Partitioning of plasmid R1 in Escherichia coli,: I. Kinetics of loss of plasmid derivatives deleted of the par region

The stability of inheritance of plasmid R1drd-19 was tested. The copy number of the plasmid was determined in two different ways: As the ratio between covalently closed circular DNA and chromosomal DNA, and by quantitative determination of single-cell resistance to ampicillin. In the latter case, strains carrying the R1 ampicillin transposon Tn3 on prophage λ was used as standard. The values were transformed to copy number per cell by using the Cooper-Helmstetter model for chromosome replication as well as by determination of chromosomal DNA per cell by the diphenylamine method. The copy number was found to be five to six per cell (or about four per newborn cell). Nevertheless, plasmid R1drd-19 was found to be completely stably inherited. This stability was shown not to be due to retransfer of the plasmid by the R1 conjugation system, since transfer-negative derivatives of the plasmid were also completely stably inherited. Smaller derivatives of plasmid R1drd-19 were found to be lost at a frequency of about 1.5% per cell generation. The copy-number control was not affected in these miniplasmids, since their copy numbers were the same as that of the full size plasmid. Quantitatively, the instability of the miniplasmids was in accord with random partitioning. It is, therefore, suggested that the plasmid R1drd-19 carries genetic information for partitioning (par) of plasmid copies at cell division, and that the par mechanism is distinct from the copy number control (cop) system. Finally, the par gene maps on the resistance transfer part of the plasmid, but far away from the origin of replication and the so-called basic replicon; this is in accord with the approximate location of the repB gene (Yoshikawa, 1974, J. Bacteriol.,, 118, 1123–1131).     

The nucleotide sequence of a DNA fragment from the replication origin of the antibiotic resistance factor R1drd19

Summary The recombinant plasmid pRK101 contains a DNA fragment which carries the complete replication origin of the antibiotic resistance factor R1drd-19 inserted into the vector plasmid pBR322. In a spontaneously arising mutant of this plasmid (pRK 103) a deletion of about 215 base pairs (bp) has been detected by heteroduplex analysis and mapping with restriction endonucleases. Essential parts of the replication origin must be located in the deleted sequence. The deletion mutant pRK103, in contrast to its parent plasmid pRK101 is not replicated under the control of the R1 replicon, even when the R1 factor or copy mutants of it are present within the same cell. These latter plasmids can complement a plasmid-specific protein not coded by pRK101 but essential for R1-directed replication. The nucleotide sequence of a 252 bp HpaII fragment covering about 170–200 bp of the deletion was determined. This piece of DNA is rich in G and C and contains a series of small palindromes, symmetrically arranged repeated sequences and short selfcomplementary structures which may be of significance for the initiation of the DNA replication. The possibility that the sequenced DNA fragment comprises a major part of the replication origin of R1drd-19 is discussed.     

Properties of hybrid plasmids, consisting of parts of the mini-R1 factor Rsc11 and ColE1.

Summary In vitro joining of the two small multicopy plasmidsRsc11 andColE1 by a poly dAdT linker resulted in hybrid plasmids, which determine resistance to ampicillin and immunity to colicin E1. Isolation of the plasmid DNA from single colonies revealed that a variety of hybrid plasmids was formed. Cleavage of these plasmids with restriction endonucleasesHincII,HindIII,EcoR1,SmaI andBamI and hybridization withColE1 demonstrated that they contain different parts of the parent plasmids,Rsc11 andColE1. Their copy number in the cell is between 6 and 15 per chromosome depending on the plasmid. None of these plasmids can replicate inpolA mutants. Replication continues in the presence of chloramphenicol. This suggests that replication can only occur from theColE1 origin and that the replication function of theRsc11 part is lost. The hybrid plasmids are compatible withRsc11 but not withColE1. The comparison of the physical maps of theseRsc11-ColE1 hybrids with their functions allows a partial determination of the location of ampicillin resistance, replication and incompatibility on theRsc11 genome.Schering AG, Müllerstr. 170–178, D-1000 Berlin 65Gesellschaft für Biotechnologische Forschung mbH, Abt. Genetik, Mascheroder Weg 1, D-3300 Braunschweig-Stöckheim     

Restriction map of the antibiotic resistance plasmid R1drd-19 and its derivatives pKN102 (R1drd-19B2) and R1drd-16 for the enzymes BamHI, HindIII, EcoRI and SalI.

