Persistence of pBR322-related plasmids in Escherichia coli grown in chemostat cultures

Abstract The stability of plasmid pBR322 and a number of close derivatives was examined by continuous culture of Escherichia coli . Cultures were subjected to either glucose, phosphate or magnesium limitation in non-selective medium at a dilution rate of 0.1/h. Under these conditions pBR322 was eventually lost from the population, but only after a distinct lag period. The closely related plasmids pBR325 and especially pBR327 and pBR328, but not pAT153, were lost more rapidly. Three cosmids pHC79, pSJ55 and pJB8 were generally found to be less stable than the pBR322-type plasmids from which they were derived. Chimaeric plasmids containing DNA from yeast and from a thermophilic bacillus were also unstable in E. coli .     

Rifampicin-induced replication of the plasmid pBR322 in Escherichia coli strains carrying dnaA mutations

The replication pattern of the plasmid pBR322 was examined in the dnaA mutants of Escherichia coli. The rate of pBR322 DNA synthesis is markedly decreased after dnaA cells are shifted to the restrictive temperature of 42 degrees C. However, addition of rifampicin (RIF) to cultures of dnaA strains incubated at 42 degrees C after a lag of 90 min results in a burst of pBR322 synthesis. This RIF-induced pBR322 replication remains dependent on DNA polymerase I activity. Efficient plasmid pBR322 replication is observed at 42 degrees C in the double mutant dnaA46cos bearing an intragenic suppressor of dnaA46. Though replication of pBR322 in dnaA46cos growing at 42 degrees C is initially sensitive to RIF plasmid synthesis is restored after 90 min incubation in the presence of the drug. RIF-induced replication of the plasmid pBR327, lacking the rriB site implicated in RIF-resistant synthesis of the L strand of ColE1-like plasmids (Nomura and Ray 1981; Zipursky and Marians 1981), was observed also in dnaA46 at 42 degrees C.     

Efficient transformation of Serratia marcescens with pBR322 plasmid DNA

Eight Serratia marcescens strains tested could be transformed with the plasmid pBR322. Transformants were selected on the basis of resistance to high levels of ampicillin (400 to 500 micrograms/ml). For six of the strains, the CaCl2- mediated transformation procedure developed for Escherichia coli was successful. For the other two strains, no transformants were obtained with the CaCl2-mediated transformation procedure unless the cells first received a heat treatment. Transformation frequency was dependent on DNA concentration, and no transformation was detected with linear pBR322 DNA. The stability and copy number of pBR322 were similar in S. marcescens and E. coli. As in E. coli, the pBR322 DNA was amplified in S. marcescens after inhibition of proteins synthesis. Based on these results, cloning in S. marcescens should be possible and pBR322 should be a useful cloning vehicle.     

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.     

Construction and characterization of new cloning vehicles. IV. Deletion derivatives of pBR322 and pBR325

In vitro recombinant DNA experiments involving restriction endonuclease fragments derived from the plasmids pBR322 and pBR325 resulted in the construction of two new cloning vehicles. One of these plasmids, designated pBR327, was obtained after an EcoRII partial digestion of pBR322. The plasmid pBR327 confers resistance to tetracycline and ampicillin, contains 3273 base pairs (bp) and therefore is 1089 bp smaller than pBR322. The other newly constructed vector, which has been designated pBR328, confers resistance to chloramphenicol as well as the two former antibiotics. This plasmid contains unique HindIII, BamHI and SalI sites in the tetracycline resistance gene, unique PvuI and PstI sites in the ampicillin resistance gene and unique EcoRI, PvuII and BalI sites in the chloramphenicol resistance gene. The pBR328 plasmid contains approx. 4900 bp.     

Maintenance of plasmids pBR322 and pUC8 in nonculturable Escherichia coli in the marine environment.

Maintenance of plasmids pBR322 and pUC8 in Escherichia coli that was nonculturable after exposure to seawater was studied. E. coli JM83 and JM101, which contained plasmids pBR322 and pUC8, respectively, were placed in sterile artificial seawater for 21 days. Culturability was determined by plating on both nonselective and selective agar, and plasmid maintenance was monitored by direct isolation of plasmid nucleic acid from bacteria collected on Sterivex filters. E. coli JM83 became nonculturable after incubation for 6 days in seawater yet maintained plasmid pBR322 for the entire period of the study, i.e., 21 days. E. coli JM101 was nonculturable after incubation in seawater for 21 days and also maintained plasmid pUC8 throughout the duration of the microcosm experiment. Direct counts of bacterial cells did not change significantly during exposure to seawater, even though plate counts yielded no viable (i.e., platable) cells. We concluded that E. coli cells are capable of maintaining high-copy-number plasmids, even when no longer culturable, after exposure to the estuarine or marine environment.     

