Characterization, localization, and sequence of F transfer region products: the pilus assembly gene product TraW and a new product, TrbI.

The traW gene of the Escherichia coli K-12 sex factor, F, encodes one of the numerous proteins required for conjugative transfer of this plasmid. We have found that the nucleotide sequence of traW encodes a 210-amino-acid, 23,610-Da polypeptide with a characteristic amino-terminal signal peptide sequence; in DNA from the F lac traW546 amber mutant, the traW open reading frame is interrupted at codon 141. Studies of traW expression in maxicells in the presence and absence of ethanol demonstrate that the traW product does undergo signal sequence processing. Cell fractionation experiments additionally demonstrated that mature TraW is a periplasmic protein. Electron microscopy also showed that F lac traW546 hosts do not express F pili, confirming that TraW is required for F-pilus assembly. Our nucleotide sequence also revealed the existence of an additional gene, trbI, located between traC and traW. The trbI gene encodes a 128-amino-acid polypeptide which could be identified as a 14-kDa protein product. Fractionation experiments demonstrated that TrbI is an intrinsic inner-membrane protein. Hosts carrying the pOX38-trbI::kan insertion mutant plasmids that we constructed remained quite transfer proficient but exhibited increased resistance to F-pilus-specific phages. Mutant plasmids pOX38-trbI472 and pOX38-trbI473 expressed very long F pili, suggestive of a pilus retraction deficiency. Expression of an excess of TrbI in hosts carrying a wild-type pOX38 plasmid also caused F-pilus-specific phage resistance. The possibility that TrbI influences the kinetics of pilus outgrowth and/or retraction is discussed.     

Characterization of trbC, a new F plasmid tra operon gene that is essential to conjugative transfer.

We have characterized a previously unidentified gene, trbC, which is contained in the transfer region of the Escherichia coli K-12 fertility factor, F. Our data show that the trbC gene is located between the F plasmid genes traU and traN. The product of trbC was identified as a polypeptide with an apparent molecular weight (Ma) of 23,500 that is processed to an Ma-21,500 mature protein. When ethanol was present, the Ma-23,500 polypeptide accumulated; the removal of ethanol resulted in the appearance of the processed mature protein. Subcellular fractionation experiments demonstrated that the processed, Ma-21,500 mature protein was located in the periplasm. DNA sequence analysis showed that trbC encodes a 212-amino-acid Mr-23,432 polypeptide that could be processed to a 191-amino-acid Mr-21,225 mature protein through the removal of a typical amino-terminal signal sequence. We also constructed two different Kmr gene insertion mutations in trbC and crossed these onto the transmissible F plasmid derivative pOX38. We found that cells carrying pOX38 trbC mutant plasmids were transfer deficient and resistant to infection by F-pilus-specific phages. Transfer proficiency and bacteriophage sensitivity were restored by complementation when a trbC+ plasmid clone was introduced into these cells. These results showed that trbC function is essential to the F plasmid conjugative transfer system and suggested that the TrbC protein participates in F-pilus assembly.     

Construction and characterization of derivatives carrying insertion mutations in F plasmid transfer region genes, trbA, artA, traQ, and trbB.

We devised a method for construction of insertion mutations in F plasmid tra region genes as a means of investigating the functions associated with previously uncharacterized loci. First, we constructed mutations in vitro, by insertion of a kanamycin resistance gene into a unique restriction site within a tra region fragment carried by a small, chimeric plasmid. Second, we crossed the insertion mutations, in vivo, onto a plasmid containing the complete F tra region sequence (either F lac, or pOX38, a Tra+ F plasmid derivative). Using this method, we obtained F lac mutant derivatives carrying KmR gene insertions in traQ, and a set of pOX38 mutant derivatives carrying a KmR gene insertion in trbA, artA, traQ, or trbB. Analysis of these derivatives showed that insertion of a kan gene at the NsiI site of traQ resulted in transfer deficiency, F-pilus-specific-phage resistance and an absence of detectable F-pilin subunit synthesis. Since the traQ mutants regained a wild-type phenotype when complemented with a traQ+ plasmid clone, we concluded that traQ expression is essential to transfer and F-pilus synthesis. However, pOX38 derivatives carrying kan gene inserts in genes trbA, artA, or trbB retained F-pilus-specific phage sensitivity and transferred at normal levels. Thus, these three gene products may not be essential for F-transfer from Escherichia coli K-12 under standard mating conditions.     

