Specific binding of the TraY protein to oriT and the promoter region for the traY gene of plasmid R100

Relaxosome function and conjugation regulation in F-like plasmids - a structural biology perspective

The tra operon of the prototypical F plasmid and its relatives enables transfer of a copy of the plasmid to other bacterial cells via the process of conjugation. Tra proteins assemble to form the transferosome, the transmembrane pore through which the DNA is transferred, and the relaxosome, a complex of DNA-binding proteins at the origin of DNA transfer. F-like plasmid conjugation is characterized by a high degree of plasmid specificity in the interactions of tra components, and is tightly regulated at the transcriptional, translational and post-translational levels. Over the past decade, X-ray crystallography of conjugative components has yielded insights into both specificity and regulatory mechanisms. Conjugation is repressed by FinO, an RNA chaperone which increases the lifetime of the small RNA, FinP. Recent work has resulted in a detailed model of FinO/FinP interactions and the discovery of a family of FinO-like RNA chaperones. Relaxosome components include TraI, a relaxase/helicase, and TraM, which mediates signalling between the transferosome and relaxosome for transfer initiation. The structures of TraI and TraM bound to oriT DNA reveal the basis of specific recognition of DNA for their cognate plasmid. Specificity also exists in TraI and TraM interactions with the transferosome protein TraD.

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.

GroEL plays a central role in stress-induced negative regulation of bacterial conjugation by promoting proteolytic degradation of the activator protein TraJ

Transcription of DNA transfer genes is a prerequisite for conjugative DNA transfer of F-like plasmids. Transfer gene expression is sensed by the donor cell and is regulated by a complex network of plasmid- and host-encoded factors. In this study we analyzed the effect of induction of the heat shock regulon on transfer gene expression and DNA transfer in Escherichia coli. Raising the growth temperature from 22 degrees C to 43 degrees C transiently reduced transfer gene expression to undetectable levels and reduced conjugative transfer by 2 to 3 orders of magnitude. In contrast, when host cells carried the temperature-sensitive groEL44 allele, heat shock-mediated repression was alleviated. These data implied that the chaperonin GroEL was involved in negative regulation after heat shock. Investigation of the role of GroEL in this regulatory process revealed that, in groEL(Ts) cells, TraJ, the plasmid-encoded master activator of type IV secretion (T4S) system genes, was less susceptible to proteolysis and had a prolonged half-life compared to isogenic wild-type E. coli cells. This result suggested a direct role for GroEL in proteolysis of TraJ, down-regulation of T4S system gene expression, and conjugation after heat shock. Strong support for this novel role for GroEL in regulation of bacterial conjugation was the finding that GroEL specifically interacted with TraJ in vivo. Our results further suggested that in wild-type cells this interaction was followed by rapid degradation of TraJ whereas in groEL(Ts) cells TraJ remained trapped in the temperature-sensitive GroEL protein and thus was not amenable to proteolysis.

Nucleotide and amino acid sequences of oriT-traM-traJ-traY-traA-traL regions and mobilization of virulence plasmids of Salmonella enterica serovars enteritidis, gallinarum-pullorum, and typhimurium

The virulence plasmid of Salmonella enterica serovar Gallinarum-Pullorum (pSPV) but not those of Salmonella enterica serovars Enteritidis (pSEV) and Typhimurium (pSTV) can be readily mobilized by an F or F-like conjugative plasmid. To investigate the reason for the difference, the oriT-traM-traJ-traY-traA-traL regions of the three salmonella virulence plasmids (pSVs) were cloned and their nucleotide and deduced amino acid sequences were examined. The cloned fragments were generally mobilized more readily than the corresponding full-length pSVs, but the recombinant plasmid containing the oriT of pSPV was, as expected, more readily mobilized, with up to 100-fold higher frequency than the recombinant plasmids containing the oriT of the other two pSVs. The nucleotide sequences of the oriT-traM-traJ-traY-traA-traL region of pSEV and pSTV were almost identical (only 4 bp differences), but differed from that of pSPV. Major nucleotide sequence variations were found in traJ, traY, and the Tra protein binding sites sby and sbm. sby of pSPV showed higher similarity than that of pSEV or pSTV to that of the F plasmid. The reverse was true for sbm: similarity was higher with pSEV and pSTV than with pSPV. In the deduced amino acid sequences of the five Tra proteins, major differences were found in TraY: pSEV's TraY was 75 amino acids, pSTV's was 106 amino acids, and pSPV's was 133 amino acids; and there were duplicate consensus betaalphaalpha fragments in the TraY of pSPV and F plasmid, whereas there was only a single betaalphaalpha fragment in that of pSEV and pSTV.

