Location of F plasmid transfer operon genes traC and traW and identification of the traW product.

As part of an analysis of the conjugative transfer genes associated with the expression of F pili by plasmid F, we have investigated the physical location of the traC and traW genes. We found that plasmid clones carrying a 2.95-kilobase EcoRI-EcoRV F transfer operon fragment were able to complement transfer of F lac traC mutants and expressed an approximately 92,000-dalton product that comigrates with TraC. We also found that traW-complementing activity was expressed from plasmids carrying a 900-base-pair SmaI-HincII fragment. The traW product was identified as an approximately 23,000-dalton protein. The two different F DNA fragments that expressed traC and traW activities do not overlap. Our data indicate that the traC gene is located in a more-tra operon promoter-proximal position than suggested on earlier maps and that traW is distal to traC. These results resolve a long-standing question concerning the relationship of traW to traC. The clones we have constructed are expected to be useful in elucidating the role of proteins TraC and TraW in F-pilus assembly.     

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.     

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.     

Physical mapping of the conjugative bacteriocin plasmid pPD1 of Enterococcus faecalis and identification of the determinant related to the pheromone response.

The pheromone-responding conjugative bacteriocin plasmid pPD1 (59 kb) of Enterococcus faecalis was mapped physically by using a relational clone approach, and transposon analysis with Tn917 (Emr) or Tn916 (Tcr) facilitated the location of the bacteriocin-related genes in a segment of about 6.7 kb. Tn917 insertions within a 3-kb region resulted in constitutive clumping. The nucleotide sequence of the region that included the insertions giving rise to constitutive clumping was determined. The region of pPD1 spanned about 8 kb and was found to contain a number of open reading frames, some of which were named on the basis of homologies with two other pheromone-responding plasmids, pAD1 and pCF10. The genes were arranged in the sequence repB-repA-traC-traB-traA-ipd-traE-traF- orfY-sea-1 with all but repB and traA oriented in the same (left-to-right) direction. traC and traB corresponded, respectively, to traC and traB of pAD1 and to prgY and prgZ of pCF10.     

A new activity in the Ftra operon which is required for F-pilin synthesis

Summary Membrane preparations from a series of Hfr mutant strains of Escherichia coli K12 deleted in the promoter distal end of the F transfer operon were analyzed. Deletions which extended into traG, as expected, had no discernible effect on synthesis of membrane F-pilin. A more extensive deletion in strain KI777 which eliminated traH activity similarly had no effect on F-pilin synthesis. Membranes from three other TraF⁺ TraH^- deletion strains, as well as membranes from all strains carrying deletions extending into traF or further, lacked F-pilin, however. Since traH amber mutations do not affect synthesis of membrane pilin (Moore et al. 1981 b) we conclude that a gene required for F-pilin biosynthesis is located between traF and traH. We have named this gene traQ.Further evidence for traQ and an assay for its activity was obtained by examining the products of a TraM⁺ TraJ⁺ TraA⁺ lambda transducing phage, KI13, in UV irradiated cells. Infection of F^- cells with KI13 does not result in F-pilin synthesis. Membrane pilin is synthesized as a product of the transducing phage if an Flac or Hfr irradiated host is used, however. Mutant analysis demonstrated that this synthesis is independent of host expression of traA, traL, traE, traK, traB, traV, traW, traC, traU, traF, or traH, but dependent on expression of the traF-traH region. We interpret our data to indicate that an activity encoded by traQ is required for the conversion of traA product to F-pilin.     

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.     

The tra region of the nopaline-type Ti plasmid is a chimera with elements related to the transfer systems of RSF1010, RP4, and F.