DNA sequence analysis of point mutations in traA, the F pilin gene, reveal two domains involved in F-specific bacteriophage attachment

Summary Six missense point mutations in traA (WPFL43,44,45,46,47 and 51), the gene encoding F pilin in the transfer region of the F plasmid, have been characterized for their effect on the transfer ability, bacteriophage (R17, QB and fl) sensitivity and levels of piliation expressed by the plasmid. The sequence analysis of the first five of these mutations revealed two domains in the F pilin subunit exposed on the surface of the F pilus which mediate phage attachment. These two domains include residues 14–17 (approximately) and the last few residues at the carboxy-terminus of the pilin protein. One of these mutants had a pleiotropic affect on pilus function and was thought to have affected pilus assembly. The sixthe point mutant (WPFL51), previously thought to be in traA, was complemented by chimeric plasmids carrying the traG gene of the F transfer region, which may be involved in the acetylation of the pilin subunit. A traA nonsense mutant (JCFL1) carried an amber mutation near the amino-terminus which is well suppressed in SuI⁺ (supD) and SuIII⁺ (supF) strains. Neither the antigenicity of the pilin nor the efficiency of plating of F-specific bacteriophages were affected when this plasmid was harbored by either suppressor strain. A second amber mutant (JCFL25) which is not suppressible, carried its mutation in the codon for the single tryptophan in F pilin, suggesting that this residue is important in subunit interactions during pilus assembly. Two other point mutants (JCFL32 and 44) carried missense mutations in the leader sequence (positions 9 and 13) which affected the number of pili per cell presumably by altering the processing of propilin to pilin.     

A traC mutant that retains sensitivity to f1 bacteriophage but lacks F pili.

An F lac pro mutant which was temperature sensitive for infection by the filamentous bacteriophage f1 but resistant to the F-specific icosahedral RNA phage f2 was isolated. Cells carrying the F' mutation failed to elaborate F pili at all temperatures. Mutant cells were able to pair with recipient cells during bacterial conjugation, but transfer of conjugal DNA occurred at a greatly reduced frequency. Complementation analyses showed the F' mutation to be in the traC gene. When a plasmid carrying traC was introduced into hosts harboring the F' mutation, phage sensitivity, the ability to elaborate F pili, and conjugation efficiency were restored. The mutation was named traC1044. The F lac pro traC1044 mutant appears to be unique among traC mutants in retaining host sensitivity to the filamentous phage f1 in the absence of expression of extended F pili. Phage f1 attachment sites appeared to be present at the cell surface in traC1044 mutants. The reduced accessibility of these sites may account for the reduced efficiency of phage f1 infection of traC1044 hosts, although the possibility that a defect was present in the receptor site itself was not eliminated. Membranes of hosts carrying the F' mutation contained a full complement of mature F-pilin subunits, so the product of traC is presumably required for pilus assembly but not for pilin processing. This, together with the deficiency in conjugal DNA transfer, suggests that traC may be part of a membrane-spanning tra protein complex responsible for pilus assembly and disassembly and conjugal DNA transmission.     

Serological characteristics of pili determined by the plasmids R711b and F0lac.

The plasmids R711b (at present IncX) and F0lac (IncFV) both determine pili morphologically like those of F (IncFI), and confer sensitivity to the F-specific filamentous bacteriophages, but not to the F-specific isometric RNA phages. Detailed serological studies show that the two pilus types are unrelated, and that neither is related to any of the previously defined F pilus serotypes. Adsorption of the isometric RNA phage MS2 to R711b pili occurs in the presence but not in the absence of formalin, which presumably prevents elution of reversibly adsorbed virions. No adsorption occurs with F0lac pili. MS2 multiplication, as measured by titre increase tests in liquid medium, is found with neither plasmid. The two plasmids are not incompatible. These observations indicate that R744b and F0lac are different both from one another and from the plasmids belonging to the incompatibility groups IncFI--IV.     

Bacteriophages F0lac h, SR, SF: phages which adsorb to pili encoded by plasmids of the S-complex

Phage F0lac is an RNA-containing phage which plates only on strains carrying the plasmid EDP208, a pilus derepressed derivative of the unique incompatibility plasmid F0lac. A host range mutant, phage F0lac h, was selected which plated on strains carrying the ungrouped plasmid pPLS::Tn5 and lysed strains carrying another ungrouped plasmid TP224::Tn10 or the Com9 plasmid R71. An RNA-containing phage, SR, was isolated from sewage on bacteria harbouring plasmid pPLS::Tn5. It was antigenically distinct from the above two phages but had the same host range as phage F0lac h. Phages F0lac h and SR adsorbed unevenly to the shafts of the conjugative pili. Another phage, SF, was filamentous and plated or propagated on strains carrying any of the above plasmids as well as on strains harbouring IncD or F-complex plasmids. Plasmids TP224::Tn10 and pPLS::Tn5 were compatible with representative plasmids of all Inc groups also encoding thick flexible pili. The four plasmids EDP208, R71, TP224::Tn10 and pPLS::Tn5 were compatible with one another except for the reaction of TP224::Tn10 in the presence of pPLS::Tn5 which was slightly ambiguous. The host ranges of the bacteriophages, together with the serological relatedness of the thick flexible pili determined by these four compatible plasmids, suggested that they constitute a new complex, here designated S.     