Maintenance of plasmids pBR322 and pUC8 in nonculturable Escherichia coli in the marine environment

Maintenance of plasmids pBR322 and pUC8 in Escherichia coli that was nonculturable after exposure to seawater was studied. E. coli JM83 and JM101, which contained plasmids pBR322 and pUC8, respectively, were placed in sterile artificial seawater for 21 days. Culturability was determined by plating on both nonselective and selective agar, and plasmid maintenance was monitored by direct isolation of plasmid nucleic acid from bacteria collected on Sterivex filters. E. coli JM83 became nonculturable after incubation for 6 days in seawater yet maintained plasmid pBR322 for the entire period of the study, i.e., 21 days. E. coli JM101 was nonculturable after incubation in seawater for 21 days and also maintained plasmid pUC8 throughout the duration of the microcosm experiment. Direct counts of bacterial cells did not change significantly during exposure to seawater, even though plate counts yielded no viable (i.e., platable) cells. We concluded that E. coli cells are capable of maintaining high-copy-number plasmids, even when no longer culturable, after exposure to the estuarine or marine environment.     

Escherichia coli relA strains as hosts for amplification of pBR322 plasmid DNA

Abstract We have proposed that guanosine tetraphosphate produced in Escherichia coli cells subjected to an isoleucine limitation inhibits pBR322 DNA replication [1]. In E. coli relA which cannot synthesize guanosine tetraphosphate (ppGpp) upon amino acid limitation pBR322 DNA is amplified after arginine starvation. The yield of plasmid DNA amplified either by chloramphenicol (Cm) or by arginine limitation is compared. The plasmid yield per cell is equal in amino acid-starved cells and in cells treated with Cm. To increase the plasmid content per ml of cell suspension the growth medium was supplemented with increasing amounts of nutrients. Plasmid DNA can be isolated in large quantities by this procedure. This simple method can be used for the enrichment of pBR325 DNA which cannot be amplified by Cm treatment. Our results indicate that E. coli relA strains might be suitable hosts for the amplification of pBR322 and related plasmids in E. coli .     

Increased stability of pBR322-related plasmids in Escherichia coli W3101 grown in carrageenan gel beads

Abstract The stability and the copy number of pBR322, pBR325 and pBR328 were studied during continous cultures of free and immobilized E. coli W3101 without selective pressure. In the free-cell system, it was found that pBR328 and pBR325-free E. coli cells appeared after a lag period. They rapidly overgrew the cultures and the plasmid copy number subsequently declined. On the other hand, an increase in the proportion of pBR322- carrying cells during a free continuous culture was observed. This increase correlated with that of plasmid copy number. By contrast, in the immobilized- cell system, plasmid free segregants were not detected in all the cases even after 250 generations. We have also shown that plasmid copy number remained constant and phenomena such as fluctuations or genetic modifications which occured after long term growth of bacteria in a free continuous culture could be avoided throughout cell immobilization.     

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.     

Stability of ColE1-like and pBR322-like plasmids in Escherichia coli

The average copy number, the level of ampicillin resistance conferred by one plasmid, and the degree of plasmid multimerization were determined for several ColE1-like and pBR322-like plasmids. From the results obtained, the variance of the units of partition corresponding to each plasmid studied was calculated. Experimentally determined plasmid stability was compared with that calculated using the variance of the units of partition and the ratio between the generation times of plasmid-free and of plasmid-carrying cells, assuming that the units of partition are distributed randomly between daughter cells. Stability of the pBR322-like plasmids present mainly as monomers in the bacterial host was consistent with random partitioning, whereas pBR322-like plasmids, present mainly as dimers, and the ColE1-like plasmid showed greater stability than that predicted with random partitioning at cell division.     

Analysis of pBR322 replication kinetics and its dependency on growth rate

Accurate estimates of plasmid copy number in a cell are a prerequisite for predicting plasmid stability and protein production. A refined version of a structured model for the pBR322 plasmid replication mechanism is described. The model is capable of accurately predicting pBR322 plasmid copy number in Escherichia coli B/r for a wide range of growth rates. The refinements include better estimates of promoter strength, the degradation rate of RNA species, binding constant of RNAI-RNAII reaction, and dependency of promoter strength on growth rate. The predictions of the model are verified by recent experimental observations but differ from some previous reports. This model can also be used to predict the binding constant of the RNAI-RNAII reaction of ColE1 type plasmids. At 37 degrees C, the binding constant is estimated to be 77 +/- 11 x 10(-13) mL/molecule-h for pBR322.     

