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.     

Isolation of High-Frequency Recombining Strains from Escherichia coli Containing the V Colicinogenic Factor

The isolation and characterization of high-frequency recombining strains from different Escherichia coli host cells containing either the F factor or the Col V factor are described. The strains (with one exception) formed from three of the V⁺ parents showed the same origin and polarity of transfer (xyl-arg-pro-trp-his-mal). The Hfr strains formed from the one remaining V⁺ and the F⁺ host cells showed a greater variety in their points of origin. In addition, several Hfr strains isolated from V⁺ parents lost the ability to produce colicin V. F_v⁺ segregants of these were isolated, and the F_v factors appeared to retain their preferential site for Hfr formation, but they lacked other propertes controlled by the Col V factor. Chromosomal integration of episomes and its relation to the fertility of F⁺ and V⁺ strains are discussed. Production of colicin V appeared to be uninfluenced by the state of the Col V factor within the cell.     

Recombinant F′ Factors from Escherichia coli K-12 Strains Carrying recB or recC

The frequency of genetic exchanges between F' factors and the bacterial chromosome was studied in recombination-deficient Escherichia coli mutants under conditions in which the recombinant F' factors were immediately transferred to new hosts. In a series of double matings, F101-1 thr(+)leu(-) episomes were first transferred into each of four intermediate F(-)thr(-)leu(+) strains carrying various rec alleles. After the original F' donors were killed with phage T6, the F101-1 episomes were then transferred from the intermediate cells to F(-)thr(-)leu(-)Str(R)recA(-) females. Recipients of nonrecombinant episomes formed Thr(+) (Str(R)) colonies, and recipients of recombinant episomes formed Leu(+)(Str(R)) colonies. A comparison of the numbers of Leu(+)(Str(R)) and Thr(+)(Str(R)) colonies shows that recB(-) males formed 18 to 21% and recC(-) formed 47 to 60% of the wild-type level of recombinant episomes that could be detected after transfer. No recombinant episomes were detected using a recA(-) intermediate strain. If the intermediate strains harboring the F101 episomes were purified, allowed to grow for 50 generations, and then mated with the recA(-) recipient, recombinant episomes were transferred at 8% of the wild-type level for recB(-) and 13% for recC(-). In contrast, only 0.4 and 0.6% of the normal number of recombinants were obtained from crosses between Hfr Cavalli donors and the same recB(-) and recC(-) strains. Recombinant episomes were detected with greater frequency among newly formed rec(+), recB(-), and recC(-) partial diploids than in those which were 50 generations old.     

A novel pleiotropic mutation in Escherichia coli K12 which affects transduction, transformation and rates of mutation.

A mutant strain of Escherichia coli K12, R2721, has been shown to differ from its parent strain, S491, in four associated phenotypic characters as a result of a single mutation. This strain did not give recombinants with DNA transduced by bacteriophage PI or bacteriophage Mu, nor transformats after exposure to R factor DNA: lysates of bacteriophage PI grown on this strain did not appear to contain any transducing particles when tested on normal recipients. Moreover, the reversion rates, both spontaneous and ultraviolet-induced, for two auxotrophic markers were reduced. The frequency of revertants was at least two orders of magnitude lower in cultures of R2721 than in cultures of S491I. Many of the rare revertants for one or other of the auxotrophic markers were found to have regained normal reversion frequencies for the other marker and for the capacity to be transduced. In all other respects, recombination in R2721 appeared normal, the frequency of chromosomal mobilization by and F' factor was unaffected and normal yields of recombinants were obtained from matings with Hfr strains. The only circumstance in which transduction of R2721 was observed was when the capacity to ferment galactose was selected and PI had been grown on a strain carrying lambdadgal when, presumably, integration was effected by the phage-coded gene products. The mutation has been located on the E. coli chromosone map between tonA and pro and has been given the symbol tdi (transduction inhibition). Double mutants, (tdi recA) and (tdi recB), have been isolated and show no unexpected properties.     

