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 (PT7) 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 PT7 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 PY 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 PY 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.

Membrane insertion of the F-pilin subunit is Sec independent but requires leader peptidase B and the proton motive force.

F pilin is the subunit required for the assembly of conjugative pili on the cell surface of Escherichia coli carrying the F plasmid. Maturation of the F-pilin precursor, propilin, involves three F plasmid transfer products: TraA, the propilin precursor; TraQ, which promotes efficient propilin processing; and TraX, which is required for acetylation of the amino terminus of the 7-kDa pilin polypeptide. The mature pilin begins at amino acid 52 of the TraA propilin sequence. We performed experiments to determine the involvement of host cell factors in propilin maturation. At the nonpermissive temperature in a LepBts (leader peptidase B) host, propilin processing was inhibited. Furthermore, under these conditions, only full-length precursor was observed, suggesting that LepB is responsible for the removal of the entire propilin leader peptide. Using propilin processing as a measure of propilin insertion into the plasma membrane, we found that inhibition or depletion of SecA and SecY does not affect propilin maturation. Addition of a general membrane perturbant such as ethanol also had no effect. However, dissipation of the proton motive force did cause a marked inhibition of propilin processing, indicating that membrane insertion requires this energy source. We propose that propilin insertion in the plasma membrane proceeds independently of the SecA-SecY secretion machinery but requires the proton motive force. These results present a model whereby propilin insertion leads to processing by leader peptidase B to generate the 7-kDa peptide, which is then acetylated in the presence of TraX.

Role of the propilin leader peptide in the maturation of F pilin.

F-pilin maturation and translocation result in the cleavage of a 51-amino-acid leader sequence from propilin and require LepB and TraQ but not the SecA-SecY secretion pathway. The unusual propilin leader peptide and the dependence of its cleavage on TraQ suggested that TraQ recognition may be specific for the leader peptide. An in vitro propilin cleavage assay yielded propilin (13 kDa), the pilin polypeptide (7 kDa), and a 5.5-kDa protein as the traA products. The 5.5-kDa protein comigrates with the full-length 51-amino-acid leader peptide, and [14C]proline labeling confirmed its identity since the only proline residues of propilin are found within the leader peptide. The in vitro and in vivo propilin-processing reactions proceed similarly in a single polypeptide cleavage step. Furthermore, TraQ dependence is a property of F-pilin maturation specifically rather than a property of the leader peptide. A propilin derivative with an amino-terminal signal sequence generated by deleting codons 2 to 28 required TraQ for processing in vivo. On the other hand, a chimeric protein with the propilin wild-type leader peptide fused to the mature portion of beta-lactamase was processed in a TraQ-independent manner. Thus, despite its unusual length, the propilin leader peptide seems to perform a function similar to that of the typical amino-terminal signal sequence. This work suggests that TraQ is not necessary for the proteolysis of propilin and therefore is likely to act as a chaperone-like protein that promotes the translocation of propilin.

Analysis of the traLEKBP sequence and the TraP protein from three F-like plasmids: F, R100-1 and ColB2.

The sequence of a region of the F plasmid containing the traLEKBP genes involved in plasmid transfer was compared to the equivalent regions of two IncFII plasmids, R100-1 and ColB2. The traLEK gene products of all three plasmids were virtually identical, with the most changes occurring in TraE. The TraB genes were also nearly identical except for an 11-codon extension at the 3' end of the R100-1 traB gene. The TraP protein of R100-l differed from those of F and ColB2 at its N terminus, while the ColB2 TraP protein contained a change of sequence in a predicted loop which was shown to be exposed in the periplasmic space by TnphoA mutagenesis. The effect of the altered TraP sequences was determined by complementing a traP mutant with clones expressing the traKBP genes of F, R100-1, and ColB2. The traP mutation in pOX38 (pOX38-traP474), a derivative of F, was found to have little effect on pilus production, pilus retraction, and filamentous phage growth and only a moderate effect on transfer. The transfer ability of pOX38-traP474 was shown to be affected by mutations in the rfa (lipopolysaccharide) locus and in ompA in the recipient cell in a manner similar to that for the wild-type pOX38-Km plasmid itself and could be complemented with the traP analogs from R100-1 and ColB2 to give an F-like phenotype. Thus, the TraP protein appears to play a minor role in conjugation and may interact with TraB, which varies in sequence along with TraP, in order to stabilize the proposed transmembrane complex formed by the tra operon products.