Plasmid transcriptional repressor CopG oligomerises to render helical superstructures unbound and in complexes with oligonucleotides

CopG is a 45 amino acid residue transcriptional repressor involved in the copy number control of the streptococcal plasmid pMV158. To do so, it binds to a DNA operator that contains a 13 bp pseudosymmetric DNA element. Binding of CopG to its operator results in repression, at the transcriptional level, of its own synthesis and that of the initiator of replication protein, RepB. Biochemical experiments have shown that CopG co-operatively associates to its target DNA at low protein:DNA ratios, completely protecting four helical turns on the same face of the double helix in both directions from the inverted repeat that constitutes the CopG primary target. This has been correlated with a CopG-mediated DNA bend of about 100 degrees. Here, we show that binding of CopG to DNA fragments containing the inverted repeat just at one end led to nucleation of the protein initiating from the inverted repeat. Nucleation extended to the entire fragment, with CopG-DNA contacts occurring on the same face of the DNA helix. The protein, the prototype for a family of homologous plasmid repressors, displays a homodimeric ribbon-helix-helix arrangement. It polymerises within the unbound crystal to render a continuous right-handed protein superhelix of homodimers, around which a bound double-stranded (ds) DNA could wrap. We have solved the crystal structure of CopG in complex with a 22 bp dsDNA oligonucleotide encompassing the cognate pseudosymmetric element. In the crystal, one protein tetramer binds at one face of the DNA with two parallel beta-ribbons inserted into the major groove. The DNA is bent about 50 degrees under compression of both major and minor grooves. A continuous right-handed complex helix made up mainly by protein-protein and some protein-DNA interactions is observed. The protein-protein interactions involve regions similar to those observed in the oligomerisation of the native crystals and those employed to set up the functional tetramer. A previously solved complex structure of the protein with a 19 bp dsDNA had unveiled a left-handed helical superstructure just made up by DNA interactions.

Transfer protein TraY of plasmid R1 stimulates TraI-catalyzed oriT cleavage in vivo

The effect of TraY protein on TraI-catalyzed strand scission at the R1 transfer origin (oriT) in vivo was investigated. As expected, the cleavage reaction was not detected in Escherichia coli cells expressing tral and the integration host factor (IHF) in the absence of other transfer proteins. The TraM dependence of strand scission was found to be inversely correlated with the presence of TraY. Thus, the TraY and TraM proteins could each enhance cleaving activity at oriT in the absence of the other. In contrast, no detectable intracellular cleaving activity was exhibited by TraI in an IHF mutant strain despite the additional presence of both TraM and TraY. An essential role for IHF in this reaction in vivo is, therefore, implied. Mobilization experiments employing recombinant R1 oriT constructions and a heterologous conjugative helper plasmid were used to investigate the independent contributions of TraY and TraM to the R1 relaxosome during bacterial conjugation. In accordance with earlier observations, traY was dispensable for mobilization in the presence of traM, but mobilization did not occur in the absence of both traM and traY. Interestingly, although the cleavage assays demonstrate that TraM and TraY independently promote strand scission in vivo, TraM remained essential for mobilization of the R1 origin even in the presence of TraY. These findings suggest that, whereas TraY and TraM function may overlap to a certain extent in the R1 relaxosome, TraM additionally performs a second function that is essential for successful conjugative transmission of plasmid DNA.

Mobilization of chimeric oriT plasmids by F and R100-1: role of relaxosome formation in defining plasmid specificity

Cleavage at the F plasmid nic site within the origin of transfer (oriT) requires the F-encoded proteins TraY and TraI and the host-encoded protein integration host factor in vitro. We confirm that F TraY, but not F TraM, is required for cleavage at nic in vivo. Chimeric plasmids were constructed which contained either the entire F or R100-1 oriT regions or various combinations of nic, TraY, and TraM binding sites, in addition to the traM gene. The efficiency of cleavage at nic and the frequency of mobilization were assayed in the presence of F or R100-1 plasmids. The ability of these chimeric plasmids to complement an F traM mutant or affect F transfer via negative dominance was also measured using transfer efficiency assays. In cases where cleavage at nic was detected, R100-1 TraI was not sensitive to the two-base difference in sequence immediately downstream of nic, while F TraI was specific for the F sequence. Plasmid transfer was detected only when TraM was able to bind to its cognate sites within oriT. High-affinity binding of TraY in cis to oriT allowed detection of cleavage at nic but was not required for efficient mobilization. Taken together, our results suggest that stable relaxosomes, consisting of TraI, -M, and -Y bound to oriT are preferentially targeted to the transfer apparatus (transferosome).