Molecular Studies on Entry Exclusion in Escherichia coli Minicells

Minicells produced by abnormal cell division in a strain of Escherichia coli (K-12) have been employed here to investigate the phenomenon of "entry exclusion." When purified minicells from strains containing F' or R factors, or both, are mated with radioactive thymidine-labeled Hfr or R(+) donors, the recipient minicells can be conveniently separated from normal-sized donors following mating, and the products of conjugation can be analyzed in the absence of donors and of further growth of the recipients. Transmissible plasmids or episomes are transferred less efficiently to purified minicells derived from strains carrying similar or related elements than to strains without them. Measurement of deoxyribonucleic acid (DNA) degradation and determination of weight-average molecular weights following transfer indicate that degradation of transferred DNA or transfer of smaller pieces cannot account for the comparative reduction in transfer to entry-excluding recipients. Therefore, we conclude that entry exclusion operates to prevent the physical entry of DNA into recipients expressing the exclusion phenotype. The R-produced repressor (product of the drd(+) gene), which represses fertility (i.e., ability to act as donor), reduces exclusion mediated by R or F factor, or both, in matings between strains carrying homologous elements. Furthermore, the data suggest that the presence of the F pilus or F-like R pilus on recipient cells ensures maximum expression of the exclusion phenotype but is not essential for its expression. In contrast to previous suggestions, we found no evidence for a reduction of entry exclusion attributable to the DNA temperature-sensitive chromosomal mutation dnaB(TS).     

Incompatibility of Integrated Sex Factors in Double Male Strains of ESCHERICHIA COLI

Several strains of Escherichia coli K-12 harboring two F factors were isolated from Hfr x Hfr crosses. These strains were transiently capable of initiating chromosome transfer from two separate points of origin, and of transferring two different sex factors as integrated chromosomal markers. Each strain tested invariably reverted to a simple Hfr by loss of one of the inherited F factors. The F factor persisting in the revertant was, in nearly every case, that which had been inherited from the recipient Hfr parent.     

Derivation of an F-Merogenote and a φ80 High-Frequency Transducing Phage Carrying the Histidine Operon of Salmonella

An F' factor, FS400, carrying the his operon, the gnd gene, and the rfb gene cluster of Salmonella typhimurium was isolated. FS400 was introduced into an Escherichia coli strain having a lengthy deletion of the his gene region. From this strain, Hfr derivatives were isolated which had the F' factor integrated in the tonB locus near the attachment site of phi80. One of the Hfr strains was lysogenized with a heat-inducible, h mutant of phi80, and from this strain a high-frequency transducing phage carrying the his genes and the gnd gene of Salmonella was isolated.     

Recipient Gene Duplication during Generalized Transduction

An Hfr13 Delta(proA-lac) deletion recipient, -Delta(proA-lac)-F-purE(+)-, has been utilized in a study of the origins of duplications formed during chromosome fragment integration. Among the Pro(-)Lac(+) transductants, some have duplications spanning the F locus. These transductants are, or segregate, strains with F' episomes carrying genes of the duplication. Some of the duplications include purE(+), a gene which is not coinherited with lac(+) during bacteriophage P1-mediated transduction. Thus recipient genes have been duplicated during recombinant formation. Crossing-over models including replication steps provide a basis for explaining the duplication process.     

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

A class of F' plasmids, designated Fpoh+, was previously shown to be able to replicate extra-chromosomally 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.     

Effect of tra mutations on F factor-specified immunity to lethal zygosis

Summary Hfr, F⁺, and F-prime cells are, unlike F^– cells, insensitive to an excess of Hfr donor cells, indicating that there is an F factor mediated immunity to lethal zygosis (Ilz). Results with Flac episomes carrying traJ, traS or various polar mutations in the tra region indicate that this immunity is independent of surface exclusion, of traJ control, and of all known genes within the tra operon. However, analysis of a series of strains with deletions in the F factor, extending from the right into the tra region, suggests that a gene for immunity to lethal zygosis is located within the tra region. We therefore conclude that Ilz is genetically complex, and present a hypothesis to account for these results.     

Suppression of an Escherichia coli dnaA mutation by the integrated R factor R.100.1: Change of chromosome replication origin in synchronized cultures.

