R plasmid gene dosage effects in Escherichia coli K-12: copy mutants of the R plasmic R1drd-19.

Copy mutants of the R plasmid R1drd-19 were used to study gene dosage effects in Escherichia coli K-12. The specific activity of β-lactamase, chloramphenicol acetyltransferase, and streptomycin adenylylase, as well as ampicillin resistance, increased linearly with the gene dosage up to a level at least tenfold higher than that of the wild-type plasmid. This makes it possible to use ampicillin resistance to determine plasmid copy number and also to select for plasmid copy mutants with defined copy number. Chloramphenicol resistance, despite the increase in enzyme activity, reached a plateau level at a gene dosage less than twice that of the wild-type plasmid, presumably due to the high energy demand on the cells during inactivation of the antibiotic by acetylation with acetyl-coenzyme A. Similarly, resistance to streptomycin plateaued at a gene dosage about three times that of the wild-type plasmid, presumably because of a decreased efficiency of the cells' outer penetration barriers when carrying the R plasmid. The susceptibility of the cells to rifampicin was increased by the presence of plasmid copy mutants.     

RecP, a new minor pathway of general recombination in Escherichia coli encoded by plasmid R1drd-19.

Plasmid R1drd-19 markedly improves the recombination deficiency of recB and recBrecC mutants of Escherichia coli K12 as measured by Hfr crosses and increases their resistance to uv inactivation. The effect correlates with the production of an ATP-dependent ds DNA exonuclease in recB/R1drd-19 cells. This paper further investigates the suppressive effect of plasmid R1drd-19 on the recB mutation of E. coli. The gene(s) responsible for the effect was localized to the 13.1-kb EcoRI-C fragment of the resistance transfer factor (RTF) portion of R1drd-19. The plasmid-encoded activity does not merely replace the RecBCD enzyme failure but differs in several significant ways. It promotes a hyper-recombinogenic phenotype, as judged by the phenomenon of super oligomerization of the tester pACYC184 plasmid in recB/R1drd-19 cells and two inter- and intramolecular plasmid recombination test systems. It is probably not inhibited by lambda Gam protein and does not restrict plating of T4gp2 mutant. No significant homology between the E. coli chromosomal fragment carrying recBrecCrecD genes and the EcoRI-C fragment of R1drd-19 was observed. It is suggested that the plasmid-encoded recombination activity is involved in a new minor recombination pathway (designated RecP, for Plasmid). RecP resembles in some traits the RecBCD-independent pathways RecE and RecF but differs in activity and perhaps substrate specificity from the main RecBCD pathway.     

Colloidal clay inhibits conjugal transfer of R-plasmid R1drd-19 in Escherichia coli.

Colloidal clay (montmorillonite) strongly inhibited the conjugal transfer of R-plasmid R1drd-19 in Escherichia coli. This finding is discussed in the context of the feasibility of plasmid transfer in environmental waters.     

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.     

Identification of the plasmid R1drd-19 region complementing the mutant phenotype recB- in Escherichia coli K12 strain

Plasmid R1-19 and its copy number mutants markedly increase the recombinational efficiency of a recB- strain of E. coli K12 and its resistance to the lethal action of UV and mitomycin C. These effects are associated with the appearance of a new ATP-dependent exonuclease activity in recB- cells known to be deficient in the ATP-dependent exonuclease V. Using hybrid plasmids carrying different EcoRI fragments of R1-19 (in the pSF124 vector), the gene(s) responsible for effect of R1-19 in recB-cells were localized in the EcoRI-C fragment (8.5 MD) belonging to the RTF portion of R1-19. Expression of the gene(s) in hybrid plasmids depends on the orientation of EcoRI-C fragment in the vector. The copy number of the EcoRI-C fragment was not strictly correlated with the degree of expression of the effects in the recB- mutant.     