Sequence alterations affecting F plasmid transfer gene expression: a conjugation system dependent on transcription by the RNA polymerase of phage T7

We constructed derivatives of the Escherichia coli conjugative plasmid F that carry altered sequences in place of the major transfer operon promoter, PY. Replacement of PY with a promoter-deficient sequence resulted in a transfer-deficient, F-pilus-specific phage-resistant plasmid (pOX38-tra701) that could still express TraJ and TraT; TraY, F-pilin, TraD, and TraI were not detectable on Western blots. On a second plasmid (pOX38-tra715) we replaced PY with a phage T7 late promoter sequence. In hosts carrying a lacUV5-promoter-regulated T7 RNA polymerase gene, all transfer-associated properties of pOX38-tra715 could be regulated with IPTG. After induction, pOX38-tra715 transferred at the wild-type frequency, expressed normal numbers of F-pili and conferred sensitivity to pilus-specific phages. No adverse effects on cell viability were apparent, and additional mutations could easily be crossed onto pOX38-tra715. A traJ deletion (pOX38-tra716) had no effect on the IPTG-induced transfer phenotype. Insertion of cam into trbC, resulted in a mutant (pOX38-tra715trbC33) which, after induction, exhibited the same phenotype associated with other trbC mutants; it could also be complemented by expression of trbC in trans. With pOX38-tra715 or its derivatives, we were able to label specifically the products of tra genes located throughout the long tra operon, by using rifampicin. This feature can be used to investigate transfer protein interactions and to follow changes in these proteins that are associated with conjugal mating events.     

The effect of tra mutations on the synthesis of the F-pilin membrane polypeptide

Summary We had previously demonstrated that several F specific polypeptide bands could be detected in the membranes of Flac, but not F^- strains of Escherichia coli K 12, (Moore et al. 1981). One of these polypeptides co-migrated with F-pilin protein on polyacrylamide gels. We have now analyzed ³⁵[S]methionine labelled membrane preparations from a series of strains containing Flac tra mutant plasmids. The F-pilin polypeptide was absent from preparations of strains containing all traA mutants tested, confirming the importance of the traA gene in F-pilin biosynthesis. A polypeptide which migrated in the F-pilin position was still present, however, in membranes prepared from Flac strains carrying mutations in traL, traE, traK, traB, traV, traW, traC, traU, traF, traH or traG despite the inability of these mutants to elaborate F-pili filaments. Thus, all of these gene products may be concerned with F-pilus assembly and outgrowth rather than biosynthesis of the F-pilin subunit. The polar mutation tra-4 did, however, prevent the appearance of pilin polypeptide, indicating that at least one unidentified gene in the region between traE and traG must also be required in F-pilin biosynthesis.Our analysis also permitted the identification of a 100,000 dalton membrane protein as the product of traG. The appearance of an F specific 12,000 dalton protein was prevented by traD amber mutants. As expected, traJ mutants prevented the expression of all the tra operon products detected except the product of traT. The traT product band was reduced only to 50–60% of its normal intensity.     

Analysis and characterization of the IncFV plasmid pED208 transfer region

pED208 is a transfer-derepressed mutant of the IncFV plasmid, F(0)lac, which has an IS2 element inserted in its traY gene, resulting in constitutive overexpression of its transfer (tra) region. The pED208 transfer region, which encodes proteins responsible for pilus synthesis and conjugative plasmid transfer, was sequenced and found to be very similar to the F tra region in terms of its organization although most pED208 tra proteins share only about 45% amino acid identity. All the essential genes for F transfer had homologs within the pED208 transfer region with the exception of traQ, which encodes the chaperone for stable F-pilin expression. F(0)lac appears to have a fertility inhibition system different than the FinOP system of other F-like plasmids, and its transfer efficiency was increased in the presence of F or R100, suggesting that it could be mobilized by these plasmids. The F-like transfer systems specified by F, R100, and F(0)lac were highly specific for their cognate origins of transfer (oriT) as measured by their abilities to mobilize chimeric oriT-containing plasmids.     