Summary The conjugative R plasmid R1drd-19, mediating antibiotic resistance to ampicillin (Ap), chloramphenicol (Cm), kanamycin (Km), streptomycin (Sm) and sulfonamides (Su) was mapped using the restriction endonucleases BamHI, HindIII, EcoRI and SalI. BamHI generates 5 fragments (A-E) with molecular weights between 46×10⁶ dalton (representing mainly the RTF) and 0.25×10⁶ dalton, and HindIII 8 (A-H) between 42×10⁶ dalton (representing the main part of the RTF) and 0.1×10⁶ dalton. EcoRI recognises 17 sites and produces fragments (A-Q) with molecular weights between 11.7 and 0.1×10⁶ dalton. SalI yields 7 fragments (A-G) of 16.5 to 2.0×10⁶ dalton.A physical map was constructed from fragments obtained by partial digestion of R1drd-19 with one restriction enzyme, by double and triple digestion of the DNA with two or three enzymes with and without isolation of individual bands from preparative gels. In addition the restriction patterns of several mutants of R1drd-19 were compared with it.Evidence is presented which indicates that the derivatives of R1 investigated are generated by extende deletions, namely the copy mutant pKN102 which has lost the Km resistance, R1 drd-16, which has lost all resistances other than Km and the Km^s derivative of R1drd-16, which represents the pure RTF. The map of R1drd-19 is remarkably different from those of R100 and R6-5. Its molecular weight was estimated to be 62.5 Md. The circular fragment order for BamHI is: A-C-B-D-E, for HindIII: A-D-C-B-F-H-E-G, for EcoRI: A-C-K-B-F-J-O-D-H-L-G-P-Q-N-I-E-M-and for SalI A-B-C-D-G-F-E.     

Transposition and insertion of intact, deleted and enlarged ampicillin transposon Tn3 from mini-R1 (Rsc) plasmids into transfer factors

Summary The miniR1-(Rsc)-plasmids which derive from the copy mutant R1drd-19B2 (pKN102) are nonconjugative extrachromosomal elements which can not be co-transferred by various transfer factors to recipient strains under standard mating conditions. The attempts to mobilize Rsc11 by F'lac lead to transconjugants carrying F'lac::Tn3 with Tn3 mainly inserted into the lac operon. In addition it can be shown that Rsc11 can become inserted as a complete unit into the transfer factor giving rise to rather unstable recombinant intermediates. Dissociation of these intermediates may lead to alterations of the original plasmids.The Tn3 part of Rsc13 can be enlarged or deleted by in vitro manipulations. In vitro insertion of EcoRI-fragments into an EcoRI⁺ site of Tn3 leads to new transposable units which can be transposed to the RTF part of R1. This new genetic entity can be stably integrated into the chromosome of E. coli by integrative suppression of a dnaA^ts-mutation.Deletions at one end or the central region of Tn3 abolish the capability of transposition. However, the Rsc-plasmids containing the deleted Tn3 can still be inserted into the transfer factor as complete units. The resulting recombinants are unstable leading after dissociation in some cases to new plasmids with altered properties.     

Selection and timing of replication of plasmids R1drd-19 and F'lac in Escherichia coli.

The selection and timing of plasmid replication was studied in exponentially growing cultures of Escherichia coli K-12 carrying the plasmid R1drd-19 and E. coli strains B/r A and B/r F carrying the plasmid F′lac. In all cases plasmid replication was studied by analysis of covalently closed circular (CCC) DNA. The turnover time of replicating plasmid DNA into CCC-DNA was found to be less than 4 min. Density shift experiments (from ¹⁵NH₄⁺, D₂O to ¹⁴NH₄⁺, H₂O) showed that plasmids R1drd-19 and F′lac are selected randomly for replication. This means that one of the plasmid copies in a cell is selected and replicated. There is no further plasmid replication in the cell until all plasmid copies, including the newly formed ones, have the same probability of being selected for replication. The early kinetics of the appearance of light plasmid DNA after the density shift showed that the time interval between successive replications of plasmids R1drd-19 and F′lac is $\text{τ}\text{n}$, where τ is the generation time and n is the average number of plasmid replications per cell and cell cycle. In a second type of experiment, exponentially growing cells were separated into a series of size classes by low-speed centrifugation in sucrose step gradients. Replication of plasmids R1drd-19 and F′lac was equally frequent in all size classes. This result is in accordance with the results of the density shift experiment. It can therefore be concluded that replication of plasmids R1drd-19 and F′lac is evenly spread over the whole cell cycle, which means that one plasmid replication occurs every time the cell volume has increased by one initiation mass.     

