Identification and characterization of the products from the traJ and traY genes of plasmid R100

Conjugative DNA metabolism in Gram-negative bacteria

Bacterial conjugation in Gram-negative bacteria is triggered by a signal that connects the relaxosome to the coupling protein (T4CP) and transferosome, a type IV secretion system. The relaxosome, a nucleoprotein complex formed at the origin of transfer (oriT), consists of a relaxase, directed to the nic site by auxiliary DNA-binding proteins. The nic site undergoes cleavage and religation during vegetative growth, but this is converted to a cleavage and unwinding reaction when a competent mating pair has formed. Here, we review the biochemistry of relaxosomes and ponder some of the remaining questions about the nature of the signal that begins the process.

Transcription of the transfer genes traY and traM of the antibiotic resistance plasmid R100-1 is linked

Three separate traY deletion mutants of R100-1 were prepared by allele replacement. These mutants retained the ability to transfer at a level 100 times greater than R100 and 1/50 that of the parental R100-1. The mutants were complemented to normal R100-1 transfer levels by pDSP06, a multicopy traY clone. Comparison of transcripts initiated at the traY promoter, P(Y), by primer extension experiments showed that there was no detectable P(Y) activity in R100 and that the level of P(Y) activity in the traY deletion mutants was lower than that in R100-1. Similar measurements performed on RNA from a set of previously described traM deletion mutants showed that those traM deletion mutants that produced more traM and finM (M) transcripts than the parental R100-1 also produced more traY transcripts than R100-1 and that those traM mutants that produced fewer M transcripts than R100-1 also produced fewer traY transcripts than R100-1. We conclude that in R100, TraY regulates P(Y) activity and that transcripts originating in traM affect P(Y) activity.

Comparison of proteins involved in pilus synthesis and mating pair stabilization from the related plasmids F and R100-1: insights into the mechanism of conjugation

F and R100-1 are closely related, derepressed, conjugative plasmids from the IncFI and IncFII incompatibility groups, respectively. Heteroduplex mapping and genetic analyses have revealed that the transfer regions are extremely similar between the two plasmids. Plasmid specificity can occur at the level of relaxosome formation, regulation, and surface exclusion between the two transfer systems. There are also differences in pilus serology, pilus-specific phage sensitivity, and requirements for OmpA and lipopolysaccharide components in the recipient cell. These phenotypic differences were exploited in this study to yield new information about the mechanism of pilus synthesis, mating pair stabilization, and surface and/or entry exclusion, which are collectively involved in mating pair formation (Mpf). The sequence of the remainder of the transfer region of R100-1 (trbA to traS) has been completed, and the complete sequence is compared to that of F. The differences between the two transfer regions include insertions and deletions, gene duplications, and mosaicism within genes, although the genes essential for Mpf are conserved in both plasmids. F+ cells carrying defined mutations in each of the Mpf genes were complemented with the homologous genes from R100-1. Our results indicate that the specificity in recipient cell recognition and entry exclusion are mediated by TraN and TraG, respectively, and not by the pilus.

Regulatory mechanisms in expression of the traY-I operon of sex factor plasmid R100: involvement of traJ and traY gene products

BACKGROUND

The plasmid R100 encodes tra genes essential for conjugal DNA transfer in Escherichia coli. Genetic evidence suggests that the traJ gene encodes a positive regulator for the traY-I operon, which includes almost all the tra genes located downstream of traJ. The molecular mechanism of regulation by TraJ, however, is not yet understood. traY is the most proximal gene in the traY-I operon. TraY promotes DNA transfer by binding to a site, sbyA, near the origin of transfer. TraY is suggested to have another role in regulation of the traY-I operon, since it binds to two other sites, named sbyB and sbyC, located in the region preceding traY-I.

RESULTS

Using a traY-lacZ fusion gene, we showed that the traY-I operon was expressed only in the presence of traJ. The TraJ-dependent expression of traY-I required the E. coli arcA gene, which encodes a host factor required for conjugation. TraJ-dependent transcription occurred from a promoter (named pY) located upstream of traY-I. The isolated TraJ protein was found to bind to a dyad symmetry sequence, named sbj (specific binding site of TraJ), which existed in the intergenic region between traJ and traY-I. We also demonstrated that TraY repressed the TraJ-dependent expression of traY-I at the TraY binding sites, sbyB and sbyC, which overlapped with pY.

