Plasmid replication and Hfr formation in strains of Escherichia coli carrying seg mutations.

Summary Several conditional-lethal mutations that do not permit the replication of F-factors ofEscherichia coli K-12 are located at a site calledseg. This gene is located on theE. coli chromosome betweenserB andthr. It is unrelated to other known genes involved in DNA replication. Strains carryingseg mutations were unable to replicate F-lac⁺, several F-gal⁺s, F-his⁺ and bacteriophage at 42°. However, neither phage T4, ColE1, nor any of the R factors tested were prevented from replicating at 42°C.When the kinetics of the loss of F-primes is studied inseg strains, it is found that the rate of curing depends on the size of the plasmid, larger F factors curing faster than smaller ones, and that Hfrs are formed at high frequencies. The Hfrs showed both F-genote enlargement and normal transfer of chromosomal markers. The F-genotes are unstable and segregate chromosomal markers at high frequencies. Some orthodox Hfrs were examined, and two that were known to revert to the F⁺ condition relatively frequently were found to generate enlarged F-genotes on mating, whereas two strains that were very stable with respect to reversion to the F⁺ state did not show F-genote formation.F-genote formation fromseg Hfr strains is dependent of a functionalrecA gene, as F-genote formation was not seen with aseg-2, recA-1 Hfr. This is in contrast to F-genote enlargement shown by both orthodox Hfrs and an Hfr strain constructed by integration of a temperature-sensitive F-gal⁺, whose F-genote enlargement is Rec-independent. Thus there may be more than one mechanism for the formation of enlarged F-genotes.     

Formation of type II F-primes from unstable Hfrs and their recA-independent conversion to other F-prime types

Summary Four E. coli Hfr strains, representing stable (Hfr Cavalli), moderately stable (AB312) and unstable (Ra-1, Ra-2) Hfr states, were used in the isolation of a series of F plasmids. Type II Fs were found to be the most prevalent F plasmid formed from all of the Hfrs, while the percentages of tra Fs increased as the stability of the Hfr increased. Two observations suggested that F formation in unstable Hfrs like Ra-2 may proceed through a type II F precursor. First, the major F products of Ra-2 are tra ⁺ type II Fs and, second, other F types (I, II) and classes (tra ⁺, tra) from Ra-2 appeared to be deletion derivatives of a larger F progenitor. By monitoring the molecular changes that occur when the Ra-2 derived type II F pWS200 is transferred from one recA host to another, we have found that all F types and classes can be generated from pWS200 in a recA-independent manner. F sequences involved in the genetic conversions of pWS200 include the oriT locus and the directly repeated junctions of F and chromosomal DNA. A model for the formation of Fs in unstable Hfrs is postulated in which a tra ⁺ type II F primary excision product is seen to be modified, through recA-independent processes, to other F types and classes. This model differs from the current model of F formation in that independent excision events from the Hfr chromosome are not seen as the source of type I and type II Fs.These studies have also shown that the formation of tra Fs is a recA-independent process that can occur from the F and Hfr states, that -mediated deletions in pWS200 often demonstrate regional specificity in having endpoints near the ilv operon and that genetic alterations in either replication origin of pWS200 (F oriV, chromosomal oriC) stabilize the replication of this mini-Hfr cointegrate.     

Replication of Fpoh+ plasmid in mafA mutants of Escherichia coli defective in plasmid maintenance

Summary A class of F plasmids, designated Fpoh ⁺, was previously shown to be able to replicate extrachromosomally on Hfr strains by virtue of carrying the specific site or region poh ⁺ (permissive on Hfr) of the E. coli chromosome (Hiraga, 1975, 1976a). These plasmids were now found to replicate on E. coli mafA mutants (mafA1 and mafA23) that cannot support vegetative replication of F and some other F-like plasmids. The derivatives of Fpoh ⁺ that have lost the poh ⁺ site, on the other hand, failed to replicate on mafA mutants. These mutants harboring Fpoh ⁺ (but not Poh^- derivatives thereof) exhibit abnormal cell division and form elongated cells, presumably due to competition between Fpoh ⁺ and the host chromosome for some factor(s) essential for the initiation of DNA replication of the both replicons. It is tentatively concluded that the poh ⁺ site is required for F plasmids to replicate on mafA mutants as well as on Hfr strains. In view of the fact that the mechanism of inhibition of autonomous F DNA replication in mafA mutants and in Hfr strains are clearly different, the present data seem to provide strong support to the notion that the poh ⁺ region contains the replication origin of the E. coli chromosome.     

