Inhibition of replication of an F'lac episome in Hfr cells of Escherichia coli

Cell-cycle-specific initiation of replication

The following characteristics are relevant when replication of chromosomes and plasmids is discussed in relation to the cell cycle: the timing or replication, the selection of molecules for replication, and the coordination of multiple initiation events within a single cell cycle. Several fundamentally different methods have been used to study these processes: Meselson-Stahl density-shift experiments, experiments with the so-called 'baby machine', sorting of cells according to size, and flow cytometry. The evidence for precise timing and co-ordination of chromosome replication in Escherichia coli is overwhelming. Similarly, the high-copy-number plasmid ColE1 and the low-copy-number plasmids R1/R100 without any doubt replicate randomly throughout the cell cycle. Data about the low-copy-number plasmids F and P1 are conflicting. This calls for new types of experiments and for a better understanding of how these plasmids control their replication and partitioning.

Identification and classification of bacterial plasmids

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The integrated and free states of Streptomyces griseus plasmid pSG1

A 16.6-kb plasmid-pSG1-was isolated from Streptomyces griseus following transformation of protoplasts with unrelated plasmids. Southern hybridization experiments with radioactive probes prepared from pSG1 fragments and immobilized S. griseus DNA fragments indicated that the plasmid was present in the progenitor strain, in an integrated state. In the pSG1+ isolates plasmid sequences existed both as integrated sequences and as free plasmids. The integrated state of maintenance persisted in strains which have been cured of the free plasmid. The junction site on the plasmid was located on a 0.5-kb EcoRI-SalI fragment. The chromosomal integration site was demonstrated to be the same in all strains derived from S. griseus NRRL3851. The occurrence of both states of plasmid maintenance in the same clones indicates that an integrated pSG1 sequence does not interfere with free plasmid replication and partition. It suggests that the establishment of the free state may involve a replicative excision of pSG1 from the S. griseus chromosome.

High frequency FP2 donor of Pseudomonas aeruginosa PAO

After NG mutagenesis an FP2 donor was isolated which exhibited an enhanced conjugational capacity for chromosomal genes. The recombination frequency was increased by two orders of magnitude as compared to the parental strain. In plate matings recombinants arose at a frequency up to 5 X 10(-1) per donor cell. Late markers also recombined efficiently. An Hfr state of the donor strain was supported by (i) the high recombination frequency, (ii) the incompatibility reaction with plasmid pRO271 (= FP2::Tn401) and (iii) the clearcut transfer kinetics in interrupted matings, even for a late marker.

Control of replication of bacterial plasmids: genetics, molecular biology, and physiology of the plasmid R1 system

Plasmids are autonomously replicating DNA molecules that are present in defined copy numbers in bacteria. This number may for some plasmids be very low (2-5 per average cell). In order to be stably inherited, replication and partitioning of the plasmid have to be strictly controlled. Plasmids carry genetic information for both processes. In the present paper we summarize what is known about the replication control system of one low-copy-number plasmid, R1, belonging to the FII incompatibility group. We do so because the FII group seems to be one of the best understood examples with respect to genetics, molecular biology, and physiology of the replication control system. The paper is not a classical review, but rather an essay in which we discuss the aspects of replication control that we regard as being important.

Autogenous transduction of phi 11de in Staphylococcus aureus: transfer and genetic properties

The staphylococcal plasmid phi 11de is capable of transduction in the absence of both a helper bacteriophage and detectable plaque-forming bacteriophage. The mechanism of transfer is distinct from generalized transduction in that it does not transduce chromosomal material and is selective with respect to the plasmid DNA that is transduced. The transductants containing phi 11de have the following characteristics: (i) erythromycin resistance at levels displayed by the donor, (ii) expression of and susceptibility to plasmid incompatibility, (iii) dependence upon the host recombination system during transduction, (iv) complementation of phi 11 mutants, and (v) reactivation of UV-irradiated phage.

Trimethoprim-induced DNA polymerase I deficiency in Escherichia coli K-12

Curing of the mini-ColE1 plasmid pML21 was observed among cells of Escherichia coli K-12 strain C600(pML21) grown under subinhibitory conditions in the presence of trimethoprim, a specific inhibitor of dihydrofolate reductase. Some of the cured colonies showed (i) a reduction in frequency of transformation with pML21 compared with those of isogenic strains not treated with trimethoprim, (ii) loss of viability after acquisition of a recA mutation, and (iii) UV sensitivity greater than that of the original isogenic strain. These colonies therefore had PolA- phenotypes. Moreover, they were found to be deficient in DNA polymerase I activity in the in vitro assays, indicating the occurrence of a polA mutation in them. Many of the colonies with PolA- phenotypes were also thyA deoC mutants, and these mutations, in addition to the polA mutations, appeared to be involved in the expression of the PolA- phenotypes.

