Inversion of Transfer Modes and Sex Factor-Chromosome Interactions in Conjugation in Escherichia coli

A study was made of the mating properties of an unusual system of interconvertible donor strains of Escherichia coli K-12: Ra-1, Ra-2, and RaF⁺. The Ra-1 and Ra-2 strains are Hfr strains whose origins are widely separated on the chromosome and whose transfer modes proceed in the opposite direction from one another. When Ra-1 cells were mated with females, a small fraction of the donors transferred markers via the Ra-2 mode. This effect was enhanced by preconjugal ultraviolet (UV) treatment of the Ra-1 cells. Among the survivors of UV-treated Ra-1 cells, a few stable Ra-2 cells were found. When Ra-2 cells were used as the donors, some of them were found to mate via the Ra-1 mode, in analogy with the Ra-1 to Ra-2 alteration with inversion of F mentioned above. Related experiments suggested that the inversion occurs by detachment of the F factor from one Hfr origin locus, followed by reassociation of the F factor with the other Hfr origin locus. Both the Ra-1 and Ra-2 strains reverted spontaneously to an F⁺ strain, called RaF⁺. Cultures of RaF⁺ cells were found to mate primarily according to the Ra-1 and Ra-2 transfer modes, with smaller contributions also coming from transfer modes with origins elsewhere on the chromosome in a way which is similar to the transfer of markers from a normal F⁺ strain. The RaF⁺ sex factor was found to be wild type, whereas the chromosome was found to carry irregularities (sex factor affinity loci) at the locations of the Ra-1 and Ra-2 origins. Only about 10% of the donor capacity of the RaF⁺ strain was due to stable spontaneous Hfr cells in cultures of RaF⁺ cells.     

Chromosome replication in an Hfr strain of Escherichia coli

The pattern of chromosome replication in an exponentially growing culture of an Hfr strain of Escherichia coli has been compared to that obtained with the same Hfr following a procedure which synchronizes rounds of DNA replication. The results indicate that there is significant replication from the integrated plasmid following the synchronization procedure, whereas in the exponentially growing culture replication starts most frequently from the normal origin with little, if any, replication from the sex factor, 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.     

Genetic Transfer of the Vi Antigen from Salmonella typhosa to Escherichia coli

The Vi antigen was expressed in a strain of Escherichia coli after transfer of the viaB locus from a Salmonella typhosa Hfr donor.     

Apparent non-involvement of transfer RNA nucleotidyltransferase in the biosynthesis of Escherichia coli suppressor transfer RNAs

Transfer RNA nucleotidyltransferase has previously been shown to be required for the normal growth of Escherichia coli and for the biosynthesis of some bacteriophage T4 tRNAs. In order to obtain information about the involvement of this enzyme in E. coli tRNA biosynthesis we have measured the level of activity of suppressors 1 to 6 in strains carrying either a cca⁺ or cca allele. We found that cca strains, deficient in tRNA nucleotidyltransferase, contained the same amount of suppressor activities as the wild-type cca⁺ strains as determined by suppression of nonsense mutations in both E. coli alkaline phosphatase and in genes of bacteriophage T4. The results suggest that tRNA nucleotidyltransferase is not required for the biosynthesis of tRNAs specified by suppressors 1 to 6.     

Gross Map Distances and Hfr Transfer Times in Escherichia coli K-12

Hfr strains B4 and B8 transfer the Escherichia coli chromosome in opposite directions, each transferring lac⁺ as the last known marker. They were mated in concurrent crosses with the proA leu metE lys trp purE lac strain χ462. Analysis of the time of entry values for these markers showed that Hfr strain B8 transfers the whole chromosome more rapidly than does Hfr strain B4. In both crosses, the rate of transfer observed decelerates. If deceleration occurs as a function of the amount of chromosome transferred, the data are consistent with the markers examined being very accurately placed on the Taylor-Trotter map of the E. coli K-12 genome.     

Involvement of Outer Membrane Protein TolC, a Possible Member of the mar-sox Regulon, in Maintenance and Improvement of Organic Solvent Tolerance of Escherichia coli K-12

Escherichia coli mutants with improved organic solvent tolerance levels showed high levels of outer membrane protein TolC and inner membrane protein AcrA. The TolC level was regulated positively by MarA, Rob, or SoxS. A possible mar-rob-sox box sequence was found upstream of the tolC gene. These findings suggest that tolC is a member of the mar-sox regulon responsive to stress conditions. When a defective tolC gene was transferred to n-hexane- or cyclohexane-tolerant strains by P1 transduction, the organic solvent tolerance level was lowered dramatically to the decane-tolerant and nonane-sensitive level. The tolerance level was restored by transformation of the transductants with a wild-type tolC gene. Therefore, it is evident that TolC is essential for E. coli to maintain organic solvent tolerance.     