Construction in Escherichia coli K12 of derivatives of sex factor F143 carrying lexB and recA mutations

Summary Various F sex factors have been derived from F143, an episome extending from lysA to pheA. F143 derivatives carrying recA and lexB alleles and also mutations in genes thyA, argA, cysC were constructed as follows. Recombination was used as a means to generate genetically labelled F-primes. Using trimethoprim as agent of counterselection of Thy⁺ cells in thyA ^–/F-thyA ⁺bacteria, it was possible to collect, after transfer, F-primes modified by deletion of the thyA region or recombination between chromosome and episome. F-primes which had spontaneously recombined with the chromosome and integrated chromosomal markers, were also selected by transfer to proper F^– recipients. P1 transduction of a dominant marker allele into a strain homodiploid for a recessive allele was used to construct F-primes carrying mutations introduced by cotransduction. These F-primes have been useful to establish the dominance and complementation pattern of recA and lexB mutations (Morand, Goze and Devoret, accompanying paper; Glickman, Guijt and Morand, accompanying paper).     

Early and late transfer of F genes by Hfr donors of E. coli K-12

Summary The results of short interrupted matings between an Hfr donor and a recipient strain carrying a temperature-sensitive replication mutant (frp ^–) of Flac demonstrate that the Hfr strain transfers this frp gene of F early in conjugation. This frp gene was also shown to function in the maintenance of mutant F plasmids which appear to be generated from the DNA transferred early in conjugation by Hfr donors. In the course of these experiments, it was further demonstrated that certain Hfr strains which had been described as transferring the tra genes early in fact transfer that region of F late in conjugation.     

Escherichia coli mutants temperature-sensitive for DNA synthesis

Summary A series of mutants of E. coli temperature-sensitive for DNA synthesis has been studied. The temperature-sensitive DNA mutations map in seven distinct genetic loci most of which have not been previously reported. Mutations in dnaA and in dnaC affect the initiation of DNA replication; those at the remaining loci affect chain elongation. A temperature-sensitive Flac is shown to suppress a group A mutant with somewhat less efficiency than other F factors previously reported by others. The gene products rendered temperaturesensitive by the mutations have not been identified for any of the loci.     

pac sites are indispensable for in vivo packaging of DNA by phage P22

Summary F pro ⁺ plasmids were selected and used as donors to prepare P22 transducing phages. Two types of result were observed. pro ⁺ from type I donors cannot be packaged by wild-type P22 to yield transducing particles unless a prophage pac site is introduced into the plasmid. Transposon Tn10 also allows initiation of packaging. pro ⁺ from type II plasmids can be transduced with the same efficiency as pro ⁺ DNA on the chromosome, indicating that a chromosomal pac site was included when the F pro ⁺ was excised from the Hfr strain. The usefulness of type I plasmids as a test substrate for pac signals is discussed.     

A nonsense mutation in bacteriophage P1 eliminates the synthesis of a protein required for normal plasmid maintenance

A mutant of bacteriophage P1 that is defective in plasmid maintenance was isolated. P1 seg-101 carries an amber mutation in a region previously implicated in the control of plasmid maintenance. By use of a host bearing a temperature-sensitive suppressor, the dependence of P1 maintenance on the seg-101⁺ protein product was established. The rates of segregation of cured cells under various conditions suggest a role for the seg-101⁺ product in the partition of plasmids to daughter cells rather than in the replication of the plasmid. This hypothesis is supported by the observation that P1 seg-101 can drive host chromosomal DNA replication when integrated into the chromosome of a dnaA host under conditions that are nonpermissive for both the seg-101 and dnaA alleles.     

