Partition functions of unit-copy plasmids can stabilize the maintenance of plasmid pBR322 at low copy number.

The maintenance of plasmid pBR322 is highly unstable in a polA12 strain of Escherichia coli at 29 degrees C due to severely reduced copy number. Under these conditions, introduction of the par (partition) locus of plasmid P1 or the par (sop) region of F into pBR322 stabilizes it. A region with similar activity was detected in the P7 plasmid. The activity of the P1 par locus was dependent on the P1 parA gene product and was sensitive to par-specified incompatibility.     

Role of the rom protein in copy number control of plasmid pBR322 at different growth rates in Escherichia coli K-12

The copy number per cell mass of plasmid pBR322 and a rom- derivative was measured as a function of generation time. In fast growing cells the copy number per cell mass was virtually identical for rom+ and rom- derivatives. However, the copy number of pBR322 only increased 3- to 4-fold from a 20- to 80-min generation time, whereas the copy number of the rom- derivative increased 7- to 10-fold. The copy number stayed constant for the rom+ and rom- plasmids at generation times longer than 80-100 min. Thus, the presence of the rom gene decreased the copy number of plasmid pBR322 in slowly growing cells at least 2-fold when compared with the rom- plasmid. To study the effect of the rom gene in trans we cloned the gene into the compatible P15A-derived rom- plasmid pACYC184. In cells carrying both pACYC184 rom+ and pBR322 rom- the presence of the rom gene in trans had little effect on the copy number of pBR322 rom- at fast growth, but it decreased its copy number at slow growth to the same level as found for pBR322, i.e., complemented the pBR322 rom- plasmid. The pACYC184 plasmid and its rom+ derivatives showed copy numbers similar to those of pBR322 rom- and pBR322 itself, respectively, at fast and slow growth. We conclude that the rom gene product-the Rom protein-is an important element in copy number control of ColE1-type plasmids especially in slowly growing cells.     

The site-specific deletion in plasmid pBR322

The formation of a deletion derivative of plasmid pBR322, designated pBR322 delta 1, was observed during cloning of various eukaryotic DNAs, when the BamHI site of the plasmid vector was used for construction of the recombinant molecules. The restriction analysis of six independently isolated pBR322 delta 1 plasmids allowed establishment of their complete identity. Similar deletion derivatives were also formed as a result of transformation of Escherichia coli cells by the linear form of vector pBR322 produced by BamHI cleavage, but not by SalI or HindIII. The endpoints of the deletion in one of the pBR322 delta 1 plasmids occurred at positions 375 and 16666 bp from the EcoRI site, as determined by sequence analysis. Formation of pBR322 delta 1 is most probably due to site-specific recombination between the sequence in the 1666-1670 bp region and the BamHI end of the linear pBR322 molecule. THe deletion was not controlled by the recA system of the host bacteria.     

Structure and function of the F plasmid genes essential for partitioning

The F plasmid in Escherichia coli has its own partition mechanism controlled by the sopA and sopB genes, and by the cis-acting sopC region. The DNA sequence of the entire partition region and its flanking regions is described here. Two large open reading frames coding for 43,700 Mr and 35,400 Mr proteins correspond to sopA and sopB, respectively. The sopB reading frame is located immediately downstream from the sopA reading frame. Twelve 43 base-pair direct repeats exist in the sopC region without any spacer regions, and one pair of seven base-pair inverted repeats exists in each of the direct repeats. Analysis of deletions in the sopC region showed that the direct repeats play an important role in plasmid partition and IncD incompatibility. IncG incompatibility is exhibited by pBR322 derivatives carrying the sopB gene alone. When compared with the partition genes parA and parB of plasmid P1, homology in amino acid sequence was found between the SopA protein of F and the ParA protein of P1, and also between SopB protein of F and ParB protein of P1. In addition, homology was found between Rep proteins of F and P1.     