DNA recognition by beta-sheets

The modes of DNA recognition by beta-sheets are analyzed by using the known crystal and solution three-dimensional structures of DNA-protein complexes. Close fitting of the protein surface and the DNA surface determines the binding geometry. Interaction takes place so that essentially the N-to-C direction of the beta-strands either follows or crosses the DNA groove. Upon following the major groove a two-stranded antiparallel beta-sheet dives into the groove and contacts DNA bases with its convex side facing the DNA, while upon following the minor groove, it binds around the sugar-phosphate backbones, with its opposite concave side shielding the DNA. In order for the beta-strands crossing the minor groove to interact with the DNA, the dinucleotide steps need to almost totally helically untwist and roll around major groove. The beta-sheet, on the other hand, needs to adopt a concave curvature on the binding surface in the direction that follows the DNA minor groove, and a convex surface in the direction that bridges the sugar-phosphate backbones across the groove. The result is to produce a hyperbolic paraboloidal DNA-binding surface.

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.

IHF protein inhibits cleavage but not assembly of plasmid R388 relaxosomes

Relaxosomes are specific nucleoprotein structures involved in DNA-processing reactions during bacterial conjugation. In this work, we present evidence indicating that plasmid R388 relaxosomes are composed of origin of transfer (oriT) DNA plus three proteins TrwC relaxase, TrwA nic-cleavage accessory protein and integration host factor (IHF), which acts as a regulatory protein. Protein IHF bound to two sites (ihfA and ihfB) in R388 oriT, as shown by gel retardation and DNase I footprinting analysis. IHF binding in vitro was found to inhibit nic-cleavage, but not TrwC binding to supercoiled DNA. However, no differences in the frequency of R388 conjugation were found between IHF- and IHF+ donor strains. In contrast, examination of plasmid DNA obtained from IHF- strains revealed that R388 was obtained mostly in relaxed form from these strains, whereas it was mostly supercoiled in IHF+ strains. Thus, IHF could have an inhibitory role in the nic-cleavage reaction in vivo. It can be speculated that triggering of conjugative DNA processing during R388 conjugation can be mediated by IHF release from oriT.

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.

Signal transduction and bacterial conjugation: characterization of the role of ArcA in regulating conjugative transfer of the resistance plasmid R1

The role of the two-component response regulator ArcA protein in the transfer of the conjugative resistance plasmid R1 was investigated using a variety of in vivo and in vitro assays. The frequency of conjugal DNA transfer of plasmid R1-16, a derepressed variant of R1, was reduced by four orders of magnitude in an Escherichia coli host with a mutation in the arcA gene. Measurements of mRNAs transcribed from key plasmid transfer genes revealed that the abundance of each of the mRNA species investigated was reduced significantly in an arcA background. Gene fusion studies with the R1 PY promoter, the major promoter of the transfer operon, and a lacZ reporter gene, indicated that arcA is required for maximal expression from this promoter. However, a stimulating effect of arcA could only be detected when the plasmid-specified positive regulator of the transfer genes, traJ, was present. Electrophoretic mobility shift assays were used to demonstrate specific binding of purified ArcA protein and a purified and phosphorylated oligohistidine-tagged ArcA (His6-ArcA) to a DNA fragment containing the PY promoter region. The binding of phosphorylated His6-ArcA to the PY promoter was further characterized by DNase I footprinting. The observed protection pattern was characteristic for ArcA acting as a transcriptional activator.

oriT-processing and regulatory roles of TrwA protein in plasmid R388 conjugation

TrwA protein was purified from an overproducing Escherichia coli strain and characterized as a 53 kDa tetrameric DNA-binding protein. Gel shift assays showed that TrwA bound specifically to the oriT sequence of plasmid R388. DNAse I footprinting analysis defined two DNA regions within oriT (sites A and B) that were protected by TrwA. At low TrwA concentrations only region A was protected (K(D) = 4 x 10(-8) M) while region B required higher TrwA concentrations (K(D) = 4 x 10(-7) M). As a result of its binding to oriT, TrwA was found to perform two biochemical activities related to its role in R388 conjugation. First, TrwA binding to oriT resulted in transcriptional repression of the trwABC operon as indicated by its effect on the beta-galactosidase activity of transcriptional fusions in trwB and trwC, and by direct measurement of the trwA mRNA levels by hybridization. This result was further confirmed by the fact that TrwA overexpression resulted in lowered conjugation frequencies. Second, TrwA enhanced the relaxation activity of TrwC in vitro. This effect was correlated to a 10(5)-fold increase in the frequency of conjugation in vivo and was shown to be independent of the regulation of transcription. Thus, TrwA shows functional similarities to protein TraY of F-like plasmids, that could be correlated to a structural similarity in their DNA-binding motifs.