Inactivation of a newly transferred gene in recombination-deficient recipients of Escherichia coli

Summary The expression of a newly transferred lacZ ⁺ gene in lacZ recipients carrying various mutations in the recA and recB genes was studied by measuring the rates of induced synthesis of -galactosidase in zygotes formed after mating with either F or Hfr donors. The ability to synthesize -galactosidase decreases with time in both recA and recB zygotes when the lacZ ⁺ gene is transferred from an Hfr donor, but not when the lacZ gene is transferred from an F donor. There is no such inactivation of the newly transferred lacZ ⁺ gene in Rec⁺ zygotes. We conclude that the functioning of the transferred DNA is progressively inactivated in rec recipients unless the DNA is contained in an episome such as F.     

IS21 insertion in the trfA replication control gene of chromosomally integrated plasmid RP1: a property of stable Pseudomonas aeruginosa Hfr strains

Summary Broad host range IncP-1 plasmids are able to integrate into the chromosome of gram-negative bacteria. Strains carrying an integrated plasmid can be obtained when the markers of a temperature-sensitive (ts) plasmid derivative are selected at non-permissive temperature; in this way Hfr (high frequency) donor strains can be formed. The integrated plasmids, however, tend to be unstable in the absence of continuous selective pressure. In order to obtain stable Hfr donor strains of Pseudomonas aeruginosa PAO, we constructed a derivative of an RP1 (ts) plasmid, pME134, which was defective in the resolvase gene (tnpR) of transposon Tn801. Chromosomal integration of pME134 was selected in a recombination-deficient (rec-102) PAO strain at 43°C. Plasmid integration occurred at different sites resulting in a useful set of Hfr strains that transferred chromosomal markers unidirectionally. The tnpR and rec-102 mutations prevented plasmid excision from the chromosome. In several (but not all) Hfr strains that grew well and retained the integrated plasmid at temperatures below 43°C, the insertion element IS21 of RP1 was found to be inserted into the trfA locus (specifying an essential trans-acting replication funtion) of the integrated plasmid. One such Hfr strain was rendered rec ⁺; from its chromosome the pME134::IS21 plasmid (=pME14) was excised and transferred by conjugation to Escherichia coli where pME14 could replicate autonomously only when a helper plasmid provided the trfA ⁺ function in trans. Thus, it appears that trfA inactivation favours the stability of chromosomally integrated RP1 in P. aeruginosa.     

Host controlled restriction and modification of bacteriophage Mu and Mu-promoted chromosome mobilization in Citrobacter freundii

Summary Bacteriophage Mu grown on Escherichia coli K12 (Mu. K) is restricted by wild type Citrobacter freundii. In two C. freundii mutants, where the restriction of foreign F factors is absent (de Graaff and Stouthamer, 1971), the restriction for Mu. K, although at a lower level, still exists. Consequently two host specificity systems exist in C. freundii, one affecting mainly the acceptance of foreign plasmidal and chromosomal DNA and one affecting foreign DNA of bacteriophage Mu. Mu is able to lysogenize C. freundii and to induce mutations at random in its chromosome. Furthermore Mu is able to promote the mobilization of the C. freundii chromosome in strains carrying F factors. Mu promoted integration of F ts 114 lac ⁺ into the C. freundii chromosome was observed, resulting in the formation of stable Hfr strains. In this way it is possible to devise a method for chromosome transfer in other genera than E. coli to which plasmids of E. coli can be transferred, but in which no chromosome mobilization is possible because of poor DNA homology between the foreign plasmid and the host chromosome.     