Partitioning of plasmid R1. Structural and functional analysis of the parA locus

The stability locus, parA+, of plasmid R1 is shown to be localized within a 1500 base-pair region of DNA on the largest EcoRI restriction fragment of plasmid R1. The nucleotide sequence of the region revealed the presence of two open reading frames, one of 320 codons, and another of 60 codons. The larger open reading frame encodes a polypeptide of 36,000 Mr. Deletions covering the promoter distal end of the 36,000 Mr reading frame give rise to synthesis of large amounts of truncated protein. Construction of promoter fusions between the parA+ promoter and the lacZ gene showed that the parA+ region encodes a factor that negatively regulates the expression of the 36,000 Mr protein. The locus exerting parA+-associated incompatibility, denoted incA+, was mapped to a 60 base-pair region covering the parA+ promoter. Most likely, this region is involved both in the negative regulation of the parA+ operon and in the parA+-associated incompatibility. Two explanations are suggested to explain this possible dual function of the parA+ promoter region. The parA+ region was cloned into an unstably inherited (par-) derivative of a mini-F derivative. The low copy number plasmid mini-F devoid of its own partition genes was stabilized more than 100-fold by carrying the parA+ genes. This observation is in accordance with the proposal that the parA+ locus specifies the true partition function of plasmid R1.     

Structural instability of co-integrates formed during interaction of plasmid R57 with pB322 and RP1. Possible role of IS1 element in the degradation of co-integrates

The conjugative plasmid R57 determines resistance to ampicillin and chloramphenicol. Earlier it was shown that R57 encodes site-specific recA-independent recombinase, which acts in cis and resolves IS1-mediated cointegrates arising in the Escherichia coli recA cells between R57 and pBR322. In the present work the properties of the cointegrates between R57 and pBR322 or RP1 arising in the E. coli rec+ strains were studied. It was found that the cointegrates between R57 and pBR322, obtained by mating of the respective biplasmid donors of E. coli rec+ and the rec+ recipients, lost as a result of deletion a large DNA segment of R57 containing determinant Cmr. The resulting hybrid replicons preserved determinants Apr and Tcr of pBR322 and the R57 conjugative properties and were structurally identical. By using plasmid RP1ts12, which is temperature-sensitive in replication, it was demonstrated that in cells rec+ the cointegrates between R57 and RP1 are extremely unstable. On storage they undergo structural degradation mainly affecting the RP1 replicon. The degradation products of the hydrid complex had lost their RP1 genes but preserved the R57 functional determinants. For elucidation of the observed phenomena the properties of the IS1-mediated cointegrates between pBR322:Tn9 and plasmid pBR3.1--deletion derivative of RP1 were studied. It was found that insertion of IS1 sometimes resulted in formation of unstable cointegrates capable of resolving and loosing determinant Cmr with a high frequency. It was suggested that IS1 encodes the site-specific recombinase responsible for resolution of the IS1-mediated cointegrates and deletion generation. Expression of this recombinase appears to be dependent on structure of the insertion sites. The possible role of IS1 and recombinase encoded by it in resolution and structural instability of the cointegrates between R57 and pBR322 or RP1 is discussed.     

Genetic transformation of Rhodopseudomonas sphaeroides by plasmid DNA.

A broad-host-range cloning vector, pUI81, was constructed in vitro from plasmids RSF1010 and pSL25 (a pBR322 derivative) and used to assay for transformation in Rhodopseudomonas sphaeroides. Washing cells with 500 mM Tris was an effective means of inducing competence for DNA uptake. Transformation frequencies as high as 10(-5) (transformants per viable cell) have been achieved by incubating Tris-treated cells with plasmid DNA, 100 mM CaCl2, and 20% polyethylene glycol 6000. Maximum frequencies were obtained when recipient cells were spread onto selective media after a 6.5-h outgrowth period in antibiotic-free medium. The structure (open circular versus closed, covalent circular), size, and concentration of plasmid DNA all significantly affected the transformation frequency. Four different plasmids, all small and suitable as cloning vectors, have been introduced by transformation into several different R. sphaeroides strains. Recombinant DNA carried on small, nonconjugative plasmids with broad host ranges can now be directly transferred to R. sphaeroides by this method.     

Incompatibility mutants of IncFII plasmid NR1 and their effect on replication control

DNA from the replication control region of plasmid NR1 or of the Inc- copy mutant pRR12 was cloned into a pBR322 vector plasmid. These pBR322 derivatives were mutagenized in vitro with hydroxylamine and transformed into Escherichia coli cells that harbored either NR1 or pRR12. After selection for the newly introduced pBR322 derivatives only, those cells which retained the unselected resident NR1 or pRR12 plasmids were examined further. By this process, 134 plasmids with Inc- mutations in the cloned NR1 or pRR12 DNA were obtained. These mutants fell into 11 classes. Two of the classes had plasmids with deletions or insertions in the NR1 DNA and were not examined further. Plasmids with apparent point mutations were classified by examining (i) their ability to reconstitute a functional NR1-derived replicon (Rep+ or Rep-), (ii) the copy numbers of the Rep+ reconstituted replicons, (iii) the cross-reactivity of incompatability among the various mutant classes and parental plasmids, and (iv) the trans effects of the mutants on the copy number and stable inheritance of a coresident plasmid.     