Characterization of traX, the F plasmid locus required for acetylation of F-pilin subunits.

Acetylation of F-pilin subunits has previously been shown to depend upon expression of the F plasmid transfer operon gene traX. To assess the requirement for pilin acetylation in conjugative transfer of F, we constructed traX::kan insertion mutations and crossed them onto the transmissible F derivative pOX38. Under standard conditions, the function of traX seemed to be dispensable. Although pilin synthesized by mutant plasmids pOX38-traX482 and pOX38-traX483 was not acetylated, F-pilus production and F-pilus-specific phage infection appeared to be normal and transfer occurred at wild-type frequency. Analysis of labeled products showed that TraX+ plasmids expressed two approximately 24- (TraX1) and 22-kDa (TraX2) polypeptides that localized in the cytoplasmic membranes of cells. No product that was similar in size to the product predicted from the traX open reading frame (27.5 kDa) was detected. Therefore, we used site-directed mutagenesis, stop codon linker insertions, and phoA fusion analysis to investigate traX expression. Both TraX1 and TraX2 appeared to be encoded by the traX open reading frame. Insertion of a stop codon linker into the traX C-terminal coding region led to synthesis of two correspondingly truncated products, and fusions to phoA indicated that only the traX reading frame was translated. Expression was also very dependent on the traX M1 start codon; when this was altered, no protein products were observed. However, pilin acetylation activity was still detectable, indicating that some other in-frame start codon(s) can also be used. All sequences that are essential for activity are contained between traX codons 29 and 225. Sequence analysis indicated that traX mRNA is capable of forming a variety of base-paired structures. We suggest that traX expression is translationally controlled and that F-pilin acetylation activity may be regulated by physiological conditions in cells.

Analysis of the sequence and gene products of the transfer region of the F sex factor.

Bacterial conjugation results in the transfer of DNA of either plasmid or chromosomal origin between microorganisms. Transfer begins at a defined point in the DNA sequence, usually called the origin of transfer (oriT). The capacity of conjugative DNA transfer is a property of self-transmissible plasmids and conjugative transposons, which will mobilize other plasmids and DNA sequences that include a compatible oriT locus. This review will concentrate on the genes required for bacterial conjugation that are encoded within the transfer region (or regions) of conjugative plasmids. One of the best-defined conjugation systems is that of the F plasmid, which has been the paradigm for conjugation systems since it was discovered nearly 50 years ago. The F transfer region (over 33 kb) contains about 40 genes, arranged contiguously. These are involved in the synthesis of pili, extracellular filaments which establish contact between donor and recipient cells; mating-pair stabilization; prevention of mating between similar donor cells in a process termed surface exclusions; DNA nicking and transfer during conjugation; and the regulation of expression of these functions. This review is a compendium of the products and other features found in the F transfer region as well as a discussion of their role in conjugation. While the genetics of F transfer have been described extensively, the mechanism of conjugation has proved elusive, in large part because of the low levels of expression of the pilus and the numerous envelope components essential for F plasmid transfer. The advent of molecular genetic techniques has, however, resulted in considerable recent progress. This summary of the known properties of the F transfer region is provided in the hope that it will form a useful basis for future comparison with other conjugation systems.

The pKSM710 vector cassette provides tightly regulated lac and T7lac promoters and strategies for manipulating N-terminal protein sequences.

