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

xvi, 320 hlm 22 c

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

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

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

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

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

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