CONCLUSIONS

TraJ is a protein which binds to the sbj site in the region upstream of the promoter pY and positively regulates expression of the traY-I operon in the presence of the E. coli arcA gene. Since sbj is located 93bp upstream of pY in the intergenic region between traJ and traY-I, TraJ presumably contacts with a transcription apparatus to promote transcription from pY. TraY, which is known to activate the initiation of conjugal DNA transfer, has a new role in the transcriptional autoregulation of traY-I expression. At levels which are sufficient to initiate conjugal DNA transfer, TraY represses traY-I transcription in the presence of TraJ.

Biophysical characterization of the TraY protein of Escherichia coli F factor

The TraY protein is required for efficient bacterial conjugation by Escherichia coli F factor. TraY has two functional roles: participating in the "relaxosome," a protein-DNA complex that nicks one strand of the F factor plasmid, and up-regulating transcription from the traYI promoter. The traY gene was cloned, and the TraY protein was expressed, purified, and characterized. TraY has a mixed alpha-helix and beta-sheet secondary structure as judged by its circular dichroism spectrum, is monomeric, and undergoes reversible urea denaturation with delta Gu = 6 kcal/mol at 25 degrees C. The kinetics of protein unfolding and refolding, as measured by changes in fluorescence, are complex, suggesting the presence of intermediates or of heterogeneity in the folding reaction. TraY has been classified as a member of the ribbon-helix-helix family of transcription factors but is unusual in appearing to have tandem repeats of the beta alpha alpha motif in the same polypeptide chain. The data presented here show that folding and assembly of the functional (beta alpha alpha)2 unit occurs as an intramolecular reaction and not by cross-folding between different polypeptide chains.

The F plasmid traY gene product binds DNA as a monomer or a dimer: structural and functional implications

The F factor traY gene product (TraYp) is a site-specific DNA-binding protein involved in initiation of DNA transfer during bacterial conjugation. The sequence of TraYp exhibits a unique direct-repeat structure predicted to have a ribbon-helix-helix DNA-binding motif in each repeat unit. The stoichiometry of TraYp binding to DNA was determined to further support the hypothesis that TraYp is a member of the ribbon-helix-helix family of DNA-binding proteins. A glutathione-S-transferase-traY fusion protein was purified and shown to possess almost wild-type DNA-binding activity. DNA-binding experiments were performed in which the DNA ligand was incubated with either the fusion protein, the wild-type protein, or both. The results indicate that TraYp can bind DNA as a monomer or a dimer. Thus a TraYp monomer folds into a stable three-dimensional structure similar to that of a dimer of the ribbon-helix-helix proteins Arc or Mnt. A homology model of a TraYp monomer has been constructed using the co-crystal structure of Arc bound to DNA as a template to provide additional support for this conclusion. In addition, we have shown that an origin of the transfer-deletion mutant lacking approximately half of the TraYp-binding site can only be bound by a monomer of TraYp. The functional implications of this result are discussed.

Large scale purification and characterization of TraI endonuclease encoded by sex factor plasmid R100

The TraI protein encoded by plasmid R100 was purified in a large scale by monitoring the strand- and site-specific nicking activity at the origin of transfer, oriT. The N-terminal amino acid sequence of the purified protein was identical to that deduced from the DNA sequence of an open reading frame encoding TraI. The TraI protein is a DNA helicase which is highly processive and unwinds DNA in the 5' to 3' direction. The Stokes radius and the sedimentation coefficient for the TraI protein in 200 mM NaCl indicate that the protein is a rod-shaped monomer, whose native molecular weight is 186,000. Chemical cross-linking analysis revealed that there exist more dimers of TraI under the low salt conditions, under which both nicking and unwinding reactions catalyzed by TraI are the most efficient, indicating that the TraI protein is functionally active in a dimer form. TraI hardly introduced a nick into the linearized plasmid DNA and only slightly into the relaxed closed circular DNA, indicating that TraI requires superhelical structure of substrate DNA for the nicking reaction. Deletion analysis in the oriT region revealed that a particular region of 54 base pairs containing oriT is required for the nicking reaction.