Chromosomal genes essential for stable maintenance of the mini-F plasmid in Escherichia coli

We have isolated mutants of Escherichia coli which do not support stable maintenance of mini-F plasmids (delta ccd rep+ sop+). These host mutations, named hop, were classified into five linkage groups on the E. coli chromosome. Genetic analyses of these hop mutations by Hfr mating and P1 transduction showed their loci on the E. coli genetic map to be as follows: hopA in the gyrB-tnaA region, hopB in the bglB-oriC region, hopD between 8 and 15 min, and hopE in the argA-thyA region. Kinetics of stability of the sop+ and delta sop mini-F plasmids in these hop mutants suggest that the hopA mutants are defective in partitioning of mini-F rather than in plasmid replication. The hopB, hopC, and hopD mutants were partially defective in replication of mini-F. The physical structure of the plasmid DNA was normal in hopA, B, C, and D mutants. Large amounts of linear multimers of plasmid DNA accumulated in mutants of the fifth linkage group (hopE). None of the hop mutations in any linkage group affected the normal growth of cells.     

Altered ParA partition proteins of plasmid P1 act via the partition site to block plasmid propagation

The partition system of the P1 plasmid, P1 par consists of the ParA and ParB proteins and a cis -acting site, parS . It is responsible for the orderly segregation of plasmid copies to daughter cells. Plasmids with null mutations in parA or parB replicate normally, but missegregate. ParB binds specifically to the parS site, but the role of ParA and its ATPase activity in partition is unclear. We describe a novel class of parA mutants that cannot be established or maintained as plasmids unless complemented by the wild-type gene. One, parAM314I , is conditional: it can be maintained in cells in minimal medium but cannot be established in cells growing in L broth. The lack of plasmid propagation in L broth-grown cells was shown to be caused by a ParB-dependent activity of the mutant ParA protein that blocks plasmid propagation by an interaction at the parS site. Thus, ParA acts to modify the ParB– parS complex, probably by binding to it. Partition is thought to involve selection of pairs of plasmids before segregation, either by physical pairing of copies or by binding of copies to paired host sites. We suggest that ParA is involved in this reaction and that the mutant ParA protein forms paired complexes that cannot unpair.     

Escherichia coli dnaT gene function is required for pBR322 plasmid replication but not for R1 plasmid replication.

Plasmid pBR322 was unable to replicate in a temperature-sensitive dnaT1 strain at a nonpermissive temperature, whereas a pBR322-derived plasmid carrying the wild-type dnaT+ gene was able to replicate under the same conditions. In contrast to pBR322, plasmid R1 could replicate in the dnaT1 strain at a nonpermissive temperature. In keeping with this finding, in vitro replication of plasmid R1 did not require DnaT protein.     

Replication functions of pC194 are necessary for efficient plasmid transduction by M13 phage.

Escherichia coli plasmids pBR313 and pBR322 were transduced by phage M13 with low efficiency (10(-8) transductants/phage). Hybrid plasmids pHV12 or pHV33, composed of Staphylococcus aureus plasmid pC194 and pBR313 or pBR322, respectively, were transduced much more efficiently (10(-4) transductants/phage). Inactivation of either of the two zones necessary for pC194 replication, one coding for a protein, the other not, reduced the transforming efficiency of hybrids to the level of pBR322. Activity of the pC194 replication region was not necessary for the formation of chimeras between M13 and the transduced plasmid in the donor cells, but rather for the establishment of the plasmid in the recipient cells.     

Nucleotide sequence and characterization of the trbABC region of the IncI1 Plasmid R64: existence of the pnd gene for plasmid maintenance within the transfer region.