Effect of traY amber mutations on F-plasmid traY promoter activity in vivo

We have examined the effect of the F plasmid TraY protein on tra gene expression in vivo. Expression was assayed as alkaline phosphatase activity in cells containing a traY phi(traA'-'phoA)hyb operon under traY promoter control. Amber mutations in traY significantly reduced alkaline phosphatase activity. Since nonsense polarity effects were minimal, if they occurred at all, these data provide the first direct evidence that TraY regulates tra gene expression.

Differential mRNA decay within the transfer operon of plasmid R1: identification and analysis of an intracistronic mRNA stabilizer

Processing of the transfer operon mRNA of the conjugative resistance plasmid R1-19 results in the accumulation of stable traA mRNAs. The stable traA transcripts found in vivo have identical 3' ends within downstream traL sequences, but vary at their 5' ends. The 3' ends determined coincide with the 3' base of a predicted large clover-leaf-like RNA secondary structure. Here we demonstrate that this putative RNA structure, although part of a coding sequences, stabilizes the upstream traA mRNA very efficiently. We also show that the 3' ends of the stable mRNAs are formed posttranscriptionally and not by transcription termination. Half-life determinations reveal the same half-lives of 13 +/- 2 min for the traA mRNAs transcribed from hybrid lac-traAL-cat test plasmids, the R1-19 plasmid, and the F plasmid. Protein expression experiments demonstrate that the processed stable traA mRNA is translationally active. Partial deletions of sequences corresponding to the predicted secondary structure within the traL coding region drastically reduce the chemical and functional half-life of the traA mRNA. The results presented here unambiguously demonstrate that the proposed secondary structure acts as an efficient intracistronic mRNA stabilizer.

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.

Studies on the binding of integration host factor (IHF) and TraM to the origin of transfer of the IncFV plasmid pED208

The origin of transfer (oriT) of the IncFV plasmid pED208 contains a region with three binding sites for both the plasmid-encoded TraM protein and the integration host factor (IHF) of Escherichia coli, a sequence-specific DNA-binding protein. One region, containing overlapping TraM and IHF binding sites, could be interpreted as containing two binding sites for each protein. Using gel retardation assays, an affinity constant for IHF binding to the three main sites was estimated in the presence and absence of 0.1 M potassium glutamate, which increased the avidity of IHF binding to the weaker sites by two orders of magnitude. DNase I protection analyses and electron microscopy were used to determine the affinity of IHF for oriT-containing DNA in the presence and absence of TraM. The binding of IHF and TraM was found to be non-cooperative by the two techniques employed. Electron microscopy also demonstrated that IHF bent the oriT region in a manner consistent with its previously determined mode of action, while TraM had no discernible effect on the appearance of the DNA. This suggested that IHF and TraM interact with a 295 bp sequence in the oriT region and organize it into a higher order structure that may have a role in the initiation of DNA transfer and control of traM expression.

Specific binding of the NikA protein to one arm of 17-base-pair inverted repeat sequences within the oriT region of plasmid R64

Products of the nikA and nikB genes of plasmid R64 have been shown to form a relaxation complex with R64 oriT DNA and to function together as an oriT-specific nickase. We purified the protein product of the nikA gene. The purified NikA protein bound specifically to the oriT region of R64 DNA. Gel retardation assays and DNase I footprinting analyses indicated that the NikA protein bound only to the right arm of 17-bp inverted repeat sequences; the right arm differed from the left arm by a single nucleotide. The binding site is proximal to the nick site and within the 44-bp oriT core sequence. Binding of the NikA protein induced DNA bending within the R64 oriT sequence.

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.

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.

