copy of IS1 which produces deletions to left and to right. Most of these inactivate either the CmR or the TcR determinant. An internal 280 bp deletion of IS1 DNA in pPH207 greatly reduces the frequency at which deletions are observed. The main feature of these plasmids is a site that is cleaved by some preparations of EcoRI in only one strand of the DNA duplex (the EcoRIn site). This site facilitates strand separation of sequences inserted at the HindIII, BamI and SalI sites of the TcR gene, and also of any inserted at the true EcoRI site by a method that destroys that site. Since the orientation of the EcoRIn site is known, the orientation of sequences inserted at the neighbouring sites can be easily determined. Plasmid pPH207 is not mobilised by a Hfr, but its mobilisation is promoted by ColEl. It is therefore Mob- bom+. Experiments with minicells show that it directs the copious synthesis of chloramphenicol transacetylase.