We describe a set of plasmid vectors that are very useful for cloning, expressing, mutagenizing, deleting, and sequencing DNA fragments. A strategy for using one (pKSM717) to obtain mutant protein products that contain deletions of N-terminal amino acids is also presented. Desirable sequences were first combined in plasmid pKSM710 in a manner that facilitates construction of similar vectors carrying alternative selectable markers or replication origins: a cassette that includes LacI-regulated T7 (T7lac) and lacUV5 promoters, a multiple cloning site (MCS)/lacZ alpha sequence, a set of transcription terminators (T phi, rrnBT1, rrnBT2, and Tfd), and an fd origin of replication can be moved as a single unit. Alternative restriction sites permit a lambda PL promoter and/or the sequence of the pMB1 replicon to be included in this unit when desired. With vectors containing the cassette, inserts in the MCS can be identified by their lack of lacZ alpha peptide complementing activity and expressed from the dually regulated T7 (T7lac) and/or lacUV5 promoter. We found expression from this pair of promoters to be very tightly regulated in appropriate hosts; the degree of repression obtainable in the absence of inducer (IPTG) should allow these constructs to be useful for engineering and expressing gene products that are potentially toxic to the cell. Using the pKSM710 cassette, we made derivatives carrying kan (KmR) (pKSM711, pKSM712), kan and lacI (pKSM715), kan and lacIq (pKSM713, pKSM714), and amp (pKSM717, pKSM718). One can use pKSM717 to obtain deletion derivatives that lack the original amino-terminal coding region of a cloned gene sequence but express the polypeptide encoded by the portion of the gene that remains.

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.

Construction and analysis of F plasmid traR, trbJ, and trbH mutants.

F plasmid derivatives carrying kan insertion mutations in the transfer region genes traR, trbJ, and trbH were constructed. Standard tests indicated that these loci are not essential for F pilus production or F transfer among Escherichia coli K-12 hosts. Among the traR and trbH mutants tested, the orientation of the kan cassette had no effect on the mutant phenotype. In each case, there was no significant effect on the appearance of F pili, the transfer frequency, or the plating efficiency of F-pilus-specific phages. The trbJ insertion carrying a kan gene oriented in the direction opposite to tra transcription had very little effect on phage sensitivity but markedly reduced the plasmid transfer efficiency. However, the kan insertion mutation at the same site, in the tra orientation, did not seem to affect either property. Analysis of clones carrying trbJ sequences regulated by a phage T7 promoter showed that trbJ expresses an approximately 11-kDa protein product. The TrbJ protein was not expressed from clones carrying a kan insertion or stop codon linker insertion in the trbJ sequence. However, it was expressed from clones that did not include sequences at the beginning of the 113-codon open reading frame in this region. Our data indicated that translation of trbJ must be initiated at the more distal GUG codon in this frame. This would result in expression of a 93-amino-acid polypeptide.

Synthesis of F pilin.

Transfer of the Escherichia coli fertility plasmid, F, is dependent on expression of F pili. Synthesis of F-pilin subunits is known to involve three F plasmid transfer (tra) region products: traA encodes the 13-kDa precursor protein, TraQ permits this to be processed to the 7-kDa pilin polypeptide, and TraX catalyzes acetylation of the pilin amino terminus. Using cloned tra sequences, we performed a series of pulse-chase experiments to investigate the effect of TraQ and TraX on the fate of the traA product. In TraQ- cells, the traA gene product was found to be very unstable. While traA polypeptides of various sizes were detected early in the chase period, almost all were degraded within 5 min. Rapid traA product degradation was also observed in TraX+ cells, although an increased percentage of these products persisted during the chase. In TraQ+ cells, most of the traA product was processed to the 7-kDa pilin polypeptide within the 1-min pulse period; this product [7(Q)] was not degraded but was increasingly converted to an 8-kDa form [8(Q)] as the chase continued, suggesting that host enzymes can modify the pilin polypeptide. Similar results were observed in TraQ+ TraX+ cells, but the primary 7-kDa product appeared to be N-acetylated pilin (Ac-7). An 8-kDa product (Ac-8) was also detected, but this band did not increase in intensity during the chase. We suggest a pathway in which TraQ prevents the traA product from folding to a readily degradable conformation and assists its entry into the membrane, Leader peptidase I cleaves the traA product signal sequence, and a subset of the pilin polypeptides becomes modified by host enzymes; TraX then acetylates the N terminal of both the modified and unmodified pilin polypeptides.

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.

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 the F plasmid mating aggregation gene traN and of a new F transfer region locus trbE.