A 6.72-kb DNA sequence between the exc gene and the oriT operon within the transfer region of IncI1 plasmid R64 was sequenced and characterized. Three novel transfer genes, trbA, trbB, and trbC, were found in this region, along with the pnd gene responsible for plasmid maintenance. The trbABC genes appear to be organized into an operon located adjacent to the oriT operon in the opposite orientation. The trbA and trbC genes were shown to be indispensable for R64 plasmid transfer, while residual transfer activity was detected in the case of R64 derivatives carrying the trbB++ deletion mutation. The T7 RNA polymerase-promoter system revealed that the trbB gene produced a 43-kDa protein and the trbC gene produced an 85-kDa protein. The nucleotide sequence of the pnd gene is nearly identical to that of plasmid R483, indicating a function in plasmid maintenance. The plasmid stability test indicated that the mini-R64 derivatives with the pnd gene are more stably maintained in Escherichia coli cells under nonselective conditions than the mini-R64 derivatives without the pnd gene. It was also shown that the R64 transfer system itself is involved in plasmid stability to a certain degree. Deletion of the pnd gene from the tra+ mini-R64 derivative did not affect transfer frequency. DNA segments between the exc and trbA genes for IncI1 plasmids R64, Colb-P9, and R144 were compared in terms of their physical and genetic organization.     

Stabilization of anE. coli plasmid by a mini-F fragment of DNA

Summary In anEscherichia coli K-12 strain (trpA trpE tnaA) cultured in LB broth without selective pressure, a pBR322 derivative containing the gene for tryptophan synthase (pBR322-trpBA) was found to be unstable. After 70 cell-number doublings, only 50% of the host cells retained the gene for ampicillin resistance (Ap^r). Insertion of the mini-F fragment of F factor DNA into this plasmid could effectively reduce the plasmid loss. Partial derepression of the tryptophan promotor-operator by 3-indopleacrylic acid further decreased the stability of the pBR322-trpBA but not that of the mini-F inserted plasmid (pBR322F-trpBA) The vector pBR322F-trpBA could be maintained at high copy number in the culture after 100 generations of growth; the culture was able to overproduce tryptophan synthase in the presence of 3-indoleacrylic acid.l-Tryptophan was produced from indole andl-serine using andE. coli host transformed with.pBR322F-trpBA DNA. After 8 h of incubation, the expression level was approximately 180 g/l.     

Retrovirus-mediated insertional mutagenesis: phagemid rescue of flanking DNA by selecting plasmid ori

A method for screening recombinant lambda libraries was devised to select phage containing genomic regions containing provirus insertions of retroviruses that carry the kanamycin and G418 resistance factor neo and the origin of replication derived from pBR322 (oripBR). Such recombinants are phagemids, able to replicate as bacteriophages or as plasmids under lambda repressor control. lambda repressor was cloned into a plasmid derived from pSC101 that is compatible with pBR322-derived phagemids. A strain carrying this plasmid may be used to select phagemids derived from a single proviral insertion with 100% efficiency from complex recombinant libraries. Homologous recombination between proviral long terminal repeats was observed at a rate of 10(-4)/plaque-forming unit in recABC+ strains. Despite this frequency, intact phagemids are easily recovered as phage after temperature shift to 42 degrees C. Since oripBR itself is a selectable marker in this system, the method could be applied to recover any sequence carrying the ori sequence from pBR322.     

The transformation of legionellae by plasmid DNA

For the first time the possibility of the genetic transformation of L. pneumophila and L. bozemanii strains with the use of purified DNA of plasmids pUC19, pUC4K, pSC101 and RSF1010-pBR322 was shown. The frequency of transformation varied from 5.2 x 10(-6) to 5.8 x 10(-7), depending on the strain used in the experiment and plasmid DNA. In some of the transformants obtained in this investigation plasmid DNA whose molecular weight was similar to that of the plasmid DNA used for transformation was detected. The relatively stable preservation of plasmids pSC101 and RSF1010 in Legionella strains and the loss of plasmids pUC19, pUC4K and pBR322 in 80% of transformants during storage were shown.     

The use of a partition locus to increase stability of tryptophan-operon-bearing plasmids in Escherichia coli

The stability of different derivatives of plasmid vectors pBR322 and pACYC184 carrying the tryptophan operon of Escherichia coli was monitored in various media. It was found that in the absence of any special selective pressure, all plasmids were lost from the culture. The stability varied depending both on the orientation of the inserted tryptophan fragment and the growth media used. The pBR322::trp+ plasmids were lost at an average frequency of 0.3 to 0.8% per cell generation, while the pACYC184::trp+ plasmid was lost at a rate higher than 5%. In all cases the whole plasmid was lost at a rate higher than 5%. In all cases the whole plasmid was lost, indicating a high stability of the plasmid::cloned DNA as such. To increase the stability of the cloning vectors, the partition locus of plasmid pSC101 was added to both the pBR322::trp+ and pACYC184::trp+ plasmids. The addition of this gene increased the replicon stability at least 3- to 10-fold, with the pBR322::trp+-par+ plasmids being the most stable. Also in this case, the stability was dependent on the plasmid type and on the growth medium. In no case was there a discoordinate loss of the antibiotic-resistance and tryptophan genes from the vectors.     

