Overproduction in Escherichia coli K-12 and purification of the TraJ protein encoded by the conjugative plasmid F

The TraJ protein encoded by the conjugative plasmid F has been designated an Escherichia coli K-12 envelope protein that participates in a mechanism of gene regulation. We have purified the TraJ protein, using an Flac::lambda traJ lysogen that overproduces the protein after heat induction of the prophage. Sufficient TraJ protein was synthesized within 40 min after induction to follow the purification by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Our purification exploited the observation that the TraJ protein remains insoluble after repeated Triton X-100/EDTA extractions of crude envelope fractions. The protein was then solubilized in sodium dodecyl sulfate at 60 degrees C and fractionated further by gel filtration and hydroxylapatite chromatography, both in the presence of sodium dodecyl sulfate. After hydroxylapatite chromatography, the protein was greater than 95% pure. The identity of the purified protein was confirmed by analysis of its NH2-terminal amino acid sequence, which was the same as that predicted from the partial nucleotide sequence of the traJ gene (Thompson, R., and Taylor, L. (1982) Mol. Gen. Genet. 188, 513-518). This analysis also indicated that the TraJ protein is localized in the cell without proteolytic modification of its NH2-terminus. We discuss the possible significance of these observations with respect to the cellular functions of the TraJ protein.     

Participation of plasmid F in the replication of the chromosome of an Hfr strain of Escherichia coli K-12

In the region of plasmid F DNA with coordinates 52,2-55,8 kb, the chr ("chromosome replication") locus has been revealed. A failure in the functioning of this locus in the integrated plasmid, which leads to a temperature-sensitive disturbance in chromosome replication of the Hfr strain and to the changes in its sensitivity to some membranotropic agents. Integration of an F segment containing the chr+ allele into the chromosome of an F-like derivative of such Hfr strain (retaining a mutant part of the F DNA), results in formation of temperature-resistant clones. In these clones, chromosomal replication is controlled by the plasmid replicon at the elevated temperature. It has been concluded that the F plasmid can control chromosome replication of the dna+ HfrC strain of Escherichia coli K-12 and that the product of the chr gene is a membrane protein involved in chromosomal replication.     

Accumulation of the F plasmid TraJ protein in cpx mutants of Escherichia coli.

We report here studies of the cellular control of F plasmid TraJ protein levels, focusing on the effects of chromosomal cpx mutations. The principal conclusion from our results is that the cpx mutations impair accumulation of the TraJ protein, thereby reducing tra gene expression. We measured TraJ activity in vivo by expression of a traY'-'lacZ fusion gene and TraJ protein by immuno-overlay blot. In strains with normal TraJ levels, traY expression and donor-related functions were reduced in cells carrying any of four cpxA mutations. In the strain background used to isolate cpx mutants, these reductions were especially evident in cells grown to high density, when traY expression and donor activity both increased in cpx+ cells. In each of the four cpxA mutants tested, TraJ levels were lower than in the otherwise isogenic cpxA+ strain. In cells grown to high density, the differences ranged from 4-fold in the cpxA6 strain to > 10-fold in the cpxA2, cpxA5, and cpxA9 strains. The cpxA2 mutation had little or no effect on traY expression or on donor-related functions when TraJ was present in excess of its limiting level in F' or Hfr cells or on a mutant traY promoter whose expression in vivo was independent of TraJ.     

Integration of plasmid RP1 with the chromosome of Escherichia coli K-12 recA. 2 classes of Hfr strains

Integration of broad host range RP1 plasmid into the chromosome of Escherichia coli K-12 recA- cells has been studied. Using temperature-sensitive for replication plasmids pVD1 and pVD3, the derivatives of RP1, it has been shown that integration of RP1 into the bacterial chromosome results in formation of two classes of Hfr strains. Properties of these Hfrs have been examined. From the data obtained, it has been concluded that the plasmid integration and formation of one of the Hfrs classes appear to be mediated by transposon Tn1 residing on RP1. The other class of Hfr strains is formed due to a stable integration of RP1. In the course of analysis of R+ transconjugants arising at low frequency in crosses between stable Hfrs and E. coli rec+ recipients, it has been found that the significant part of them contain plasmid-chromosome hybrids (R-prim plasmids). On the basis of the latter results, a new simple method for R' plasmids selection has been proposed. Using restriction endonuclease analysis, the structure of plasmids that were excised from chromosomes of the stable Hfr strains and were comparable in their size to RP1, has been investigated. Probable mechanisms of the stable Hfr strains formation are discussed.     

Origin of Escherichia coli K-12 Hfr B7.