Plasmid R1drd-19-mediated superoligomerization of the plasmid pACYC184in the recB mutant of Escherichia coli K12

It was found that monomers of the pACYC184 plasmid undergo superoligomerization in a recB mutant of Escherichia coli K12 which is deficient in ATP-dependent RecBC nuclease and carries the drug resistance plasmid R1drd-19. The observed effect is specifically related to the ability of R1drd-19 to determine an ATP-dependent exonucleolytic activity which is functionally similar but not identical to the RecBC nuclease. The oligomerization of pACYC184 is accompanied by the formation of high-order circular structures, and this leads to elimination of the plasmid from cells growing under non-selective conditions.     

Isolation and characterization of Escherichia coli chromosomal mutants affecting plasmid copy number.

We have isolated chromosomal mutants of an Escherchia coli K-12 strain that maintain higher levels of an F' plasmid. The mutants are designated as plasmid copy number (pcn) mutants. They were detected by selecting for increased lactose fermentation in bacteria deleted for the lac operon but harboring an F'lacI,P pro+ plasmid. When examined for the amount of F' plasmid deoxyribonucleic acid (DNA) by the dye-CsCl isopycnic technique, the mutants show two to seven times as much covalently closed, circular (CCC) DNA as does the parental strain. The increased plasmid level in one mutant strain (pcn-24) was confirmed by DNA-DNA hybridization; however, this latter technique indicated about a twofold lower increase when compared with the increase measured for pcn-24 by the dye-CsCl technique. In mutant pcn-24 the increased amount of F' DNA reflects a proportional increase in monomeric-size plasmid molecules because oligomeric forms are not found. Also, in mutant pcn-24 the extra CCC plasmid copies do not seem to be randomly distributed throughout the cell's cytoplasm but appear complexed in situ with their host's folded chromosome. In all pcn mutants examined to date, the classical sex factor F is maintained at normal levels, whereas the viral plasmid Pl CM is maintained at two to three times the normal level. In all 17 pcn mutants isolated, the pcn mutation maps on the chromosome and not on the plasmid. Finally, the absolute amount of CCC F' DNA detectable in lysates of the six different pcn mutants examined decreased 50 to 90% upon incubation of the lysate at 37 C. In contrast, no loss of CCC DNA occurs when lysates of the parental F' strain are incubated at 37 C.     

A comparative study of the functions of recBCD-nuclease from Escherichia coli and "recombinase", encoded by plasmid R1drd-19]

The RecBCD nuclease of Escherichia coli and "recombinase" determined by R1drd-19 plasmid (the latter is able to replace at least partially the indicated cellular enzyme) were shown to differ from each other in some essential features. The product encoded by the plasmid as distinct from RecBCD nuclease practically is not sensitive to inhibition by GamS protein of the lambda phage. Earlier, it was found that the presence of R1drd-19 plasmid in the recBC cells restores the level of the total ATP-dependent exonuclease activity because of appearance in such cells of a new exonuclease activity also ATP-dependent. The exonuclease activity determined by R1drd-19 plasmid was found to differ from the corresponding activity of the RecBCD enzyme. The plasmid enzyme was able to prevent reproduction of T4g2- mutant on recBC cells. The ability of the plasmid "recombinase" to some stimulation of intrachromosomal recombination in recA mutant witness to incomplete RecA-dependence of its function. No significant homology was registered between Escherichia coli DNA fragment containing the recB, recC, recD genes and the EcoRI-C-fragment of R1drd-19 carrying the sequences responsible for recombination and repair functions of the plasmid.     

Intra- and intermolecular recombination of test plasmids in K12 Escherichia coli cells carrying an RTF derivative of the R1drd-19 plasmid

The RTF derivative of the plasmid R1drd-19 was found to stimulate recombination of the tester plasmids in a recB mutant of Escherichia coli K12. The frequency of intramolecular recombination is increased 3.5 and 20-fold, as compared to the one in rec+ and rec- strains, respectively. The frequency of interplasmid recombination is enhanced 4 and 9-fold, respectively. Considerable heterogeneity of the recombination products of the tester plasmid intramolecular recombination in recB-/RTFR1-19 strain has been revealed. It is hypothesized that a "recombinase" encoded by Rldrd-19 plasmid determines a new minor pathway in recB- (Rec P) which differs in activity and, perhaps substrate specificity from the main Rec BCD pathway.     