The product of the F plasmid transfer gene, traN, is thought to be required for the formation of stable mating aggregates during F-directed conjugation. By testing chimeric plasmids that express F transfer region segments for complementation of F lac traN mutant transfer, we mapped traN to the F transfer region between trbC and traF. Both protein and DNA sequence analysis determined the traN product to be a large, 66,000-Mr, polypeptide that undergoes signal sequence processing. The mature polypeptide was associated with outer membrane protein fractions, and a protease accessivity test confirmed that at least one portion of TraN is exposed on the cell surface. Our DNA sequence analysis also revealed that another gene, trbE, is located between traN and traF. The product of trbE was identified and shown to be a small, integral, inner membrane protein. The mating efficiency and pilus-specific phage susceptibility of a trbE::kan insertion mutant suggested that trbE is not essential for F transfer from Escherichia coli K-12 under standard mating conditions.

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.

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.

Nucleotide sequence of the F plasmid gene, traC, and identification of its product.

The traC gene of the F plasmid tra operon is required for the assembly of mature F-pilin subunits into extended F pili. The nucleotide sequence of traC was determined with a determined with a deduced coding region of 875 amino acids (aa) and 99066 Da. The traC1044 mutant allele, which allows filamentous phage infection in the absence of piliation, contains a C-to-T transition leading to an Arg----Cys substitution. Confirmation of the translational start came from the direct N-terminal aa sequencing of a TraC-alkaline phosphatase fusion protein.

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.

Nucleotide sequence of traQ and adjacent loci in the Escherichia coli K-12 F-plasmid transfer operon.

The F tra operon region that includes genes trbA, traQ, and trbB was analyzed. Determination of the DNA sequence showed that on the tra operon strand, the trbA gene begins 19 nucleotides (nt) distal to traF and encodes a 115-amino-acid, Mr-12,946 protein. The traQ gene begins 399 nt distal to trbA and encodes a 94-amino-acid, Mr-10,867 protein. The trbB gene, which encodes a 179-amino-acid, Mr-19,507 protein, was found to overlap slightly with traQ; its start codon begins 11 nt before the traQ stop codon. Protein analysis and subcellular fractionation of the products expressed by these genes indicated that the trbB product was processed and that the mature form of this protein accumulated in the periplasm. In contrast, the protein products of trbA and traQ appeared to be unprocessed, membrane-associated proteins. The DNA sequence also revealed the presence of a previously unsuspected locus, artA, in the region between trbA and traQ. The artA open reading frame was found to lie on the DNA strand complementary to that of the F tra operon and could encode a 104-amino-acid, 12,132-dalton polypeptide. Since this sequence would not be expressed as part of the tra operon, the activity of a potential artA promoter region was assessed in a galK fusion vector system. In vivo utilization of the artA promoter and translational start sites was also examined by testing expression of an artA-beta-galactosidase fusion protein. These results indicated that the artA gene is expressed from its own promoter.

The product of the F plasmid transfer operon gene, traF, is a periplasmic protein.

The products of clones carrying the F plasmid transfer operon gene, traF, were analyzed. Proteins expressed in maxicells were labeled with [35S]methionine and examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Clones carrying the wild-type traF gene expressed two polypeptide products that were not products of clones containing the traF13 amber mutation. These migrated with apparent molecular weights (Ma) of 27,000 and 25,000. A pulse-chase experiment suggested that the larger product was a precursor of the smaller one. In the presence of ethanol, the Ma-27,000 polypeptide accumulated and the Ma-25,000 product was not expressed. These results indicated that the traF protein undergoes proteolytic processing associated with export. Cell fractionation experiments further indicated that the greatest concentration of the mature (Ma 25,000) TraF protein was located in the periplasm. The DNA sequence of traF and the position of the transition mutation in traF13 DNA were also determined. Sequence analysis suggested that traF would be expressed as a 247-amino-acid, Mr-28,006 polypeptide. The 19 amino acids at the amino terminus of this polypeptide appear to constitute a typical membrane leader peptide, while the remainder of the molecule (Mr 25,942) is predicted to be primarily hydrophilic in character.

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.