Trimethoprim-produced F-specific insertion mutations in Escherichia coli K-12

Besides producing thymine-requiring mutants (thy), trimethoprim (TMP) cured the mini-ColE1 replicon pML21 at an appreciable frequency. The cured Escherichia coli K-12 cells behaved like polA mutants by failing to support the stable maintenance of the ColE1 plasmid. The mini-F replicon pSC138, which was lacking all three insertion sequences (IS3, gammadelta, and IS2) normally used for F-specific integration and excision, was not cured by TMP. Instead, it integrated into specific regions of the E. coli chromosome and thus caused auxotrophic mutations in operons which were always localized on either side of oriC (origin of chromosomal replication). The incompatibility and replication functions of the integrated plasmid in auxotrophs were retained, and the plasmid DNAs recovered from spontaneously occurring revertants did not show any alterations in their contour lengths as determined by electron microscopy. The F replicon (fragment 5) contained in plasmid pSC138 carried two origins of replication, the primary origin, oriV(1) at 42.6F and the secondary origin, oriV(2), at 44.1F. Another mini-F plasmid pMF21, deleted of the primary origin of replication (oriV(1)), was still capable of autonomous replication but failed to integrate onto the chromosome after TMP treatment. Furthermore, the composite plasmid pRS5, which normally uses only the replication origin and functions of the pSC101 component, was also insensitive to TMP. On the basis of these results, we propose a new scheme of F integration via the functional oriV(1) and suggest the involvement of a similar mechanism in the formation of Hfr strains by integrative suppression.

Transfer of a CFA/I-ST plasmid promoted by a conjugative plasmid in a strain of Escherichia coli of serotype O128ac:H12

Escherichia coli strains belonging to serotype O128ac:H12 and producing heat-stable enterotoxin (ST) and colonization factor CFA/I were found in Sao Paulo in children with diarrhea, but not in normal children. Segregants occurred in such strains with a frequency of about 10%, which have lost the ability to produce ST and CFA/I at the same time. From one strain, both properties were transformed jointly in matings to an E. coli K-12 strain. All such ST+ CFA/I+ progeny had received two plasmids of length 97 and 64 kilobases in the matings. Insertion of a transposon, Tn5, carrying a gene for kanamycin resistance, into the two plasmids enabled us to select for kanamycin-resistant progeny in further matings. Analysis of such progeny strains in terms of plasmid content and production of ST and CFA/I revealed that the larger plasmid carries the genes for St and CFA/I and is not self-transmissible, whereas the smaller plasmid does not carry any recognizable phenotypic traits, but is conjugative and promotes cotransfer of the larger plasmid with a frequency of about 30%.

Mutants of the mini-F plasmid pML31 thermosensitive in replication

Hydroxylamine mutagenesis was used for the induction of thermosensitive replication mutants of the mini-F plasmid pML31. Replication mutants were characterized by studying the segregation kinetics and the incorporation of [3H]-thymidine into plasmid deoxyribonucleic acid at the nonpermissive temperature. Based on these experiments two types of mutants could be distinguished. Mutants of type I are fast segregating with the kinetics expected if plasmid replication was blocked immediately. Double-label experiments showed a rapid shut-off of replication in these mutants at 42 degrees C. Mutants of type II segregate slower, showing only a partial inhibition of plasmid deoxyribonucleic acid synthesis at the nonpermissive temperature. The label incorporated at 42 degrees C was predominantly found in open circular plasmid molecules.

Isolation and characterization of enterotoxin-deficient mutants of Escherichia coli

The genes controlling the production of two types of enterotoxin of Escherichia coli, one heat-labile (LT) and the other heat-stable (ST), are found on plasmids. The absence of a direct selection procedure has made it difficult to isolate mutants affecting toxin production. However, the availability of a naturally occurring "recombinant" plasmid, carrying genes for LT and ST formation and also for resistance to tetracycline, streptomycin, and sulfonamides, made it possible to use comutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine to enrich for such mutants. We have isolated and characterized 58 LT- mutants and 7 ST- mutants. Among the LT- group we found amber mutants, temperature-sensitive mutants (most of which produce unusually heat-labile LT), and "leaky" mutants with reduced LT activity. The majority of the tested LT- mutants produced immunologically crossreacting material, in most cases in wild-type amounts. Among all 17 of the LT- mutants that could be transferred, the mutation was found to be on the plasmid. In contrast, only one of four transferrable ST- mutants appeared to be a plasmid mutant.