We have followed, by deoxyribonucleic acid-deoxyribonucleic acid hybridization, the order of replication of three chromosomal markers during a synchronous round of replication in three strains of Escherichia coli carrying a dnaAts mutation: one strain in which the F-like R factor R.100.1 was established as a plasmid and two strains in which the dnaA mutation was suppressed by the integration of R.100.1 into the chromosome. In the R+ strain at 30C, replication of the plasmid took place simultaneously with the initiation of chromosome replication at the normal origin. In the integratively suppressed Hfr strains, at 42.5 C, chromosome replication was initiated preferentially from the integrated plasmid; little or no initiation occurred at the normal origin. Similar results were obtained for the one strain tested at 30 C. For both Hfr strains at 42.5 C, the data suggest that at least part of the population replicated bidirectionally. This conclusion had been confirmed using an autoradiographic procedure. Both types of experiment indicate a wide variation in the rate of travel of individual replication forks within the population.     

Evolution of a Site of Specific Genetic Homology on the Chromosome of Escherichia coli

Integration of the factors F(v) and F into the chromosome of a substrain of Escherichia coli K-12 has been studied. The F(v) factor is a fertility factor derived from Col V, lacking the ability to govern the production of colicin V. The derivatives of an Hfr(v) (Hfr isolated from a V colicinogenic parent) strain, PK2 (initially isolated from C600 V(+)), were shown to retain a unique bidirectional sex factor affinity locus between recA and pheA. This site shows no affinity for the E. coli K-12 F factor as shown by inability to isolate Hfr strains with origins in this region from a parental strain containing a cytoplasmic F factor. However this area exhibits two regions of homology to the V colicinogenic factor. One gives rise to Hfr(v) strains identical to the original Hfr(v) strain, PK2, with an origin and polarity of transfer designated pheA-CC injecting markers in the order pheA-his-trp-pro. The second gives rise to strains apparently originating at the same site but with reverse polarity designated recA-C, transferring markers in the order recA-thyA-str-xyl. For strains possessing the F(v) factor only the second homology is apparent. A model for the evolution of these strains is presented.     

Identification of a membrane protein associated with expression of the surface exclusion region of the F transfer operon.

Membrane preparations from radioactively labeled male and female strains of Escherichia coli K-12 were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. An intensely labeled band corresponding to a protein of molecular weight of 24,000 was readily apparent in preparations from Hfr and F-prime strains but not in those from female strains. When preparations from a series of Hfr strains containing transfer operon deletions were examined, presence of the band was found to be associated with retention of the region of the F transfer operon between ilzA and traD. Thus, the band ("protein S") appears to be the product of an F tra operon activity corresponding to traS (the gene for surface or entry exclusion), or an unknown gene in its vicinity. As predicted, protein S was subject to Fin+ control; only a faint band was detectable if the repressed plasmid R100 was also present in the F lac strain. A 24,000-dalton protein was also found in membrane preparations from strains carrying the derepressed plasmids R100-1 and R1-19 but not in those from strains carrying the repressed plasmids R100 or R1. Thus, the appearance of protein S in the membrane may be a general phenomenon resulting from transfer operon expression of F-like plasmids.     

Gene Transmission Among Strains of Erwinia amylovora

Stable donor strains of Erwinia amylovora were obtained from strain EA178R(1) (harboring an Escherichia coli F'lac) by selection for clones resistant to curing by acridine orange. These donor strains (EA178R(1)-99 and EA178R(1)-111) transfer chromosomal markers (arg, cys, gua, ilv, met, pro, ser, trp); the frequency of the appearance of recombinants prototrophic for Cys, Gua, Met, Ser, and Trp is highest (> 10(-5)), followed by recombinants prototrophic for Arg, Ilv, and Pro (10(-7) to 10(-5)). The results of interrupted matings, as well as the frequency of transmission of various markers, suggest that cys is transferred as an early marker by both donor strains. The Hfr state of these donor strains is rather likely on the basis of the following observations. The donor strains exhibit a relatively efficient and possibly oriented chromosome transfer; the Lac(+) character is not cured by acridine orange in these donor strains; and these donor strains do not transfer F.     