High-level expression of the FtsA protein inhibits cell septation in Escherichia coli K-12.

DNA fragments encoding the ftsA gene were subcloned into plasmids downstream of a lac promoter or a tac promoter. These plasmid constructs, when transformed into wild-type and mutant strains, inhibited normal cell septation, causing the formation of long nonseptate filaments. This phenotype is due to overproduction of the FtsA protein.     

Role of Agrobacterium VirB11 ATPase in T-pilus assembly and substrate selection

The VirB11 ATPase is a subunit of the Agrobacterium tumefaciens transfer DNA (T-DNA) transfer system, a type IV secretion pathway required for delivery of T-DNA and effector proteins to plant cells during infection. In this study, we examined the effects of virB11 mutations on VirB protein accumulation, T-pilus production, and substrate translocation. Strains synthesizing VirB11 derivatives with mutations in the nucleoside triphosphate binding site (Walker A motif) accumulated wild-type levels of VirB proteins but failed to produce the T-pilus or export substrates at detectable levels, establishing the importance of nucleoside triphosphate binding or hydrolysis for T-pilus biogenesis. Similar findings were obtained for VirB4, a second ATPase of this transfer system. Analyses of strains expressing virB11 dominant alleles in general showed that T-pilus production is correlated with substrate translocation. Notably, strains expressing dominant alleles previously designated class II (dominant and nonfunctional) neither transferred T-DNA nor elaborated detectable levels of the T-pilus. By contrast, strains expressing most dominant alleles designated class III (dominant and functional) efficiently translocated T-DNA and synthesized abundant levels of T pilus. We did, however, identify four types of virB11 mutations or strain genotypes that selectively disrupted substrate translocation or T-pilus production: (i) virB11/virB11* merodiploid strains expressing all class II and III dominant alleles were strongly suppressed for T-DNA translocation but efficiently mobilized an IncQ plasmid to agrobacterial recipients and also elaborated abundant levels of T pilus; (ii) strains synthesizing two class III mutant proteins, VirB11, V258G and VirB11.I265T, efficiently transferred both DNA substrates but produced low and undetectable levels of T pilus, respectively; (iii) a strain synthesizing the class II mutant protein VirB11.I103T/M301L efficiently exported VirE2 but produced undetectable levels of T pilus; (iv) strains synthesizing three VirB11 derivatives with a four-residue (HMVD) insertion (L75.i4, C168.i4, and L302.i4) neither transferred T-DNA nor produced detectable levels of T pilus but efficiently transferred VirE2 to plants and the IncQ plasmid to agrobacterial recipient cells. Together, our findings support a model in which the VirB11 ATPase contributes at two levels to type IV secretion, T-pilus morphogenesis, and substrate selection. Furthermore, the contributions of VirB11 to machine assembly and substrate transfer can be uncoupled by mutagenesis.     

hisT is part of a multigene operon in Escherichia coli K-12.

The Escherichia coli K-12 hisT gene has been cloned, and its organization and expression have been analyzed on multicopy plasmids. The hisT gene, which encodes tRNA pseudouridine synthase I (PSUI), was isolated on a Clarke-Carbon plasmid known to contain the purF gene. The presence of the hisT gene on this plasmid was suggested by its ability to restore both production of PSUI enzymatic activity and suppression of amber mutations in a hisT mutant strain. A 2.3-kilobase HindIII-ClaI restriction fragment containing the hisT gene was subcloned into plasmid pBR322, and the resulting plasmid (designated psi 300) was mapped with restriction enzymes. Complementation analysis with different kinds of hisT mutations and tRNA structural analysis confirmed that plasmid psi 300 contained the hisT structural gene. Enzyme assays showed that plasmid psi 300 overproduced PSUI activity by ca. 20-fold compared with the wild-type level. Subclones containing restriction fragments from plasmid psi 300 inserted downstream from the lac promoter established that the hisT gene is oriented from the HindIII site toward the ClaI site. Other subclones and derivatives of plasmid psi 300 containing insertion or deletion mutations were constructed and assayed for production of PSUI activity and production of proteins in minicells. These experiments showed that: (i) the proximal 1.3-kilobase HindIII-BssHII restriction fragment contains a promoter for the hisT gene and encodes a 45,000-dalton polypeptide that is not PSUI; (ii) the distal 1.0-kilobase BssHII-ClaI restriction fragment encodes the 31,000-dalton PSUI polypeptide; (iii) the 45,000-dalton polypeptide is synthesized in an approximately eightfold excess compared with PSUI; and (iv) synthesis of the two polypeptides is coupled, suggesting that the two genes are part of an operon. Insertion of mini-Mu d1 (lac Km) phage into plasmid psi 300 confirmed that the hisT gene is the downstream gene in the operon.     