The Ti plasmids of Agrobacterium tumefaciens encode two transfer systems. One mediates the translocation of the T-DNA from the bacterium to a plant cell, while the other is responsible for the conjugal transfer of the entire Ti plasmid from one bacterium to another. The determinants responsible for conjugal transfer map to two regions, tra and trb, of the nopaline-type Ti plasmid pTiC58. By using transposon mutagenesis with Tn3HoHo1, we localized the tra determinants to an 8.5-kb region that also contains the oriT region. Fusions to lacZ formed by transposon insertions indicated that this region is expressed as two divergently transcribed units. We determined the complete nucleotide sequence of an 8,755-bp region of the Ti plasmid encompassing the transposon insertions defining tra. The region contains six identifiable genes organized as two units divergently transcribable from a 258-bp inter-genic region that contains the oriT site. One unit encodes traA, traF, and traB, while the second encodes traC, traD, and traG. Reporter insertions located downstream of both sets of genes did not affect conjugation but were expressed, suggesting that the two units encode additional genes that are not involved in transfer under the conditions tested. Proteins of the predicted sizes were expressible from traA, traC, traD, and traG. The products of several Ti plasmid tra genes are related to those of other conjugation systems. The 127-kDa protein expressed from traA contains domains related to MobA of RSF1O1O and to the helicase domain of TraI of plasmid F. The translation product of traF is related to TraF of RP4, and that of traG is related to TraG of RP4 and to VirD4 of the Ti plasmid T-DNA transfer system. Genetic analysis indicated that at least traG and traF are essential for conjugal transfer, while sequence analysis predicts that traA also encodes an essential function. traB, while not essential, is required for maximum frequency of transfer. Patterns of sequence relatedness indicate that the oriT and the predicted cognate site-specific endonuclease encoded by traA share lineage with those of the transfer systems of RSF1010 and plasmid F, while genes of the Ti plasmid encoding other essential tra functions share common ancestry with genes of the RP4 conjugation system.     

Nucleotide sequence and characterization of the traABCD region of IncI1 plasmid R64.

A 3.6-kb BglII-SmaI segment of the transfer region of IncI1 plasmid R64drd-11 was sequenced and characterized. Analysis of the DNA sequence indicated the presence of four genes, traA, traB, traC, and traD, in this region. The expression of the traB, traC, and traD genes was examined by maxicell experiments and that of the traA gene was examined by constructing the traA-lacZ fusion gene. The introduction of frameshift mutations into the four genes indicated that the traB and traC genes are essential for conjugal transfer in liquid medium and on a solid surface. Both were also required for the formation of the thin pilus, which is the receptor for phages I alpha and PR64FS. Upstream of the traA gene, a promoter sequence for sigma 70 of E. coli RNA polymerase was identified by S1 nuclease mapping and primer extension experiments.     

Evidence that F-plasmid proteins TraV, TraK and TraB assemble into an envelope-spanning structure in Escherichia coli

We have examined the role of the F-plasmid TraV outer membrane lipoprotein in the assembly of F-pili. Yeast two-hybrid analysis with a traV bait repeatedly identified traK, which is predicted to encode a periplasmic protein, among positive prey plasmids. A traK bait in turn identified traV and traB, which is predicted to encode an inner membrane protein. A traB bait exclusively identified traK preys. Several additional observations support the hypothesis that TraV, TraK and TraB form a complex in Escherichia coli that spans the cell envelope from the outer membrane (TraV) through the periplasm (TraK) to the inner membrane (TraB). First, two-hybrid analyses indicated that TraV and TraB bind to different TraK segments, as required if TraK bridges a ternary complex. Secondly, all three proteins fractionated with the E. coli outer membrane in tra+ cells. In contrast, TraB fractionated with the inner membrane in traV or traK mutant cells, and TraK appeared in the osmotic shock fluid from the traV mutant. These results are consistent with a TraV-TraK-TraB complex anchored to the outer membrane via the TraV lipoprotein. Further, in traK mutant cells, TraV failed to accumulate to a detectable level, and the TraB level was significantly reduced, suggesting that TraV and TraB must interact with TraK for either protein to accumulate to its normal level. Both TraK and TraV accumulated in traB2[Am] cells; however, the TraB2 amber fragment could be detected by Western blot, and sequence analysis indicated that the fragment retained the TraK-binding domain suggested by yeast two-hybrid analysis. We propose that TraV is the outer membrane anchor for a trans-envelope, Tra protein structure required for the assembly of F-pili and possibly for other events of conjugal DNA transfer.     