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.     

Inhibition of cell division in Escherichia coli K-12 by the R-factor R1 and copy mutants of R1.

The effect of the copy number of plasmid R1drd-19 on cell division of Escherichia coli K-12 was studied in populations growing as steady-state cultures at different growth rates, the growth rate being varied by use of different carbon sources. The plasmid copy number was also varied by using copy mutants of the R-factor. The mean cell size was larger in populations carrying an R-factor than in R-factorless populations, an effect that was more pronounced at low growth rates and in populations carrying R-factor copy mutants. The increased cell size was due to formation of elongated cells in a fraction of the population and to an increase in the diameter of all cells. The majority of the cells divided at a normal cell length, but the presence of an R-factor caused some cells to elongate, probably by the uncoupling of chromosome replication and cell division. This can be explained as a competition between the chromosome and plasmid replicons for some replication factor(s), presumably acting on both initiation and elongation of replication. The formation of elongated cells was a reversible process, but occasionally some of the elongated cells reached lengths 20 times that of newborn cells. If cell division did not occur at the normal cell size, the septum was not formed until the cell size was four times that of a newborn cell. When an elongated cell divided, it usually formed a polar septum, thus producing a newborn cell of normal cell length. The ability of plasmid-containing cells to omit one cell division but to retain the capacity of dividing one mass doubling later is compatible with a mechanical model for septum formation and cell division.     

Clustering of genes involved in replication, copy number control, incompatibility, and stable maintenance of the resistance plasmid R1drd-19.

Plasmid R1drd-19 is present in a small number of copies per cell of Escherichia coli. The plasmid was reduced in size by in vivo as well as in vitro (cloning) techniques, resulting in a series of plasmid derivatives of different molecular weight. All plasmids isolated contain a small region (about 2 x 10(6) daltons of deoxyribonucleic acid) of the resistance transfer factor part of the plasmid located close to one of the IS1 sequences that separates the resistance transfer factor part from the resistance determinant. All these derivatives were present at the same copy number, retained the incompatibility properties of plasmid R1drd-19, and were stably maintained during cell division. Genes mutated to yield copy mutations also were found to be located in the same region.     

Isolation and characterization of Escherichia coli dnaA amber mutants.

Specialized transducing phage lambda (formula, see text) dnaA-2 was mutagenized, and two derivatives designated lambda (formula) dnaA17(Am) and lambda (formula) dnaA452(Am) were obtained. They did not transduce such mutations as dnaA46, dnaA167, and dnaA5 when an amber suppressor was absent, but they did so in the presence of an amber suppressor. By contrast, they transduced the dna-806 and tna-2 mutations in the absence of an active amber suppressor. The dna-806 and tna-2 mutations are known to be located very close to the dnaA gene, but in separate cistrons. When ultraviolet light-irradiated uvrB cells were infected with the derivative phages and proteins specified by them were analyzed by gel electrophoresis, a 50,000-dalton protein was found to be specifically missing if an amber suppressor was absent. This protein was synthesized when an amber suppressor was present. The dnaA17(Am) mutation on the transducing phage genome was then transferred by genetic recombination onto the chromosome of an Escherichia coli strain carrying a temperature-sensitive amber suppressor supF6(Ts), yielding a strain which was temperature sensitive for growth and deoxyribonucleic acid replication. The temperature-sensitive trait was suppressed by supD, supE, or supF. We conclude that, most likely, the derivative phages acquired amber mutations in the dnaA gene whose product is a 50,000-dalton protein as identified by gel electrophoretic analysis.     