Conjugal transfer system of the IncN plasmid pKM101.

The conjugal transfer system of the broad-host range IncN plasmid pKM101 was analyzed genetically. Its organization differed significantly from that of the F plasmid. The tra genes are located in three regions, each between 3 and 4 kilobases in length. All of the genes in the first two regions are required for sensitivity to "donor-specific" phage which bind to the plasmid-mediated sex pilus, and these genes therefore are involved in the synthesis, and possibly retraction, of the sex pilus. The plasmid's origin of transfer was localized to a 1.2-kilobase region at an extreme end of the transfer region. Using two different methods, we have identified 11 complementation groups required for transfer. One of these, traC, is of special interest in that mutations at this locus can be partially suppressed if, prior to mating, cells carrying a traC mutant plasmid are incubated with cells which elaborate sex pili but are unable to transfer their plasmids. One possible explanation for this is that pilus-elaborating cells can donate traC gene product to a traC mutant in a form that can be reused.     

Construction of derivatives of the F plasmid pOX–tra715: characterization of traY and traD mutants that can be complemented in trans

A derivative of the F plasmid, pOX38– tra715 , expresses the entire F tra operon from a foreign promoter (P_T7) derived from phage T7. A series of plasmids related to pOX38– tra715 were constructed which carry either deletion mutations or point mutations in traY . When the P_T7 promoter was induced, these plasmids expressed the F pilus but were transfer deficient unless TraY was supplied in trans from compatible plasmids. Insertion of a kanamycin-resistance cassette in the traY gene of the pOX38 plasmid, which contains the wild-type P_Y promoter, resulted in loss of F piliation and transfer ability. Introduction of TraY in trans partially restored piliation and transfer suggesting that TraY has a role in positively regulating the P_Y promoter . pOX38– tra719–traD411 , which contains a chloramphenicol-resistance cassette in place of the kanamycin-resistance cassette in pOX38– tra715 and a mutation in traD , was constructed to demonstrate the utility of this series of plasmids in studying the long (30 kb) F tra operon.     

Repair of DNA double-strand breaks in Escherichia coli K12 requires a functional recN product

Summary Mutation of the recN gene of Escherichia coli in a recBC sbcB genetic background blocks conjugational recombination and confers increased sensitivity to UV light and mitomycin C. The basis for this phenotype was investigated by monitoring the properties associated with recN mutations in otherwise wild-type strains. It was established that recN single mutants are almost fully resistant to UV irradiation, and that there is no detectable defect in repair of UV lesions by excision, error-prone, or recombinational mechanisms. However, recN mutations confer sensitivity to mitomycin C and ionizing radiation both in wild-type and recB sbcB strains. The sensitivity to ionizing radiation is correlated with a deficiency in the capacity to repair DNA double-strand breaks by a UV inducible mechanism. Recombinant phages that complement the recombination and repair defects of recN recBC sbcB mutants have been identified, and the recN gene has been cloned from these phages into a low copy-number plasmid.     

Localization, cloning, and sequence determination of the conjugative plasmid ColB2 pilin gene.

ColB2 is a colicin-producing, 96-kilobase plasmid which encodes a conjugative system that is similar, but not identical, to F. A restriction map of this plasmid was generated, and DNA homology studies between F and ColB2 plasmids revealed homology only between their transfer operons. The locations of the ColB2 transfer operon and ColB2 pilin gene were localized on this restriction map. The gene encoding ColB2 pilin, traA, was cloned and sequenced. The pilin protein of ColB2 is identical to F, except at the amino terminus, where ala-gln of ColB2 pilin corresponds to Ala-Gly-Ser-Ser of F pilin. This is due to a 6-base-pair deletion in the ColB2 pilin gene. Biochemical studies on tryptic peptides derived from ColB2 pilin demonstrate the location of this gene to be correct. There is a putative signal peptidase cleavage site after the sequence Ala-Met-Ala, giving a signal peptide of 51 amino acids and a mature pilin protein of 68 amino acids (7,000 daltons). The amino terminus is blocked, probably with an acetyl group. A chimera containing the ColB2 pilin gene was able to complement an F traA mutant, demonstrating that the pilus assembly proteins of F can utilize the ColB2 pilin protein to form a pilus.