Characterization of the functional sites in the oriT region involved in DNA transfer promoted by sex factor plasmid R100

We have previously identified three sites, named sbi, ihfA, and sbyA, specifically recognized or bound by the TraI, IHF, and TraY proteins, respectively; these sites are involved in nicking at the origin of transfer, oriT, of plasmid R100. In the region next to these sites, there exists the sbm region, which consists of four sites, sbmA, sbmB, sbmC, and sbmD; this region is specifically bound by the TraM protein, which is required for DNA transfer. Between sbmB and sbmC in this region, there exists another IHF-binding site, ihfB. The region containing all of these sites is located in the proximity of the tra region and is referred to as the oriT region. To determine whether these sites are important for DNA transfer in vivo, we constructed plasmids with various mutations in the oriT region and tested their mobilization in the presence of R100-1, a transfer-proficient mutant of R100. Plasmids with either deletions in the sbi-ihfA-sbyA region or substitution mutations introduced into each specific site in this region were mobilized at a greatly reduced frequency, showing that all of these sites are essential for DNA transfer. By binding to ihfA, IHF, which is known to bend DNA, may be involved in the formation of a complex (which may be called oriT-some) consisting of TraI, IHF, and TraY that efficiently introduces a nick at oriT. Plasmids with either deletions in the sbm-ihfB region or substitution mutations introduced into each specific site in this region were mobilized at a reduced frequency, showing that this region is also important for DNA transfer. By binding to ihfB, IHF may also be involved in the formation of another complex (which may be called the TraM-IHF complex) consisting of TraM and IHF that ensures DNA transfer with a high level of efficiency. Several-base-pair insertions into the positions between sbyA and sbmA affected the frequency of transfer in a manner dependent upon the number of base pairs, indicating that the phasing between sbyA and sbmA is important. This in turn suggests that both oriT-some and the TraM-IHF complex should be in an appropriate position spatially to facilitate DNA transfer.

Regulation of R100 conjugation requires traM in cis to traJ

Deletion mutants of R100-1 were constructed by classical methods to remove various segments of the traM open reading frame, pTraM-binding sites and the traM promoters. Complementation tests showed that traM was efficiently complemented only when the trans-acting fragment contained both the complete traM gene and the adjacent traJ promoter and leader sequences. The conclusion is that traM and traJ constitute a complex operon. A deletion mutant lacking all of the traJ gene, and one containing a frameshifting traM deletion, retained the ability to transfer at a low level, thereby showing that neither pTraM nor pTraJ is absolutely essential for transfer.

traJ sense RNA initiates at two different promoters in R100-1 and forms two stable hybrids with antisense finP RNA

RNase protection experiments show that the sizes of the two R100 finP molecules are 74 and 135 nucleotides. In an RNase III mutant, finP transcripts form stable double-stranded hybrids of 108 bp and 68 bp with traJ transcripts. RNase protection experiments also show that most R100-1 transcripts originating in traM cross the traM-traJ intergenic region and end inside the untranslated leader region of traJ. Some extend into the traJ open reading frame. These findings mean that the antisense finP RNA, thought to regulate traJ translation, must regulate traJ transcripts from both J and M promoters.

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.

Mutational and physical analysis of F plasmid traY protein binding to oriT

F plasmid traY protein binding to wild-type or deleted regions containing the TraY-binding site, sbyA, was studied in vitro. The principal DNA-protein complex was formed with DNA segments including the sbyA site defined by footprinting and (with lesser affinity) with truncated segments that retained the leftward two-thirds of sbyA. This located the major sequence determinants for TraY binding between bp 204 and 227 on the oriT map. For all sequences tested, bound TraY induced bending of approximately 50 to 55 degrees, and centred between bp 214 and 221. Thermodynamic and mobility analyses indicated that two TraY protomers bind to sbyA. At higher TraY concentrations, additional TraY bound to the left of the sbyA in a region previously shown to bind IHF (site IHF A). TraY binding to this additional site (sbyC) was inhibited by IHF. Sequence similarities shared by sbyA, sbyB, and sbyC may include the critical base pairs for TraY binding.

Repression of the traM gene of plasmid R100 by its own product and integration host factor at one of the two promoters

Plasmid R100 codes for the traM gene, which is required for DNA transfer and whose product has been shown to bind to the four sites, called sbmA to sbmD, upstream of traM. To determine whether the TraM protein regulates the expression of traM, we constructed the plasmids carrying various portions of the region upstream of the initiation codon ATG for traM, which was fused with lacZ in frame, and introduced them into the cells, which did or did not harbor another compatible plasmid carrying traM. We then assayed the beta-galactosidase (LacZ) activity to monitor the expression of the fusion genes and analyzed the traM-specific transcripts made in the cells. Two promoters for traM were identified and designated pM1 and pM2. Promoter pM2 lies upstream of pM1 and overlaps the sbmC-sbmD region. Promoter pM1 is constitutively expressed, while pM2 is much stronger but is repressed almost completely by the TraM protein and partially by integration host factor, whose binding site is near pM2. The traM gene is likely to be expressed from pM2 when the TraM protein is at low levels after dilution in the donor cell during cell growth or before its expression in the recipient cell which has just received R100 by conjugation. The expression from pM2 could maintain the amount of the TraM protein at a constant level needed to initiate DNA transfer at any time. Integration host factor, which can partially repress the traM gene, may play a role in forming an active complex with the TraM protein at the sbm region to facilitate DNA transfer.