Expression of the tryptophan operon in merodiploids of Escherichia coli. I. Gene dosage, gene position and marker effects

Summary Under conditions of derepression,Escherichia coli K12 strains diploid for thetrp operon specify more than twice as much enzyme as a haploid. The disproportionate increase probably occurs because episomally carriedtrp genes tend to specify more enzyme than do chromosomal genes.Operons harboring the nonsense mutationtrpA2 or the missense mutationtrpBYS-101 specify less protein than do wild-type operons. This effect varies with operon location in the case oftrpBYS-101.In a homozygoustrp merodiploid A46/F A46 reversion totrp ⁺ occurs three times as frequently in episomal DNA as in chromosomal DNA. Thus, if the chromosome: Ftrp episome ratio inE. coli is one, as demonstrated by Helinski and co-workers, the rate of gene expression and the rate of mutation can vary and depends upon the location of the DNA within the cell.Supported by Grant AM-12150 from the National Institutes of Health. Journal Paper No. 3973 of Purdue Agricultural Experiment Station.     

High frequency mobilization of the chromosome of Escherichia coli by a mutant of plasmid RP4 temperature-sensitive for maintenance

Summary Two mutants of plasmid RP4 temperaturesensitive for maintenance were isolated and one of them (pTH 10) was extensively studied. Cells carrying pTH 10 showed temperature-sensitive drug resistance from which we isolated a number of temperature-independent derivatives. Almost all of them were Hfrs donating chromosomal genes to recipient bidirectionally from different points of origin. The Hfrs may be formed in two steps: (1) the transposon (Tn 1) carried by pTH 10 translocates into the host chromosome, and (2) pTH 10 is integrated in the host chromosome by reciprocal recombination between the Tn 1 s, one situated on pTH 10 and another on the host chromosome. That temperature-independent drug resistance selects for this type of derivative, was supported by the following observations: (1) Hfrs thus obtained were usually unstable and segregated at high frequency revertants showing temperature-sensitive drug resistance when they were cultivated at 30° C. (2) The revertants, cured of pTH 10 were still ampicillin resistant, indicating existence of Tn 1 inserted in the host chromosome. (3) Tn 1 insertions found in these derivatives mapped in the vicinity of points of origin of the original Hfrs. (4) When new Hfrs were constructed by: (a) transduction with Plkc of Tn 1 insertions found in derivatives of Hfrs, (b) introduction of pTH 10 into the transductants, and (c) isolation of clones of temperature-independent drug resistance from such pTH 10 carrying strains, they had similar characteristics to the original Hfrs from which Tn 1 insertions were derived. Possibilities for genetic manupulation using pTH 10 in a wide range of Gram-negative bacteria are discussed.     

Conjugal transfer of E. coli F''lac from Erwinia chrysanthemi to Pseudomonas syringae pv. glycinea and the apparent stable incorporation of the plasmid into the pv. glycinea chromosome

Summary The E. coli Flac plasmid was transferred from an Erwinia chrysanthemi Hfr8 donor to a multiply-auxotrophic, rifampicin-resistant Pseudomonas syringae pv. glycinea recipient. Transfer occurred at a frequency of approximately 10^-5/donor. Stable transconjugants which were able to utilize lactose as the sole carbon source after several transfers would not donate the Flac plasmid in detectable frequency to other pv. glycinea or E. coli recipients. The plasmid DNA was shown to be integrated into the pv. glycinea chromosome (Fig. 1).     

Mapping of chlorate-resistant mutants of Citrobacter freundii by deletion and complementation analysis

Summary From Citrobacter freundii mutants have been isolated, with deletions extending chl genes. 53% of these mutants mapped in the gal-bio region of the chromosome. Genetic mapping by three methods—deletion analysis, linkage analysis in crosses with C. freundii Hfr donors and complementation with Escherichia coli F factors—establishes the gene order: chl H-gal-chl D-hut-bio-uvr B-chl A-chl I-chl E In an other segment a gene order ilv-chl-pdx was found. Furthermore chl loci were found adjacent to 7 different chromosomal markers. C. freundii can form nitrate reductase A, thiosulfate reductase, tetrathionate reductase and formic dehydrogenase. These enzymes are not formed in most of the chlorate-resistant mutants. In some of these mutants the enzyme activities can be restored by complementation with F factors of E. coli.     