Gene organization and nucleotide sequence of the primase region of IncP plasmids RP4 and R751.

The primase genes of RP4 are part of the primase operon located within the Tra1 region of this conjugative plasmid. The operon contains a total of seven transfer genes four of which (traA, B, C, D) are described here. Determination of the nucleotide sequence of the primase region confirmed the existence of an overlapping gene arrangement at the DNA primase locus (traC) with in-phase translational initiation signals. The traC gene encodes two acidic and hydrophilic polypeptide chains of 1061 (TraC1) and 746 (TraC2) amino acids corresponding to molecular masses of 116,721 and 81,647 Da. In contrast to RP4 the IncP beta plasmid R751 specifies four large primase gene products (192, 152, 135 and 83 kDa) crossreacting with anti-RP4 DNA primase serum. As shown by deletion analysis at least the 135 and 83 kDa polypeptides are two separate translational products that by analogy with the RP4 primases, arise from in-phase translational initiation sites. Even the smallest primase gene products TraC2 (RP4) and TraC4 (R751) exhibit primase activity. Nucleotide sequencing of the R751 primase region revealed the existence of three in-phase traC translational initiation signals leading to the expression of gene products with molecular masses of 158,950 Da, 134,476 Da, and 80,759 Da. The 192 kDa primase polypeptide is suggested to be a fusion protein resulting from an in frame translational readthrough of the traD UGA stopcodon. Distinct sequence similarities can be detected between the TraC proteins of RP4 and R751 gene products TraC3 and TraC4 and in addition between the TraD proteins of both plasmids. The R751 traC3 gene contains a stretch of 507 bp which is unrelated to RP4 traC or any other RP4 Tra1 gene.     

Analysis of the transfer region of the Streptomyces plasmid SCP2*

plJ903, a bifunctional derivative of the 31.4 kb low-copy number, conjugative Streptomyces plasmid SCP², was mutagenized in Streptomyces lividans using Tn4560. Mutant plasmids differing in their transfer frequencies, chromosome mobilization abilities, pock formation, and complementation properties were isolated. The mutations defined five transfer-related genes, traA, traB, traC, traD and spd, clustered in a region of 9 kb. The deduced sequences of the putative TraA and TraB proteins showed no overall similarity to known protein sequences, but the phenotype of traA mutant plasmids and sequence motifs in the putative TraA protein suggested that it might be a DNA helicase.     

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.     

Cloning, expression, and mapping of the Aeromonas hydrophila aerolysin gene determinant in Escherichia coli K-12.

DNA sequences corresponding to the aerolysin gene (aer) of Aeromonas hydrophila AH2 DNA were identified by screening a cosmid gene library for hemolytic and cytotoxic activities. A plasmid containing a 5.8-kilobase EcoRI fragment of A. hydrophila DNA was required for full expression of the hemolytic and cytotoxic phenotype in Escherichia coli K-12. Deletion analysis and transposon mutagenesis allowed us to localize the gene product to 1.4 kilobases of Aeromonas DNA and define flanking DNA regions affecting aerolysin production. The reduced hemolytic activity with plasmids lacking these flanking regions is associated with a temporal delay in the appearance of hemolytic activity and is not a result of a loss of transport functions. The aerolysin gene product was detected as a 54,000-dalton protein in E. coli maxicells harboring aer plasmids and by immunoblotting E. coli whole cells carrying aer plasmids. We suggest that the gene coding aerolysin be designated aerA and that regions downstream and upstream of aerA which modulate its expression and activity be designated aerB and aerC, respectively.     