Characterization of the Escherichia coli F factor traY gene product and its binding sites

The traY gene product (TraYp) from the Escherichia coli F factor has previously been purified and shown to bind a DNA fragment containing the F plasmid oriT region (E. E. Lahue and S. W. Matson, J. Bacteriol. 172:1385-1391, 1990). To determine the precise nucleotide sequence bound by TraYp, DNase I footprinting was performed. The TraYp-binding site is near, but not coincident with, the site that is nicked to initiate conjugative DNA transfer. In addition, a second TraYp binding site, which is coincident with the mRNA start site at the traYI promoter, is described. The Kd for each binding site was determined by a gel mobility shift assay. TraYp exhibits a fivefold higher affinity for the oriT binding site compared with the traYI promoter binding site. Hydrodynamic studies were performed to show that TraYp is a monomer in solution under the conditions used in DNA binding assays. Early genetic experiments implicated the traY gene product in the site- and strand-specific endonuclease activity that nicks at oriT (R. Everett and N. Willetts, J. Mol. Biol. 136:129-150, 1980; S. McIntire and N. Willetts, Mol. Gen. Genet. 178:165-172, 1980). As this activity has recently been ascribed to helicase I, it was of interest to see whether TraYp had any effect on this reaction. Addition of TraYp to nicking reactions catalyzed by helicase I showed no effect on the rate or efficiency of oriT nicking. Roles for TraYp in conjugative DNA transfer and a possible mode of binding to DNA are discussed.

Autoregulation by cooperative binding of the PemI and PemK proteins to the promoter region of the pem operon

The low copy number plasmid R100 carries the pem region, consisting of two genes, pemI and pemK, which are required for stable maintenance of the plasmid. Here, to understand the regulation of the expression of the pem region, we constructed plasmids carrying either the pemI or the pemK gene, whose initiation codons were fused in frame with the lacZ gene, and examined their expression by assaying beta-galactosidase (LacZ) activity. The synthesis of both PemI and PemK proteins was found to be repressed coordinately in the presence of a plasmid carrying the entire pem region. This indicates that pemK and pemI cistrons form an operon, and that the expression of the operon is negatively regulated by its own products. We then conducted a gel retardation assay in vitro and found that the two pem products, each of which was obtained as a tripartite protein (PemI-collagen-LacZ and PemK-collagen-LacZ), bound cooperatively to a specific fragment containing the proximal region of the pem operon. The binding region, determined by DNase I footprinting analysis, included the promoter for the pem operon. This indicates that both PemI and PemK proteins bind to the promoter region to autoregulate their synthesis.

DNA binding domains in Tn3 transposase

Various segments of Tn3 transposase were fused individually to beta-galactosidase, and the resulting fusion proteins were examined for their DNA binding ability by a nitrocellulose filter binding assay. Analyses of a series of the fusion proteins revealed that the N-terminal segment of the transposase (amino acid positions 1-242; the transposase gene encodes 1004 residues in all) had specific DNA binding ability for the 38 bp terminal inverted repeat (IR) sequence, and the central segment (amino acid positions 243-632) had non-specific DNA binding ability. Further analyses of each of the two regions revealed that the N-terminal segment could be divided into at least two subsegments (amino acid positions 1-86 and 87-242), neither of which had specific DNA binding ability, but which both possessed non-specific DNA binding ability. The central segment included two subsegments (amino acid positions 243-289 and 439-505) with non-specific DNA binding ability. These results and other observations suggest that Tn3 transposase has several domains including those responsible for non-specific DNA binding, and a combination of two or more domains gives rise to specific DNA binding activity. The C-terminal segment of the transposase (amino acid positions 633-1004), which is very well conserved among transposases encoded by Tn3 family transposons, had no DNA binding ability. This segment may represent the main part of the catalytic domain responsible for the initiation step of transposition.