Identification of the site of translational frameshifting required for production of the transposase encoded by insertion sequence IS 1

Previous genetic analyses indicated that translational frameshifting in the--1 direction occurs within the run of six adenines in the sequence 5'-TTAAAAAACTC-3' at nucleotide positions 305-315 in IS 1, where the two out-of-phase reading frames insA and B'-insB overlap, to produce transposase with a polypeptide segment Leu-Lys-Lys-Leu at residues 84-87. IS 1 mutants with a 1 bp insertion, which encode mutant transposases with an amino acid substitution within the polypeptide segment at residues 84-87, did not efficiently mediate cointegration, except for an IS 1 mutant which encodes a mutant transposase with a Leu-Arg-Lys-Leu segment instead of Leu-Lys-Lys-Leu. An IS 1 mutant with the DNA segment 5'-CTTAAAAACTC-3' at positions 305-315 carrying the termination codon TAA in the B'-insB reading frame could still mediate cointegration, indicating that codon AAA for Lys corresponding to second, third and fourth positions in the run of adenines is the site of frameshifting. The beta-galactosidase activity specified by several IS 1-lacZ fusion plasmids, in which B'-insB is in-frame with lacZ, showed that the region 292-377 is sufficient for frameshifting. The protein produced by frameshifting from the IS 1-lacZ plasmid in fact contained the polypeptide segment Leu-Lys-Lys-Leu encoded by the DNA segment 5'-TTAAAAAACTC-3', indicating that--1 frameshifting does occur within the run of adenines.

Biochemical characterization of Escherichia coli DNA helicase I

The gene product of F tral is a bifunctional protein which nicks and unwinds the F plasmid during conjugal DNA transfer. Further biochemical characterization of the Tral protein reveals that it has a second, much lower, Km for ATP hydrolysis, in addition to that previously identified. Measurement of the single-stranded DNA-stimulated ATPase rate indicates that there is co-operative interaction between the enzyme monomers for maximal activity. Furthermore, 18O-exchange experiments indicate that Tral protein hydrolyses ATP with, at most, a low-level reversal of the hydrolytic step during each turnover.

Determination of the nick site at oriT of IncI1 plasmid R64: global similarity of oriT structures of IncI1 and IncP plasmids

The nick site at the origin of transfer, oriT, of IncI1 plasmid R64 was determined. A site-specific and strand-specific cleavage of the phosphodiester bond was introduced during relaxation of the oriT plasmid DNA. Cleavage occurred between 2'-deoxyguanosine and thymidine residues, within the 44-bp oriT core sequence. The nick site was located 8 bp from the 17-bp repeat. A protein appeared to be associated with the cleaved DNA strand at the oriT site following relaxation. This protein was observed to bind to the 5' end of the cleaved strand, since the 5'-phosphate of the cleaved strand was resistant to the phosphate exchange reaction by polynucleotide kinase. In contrast, the 3' end of the cleaved strand appeared free, since it was susceptible to primer extension by DNA polymerase I. The global similarity of the oriT structures of IncI1 and IncP plasmids is discussed.

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.

Regulation of the F plasmid traY promoter in Escherichia coli by host and plasmid factors

F plasmid DNA transfer (tra) gene expression in Escherichia coli is regulated by chromosome- and F-encoded gene products. To study the relationship among these regulatory factors, we constructed low-copy plasmids containing a phi(traY'-'lacZ)hyb gene that couples beta-galactosidase and Lac permease synthesis to the F plasmid traY promoter. Wild-type transformants maintained high levels of beta-galactosidase over a broad range of culture densities. Primer extension analysis of tra mRNA from F'lac and phi(traY'-'lacZ)hyb strains indicated very similar, though not identical, transcription initiation sites. Moreover, phi(traY'-'lacZ)hyb gene expression required both TraJ and SfrA, as does tra gene expression in F+ strains. beta-Galactosidase activity was reduced approximately 30-fold in the absence of TraJ, which could be supplied in cis or in trans. In a two-plasmid system in which TraJ was supplied in trans by a lac-traJ operon fusion, phi(traY'-'lacZ)hyb expression was a linear, saturable function of traJ expression. Enzyme activity was reduced approximately tenfold in sfrA mutants. That reduction could not be attributed to an effect on the TraJ level. Several other cellular or environmental variables had only a modest effect on phi(traY'-'lacZ)hyb expression. Hyperexpression was observed at high cell density (twofold) and in anaerobic cultures (1.2- to 1.5-fold). In contrast, expression was reduced twofold in integration host factor mutants.

The TraM protein of plasmid R1 is a DNA-binding protein

The TraM protein of the resistance plasmid R1 was purified to homogeneity and used for DNA-binding studies. Both gel retardation- and footprint experiments showed that TraM specifically binds to DNA of plasmid R1 comprising the region between the origin of transfer and the traM gene. Several TraM molecules bind and, according to the footprint experiments, two distinct sites of specific binding exist. The two sites are separated from each other by 12 nucleotides and each contains an inverted repeat. DNase I protection assays showed that the initial TraM binding occurs at these palindromic sequences. At higher protein concentrations the lengths of the DNA segments protected by TraM were increased towards the traM gene. In one region this extension leads to binding of TraM protein at its own promoters.