Recombineering with tolC as a selectable/counter-selectable marker: remodeling the rRNA operons of Escherichia coli

This work describes the novel use of tolC as a selectable/counter-selectable marker for the facile modification of DNA in Escherichia coli. Expression of TolC (an outer membrane protein) confers relative resistance to toxic small molecules, while its absence renders the cell tolerant to colicin E1. These features, coupled with the λredgam recombination system, allow for selection of tolC insertions/deletions anywhere on the E. coli chromosome or on plasmid DNA. This methodology obviates the need for minimal growth media, specialized wash protocols and the lengthy incubation times required by other published recombineering methods. As a rigorous test of the TolC selection system, six out of seven 23S rRNA genes were consecutively and seamlessly removed from the E. coli chromosome without affecting expression of neighboring genes within the complex rrn operons. The resulting plasmid-free strain retains one 23S rRNA gene (rrlC) in its natural location on the chromosome and is the first mutant of its kind. These new rRNA mutants will be useful in the study of rRNA gene regulation and ribosome function. Given its high efficiency, low background and facility in rich media, tolC selection is a broadly applicable method for the modification of DNA by recombineering.     

The effect of UV irradiation on the capacity of an Hfr recA strain of Escherichia coli to act as donor

Summary The ability of a recA Hfr strain of Escherichia coli to form colonies is extremely sensitive to inhibition by ultraviolet light (Fig. 2). Furthermore, in this strain the synthesis of DNA is stopped completely by a dose of 385 ergs/mm² of UV (Fig. 3). Nevertheless, the ability of this recA Hfr strain to act as a donor in sexual recombination was no more sensitive to UV than that of a wild type donor (Fig. 1). Furthermore, when irradiated and mated with a recA female, in which DNA synthesis was also inhibited by UV (Fig. 3), there was a net synthesis of DNA as measured by the incorporation of C¹⁴ thymidine (Fig. 4). By using nalidixic acid resistant recA donors and recipients in all combinations, irradiating with UV and treating with nalidixic acid during mating, it is shown that DNA was synthesized by the donor (Fig. 5). It is concluded that synthesis of DNA directed by the sex factor during mating in a recA donor is not as sensitive to inhibition by UV as normal DNA synthesis in a recA donor.     

Rational optimization of tolC as a powerful dual selectable marker for genome engineering

Selection has been invaluable for genetic manipulation, although counter-selection has historically exhibited limited robustness and convenience. TolC, an outer membrane pore involved in transmembrane transport in E. coli, has been implemented as a selectable/counter-selectable marker, but counter-selection escape frequency using colicin E1 precludes using tolC for inefficient genetic manipulations and/or with large libraries. Here, we leveraged unbiased deep sequencing of 96 independent lineages exhibiting counter-selection escape to identify loss-of-function mutations, which offered mechanistic insight and guided strain engineering to reduce counter-selection escape frequency by ∼40-fold. We fundamentally improved the tolC counter-selection by supplementing a second agent, vancomycin, which reduces counter-selection escape by 425-fold, compared colicin E1 alone. Combining these improvements in a mismatch repair proficient strain reduced counter-selection escape frequency by 1.3E6-fold in total, making tolC counter-selection as effective as most selectable markers, and adding a valuable tool to the genome editing toolbox. These improvements permitted us to perform stable and continuous rounds of selection/counter-selection using tolC, enabling replacement of 10 alleles without requiring genotypic screening for the first time. Finally, we combined these advances to create an optimized E. coli strain for genome engineering that is ∼10-fold more efficient at achieving allelic diversity than previous best practices.     

The plasmid of Salmonella typhimurium LT2

Summary Methods of clonal analysis were applied to the study of heterogeneity of the progeny after crosses of 4 donor strains (Hfr H, Hfr C, KL 16 and KL 99) with 3 recipient strains (PC 0212, AB 712 and ECK 022). Three markers were used in each cross. The distal one was the selective marker. The inheritance of two additional proximal markers characterized the heterogeneity of clones originating from particular zygotes. In most crosses the percentage of heterogeneity exceeded 30. One of the recipient strains, obtained by conjugation of the conventional strain PC 0212 with the donor Hfr H revealed unusual properties in respect to heterogeneity. Exconjugants derived from this recipient (ECK 022) and donor Hfr H and Hfr C had a heterogeneity index of about 5%. It is shown that this unusual behavior reflects a very fast process of segregation of recombinants.In crosses with the donors KL 16 and KL 99 the same recipient revealed normal indices of heterogeneity. All these data are explained assuming that there exists a specific genetic marker which determines the process of decay of merozygotes. Tentatively it is called het. Its approximate localization was deduced from specifically designed experiments, in which the heterogeneity of the progeny was found very different, when the donor KL 16 transmitted different parts of its chromosome to the recipient ECK 022.     