Several F' plasmids encoding resistance to tetracycline have been derived from a trg::Tn10 Hfr B7 strain of Escherichia coli K-12. One of these plasmids, JGF312, was analyzed by restriction endonuclease digestion and Southern blot hybridization to cloned chromosomal fragments. This analysis revealed that JGF312 was formed by Tn10-promoted deletion from the Tn10 insertion (31.4 min) to within the prophage rac at 30.1 min. Hfr B7 was shown to result from recombination between IS2 of F delta (33-43) and a chromosomal IS2 located within the rac-man region at 30.9 min on the genetic map.     

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.     

Kinetics of pair formation during cell cycle of Hfr and F in Escherichia coli K-12.

Pair formation ability in mating mixture of synchronized Hfr or F- culture and asynchronous culture of appropriate partner was studied. The obtained results allow to conclude that the pair formation ability of F- cells is stable over the whole cell cycle whereas in Hfr cells is it subject to cyclic changes with maximum in the first half of the cycle.     

Hfr formation by I pilus-determining plasmids in Escherichia coli K-12.

R483, an atypical, I pilus-determining plasmid, and also R144, a typical one, were shown to suppress the DnaA phenotype by integration into the Escherichia coli chromosome.     

Host cell–plasmid interactions in the expression of DNA donor activity by F+ strains of Escherichia coli K-12

DNA transfer directly from cell to cell (conjugation) is common among prokaryotes, particularly Gram-negative bacteria like Escherichia coli. The phenomenon invariably requires a set of plasmid genes in the DNA donor cell. In addition, E. coli itself makes limited and specific contributions to the donor activity of strains carrying the conjugative plasmid F. These contributions have yet to be defined biochemically, but it is already clear that the cell envelope is an importan nexus between plasmid- and chromosome-encoded proteins required for the establishment and maintenance of DNA donor activity.     

Deoxyribonucleic Acid Transferred from Ultraviolet-Irradiated Excision-Defective Hfr Cells of Escherichia coli K-12

Deoxyribonucleic acid (DNA) transfer from (3)H-thymine-labeled Hfr cells has been measured by determining the amount of radioactivity remaining after selective lysis of the donor cells in the mating mixture. DNA transfer was less effectively reduced by ultraviolet irradiation of excision-defective Hfr cells than was the yield of recombinants. The buoyant density of DNA transferred from unirradiated and irradiated Hfr cells was equivalent to that of double-stranded DNA. Mating-dependent DNA synthesis in the recipient has been measured by mating Hfr cells deficient in thymidine kinase with irradiated thymine-requiring F(-) cells in the presence of (3)H-thymine. The extent of such DNA synthesis approximated the amount of DNA transferred from unirradiated donors. Neither DNA transfer nor mating-dependent DNA synthesis could be reliably measured when both parents were irradiated. It is proposed that transferred Hfr DNA is replicated in the recipient and that this replication still occurs when the Hfr DNA contains dimers.     

dnaB gene of Escherichia coli K-12 affects superinfection inhibition between F' plasmids.

F' Escherichia coli K-12 strains bearing the chromosomal mutation dnaB43 offer significantly less resistance to the conjugational introduction of a second F' plasmid than do nonmutant strains. Both the entry exclusion and incompatibility components of superinfection inhibition are altered. This action of dnaB43 occurs regardless of the presence of a recA-minus mutation in matings in liquid cultures and on membrane filters and is not limited to a particular set of F' plasmids. These effects are co-transducible by phage P1 with the temperature sensitivity conferred by dnaB43. The effects also occur with a strain carrying dnaB107. In the double F' strains that arise, the two plasmids exist as units autonomous of one another and the chromosome.     

Characterization of the mcrBC region of Escherichia coli K-12 wild-type and mutant strains.

We have carried out an analysis of the Escherichia coli K-12 mcrBC locus in order to (1) elucidate its genetic organization, (2) to identify the proteins encoded by this region, and (3) to characterize their involvement in the restriction of DNA containing methylated cytosine residues. In vitro expression of recombinant plasmids carrying all or portions of the mcrBC region revealed that the mcrB and mcrC genes are organized as an operon. The mcrBC operon specifies five proteins, as evident from parallel in vitro and in in vivo expression studies. Three proteins of 53, 35 and 34 kDa originate from mcrB expression, while two proteins of 37 and 16 kDa arise from mcrC expression. Products of both the mcrB and mcrC genes are required to restrict the methylated substrate DNA used in this study. We also determined the nature of mutant mcrBC loci in comparison to the E. coli K-12 wild-type mcrBC locus. A major goal of these studies was to clarify the nature of the mcrB-1 mutation, which is carried by some strains employed in previous analyses of the E. coli K-12 McrBC system. Based on our analyses the mutant strains investigated could be divided into different complementation groups. The mcrB-1 mutation is a nonsense or frameshift mutation located within mcrB. It causes premature termination of mcrB gene product synthesis and reduces the level of mcrC gene expression. This finding helps to understand an existing conflict in the literature. We also describe temperature-sensitive McrA activity in some of the strains analysed and its relationship to the previously defined differences in the tolerance levels of E. coli K-12 mcrBC mutants to cytosine methylation.     