Physical and genetic characterization of the melibiose operon and identification of the gene products in Escherichia coli

We have identified hybrid plasmids carrying the melibiose operon of Escherichia coli in a colony bank of Clarke and Carbon (Tsuchiya, T., Ottina, K., Moriyama, Y., Newman, M., and Wilson, T. H. (1982) J. Biol. Chem. 257, 5125-5128). Using one of the plasmids as a starting material, the DNA fragments containing the melibiose operon were recloned in a vector pBR322. Restriction maps were prepared, and several DNA segments were subcloned into pBR322. Genetic complementation tests and recombination analyses using those plasmids and melA- and melB- mutants as well as biochemical analyses of mel mutants transformed with those plasmids enabled us to determine the physical location of promoter, melA, and melB on the DNA segment. The size of the melAB region was about 3,000 base pairs. Gene products were identified using maxicells harboring plasmids carrying the melibiose operon. The apparent molecular weight of the alpha-galactosidase (coded by melA) was about 50,000 and that of the melibiose carrier (coded by melB) was about 31,000, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The melibiose carrier was also identified as a 30,000-dalton protein in reconstituted proteoliposomes which possessed melibiose transport activity.     

Regulation of the pAD1 sex pheromone response in Enterococcus faecalis: effects of host strain and traA, traB, and C region mutants on expression of an E region pheromone-inducible lacZ fusion.

Pheromone-induced conjugal transfer of the hemolysin-bacteriocin plasmid pAD1 of Enterococcus faecalis is regulated by a cluster of determinants designated traA, traB, and regions C and E. The E region is believed to include a positive regulator that controls many structural genes related to conjugation. The pheromone-inducible Tn917-lac fusion NR5, located in the E region, is regulated by the products of traA, traB, and the C region. To more closely examine the effects of these genes on the induction of E region products, inserts in each of these genes were combined with the NR5 fusion in a novel approach involving triparental matings with a pAD1 miniplasmid and recombinational mutagenesis. Results indicate that (i) the traA gene product is a key repressor of the pheromone response; (ii) the traB gene product, in cooperation with a gene within or regulated by the E region, controls pheromone shutdown; (iii) a primary function of the C region gene product is in pheromone sensing, with secondary functions in pheromone shutdown and negative regulation; and (iv) the host in which the plasmid resides has a dramatic effect on the regulation of the NR5 fusion in traB and C region mutants. Numerous parallels were observed between the regulation of the NR5 fusion and the regulation of the aggregation and transfer response. These parallels aided in further defining the functions of particular regulatory determinants as well as further establishing the link between the regulation of the E region and the regulation of the aggregation and transfer response.     

Deletion Map of the Escherichia coli K-12 Sex Factor F: the Order of Eleven Transfer Cistrons

A series of Hfr deletion mutants was isolated. These mutants contain deletions which extend from a lambda prophage into an Flac which is integrated into the gal operon. Transfer-deficient deletion mutants were found to fall into four different phenotypic groups when tested for male- and female-specific phage resistance. Conjugational and transductional complementation tests with Flac point mutants deficient in transfer (tra(-)) were performed, and the order of 11 tra cistrons was determined. The tra genes are all located between an F gene for the inhibition of female-specific phages and the transposed lac operon originally carried by the Flac. The order of genes in the Hfr studied was established to be: proC... phi(II) (R)... traJ traA traE traK traB traC traF traH traG traD traI...lac...attlambda...bio.     

Characterization of the F-plasmid conjugative transfer gene traU.