Translocation of an ampicillin resistance determinant within an R-factor aggregate inSalmonella panama

The molecular properties of the plasmids of a natural isolate ofSalmonella panama have been studied. This strain, Sp477, harbours 5 different plasmids: the conjugative plasmid pRI477TF (molecular weight 20 megadaltons), the two non-conjugative plasmids, pRI477A and pRI477S, coding for ampicillin and streptomycin plus sulfonamide resistance respectively (molecular weights of both 5.6 megadaltons) and two cryptic plasmids with molecular weights of 1.0 and 2.7, megadaltons respectively. After conjugal transfer toEscherichia coli the ampicillin resistance determinant was frequently found to be integrated into pRI477TF or pRI477S. The translocatable sequence on pRI477A, designated as Tn901, resembles the TnA subclass transposon TnA(1).     

Isolation and characterization of lambda phages carrying the basic replicon of the resistance plasmid R1

Summary Specialized transducing lambda phages, oriR1, harboring DNA from the resistance plasmid R1drd-19 and its copy mutant pKN103 were isolated. From measurements of CCC-DNA content it is concluded that upon infection the phages can establish themselves as self-replicating plasmids in recA hosts lysogenic for lambda. It is thought that this bypassing of lambda immunity is due to the presence of the R1 origin of replication. The plasmids are sensitive to the incompatibility expressed by plasmid R1. This has been shown mainly by transduction of oriR1 into recipients containing R1 plasmids or plasmid pBR322 carrying the basic replicon. We were able to demonstrate that a copy mutant of plasmid R1 was insensitive to copA ⁺, but sensitive to the conserted action of Pst1 fragments F₁ and F₂. This mutant was previously assumed to be of the dominant type. Physical mapping of the oriR1 derivatives verified that they carry the basic replicon of plasmid R1. The plasmids are not stably maintained, but are lost in a frequency of 1%–2% per cell generation, which is consistent with their lack of the R1par region.     

Temperature-dependent and amber copy mutants of plasmid R1drd-19 in Escherichia coli.

The isolation of conditional mutants with an altered copy number of the R plasmid R1drd-19 is described. Temperature-dependent as well as amber-suppressible mutants were found. These mutant plasmids have been named pKN301 and pKN303, respectively. Both types of mutations reside on the R plasmid. No difference in molecular weight could be detected by neutral sucrose gradient centrifugation for any of the mutant plasmids when compared with the wild-type plasmid. The number of copies of the plasmids was determined by measurement of the specific activity of the R plasmid-mediated β-lactamase and by measurement of covalently closed circular (CCC) DNA in alkaline sucrose gradients and dye-CsCl density gradients. Below 34 °C the temperature-dependent mutant, pKN301, had the same copy number as the wild type, while this was four times that of the wild type above 37 °C. The amber mutant pKN303 had a copy number indistinguishable from that of the wild-type plasmid in a strain containing a strong amber suppressor and a copy number about five times that of the wild-type plasmid in a strain lacking an amber suppressor. In a strain containing a temperature-sensitive amber suppressor, the amber mutant's copy number increased with the decrease in amber suppressor activity. Thus, the existence of the temperature-dependent and the amber-suppressible R-plasmid copy mutants indicates that the system that controls the replication of plasmid R1drd-19 contains an element with a negative function and that this element is a protein.     

Transposition of a duplicate antibiotic resistance gene and generation of deletions in plasmid R6K.