Genetic Factors Affecting Recovery of Nonpoint Mutations in the Region of a Gene Coding for Ornithine Transcarbamylase: Involvement of Both the F Factor in Its Chromosomal State and the recA Gene

Mutants of E. coli K12 that overproduce ornithine transcarbamylase can be identified in Car^- strains because they permit utilization of citrulline as a carbamyl phosphate source, due to reversal of the normal OTCase reaction; they are called Cut mutants (citrulline utilizers). Hfr strains that carry the F factor adjacent to argF (one of two duplicate genes that code for ornithine transcarbamylase in E. coli K12) yield more Cut mutants than do F⁺ or F^- strains, or Hfr strains in which the F factor is not adjacent to argF. When Hfr strains in which the F factor is integrated adjacent to argF are made recA, they yield few Cut mutants. Many of the Cut mutants recovered from one of the Hfr strains used in the investigation (Hfr P4X) are unstable; the properties of these unstable mutations suggest that they carry aberrations in the region of the argF gene. Thus, the increased yields of Cut mutants probably result from aberrations that occur when the F factor is integrated adjacent to argF. The nature of these aberrations is not yet known. The unstable Cut mutants are to a large extent stabilized by recA; such stabilization is one of the properties of duplications. Other data indicate that the aberrations may be more complex than simple gene duplications; in particular properties of segregants and some recombinants derived from unstable Cut mutants are most easily interpreted by assuming that segregation from, and possibly formation of, the unstable mutants occurs in several stages.     

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.     

Conjugation in Escherichia coli: Failure to Confirm the Transfer of Part of Sex Factor at the Leading End of the Donor Chromosome

Experiments were carried out attempting to determine whether part of sex factor is transferred at the leading end of the Hfr chromosome during conjugation. In the first experiment, an analysis was made of the donor properties of recombinant strains which had inherited the terminal but not the proximal marker from an Hfr. Secondly, recombinants integrating an extremely proximal marker from an Hfr were examined for the inheritance of a sex factor affinity locus adjacent to this marker. In the third experiment, proximal transfer of the wild-type allele of a temperature-sensitive sex factor mutation was looked for, using as recipient a temperature-sensitive Hfr strain, and as donor a wild-type Hfr isogenic with respect to the site of sex factor integration. In none of these experiments could the presence of sex factor material at the leading end be demonstrated. The results do not rule out the possibility that part of F is transferred proximally but only integrated at a very low frequency. They do, however, conflict with certain findings of other authors which, in the past, have been taken as evidence for the transfer of part of F at the leading end.     

Rapid Mapping of Conditional and Auxotrophic Mutations in Escherichia coli K-12

The approximate genetic map locations of auxotrophic and conditional lethal mutations of Escherichia coli can be rapidly determined with replica plating techniques. A set of patches of 15 streptomycin-sensitive (Str^S) Hfr strains with points of origin distributed around the map is replica plated onto a recombinant-selective plate with a lawn of Str^R cells which carry an unmapped mutation. The map interval defined by the Hfr points of origin which are closest to the mutant locus is seen by the presence or absence of heavy patches of recombinants produced by transfer of early wild-type genes from the Hfrs. An alternative method is to replicate patches of different mutant strains (100 per plate) onto Hfr lawns; in this case more than 1,000 different mutants can be mapped in a single experiment in a few days. In this way, many types of mutations with similar phenotypes can be grouped as to approximate location on the genetic map. For ordering mutations within groups, the same replica plating methods can be used to cross F-prime derivatives of mutants with other mutants of the same group. Relative merits of these and other mapping methods of E. coli are 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.     

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.     

Schizosaccharomyces pombe contains separate CC- and A-adding tRNA nucleotidyltransferases

A specific cytidine-cytidine-adenosine (CCA) sequence is required at the 3′-terminus of all functional tRNAs. This sequence is added during tRNA maturation or repair by tRNA nucleotidyltransferase enzymes. While most eukaryotes have a single enzyme responsible for CCA addition, some bacteria have separate CC- and A-adding activities. The fungus, Schizosaccharomyces pombe, has two genes (cca1 and cca2) that are thought, based on predicted amino acid sequences, to encode tRNA nucleotidyltransferases. Here, we show that both genes together are required to complement a Saccharomyces cerevisiae strain bearing a null mutation in the single gene encoding its tRNA nucleotidyltransferase. Using enzyme assays we show further that the purified S. pombe cca1 gene product specifically adds two cytidine residues to a tRNA substrate lacking this sequence while the cca2 gene product specifically adds the terminal adenosine residue thereby completing the CCA sequence. These data indicate that S. pombe represents the first eukaryote known to have separate CC- and A-adding activities for tRNA maturation and repair. In addition, we propose that a novel structural change in a tRNA nucleotidyltransferase is responsible for defining a CC-adding enzyme.     

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.     

TolC-dependent exclusion of porphyrins in Escherichia coli

We found that Escherichia coli tolC mutants showed increased sensitivity to 5-aminolevulinic acid (ALA), a precursor of porphyrins. The tolC mutant cells grown in the presence of ALA showed a reddish brown color under visible light and a strong red fluorescence under near-UV irradiation. Fluorescence spectrometry and high-performance liquid chromatography analysis showed that the tolC mutant cells grown in the presence of ALA accumulated a large amount of coproporphyrin(ogen) intracellularly. In contrast, the wild-type cells produced coproporphyrin extracellularly. The tolC mutant cells grown in the presence of ALA, which were capable of surviving in the dark, were killed by near-UV irradiation, suggesting that the intracellular coproporphyrin(ogen) renders these cells photosensitive. These results suggest that the TolC-dependent efflux system is involved in the exclusion of porphyrin(ogen)s in E. coli.