Specific DNA binding of the TraM protein to the oriT region of plasmid R100

The product of the traM gene of plasmid R100 was purified as the TraM-collagen-beta-galactosidase fusion protein (TraM*) by using a beta-galactosidase-specific affinity column, and the TraM portion of TraM* (TraM') was separated by collagenolysis. Both the TraM* and TraM' proteins were found to bind specifically to a broad region preceding the traM gene. This region (designated sbm) was located within the nonconserved region in oriT among conjugative plasmids related to R100. The region seems to contain four core binding sites (designated sbmA, sbmB, sbmC, and sbmD), each consisting of a similar number of nucleotides and including a homologous 15-bp sequence. This result, together with the observation that the TraM* protein was located in the membrane fraction, indicates the possibility that the TraM protein has a function in anchoring the oriT region of R100 at the sbm sites to the membrane pore, through which the single-stranded DNA is transferred to the recipient. sbmC and sbmD, each of which contained a characteristic inverted repeat sequence, overlapped with the promoter region for the traM gene. This suggests that the expression of the traM gene may be regulated by its own product.

Characterization of the oriT region of the IncFV plasmid pED208

DNA sequence analysis of a 2.2kb EcoRI-HindIII fragment from pED208, the derepressed form of the IncFV plasmid Folac, revealed sequences highly homologous to the oriT region, traM, and traJ genes of other IncF plasmids. The TraM protein was purified and immunoblots of fractionated cells containing pED208 or Folac showed that TraM was predominantly in the cytoplasm. Using DNA retardation assays and the DNase I footprinting technique, the TraM protein was found to bind to three large motifs in the oriT region: (I) an inverted repeat, (II) two direct repeats, and (III) the traM promoter region. These three footprint regions contained a Hinfl-like sequence (GANTC) that appeared 16 times, spaced 11-12 bp (or multiples thereof) apart, suggesting that TraM protein binds in a complex manner over this entire region.

Nucleotide sequence and functions of the oriT operon in IncI1 plasmid R64

Two transfer genes of IncI1 plasmid R64, tentatively designated nikA and nikB, were cloned and sequenced. They are located adjacent to the origin of transfer (oriT) and appear to be organized into an operon, which we call the oriT operon. On the basis of the DNA sequence, nikA and nikB were concluded to encode proteins with 110 and 899 amino acid residues, respectively. Complementation analysis indicated that these two genes are indispensable for the transfer of R64 but are not required for the mobilization of ColE1. By the maxicell procedure, the product of nikA was found to be a 15-kDa protein. On treating a cleared lysate prepared from cells harboring a plasmid containing oriT, nikA, and nikB with sodium dodecyl sulfate or proteinase K, superhelical plasmid DNA in the cleared lysate was converted to an open circular form (relaxation). Relaxation of plasmid DNA was found to require the oriT sequence in cis and the nikA and nikB sequences in trans. It would thus follow that the products of nikA and nikB genes form a relaxation complex with plasmid DNA at the oriT site.

The sequences of genes bordering oriT in the enterotoxin plasmid P307: comparison with the sequences of plasmids F and R1

The nucleotide sequences of the enterotoxin plasmid P307 transfer genes traM, finP, traJ, traY, and gene 19 were determined. Gene 19 is highly conserved; its product is very similar to that coded by the F and R1 plasmids. The TraM protein is similar in P307 and in F; the R1 sequence shows differences in the 40 N-terminal amino acids. The traJ product is very different in P307, F, and R1. The traY gene from P307, which in F is almost twice as long, is similar in size to that from R1. The finP RNA shows a high degree of homology with that from R1 and F, except for the two loop regions where base changes were observed. The genes coding for proteins, except traY, could be expressed in minicell- and T7 promoter-driven expression systems, whereas traJ and gene 19 could be expressed only in the latter system.