Transformation experiments showed that spontaneous deletions which result in loss of streptomycin resistance and an increase in conjugal transfer efficiency are present at a frequency of about 10(-4) in plasmid molecules of R6K. Similar deletions were thus readily selected by conjugal transfer of R6K, and their appearance was dependent upon recA+ activity in either donor or recipient host. The deoxyribonucleic acid segment deleted in four mutants examined was concluded to extend from the same terminus of the transposon, TnA, in the same direction, but to different extents, and to retain the TnA region intact. Insertions of a duplicate TnA element were found in R6K plasmids isolated from strains selected for increased ampicillin resistance, which were unstable in recA+ strains. In four plasmids examined after transfer to a recA host, an inverted repeat of the preexisting TnA element was shown to have been inserted at a similar location and was in two instances associated with deletions which extended from the same direction as those described above. The deletions are ascribed to the result of recA+-dependent recombination between direct repeats of TnA.     

Molecular characterization of a small Haemophilus influenzae plasmid specifying beta-lactamase and its relationship to R factors from Neisseria gonorrhoeae.

The ampicillin-resistant Haemophilus influenzae strain Ve445 which caused purulent meningitis and septicaemia in a newborn child in Germany contained a 4.4 megadalton (Mdal) plasmid (pVe445) and produced a TEM type beta-lactamase. The transformation to ampicillin resistance of a sensitive Escherichia coli strain with isolated pVe445 DNA proved that the structural gene for the beta-lactamase resided on this plasmid genome. Molecular DNA-DNA hybridization studies and electron microscope DNA heteroduplex analysis indicated that pVe445 probably contained 38 to 41% of the ampicillin translocation DNA segment (TnA) found on R factors of enteric origin. The TnA fragment present in pVe445 most likely does not contain both of the inverted repeat sequences of TnA. DNA-DNA polynucleotide sequence studies indicated that the 4.4 Mdal plasmid pVe445 was unrelated to the 30 to 38 Mdal H. influenzae R plasmids but was closely related to the 4.1 Mdal ampicillin resistance specifying H. influenzae plasmid RSF0885 isolated in the U.S.A. The H. influenzae plasmid pVe445 shared 91% of its base sequences with the beta-lactamase specifying Neisseria gonorrhoeae plasmid pMR0360 (4.4 Mdal) and had 85% of its base sequences in common with the beta-lactamase specifying N. gonorrhoeae plasmid pMR0200 (3.2 Mdal). All of the four 3.2 to 4.4 Mdal beta-lactamase specifying R plasmids of H. influenzae and N. gonorrhoeae investigated probably have a common evolutionary origin.     

Cloning and characterization of EcoRI and HindIII restriction endonuclease-generated fragments of antibiotic resistance plasmids R6-5 and R6

Summary DNA fragments generated by the EcoRI or HindIII endonucleases from the low copy number antibiotic resistance plasmids R6 and R6-5 were separately cloned using the high copy number ColEl or pML21 plasmid vectors and the insertional inactivation procedure. The hybrid plasmids that were obtained were used to determine the location of the EcoRI and HindIII cleavage sites on the parent plasmid genomes by means of electron microscope heteroduplex analysis and agarose gel electrophoresis. Ultracentrifugation of the cloned fragments in caesium chloride gradients localized the high buoyant density regions of R6-5 to fragments that carry the genes for resistance to streptomycin-spectinomycin, sulfonamide, and mercury and a low buoyant density region to fragments that carry the tetracycline resistance determinant. Functional analysis of hybrid plasmids localized a number of plasmid properties such as resistances to antibiotics and mercury and several replication functions to specific regions of the R6-5 genome. Precise localisation of the genes for resistance to chloramphenicol, kanamycin, fusidic acid and tetracycline was possible due to the presence of identified restriction endonuclease cleavage sites within these determinants.Only one region competent for autonomous replication was identified on the R6-5 plasmid genome and this was localized to EcoRI fragment 2 and HindIII fragment 1. However, two additional regions of replication activity designated RepB and RepC, themselves incapable of autonomous replication but capable of supporting replication of a linked ColE1 plasmid in polA^– bacteria, were also identified.     