Incompatibility and surface exclusion properties of H1 and H2 plasmids

Plasmids of the H incompatibility group showed two types of surface exclusion and incompatibility interactions. Strong incompatibility and surface exclusion were evident between plasmids within the same subgroup, and recombination frequently occurred between these plasmids after antibiotic selection for the presence of two plasmids in the same cell. Weaker interactions were seen between plasmids of the different subgroups, H1 and H2, and recombination was not detected. Incompatibility between H1 and H2 plasmids led preferentially to the loss of the H1 plasmid, irrespective of the order of entry of the plasmids. These data are consistent with the hypothesis that incompatibility is negatively controlled.

Physical mapping of a DNA sequence common to plasmids of incompatibility group F I

We have mapped a region of homology within a 2.2 kilobase segment of plasmids of incompatibility group F I, WHICH IS CONTAINED IN AN EcoRI restriction enzyme fragment bearing genes for autonomous replication; The coordinates of the 2.2 kilobase segment are 46.4F-48.6F on the physical map of the F plasmid. The orgin of vegetative replication has been mapped at 42.5F, at which site F has no sequence homology with other group F I plasmids. Plasmids belonging to other incompatibility groups have no homology with the 46.4-48.6 F segment. Possible mechanisms underlying incompatibility are discussed. We think that incompatibility is due to either a limitation in a common equipartitioning mechanism or a limitation in a common replication control. In either case, the common mechanism is specific for plasmids belonging to a given incompatibility group.

Fusion of two F-prime factors in Escherichia coli studied by electron microscope heteroduplex analysis

A fused F prime factor was obtained from a mating of a recA donor carrying an F'- factor containing the genes metBJF, ppc and argECBH (KLF5) with a recA recipient carrying an F' factor containing att80, trp and lac (f155). lysogenization of this fused F-prime factor with gammacI857hphi80 phage followed by thermoinduction produced the transducing phages phi80 dmetBJF and phi80 dppcargECBH. This kind of fusion provides a general procedure for the construction of transducing phages carrying genes from different regions of the E. coli genome. To understand the mechanism of this fusion, the parental F prime factors (F155 and KLF5) were analyzed by the electron microscope heteroduplex technique. F155 has a length of 176 +/- 3 kilobases including two substitutions. The F sequence 0 F-2.8 F has been substituted by 53 kb of chromosomal DNA including the lac operon and the F sequences 8.5 F-16.3 F has been substituted by 27 kb of a chromosome sequence including att80 and the trp operon KLF5 contains 221 +/- 4 kilobases of DNA (molecular weight, 148 megadaltons). It contains complete F and the segment of the E. coli chromosome from polA to rif. The F sequence 2.8 F-8.5 F known to be involved in F specific recombination in recA+ and recA backgrounds occurs twice on KLF5, once at each of the junctions of F DNA with chromosomal DNA. The population of closed circular plasmid molecules extracted from KLF5-containing strains is heterogeneous. It is proposed that this heterogeneity is due to intramolecular recombination events occurring in KLF5 between the duplicated 2.8 F-8.5 F sequences. Such recombination can account for the genetic instability of KLF5 observed in both recA+ and recA hosts. The F sequence 2.8 F-8.5 (also called gammadelta) is one of the characterized integration sequences on F. A model for the fusion of the parental F prime factors is proposed in which recombination between gammadelta sequences brings att80 close to the metBJF genes. This is followed by a deletion of an F' lac factor. The resulting fused F' factor still carries two gammadelta sequences and is therefore expected to be unstable. The closed circular molecules isolated from the fused F' containing strains show two different sizes of molecules. Genetic and physical analyses of these molecules are in agreement with the predicted instability of the fused F' factor and the existance of the gammadelta sequence in the phi80 dmet phages isolated from fused F' and previously analyzed by the electron microscope heteroduplex technique.