We characterized the traU gene of the Escherichia coli K-12 conjugative plasmid F. Plasmids carrying segments of the F transfer operon were tested for their capacity to complement F lac traU526. The protein products of TraU+ clones were identified, and the nucleotide sequence of traU was determined. traU mapped between traW and trbC. It encodes a 330-amino-acid, Mr36,786 polypeptide that is processed. Ethanol caused accumulation of a precursor polypeptide; removal of ethanol permitted processing of the protein to occur. Because F lac traU526 strains appear to be resistant to F-pilus-specific phages, traU has been considered an F-pilus assembly gene. However, electron microscopic analysis indicated that the traU526 amber mutation caused only a 50% reduction in F-piliation. Since F lac traU526 strains also retain considerable transfer proficiency, new traU mutations were constructed by replacing a segment of traU with a kanamycin resistance gene. Introduction of these mutations into a transfer-proficient plasmid caused a drastic reduction in transfer proficiency, but pilus filaments remained visible at approximately 20% of the wild-type frequency. Like traU526 strains, such mutants were unable to plaque F-pilus-specific phages but exhibited a slight sensitivity on spot tests. Complementation with a TraU+ plasmid restored the wild-type transfer and phage sensitivity phenotypes. Thus, an intact traU product appears to be more essential to conjugal DNA transfer than to assembly of pilus filaments.     

Revised genetic map of the distal end of the F transfer operon: implications for DNA helicase I, nicking at oriT, and conjugal DNA transport.

The DNA transfer stage of conjugation requires the products of the F sex factor genes traMYDIZ and the cis-acting site oriT. Previous interpretation of genetic and protein analyses suggested that traD, traI, and traZ mapped as contiguous genes at the distal end of the transfer operon and saturated this portion of the F transfer region (which ends with an IS3 element). Using antibodies prepared against the purified TraD and TraI proteins, we analyzed the products encoded by a collection of chimeric plasmids constructed with various segments of traDIZ DNA. We found the traI gene to be located 1 kilobase to the right of the position suggested on previous maps. This creates an unsaturated space between traD and traI where unidentified tra genes may be located and leaves insufficient space between traI and IS3 for coding the 94-kilodalton protein previously thought to be the product of traZ. We found that the 94-kilodalton protein arose from a translational restart and corresponds to the carboxy terminus of traI; we named it TraI*. The precise physical location of the traZ gene and the identity of its product are unknown. The oriT nicking activity known as TraZ may stem from unassigned regions between traD and traI and between traI and IS3, but a more interesting possibility is that it is actually a function of traI. On our revised map, the position of a previously detected RNA polymerase-binding site corresponds to a site at the amino terminus of traI rather than a location 1 kilobase into the coding region of the gene. Furthermore, the physical and genetic comparison of the F traD and traI genes with those of the closely related F-like conjugative plasmids R1 and R100 is greatly simplified. The translational organization we found for traI, together with its identity as the structural gene for DNA helicase I, suggests a possible functional link to several other genes from which translational restart polypeptides are expressed. These include the primases of the conjugative plasmids ColI and R16, the primase-helicase of bacteriophage T7, and the cisA product (nickase) of phage phi X174.     

Organization of K88ac-encoded polypeptides in the Escherichia coli cell envelope: use of minicells and outer membrane protein mutants for studying assembly of pili

Escherichia coli K-12 minicells, harboring recombinant plasmids encoding polypeptides involved in the expression of K88ac adhesion pili on the bacterial cell surface, were labeled with [35S]methionine and fractionated by a variety of techniques. A 70,000-dalton polypeptide, the product of the K88ac adhesion cistron adhA, was primarily located in the outer membrane of minicells, although it was less clearly associated with this membrane than the classical outer membrane proteins OmpA and matrix protein. Two polypeptides of molecular weights 26,000 and 17,000 (the products of adhB and adhC, respectively) were located in significant amounts in the periplasmic space. The 29,000-dalton polypeptide was shown to be processed in E. coli minicells. The 23.500-dalton K88ac pilus subunit (the product of adhD) was detected in both inner and outer membrane fractions. E. coli mutants defective in the synthesis of murein lipoprotein or the major outer membrane polypeptide OmpA were found to express normal amounts of K88ac antigen on the cell surface, whereas expression of the K88ac antigen was greatly reduced in perA mutants. The possible functions of the adh cistron products are discussed.