Evidence that F'' lac replicates asynchronously during the cell cycle of Escherichia coli B/r.

Summary The replication of F lac was studied in exponentially growing cultures of E. coli B/r. The cells were pulse induced for the synthesis of -galactosidase and their DNA pulse labelled with ³H thymidine. The cells were then separated into age classes by centrifugation through a sucrose gradient in a zonal rotor. Plasmid replication was measured in each age fraction by three methods: the rate at which -galactosidase could be induced, the amount of label incorporated into CCC plasmid DNA which had been separated from chromosomal DNA on agarose gels, and the amount of label incorporated into plasmid DNA which had been separated from chromosomal DNA by ultracentrifugation through CsCl-EtBr gradients. All these methods gave the same result, that replication of F lac occurs in cells of all ages and is not confined to a part of the cell cycle.     

Re-examination of F plasmid replication in a dnaC mutant of Escherichia coli.

Summary The replication of an F plasmid in a dnaC mutant, thermolabile for initiation of chromosomal replication, has been re-examined using a novel DNA-DNA annealing assay. Plasmid replication ceases rapidly at non-permissive conditions, consistent with a direct role for the dnaC product in the replication of F.     

Chromosome mobilization and integration of F-factors in the chromosome of RecA strains of E. coli under the influence of bacteriophage Mu-1

Summary Transfer of chromosome promoted by an F⁺ or an F needs a recombinational event between episome and chromosome and is therefore very low in RecA strains (Wilkins, 1969).When F⁺ or F RecA cells are mated with F^- cells and simultaneously infected with bacteriophage Mu-1 the transfer of chromosome is greatly stimulated and seems to take place on any site of the chromosome even when homology is present between the F and the chromosome.A spot-test based on Mu-1 promoted chromosome-mobilization was developed to search for mutants of Mu-1 that had lost the ability to promote chromosome-mobilization. Two conditional lethal amber mutants falling in different complementation groups were found to have lost this property.The integration of an Ftslac ⁺ in the chromosome of a RecA strain is also strongly stimulated by Mu-1 and not site-specific. The resulting Hfr's are very stable and of the clockwise and counterclockwise types. Some of the integrated F-primes are sterile and not able to transfer chromosome or do not form F-pilli.Also the Mu-1 stimulated integration of an Fts(nadA-chlA)⁺ in the chromosome of a RecA strain which has a deletion on the chromosome from nadA-chlA was studied. It was found that when the F is integrated under the influence of Mu-1 also episomal genes carried by that F can be inactivated.     

Tetracycline-resistance inEscherichia coli; a genetic contribution

A non-transmissible tetracycline-resistance plasmid inE. coli was found to be transmissible by transduction and by conjugation with the aid of theE. coli K12 sex-factor. Transfer of the tetracycline-resistance plasmid (R-tet) by transduction or conjugation to anE. coli K12 Hfr strain revealed that the plasmid was incompatible with the integrated F-factor. Selection for tetracycline-resistance after conjugation or transduction yielded Hfr colonies which carried the tetracycline-resistance determinant as a chromosomal marker. The tetracycline-resistance determinant was integrated at the 1 min region of theE. coli chromosome map (Taylor and Trotter, 1967) between the markersara andleu. Apart from Hfr colonies with a chromosomal tetracycline-resistance determinant, F-gal⁺-mediated transfer of R-tet to strain Hfr R4 gave some colonies in which the tetracycline-resistance determinant was carried on a fused plasmid that, besides the resistance determinant, contained thegal ⁺ marker of the original F-gal ⁺. This fused plasmid is transmissible and confers to an F⁻ cell male-specific phage-sensitivity, like an F-factor does. It is suggested that this fused plasmid, which is compatible with the integrated F-factor in the Hfr R4 cells, arose by recombination between F-gal ⁺ and R-tet.