Expression of a mutation affecting F incompatibility in the integrated but not the autonomous state of F

Previously we have described a mutant Hfr strain in which incompatibility between the integrated F factor and an autonomous F-prime (F') factor was abolished. The mutation (inc) was located in the integrated F factor. F-prime factors isolated from the mutant Hfr strain have the same incompatibility behavior as those isolated from normal Hfr strains. Reintegration of these F' factors into the chromosome restores the Inc- phenotype characteristic of the mutant Hfr. The inc mutation thus affects incompatibility between integrated F and autonomous F(Fi-Fa incompatibility) but not incompatibility between two autonomous F factors (Fa-Fa incompatibility). The implications of this finding for the mechanism of plasmid incompatibility are discussed.

Compatibility properties of R483, a member of the I plasmid complex

R483, an I pilus-determining plasmid previously reported as belonging to a distinct incompatibility group Ibeta, proved to be an atypical Ialpha plasmid; in a growing culture, the degree of inhibition of replication of one Ialpha plasmid by the presence of another was not uniform within the Ialpha group.

Genetic and physical characteristics of an enterotoxin plasmid

We are engaged in the genetic and physical characterization of an enterotoxin (Ent) plasmid, Ent P307, which contains genes for the production of a hear-labile and a heat-stable enterotoxin. We are using an Escherichia coli K-12 strain, 711 (P307), constructed by S. Falkow, which contains no other plasmids besides Ent P307. Our genetic studies have shown that the plasmid is incompatible with the sex factor F, both in the integrated (Hfr) and the autonomous (F-prime) state. Ent P307 can thus be assigned to incompatibility group FI. An R factor, R386, which belongs to the same incompatibility group, was also found to be incompatibile with Ent P307, whereas five other R factors belonging to different incompatibility groups were compatible with Ent P307. In the presence of Ent P307, conjugal transfer and sensitivity to a male-specific phage of a derepressed F-like R factor, R1drd19, were repressed. Ent P307 is, thus, finO+. Presumably, it also causes repression of its own transfer genes since conjugal transfer of Ent P307 could not be demonstrated. Unlike F, it does not restrict the growth of female-specific phage phiII. From physical studies on extracted deoxyribonucleic acid, the molecular weight of Ent P307 was determined to be 54 X 10(6). By electron microscope heteroduplex analysis, the plasmid was found to be homologous with F in four regions, encompassing about half of its length. One long region and two short ones contain genes for conjugal transfer; the other short region carries genes for replication and incompatibility.

Recombinant plasmid obtained from two different, compatible staphylococcal plasmids

From two different, compatible staphylococcal plasmids that determine streptomycin and chloramphenicol resistance, respectively, a recombinant plasmid was obtained. This plasmid can be transduced with a rather high frequency (10(-4)/plaque-forming unit) to plasmid-negative strains, the linkage of the two markers being 100%. The maintenance of the recombinant plasmid in the host cell seems to be controlled by the chloramphenicol resistance plasmid. The recombinant plasmid proved to be incompatible with both parental plasmids, which are unrelated. The relationship between the chloramphenicol resistance plasmid and the recombinant plasmid was the same as the between genetically marked derivatives of the recombinant plasmid, whereas the relationship of the streptomycin resistance plasmid to the recombinant plasmid was of a different, asymmetrical type.

Plasmid incompatibility and control of replication: copy mutants of the R-factor R1 in Escherichia coli K-12

Plasmid incompatibility was studied in Escherichia coli K-12. By double-antibiotic selection, clones were constructed that carried the two R-factors R1 and R100, both belonging to the compatibility group FII. After release of the selection pressure, each of the two plasmids was lost at the same rate (8% per generation). Mutants of R-factor R1 showing an increased number of copies per chromosome (copy mutants) were tested for their incompatibility towards R-factor R100. The results indicate that plasmid incompatibility is quantitative and not just a qualitative property. All copy mutants studied affected incompatibility, and there were two classes of mutants: one increasing and one decreasing the incompatiblity exerted towards the test plasmid R100. Evidence is presented that incompatibility is related to the mechanisms that control replication. The implications of such a relation on proposed models for control of replication are discussed. The data do not support the hypothesis that plasmid incompatibility is due to competition for a replicational or segregational site.

Characterization of V-prime factors in Escherichia coli K-12

An episome derived from an Hfr(v) (Hfr isolated from a V colicinogenic parent) strain of Escherichia coli K-12 was isolated and characterized. The direction of gene transfer was inverted from that in the original parental strain.