Specific Action of Sodium Dodecyl Sulfate on the Sex Factor of Escherichia coli K-12 Hfr Strains

A specific action of sodium dodecyl sulfate (SDS) on the sex (F) factor in the integrated state of Escherichia coli K-12 Hfr H strain is reported. Growth of Hfr cells in Penassay Broth containing SDS results in the elimination of part or all of the F factor, yielding low and nonfertile variants of defective Hfr type and F⁺ cells and also F⁻ derivatives. Appearance of such variants was generally observed after the culture reached stationary phase. The frequencies of F⁻ cells then increased. F⁻ cells were usually isolated as the major population among survivors. Some defective variants of Hfr cells with an intermediate fertility between standard Hfr and F⁺ cells had lost sensitivity toward the male-specific ribonucleic acid phage M12. Other defective Hfr variants with as much or less fertility than standard F⁺ cells had also all lost sensitivity to phage M12. On single-colony isolation, they segregated nonfertile female H cells which, when infected with F, could restore high fertility with oriented transfer of the chromosome the same as that of the original Hfr H. Also, sensitivity to phage M12 was regained. Female H cells were characterized as those lacking fertility but still retaining a small segment of F or sfa locus at the original part of the chromosome, where newly infected F could attach. Similar results were obtained with two other Hfr strains. A possible mechanism of the specific action of SDS is discussed.     

Early transfer of genes determining transfer functions by some Hfr strains in Escherichia coli K12

Summary Sixty-eight Hfr strains were examined for their ability to transfer early in conjugation the transfer genes carried by the integrated sex factor. This was measured by mating these strains with F^- phenocopied recipient cultures of strains carrying transfer-deficient Flac ⁺ factors, and then measuring the ability of the recipient strains to transfer lac ⁺ to a further recipient strain. Most Hfr strains did not complement the missing transfer functions, though in some strains complementation was observed. It is concluded that on the sex factors of different Hfr strains either the site at which integration occurs or the origin of transfer must vary.     

Identification and mapping of the replication genes of an R factor, R100-1, integrated into the chromosome of Escherichia coli K-12

A stable Hfr strain of Escherichia coli K-12 was obtained by integrative suppression by an R factor, R100-1. The R factor was integrated into the right of 81 min, and chromosome transfer occurred counterclockwise. Mating experiments revealed two linkage groups of genes on the R factor. Drug-resistant transductants of a dnaA-ts recipient from an R-factor Hfr and from an R(+) strain differ in their drug resistance patterns, temperature sensitivity, and transferability of drug resistance as well as chromosome markers. Transductants that transferred chromosome markers were further classified as to the origin and direction of chromosome transfer. For temperature-sensitive transductants, the reversion frequency to temperature resistance was determined, and these revertants were scored for transfer of drug resistance as well as chromosome markers. Two genes responsible for integrative suppression (designated as repA) and the other for autonomous replication (designated as repB) were identified and mapped. The arrangement of genes on the R factor is... (sul, str, cml)... repA... tra... (tet, repB).... The map of the autonomously replicating R factor is probably a circle connecting both sides of this linear map. Thus, a method has been established to map a plasmid that could not finely be analyzed under autonomous state by transduction. It also permits genetic analysis of genes responsible for replication of the plasmid without making use of a conditional mutant of itself but with that of the host, dnaA.     

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.     

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.     

Hyper-Recombining Recipient Strains in Bacterial Conjugation

Using a direct enrichment and screening procedure, mutants of Escherichia coli have been isolated in which recombination frequencies for several intragenic Hfr X F- crosses are significantly higher (twofold to sixfold) than in the parental strains. These hyper-recombination mutations comprised five new mutS- and one new mutL- allele. Together with other known mut- alleles, they were analyzed for effects on intragenic recombination using several types of crosses. Hyper-recombination was found for mutS-, mutL-, mutH (= mutR)- and mutU (= uvrD)-, with the largest effects seen for certain alleles of uvrD; these resulted in over 20-fold excesses in recombinant production for Hfr X F- crosses and F'-chromosome homogenotization. Spontaneous mutator ability was not always correlated with degree of hyper-recombination.