Plasmid R1 in Salmonella typhimurium: Molecular instability and gene dosage effects

Plasmid R1 drd-19 and two of its copy mutants (pKN102 and pKN103) were transferred from Escherichia coli to Salmonella typhimurium, where the expression of the copy mutations was studied further. The copy number (ratio of plasmid DNA to chromosomal DNA) was the same in S. typhimurium and in E. coli. The activities of the plasmid-coded antibiotic-metabolizing enzymes β-lactamase, chloramphenicol acetyltransferase, and streptomycin adenylyltransferase as well as the resistances to ampicillin and streptomycin were proportional to the gene dosage up to at least a threefold increase in the steady state plasmid copy number, whereas resistance to chloramphenicol showed no increase with increased number of plasmid copies per chromosome equivalent. Also the resistance to rifampicin was affected since S. typhimurium cells became more sensitive the higher the copy number of the resident plasmid. Furthermore, plasmid R1 showed molecular instability in S. typhimurium cells since there was a tendency to dissociate into resistance transfer factors and resistance determinants and also to form miniplasmids. This tendency to instability was more pronounced the higher the plasmid copy number.     

Isolation of an IS1 flanked kanamycin resistance transposon from R1drd19

Summary We have isolated and identified an IS1-flanked transposon from the plasmid R1drd19. This transposon specifies resistance to kanamycin and is 10.4 kb long. It exhibits a frequency of transposition two orders of magnitude lower than that of the smaller, IS1-flanked transposon Tn9. We have named it Tn2350.     

Mutation and identification of the F plasmid locus determining resistance to acridine orange curing

A region in plasmid F responsible for resistance to acridine orange curing has been identified. Insertion of the transposable element for ampicillin resistance Tn3 at the 45.8- or 46.35-kilobase coordinate in mini-F plasmids results in resistance to curing by acridine orange and also results in increased plasmid copy numbers. In contrast, copy number mutants of mini-F induced by chemical mutagenesis are sensitive to acridine-induced loss of plasmid. Hence, the Tn3-induced acridine orange resistance does not represent a suppression of sensitivity because of elevated plasmid copy numbers. General hypotheses to explain our results are presented.     

Translocation of sequences encoding antibiotic resistance from the chromosome to a receptor plasmid in Salmonella ordonez

Summary Salmonella ordonez strain BM2000 carries kanamycin (Km), ampicillin (Ap), spectinomycin (Sp), chloramphenicol (Cm), tetracyline (Tc), and sulfonamide (Su) resistance and production of colicin Ib (Cib). The Km and Cib characters were carried by a 97kb IncI1 plasmid (pIP565). In addition to the Km and Cib traits, all or part of the other antibiotic resistance (R) determinants could be transferred by conjugation from S. ordonez to Escherichia coli where all the acquired characters are borne by an IncI1 plasmid, designated complete or partial composite plasmid respectively. DNA from pIP565 and composite plasmids and total DNA from strain BM2000 were studied by agarose and polyacrylamide gel electrophoresis following digestion with restriction endonucleases, and by Southern hybridization. These comparative analyses enabled us a) to show that acquisition by pIP565 of resistance to all or some of the antibiotics was due to the insertion of a single DNA fragment into the receptor plasmid; b) to detect two types of composite plasmids with regard to the specificity of insertion into pIP565 and the mapping of the inserts; c) to demonstrate that the ApCmSpSuTc resistance determinants were integrated into S. ordonez BM2000 chromosomal DNA; d) to map the restriction fragments of the translocatable sequence integrated into strain BM2000 chromosome or into pIP565.The results obtained suggest that two distinct mechanisms for the translocation of the R determinants coexist in S. ordonez BM2000. Recombination between two of the four directly repeated copies of the IS-like sequence (IS1522) present in S. ordonez chromosome leads to the circularisation of all or part of the AmCmSpSuTc R determinants and is followed by either 1) a second recombination with the copy of IS1522 in pIP565 (Type I composite plasmids), or 2) transposition of precise groups of characters in various sites of pIP565 (Type II composite plasmids).     

Transposition of a plasmid deoxyribonucleic acid sequence that mediates ampicillin resistance: identity of laboratory-constructed plasmids and clinical isolates.