Nucleotide sequence of the promoter-distal region of the tra operon of plasmid R100, including traI (DNA helicase I) and traD genes

The nucleotide sequence of the promoter-distal region of the tra operon of R100 was determined. There are five open reading frames in the region between traT and finO, and their protein products were identified. Nucleotide sequences of plasmid F corresponding to the junction regions among the open reading frames seen in R100 were also determined. Comparison of these nucleotide sequences revealed strong homology in the regions containing traD, traI and an open reading frame (named orfD). The TraD protein (83,899 Da) contains three hydrophobic regions, of which two are located near the amino-terminal region. This protein also contains a possible ATP-binding consensus sequence at the amino-terminal region and a characteristic repeated peptide sequence (Gln-Gln-Pro)10 at the carboxy-terminal region. The TraI protein (191,679 Da) contains the sequence motif conserved in an ATP-dependent DNA helicase superfamily in its carboxy-terminal region. The protein product of orfD, which is probably a new tra gene (named traX), contains 65% hydrophobic amino acids, especially rich in alanine and leucine. There exist non-homologous regions between R100 and F that could be represented as four I-D (insertion or deletion) loops in heteroduplex molecules. Assignment of each loop to the strand of R100 or F was , however, found to be the reverse from that previously assumed. The three I-D loops that were located between traT and traD, between traD and traI, and between traI and finO had no terminal inverted repeat sequences nor had they any homology with known insertion sequences, while the fourth was IS3, located within the finO gene of F. The sequences in the I-D loops, except IS3, may also code for proteins that are, however, likely to be nonessential for transfer of plasmids.

Integration host factor affects expression of two genes at the conjugal transfer origin of plasmid R100

Integration host factor (IHF) binds to two sites near the origin of transfer of the conjugative antibiotic resistance plasmid, R100. DNase I footprinting shows that one site is immediately adjacent to oriT and the gene X promoter, and another is adjacent to the traM promoter. A third site, known only from retardation gels, is near the traJ promoter. The relative promoter activities of genes X, traJ and traM are reduced in himA mutants (IHF-), as measured by chloramphenicol-resistance assays. Transcript analyses by Northern blots showed a reduction in size of the principal gene X and traJ transcripts in the absence of IHF.

Purified Escherichia coli F-factor TraY protein binds oriT

The traY gene of the Escherichia coli F plasmid has been shown by genetic studies (R. Everett and N. Willetts, J. Mol. Biol. 136:129-150, 1980) to be involved in the site-specific nicking reaction at oriT required for the initiation of DNA transfer during bacterial conjugation. In order to assign a biochemical function to TraY protein, the traY gene was cloned in a plasmid vector which utilizes the strong T7 phi 10 promoter to overproduce the protein. The plasmid-encoded TraY protein was specifically labeled with [35S]methionine, and purification of the polypeptide was accomplished by monitoring the radioactive label. Purified TraY protein had a relative molecular mass of approximately 17,000, as determined by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The amino terminus of the purified protein was sequenced to confirm that the protein was encoded by the traY gene. The protein sequence revealed that the start codon for the TraY protein was a UUG codon 36 base pairs upstream of the AUG start site originally deduced from the DNA sequence (T. Fowler, L. Taylor, and R. Thompson, Gene 26:79-89, 1983). This start sequence confirmed the premise of Inamoto et al. that the F-plasmid TraY polypeptide-coding sequence would begin with UUG, creating a reading frame which renders a large degree of amino acid sequence identity with the TraY polypeptide from R100 (S. Inamoto, Y. Yoshioka, and E. Ohtsubo, J. Bacteriol. 170:2749-2757, 1988). The purified TraY protein from F bound specifically to the origin of transfer region of the F plasmid. However, no nicking activity was detected at oriT by using TraY protein or TraY protein in conjunction with helicase I.

TraY proteins of F and related episomes are members of the Arc and Mnt repressor family

Amino acid changes known to be structurally allowed in Arc repressor were used to aid in the identification of proteins with sequence similarity to Arc and the related Mnt repressor. The sequences of the TraY proteins from the F episome and related episomes were found to be similar to those of Arc and Mnt.

Sense and antisense transcripts of traM, a conjugal transfer gene of the antibiotic resistance plasmid R100

The region of the antibiotic resistance plasmid R100 that encodes the plasmid-specific transfer gene traM has two tandemly aligned promoters separated by 145 nucleotides. The principal transcripts are 705 and 562 nucleotides long. Minor transcripts are 1550 and 1700 nucleotides long. The 705-base transcript appears to encode an 11 kD traM protein. The 562-base transcript does not encode a detectable protein. When subcloned on short fragments, the promoter for the 562-base transcript initiates efficiently but that for the 705 site does not. The 3' ends of the 705 and 562 base transcripts end inside the traJ ORF. Thus they provide additional sense RNA to compete with traJ for finP, the antisense translational regulator of traJ. A model is proposed for the participation of these sense and antisense transcripts in the control of expression of the traJ gene.