Isolation of a hybrid F' factor-carrying Escherichia coli lactose region and Salmonella typhimurium histidine region, F42-400 (F' ts114 lac+, his+): its partial characterization and behavior in Salmonella typhimurium

Episome F' ts114 lac+ (F42-114) was transferred into Salmonella typhimurium carrying an F'his+ (FS400) episome, and fused episome F' ts114 lac+, his+ (F42-400) was obtained. Episome F42-400 could be transferred to S. typhimurium, Escherichia coli and Klebsiella pneumoniae. Identification of the episome was based on: (i) temperature sensitivity of the Lac+ and His+ phenotypes; (ii) the fact that F- segregants, obtained after temperature curing or acridine orange curing, were simultaneously Lac- and His-; and (iii) linkage of lac+ with his+ in episomal transfers to E. coli and S. typhimurium. The frequency of episome transfer was influenced by the genotype of the donor. Plasmid LT2, prevalent in S. typhimurium LT2 strains, was suggested to be responsible for the low fertility of S. typhimurium donors. Episome F42-400 was capable of chromosome mobilization, and the extent of chromosome mobilization was not influenced by the presence or absence of the histidine region on the donor chromosome. Growth in a defined medium with acridine orange was able to cure F42-400. The frequency of curing was increased (the frequency of His+ cells was 0.0001%) if the cells were grown at 40 C in the presence of acridine orange. Selection for temperature-resistant Lac+, His+ derivatives in a strain without histidine deletion yielded Hfr strains. However, similar and stronger selections in strains without the chromosomal histidine region failed to yield Hfr strains. Our inability to obtain Hfr's in strains without the chromosomal histidine region was explained by assuming that the episome F42-400 has lost the F sites involved in integration into the S. typhimurium chromosome.

F deoxyribonucleic acid superinfected into phenocopies of donor strains

When F+ donor cells of Escherichia coli are conjugated with F-, F+, or Hfr recipients under the conditions of phenocopy mating, the male recipients are found capable of accepting the F episome as effectively as the F- recipients. The F deoxyribonucleic acid (DNA) superinfected into the male recipients is converted to the covalently closed, circular duplex form, as in the F- recipients. It is also found that the synthesis of the strand complementary to the transferred single strand and its subsequent conversion to the covalently closed, circular duplex occur effectively in male recipients as well as in female recipients. Under these mating conditions, F-ilv+ episome superinfected to F+ and Hfr cells is diluted out during growth, whereas F-ilv+ transferred into F-cells is replicated and established in almost all progeny cells. These results suggest that the incompatibility of the F episome is not due to the reduction in the rate of the conversion of transferred single-straned F DNA to covalently closed, circular duplex, but, rather, to an inhibition of further replication of the covalently closed, circular F DNA.

Comparison of the deoxyribonucleic acid molecular weights and homologies of plasmids conferring linked resistance to streptomycin and sulfonamides

Bacterial strains showing linked resistance to streptomycin (Sm) and sulfonamides (Su) were chosen representing a wide taxonomic and geographical range. Their SmSu resistances were transferred to Escherichia coli K-12 and then plasmid deoxyribonucleic acid (DNA) was isolated by ethidium bromide CsCl centrifugation. The plasmid DNA was examined by electron microscopy and analyzed by sedimentation through 5 to 20% neutral sucrose gradients. Plasmid DNA from strains having transmissible SmSu resistance consisted of two or three molecular species, one of which had a molecular mass of about 5.7 Mdal (10(6) daltons), the others varying between 20 to 60 Mdal. By using transformation or F' mobilization, we isolated the SmSu-resistance determinant from any fellow resident plasmids in each strain and again isolated the plasmid DNA. Cosedimentation of each of these with a differently labeled reference plasmid DNA (R300B) showed 9 out of 12 of the plasmids to have a molecular mass not significantly different from the reference (5.7 Mdal); two others were 6.3 and 9.2 Mdal, but PB165 consisted of three plasmids of 7.4, 14.7, and 21.4 Mdal. Three separate isolations of the SmSu determinant from PB165 gave the same three plasmids, which we conclude may be monomer, dimer, and trimer, respectively. DNA-DNA hybridizations at 75 C demonstrated 80 to 93% homology between reference R300B DNA and each isolated SmSu plasmid DNA, except for the 9.2-Mdal plasmid which had 45% homology and PB165 which had 35%. All the SmSu plasmids were present as multiple copies (about 10) per chromosome. The conjugative plasmid of R300 (present as 1.3 copies per chromosome) has been shown to have negligible effect on the number of copies of its accompanying SmSu plasmid R300B. We conclude that the SmSu plasmids are closely related and probably have a common evolutionary origin.