Conjugal Transfer of R-Plasmid R1drd-19 in Escherichia coli Below 22°C

The conjugal transfer of R-plasmids is known to occur at temperatures above 22°C. We found that R1drd-19 is transferable below 22°C, and we discuss this finding in the context of plasmid transfer in environmental waters.     

dnaB analog function associated with plasmid R100drd-1.

Plasmid R100 and a number of its derivatives were able to suppress the temperature sensitivity of strains carrying different alleles of the dnaB gene of Escherichia coli K-12. R100drd-l and pAR132 were able to rescue a strain carrying the dnaB266(Am) mutation in the absence of any known amber suppressors. This was taken as evidence for the existence of an R100drd-l dnaB analog function. The R100drd-l dnaB analog was different from those of bacteriophages P1 and P7 in that it was able to support the growth of bacteriophage lambda in a dnaB266(Am) background. The dnaB analog was also shown to be thermosensitive. The structural gene for this protein lies within the EcoRI fragment D of R100drd-l.     

Generation of miniplasmids from copy number mutants of the R plasmid NR1.

Small, closed circular deoxyribonucleic acid molecules, called miniplasmids, were observed in Escherichia coli harboring copy number mutants of the R plasmid NR1 after growth in medium containing tetracycline. The level of tetracycline resistance conferred by the copy mutant plasmids was lower (3 to 6 microgram/ml) than that conferred by NR1 (100 MICROGRAM/ML). The presence of the miniplasmid enhanced the level of tetracycline resistance conferred by the copy mutant. Miniplasmids of molecular weights 4 X 10(6) to 13 X 10(6) were found. They carried no antibiotic resistance markers and could be eliminated by growth in the presence of chloramphenicol and/or streptomycin-spectinomycin. Studies with the restriction endonucleases EcoRI and Sal I indicated that the miniplasmids are derived from the region of the copy mutant plasmids that contains the origin for replication of the resistance transfer factor. There were approximately 12 copies of the miniplasmid per chromosome, compared with 3 and 6 copies of the copy mutants of NR1. The miniplasmids appeared to be incompatible with the copy mutant plasmids.     

Replication of plasmid R6K in DNA polymerase deficient mutants of Escherichia coli.

The plasmid R6K has been introduced into a number of Escherichia coli polymerase deficient (pol) mutants. In polCts mutants transferred to the nonpermissive temperature to inactivate polymerase III, R6K replicates but the replication products have a density in dye-CsCl gradients intermediate between supercoiled and linear forms. This aberrant replication requires normal cellular levels of polymerase I since it does not occur in polA polCts mutants. Normal R6K replication and maintenance occur in a polA polB polC+ host, however, we cannot tell from our experiments wheather polymerase I or III replicates R6K in polA+ polC+ host. Polymerase II, the polB gene product, has no detectable role in R6K replication.     

The nucleotide sequence of the replication control region of the resistance plasmid R1drd-19

Summary The region of plasmid R1 containing the replication control genes has been sequenced using the Maxam-Gilbert method. The nucleotide sequence of two small PstI restriction fragments (a total of about 1,000 base pairs) was determined for the wildtype R1 plasmid as well as for two different copy mutants. It was found that one copy mutant has a single base substitution in the fragment which was recently shown to harbor an important inc/cop gene (Molin and Nordström 1980). Furthermore, the sequence indicates the presence of a structural gene that codes for a polypeptide of size 10,500 daltons. Possible gene products predicted from the nucleotide sequences and their role in replication control are discussed.     

Ribosomal assembly defectivity in a set of amber mutants of Escherichia coli.

Five amber mutations affecting essential genes of $\text{Escherichia coli}$ have been isolated. The procedure relies on P1-mediated localized mutagenesis(1) and on the use of a recipient strain carrying a strong but instable suppressor gene and a particular thermoinducible λ prophage which kills suppressor hosts at 42°C (2). All five mutations map close to the $\text{spcA}$ gene, in a region which codes essentially for ribosomal proteins. Strains harboring the mutations were studied biochemically; all five exhibit defective ribosomal assembly upon loss of suppression.