The structural gene for ampicillin resistance resides upon a 3.2 X 10(6)-dalton sequence of deoxyribonucleic acid, TnA that can be transposed from replicon to replicon in laboratory experiments. TnA was transposed from a large conjugative plasmid to a small nonconjugative plasmid, RSF1010. Several RSF1010::TnA plasmids isolated in these laboratory experiments have been shown to be identical to plasmids found in clinical isolates. These data provide direct support to the theory that transposition of drug resistance genes play a key role in the evolution of R plasmids.     

Molecular nature of two beta-lactamase-specifying plasmids isolated from Haemophilus influenzae type b.

The molecular nature of two beta-lactamase-specifying plasmids isolated from two separate ampicillin-resistant Haemophilus influenzae type b strains was examined. A 30 X 10(6)-dalton (30-Mdal) plasmid (RSF007) had a copy number of approximately 3 per chromosomal equivalent and a mole fraction guanine plus cytosine content of 0.39. By heteroduplex analysis the 30-Mdal plasmid was found to contain the entire ampicillin translocation DNA segment (TnA) found on R factors of enteric origin. A 3.0-Mdal plasmid (RSF0885) was found as a multicopy pool of approximately 28 copies per chromosomal equivalent, had a mole fraction guanine plus cytosine content of 0.40, and contained only about one-third of the transposable TnA sequence. RSF007 and RSF0885 appeared to be unrelated plasmids in that they share base sequence homology only within the confines of the TnA segment. The 3.0-Mdal Haemophilus plasmid was used to transform E. coli to ampicillin resistance but was found to be unstable in this host in the absence of antibiotic. The possibility that R-plasmids arose in Haemophilus by the translocation of TnA from a donor R-factor onto an indigenous H. influenzae plasmid is discussed.     

Map of plasmid RP4 derived by insertion of transposon C.

We have determined the location of 36 sites on plasmid RP4 into which transposon C (an 8.5 × 10⁶ molecular weight DNA sequence conferring trimethoprim and streptomycin resistance) had spontaneously inserted itself. These were located by sucrose gradient analysis of EcoRI-generated and then, separately, the HindIII-generated DNA fragments from each RP4-TnC² plasmid. RP4 has a single EcoRI-susceptible site and, suitably displaced from this, a HindIII-susceptible site, whereas TnC has, respectively, one and two sites for these two enzymes. Thus the sizes of the restriction fragments depend on the location and orientation of the inserted TnC.Some of the RP4-TnC clones had lost one of the RP4 characters: transferability (Tra), tetracycline (Tc) or kanamycin (Km) resistances, but no ampicillin (Ap) sensitive clones were detected. Insertions giving each of these phenotypic changes cluster together at positions on the circular RP4 map that presumably locate the genes responsible for the Tra⁺, Km^r and Tc^r phenotypes. The Tra^? plasmids were grouped into four classes on the basis of their conferred phage sensitivities and plasmid copy numbers. The gene giving Ap^r was located by its known proximity to a BamHI-susceptible site. All the plasmids analysed had TnC inserted with one particular orientation. TnC insertions giving no detectable phenotypic change were not randomly placed around RP4, but clustered into certain regions. Two large regions, one containing TnA, had no TnC insertions. Ligation experiments with restriction fragments from various RP4-TnC plasmids led to the conclusion that both these regions contain genes essential to the replication and maintenance of RP4. The location of the HindIII site of RP4 within the gene giving Km^r should prove valuable to the use of this plasmid as a cloning vehicle.     

Electron microscopic analysis of two nonconjugative derivatives of plasmid R1drd-19Km− fromEscherichia coli

The plasmids pON5300 and pON5304, nonconjugative variants of the plasmid R1drd-19Km, were analyzed by electron microscopy. It was found by heteroduplex mapping that a 1.4 kb DNA segment was inserted intoEcoRI E fragment of both plasmids, where sometra-genes andoriT are localized. Although this DNA segment was mapped to the same region its orientation was different in each of the two plasmids. The inserted DNA segment was identified as an IS10R sequence on the basis of analysis of self-annealed molecules of pON5304 and their cleavage withEcoRV restriction enzyme. These methods enable us not only to map IS10R sequences on 87 kb pON5300 and 65 kb pON5304 molecules, respectively, but also to define their orientation.