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.     

Maintenance and genetic stability of vector plasmids pBR322 and pBR325 in Escherichia coli K12 strains grown in a chemostat

Summary The maintenance and genetic stability of the vector plasmids pBR322 and pBR325 in two genetically different Escherichia coli hosts were studied during chemostat cultivation with glucose and ammonium chloride limitation and at two different dilution rates. The plasmid pBR322 was stably maintained under all growth conditions tested. However pBR325 segregated from both hosts preferentially during glucose limitation and at low dilution rate. In addition to this general segregation process a separate loss of tetracycline resistance was observed. The remaining plasmid conferred resistance to ampicillin and chloramphenicol only, without any remarkable alteration of its molecular weight.Cultivation conditions in the chemostat were found that allowed the stable genetic inheritance of both plasmids in the hosts studied.     

Supercondensed structure of plasmid pBR322 DNA in an Escherichia coli DNA topoisomerase II mutant

An unusual structural component, supercondensed pBR322 DNA, has been found in plasmid pBR322 DNA samples isolated from a DNA topoisomerase II mutant of Escherichia coli, SD108 (topA+, gyrB225). The supercondensed pBR322 DNA moved faster than supercoiled pBR322 DNA as a homogeneous band in agrose gels when the DNA samples were analysed by electrophoresis. The mobility of the supercondensed DNA was not substantially affected by chloroquine intercalation. The supercondensed pBR322 DNA migrated as a high density "third DNA band" when the samples were subjected to caesium chloride/ethidium bromide gradient equilibrium centrifugation. The unusual pBR322 DNA visualized by electron microscopy was a globoid-shaped particle. These observations suggest that the pBR322 plasmid can assume a tertiary structure other than a supercoiled or relaxed structure. DNA topoisomerases may be involved in the supercondensation of plasmid DNA and chromosomal DNA.     

The effect of the oligomerization of pBR322 on the level of transformation in Escherichia coli

The ability of the known Escherichia coli strain JC3881 recB recC recF sbc15 to produce oligomeric and multimeric forms of pBR322 underlies the study presented. The individual oligomeric forms of pBR322 were isolated from the agarose gel. The plasmid forms were used for electron microscopic control and also introduced into the system of E. coli competent cells. The E. coli transformation level of different forms of plasmid DNA rose from monomers to pentamers. CCC forms of the plasmid possessed high efficiency of the E. coli cell transformation. The systems of the host recombination are to be significant in the process of plasmid oligomerization.     

Antagonism of the B subunit of DNA gyrase eliminates plasmids pBR322 and pMG110 from Escherichia coli.

The constructed plasmid pBR322 and the native plasmid pMG110 were eliminated (cured) from growing Escherichia coli cells by the antagonism of the B subunit of the bacterial enzyme DNA gyrase. The antagonism may be by the growth of cells (i) at semipermissive temperatures in a bacterial mutant containing a thermolabile gyrase B subunit or (ii) at semipermissive concentrations of coumermycin A1, an antibiotic that specifically inhibits the B subunit of DNA gyrase. The kinetics of plasmid elimination indicate that plasmid loss occurs too rapidly to be explained solely by the faster growth of that plasmid-free bacteria and, therefore, represents interference with plasmid maintenance.     

Formation of plasmid pBR322 oligomers as depending on a tetracycline concentration

Escherichia coli K12 strains containing the plasmid pBR322 often show varying contents of plasmid oligomers, in which the monomer units are arranged in tandem. When the concentration of the plasmid-selective antibiotic tetracycline in the medium becomes increased selection of cells containing largely higher oligomers occurs. The number of monomer units organized in the oligomers increases with tetracycline concentration. recA- mutants are unable to generate oligomers under the same conditions and show lower tetracycline resistance. This observations suggest a selective advantage of oligomer containing cells in the presence of tetracycline as a result of higher gene dosage. But E. coli cells transformed with monomers, dimers, trimers, as well as tetramers of pBR322 are characterized by roughly the same plasmid DNA content as well as plasmid coded beta-lactamase and resistance to tetracycline.