Gene lon and plasmid inheritance in Escherichia coli K-12.

Lon- mutants of Escherichia coli K-12 are deficient in the inheritance of F-plasmids by conjugation. This deficiency is distinct from the conjugation deficiency caused by overproduction of capsular polysaccharide which decreases donor-recipient pair formation.     

The Escherichia coli K-12 F plasmid gene traX is required for acetylation of F pilin.

The Escherichia coli F plasmid gene required for amino-terminal acetylation of F-pilin subunits was identified. Using Western blots (immunoblots), we assayed the reaction of monoclonal antibodies with F-pilin polypeptides in inner membrane preparations from various F mutant strains. It was known that JEL92 recognizes an internal pilin epitope and JEL93 recognizes the acetylated amino-terminal sequence (L.S. Frost, J.S. Lee, D.G. Scraba, and W. Paranchych, J. Bacteriol. 168:192-198, 1986). As expected, neither antibody reacted with inner membranes from F- cells or Flac derivatives that do not synthesize pilin. Mutations that affected the individual activities of F tra genes traA, -B, -C, -D, -E, -F, -G, -H, -I, -J, -K, -L, -M, -N, -P, -R, -U, -V and -W or trb genes trbA, -B, -C, -D, -E, -G, -H, and -I did not prevent JEL92 or JEL93 recognition of membrane pilin. However, Hfr deletion mutants that lacked the most-distal transfer region genes did not express pilin that reacted with JEL93. Nevertheless, all strains that retained traA and traQ did express JEL92-reactive pilin polypeptides. Analysis of strains expressing cloned tra segments showed that traA and traQ suffice for synthesis of JEL92-reactive pilin, but synthesis of JEL93-reactive pilin is additionally dependent on traX. We concluded that the traX product is required for acetylation of F pilin. Interestingly, our data also showed that TraA+ TraQ+ cells synthesize two forms of pilin which migrate at approximately 7 and 8 kDa. In TraX+ cells, both become acetylated and react with JEL93. Preparations of wild-type F-pilus filaments contain both types of subunits.     

Characterization of Pyruvate Uptake in Escherichia coli K-12

The monocarboxylate pyruvate is an important metabolite and can serve as sole carbon source for Escherichia coli. Although specific pyruvate transporters have been identified in two bacterial species, pyruvate transport is not well understood in E. coli. In the present study, pyruvate transport was investigated under different growth conditions. The transport of pyruvate shows specific activities depending on the growth substrate used as sole carbon source, suggesting the existence of at least two systems for pyruvate uptake: i) one inducible system and probably highly specific for pyruvate and ii) one system active under non-induced conditions. Using the toxic pyruvate analog 3-fluoropyruvate, a mutant was isolated unable to grow on and transport pyruvate. Further investigation revealed that a revertant selected for growth on pyruvate regained the inducible pyruvate transport activity. Characterization of pyruvate excretion showed that the pyruvate transport negative mutant accumulated pyruvate in the growth medium suggesting an additional transport system for pyruvate excretion. The here presented data give valuable insight into the pyruvate metabolism and transport of E. coli suggesting the presence of at least two uptake systems and one excretion system to balance the intracellular level of pyruvate.     

Chromosome transfer and Hfr formation by F in rec+ and recA strains of Escherichia coli K12.

We attempted to assess the role of Hfr clones in chromosome transfer by F⁺ populations. We thought that any Hfr-independent component of fertility might be affected to a different extent by the recA mutation than was the Hfr component. However, the rate of Hfr formation and the efficiency of chromosome transfer were reduced to an equal extent (× 100-fold) by the recA mutation. Such experiments therefore provide no evidence for an Hfr-independent component. It appeared that Type II strains, which were thought to suffer a defect in Hfr formation, actually produced fertile clones but had a secondary defect which affected the persistence of these clones. Thus, evidence from Type II strains is also not useful for examining the quantitative contribution of Hfr cells to F⁺ transfer.     

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.