Intergeneric transfer and exchange recombination of restriction fragments cloned in pBR322: a novel strategy for the reversed genetics of the Ti plasmids of Agrobacterium tumefaciens

Transmission of ColE1/pMB1-derived plasmids, such as pBR322, from Escherichia coli donor strains was shown to be an efficient way to introduce these plasmids into Agrobacterium. This was accomplished by using E. coli carrying the helper plasmids pGJ28 and R64drd11 which provide the ColE1 mob functions and tra functions, respectively. For example, the broad host-range replication plasmid, pGV1150, a co-integrate plasmid between pBR322 and the W-type mini-Sa plasmid, pGV1106, was transmitted from E. coli to A. tumefaciens with a transfer frequency of 4.5 x 10(-3). As pBR322 clones containing pTiC58 fragments were unable to replicate in Agrobacterium, these clones were found in Agrobacterium only if the acceptor carried a Ti plasmid, thus allowing a co-integration of the pBR322 clones with the Ti plasmid by homology recombination. These observations were used to develop an efficient method for site-specific mutagenesis of the Ti plasmids. pTiC58 fragnents, cloned in pBR322, were mutagenized in vitro and transformed into E. coli. The mutant clones were transmitted from an E. coli donor strain containing pGJ28 and R64drd11 to an Agrobacterium containing a target Ti plasmid. Selecting for stable transfer of the mutant clone utilizing its antibiotic resistance marker(s) gave exconjugants that already contained a co-integrate plasmid between the mutant clone and the Ti plasmid. A second recombination can dissociate the co-integrate plasmid into the desired mutant Ti plasmid and a non-replicating plasmid formed by the vector plasmid pBR322 and the target Ti fragment. These second recombinants lose the second plasmid and they are identified by screening for the appropriate marker combination.     

Survival of and plasmid stability in Pseudomonas and Klebsiella spp. introduced into agricultural drainage water

Cell survival and plasmid stability in Pseudomonas fluorescens R2f and Pseudomonas putida CYM 318 containing respectively, plasmid RP4 and pRK2501, and Klebsiella aerogenes NCTC 418 harboring plasmid pBR322 were studied in sterile and nonsterile agricultural drainage water under both aerobic and anaerobic conditions and in the absence and presence of added nutrients. Both Pseudomonas strains survived well in sterile drainage water incubated aerobically, with or without added nutrients. However, Klebsiella aerogenes NCTC 418 (pBR322) only survived in the presence of added nutrients. Pseudomonas fluorescens R2f (RP4) and K. aerogenes NCTC 418 (pBR322) did not survive under anerobic conditions without added nutrients, but showed good survival in the presence of nutrients. Survival of all three strains was negatively affected in nonsterile agricultural drainage water when compared with survival in sterile water. Maintenance of the three plasmids was host, plasmid, and environment dependent. Plasmid pBR322 was not stably maintained in K. aerogenes NCTC 418 under all conditions used in the study, and pRK2501 was readily lost from P. putida CYM 318. Maintenance of RP4 by P. fluorescens R2f was markedly influenced by added nutrients, which caused a loss of the plasmid from cells. The results of the present study demonstrate the influence of nutrients, O2, and native microorganisms on the survival of introduced bacterial strains and plasmid stability in agricultural drainage water.     

Functional analysis of replication and stability regions of broad-host-range conjugative plasmid CTX-M3 from the IncL/M incompatibility group

Plasmid CTX-M3 (89 kb) isolated from Citrobacter freundii from a Warsaw hospital is a mosaic plasmid with replication functions 100% identical with those of pMU407.1 of the IncL/M group, conjugative operons with up to 60% homology to ColIb-P9 (IncI) and stability functions originating either from NR1(R100) (IncFII) or ColIb-P9 /R1/NR1 plasmids. We established the broad-host-range for pCTX-M3 and defined its minireplicon in Escherichia coli. We analyzed the role of stability cassettes and showed that the par operon consists of three orfs parA (stbA), parB (stbB) and nuc with a centromere-like region located upstream of the operon. Deletion of the par operon strongly destabilized pCTX-M3 despite the presence of the pemIK toxin-antidote system identical to that on NR1(R100) plasmids. Deletion of the pemIK operon had no effect on plasmid stability.