Incompatibility exhibited by colicin plasmids E1, E2, and E3 in Escherichia coli

Escherichia coli strains were made multiply colicinogenic for the colicin plasmids E1, E2, or E3 (Col E1, Col E2, or Col E3, respectively) by both a deoxyribonucleic acid transformation system and bacterial conjugation. The multiply colicinogenic bacteria constructed exhibited an immunity to the colicins produced by all the plasmids they carried and also produced colicins corresponding to all the plasmids they carried. An incompatibility was observed among the plasmids. In doubly colicinogenic cells where the presence of two plasmids was established, Col E2 was lost more frequently than Col E3. In triply colicinogenic cells, Col E1, Col E2, and Col E3 were lost, with Col E3 being lost least frequently. A significant reduction in the acquisition of a conjugationally transferred Col E1 plasmid by cells colicinogenic for Col E1 was demonstrated.

Mapping loci for surface exclusion and incompatibility on the F factor of Escherichia coli K-12

A series of Hfr deletion strains carrying deletions extending different distances into the integrated F factor have been used to map loci for surface exclusion (traS) and for incompatibility (inc) on the Escherichia coli K-12 sex factor F. traS mapped between traG and traD. It forms a part of the large operon, including all the known transfer genes except traJ, and is co-controlled with these. The product of traS is not required for formation of the F pilus. inc mapped between the phi(R) (11) locus and the origin of transfer; it is therefore one of the earliest loci transferred during conjugation.

Isolation and complementation of mutants in galactose taxis and transport

By using a new screening method, we have obtained 43 new Escherichia coli mutants defective in ring formation on galactose swarm plates, which score for defects in chemotaxis or transport. They were complemented and compared with mutations previously known to lie in the galactose-binding protein or the beta-methylgalactoside (mgl) permease, or both. The mutations were all found to lie in three genes, called mglA, mglB, and mglC. mglB codes for the gene specifying the binding protein. Based on co-transduction experiments, mglA, mglB, and mglC lie close to each other on the bacterial chromosome.

Camphor plasmid-mediated chromosomal transfer in Pseudomonas putida

Camphor-utilizing strains of Pseudomonas putida have been shown to carry the genetic information required for camphor degradation on a plasmid. The plasmid-carrying strains can serve as donors of both plasmid-borne and chromosomal genes. As recipients, plasmid-deleted strains are much superior to those carrying the camphor pathway genes. The transfer frequency of chromosomal, but not plasmid-borne, genes is markedly enhanced if the donor cells are irradiated with ultraviolet light followed by 3-h of growth on a rich medium in the dark. Recombinants selected for prototrophy are stable and most acquire the camphor (CAM) plasmid concomitantly; only a few of the Cam(+) recombinants inherit the donor's ability to transfer chromosomal genes at a high frequency. Transfer-defective mutations occur on the CAM plasmid, affecting both CAM and chromosomal gene transfer.

Description of an incompatibility mutant of Escherichia coli

A mutant Hfr strain of Escherichia coli which has an impaired incompatibility function but is normal for other F factor functions has been isolated. This Inc(-) Hfr permits the maintenance and transfer of both the integrated F factor and an F' factor. F' factors have been isolated from the integrated F factor of the Inc(-) Hfr strain. When these episomes were tested in matings with Hfr or F' strains, they did not differ in any observed way from wild-type F' factors.

Molecular structure of bacterial plasmids

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Characterization by electron microscopy of fused F-prime factors in Escherichia coli

During previous attempts to find mutants in which incompatibility between two F-prime (F') factors of E. coli is abolished, we found that two F' factors harbored in the same cell occasionally recombined to form a single genetic unit. Thus, a fused F'trp(+)arg(+) factor was obtained from a mating of a strain carrying recA F'trp(+) with a strain carrying recA F'arg(+). In the present paper physical fusion of the two F' factors, inferred from genetic studies, is confirmed by electron microscopy. F DNA was extracted, after detergent lysis, from four fused F' strains: the parental F'trp(+) and F'arg(+) strains and three F(+) strains. This supercoiled DNA was separated on ethidium bromide-cesium chloride gradients and converted to the open circular from before electron microscopy. The contour lengths in mum of the various DNA preparations were: F'trp(+), 59.4; F'arg(+), 33.2; the four F'trp(+)arg(+) factors, 38.5, 39.6, 63.2, and 73.5: the three F factors, 31.1, 31.1, and 31.0. Thus, different fused F' factors formed from the same parental F' factors vary in length, but are shorter than the sum of the parental F' factors.