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

Common requirement for the relaxosome of plasmid R1 in multiple activities of the conjugative type IV secretion system

Macromolecular transport by bacterial type IV secretion systems involves regulated uptake of (nucleo)protein complexes by the cell envelope-spanning transport channel. A coupling protein receptor is believed to recognize the specific proteins destined for transfer, but the steps initiating their translocation remain unknown. Here, we investigate the contribution of a complex of transfer initiation proteins, the relaxosome, of plasmid R1 to translocation of competing transferable substrates from mobilizable plasmids ColE1 and CloDF13 or the bacteriophage R17. We found that not only does the R1 translocation machinery engage the R1 relaxosome during conjugative self-transfer and during infection by R17 phage but it is also activated by its cognate relaxosome to mediate the export of an alternative plasmid. Transporter activity was optimized by the R1 relaxosome even when this complex itself could not be transferred, i.e., when the N-terminal activation domain (amino acids 1 to 992 [N1-992]) of TraI was present without the C-terminal conjugative helicase domain. We propose that the functional dependence of the transfer machinery on the R1 relaxosome for initiating translocation ensures that dissemination of heterologous plasmids does not occur at the expense of self-transfer.

Regulation of bacterial conjugation: balancing opportunity with adversity

Conjugative plasmids are involved in the dissemination of important traits such as antibiotic resistance, virulence determinants and metabolic pathways involved in adapting to environmental niches, a process termed horizontal or lateral gene transfer. Conjugation is the process of transferring DNA from a donor to a recipient cell with the establishment of the incoming DNA and its cargo of genetic traits within the transconjugant. Conjugation is mediated by self-transmissible plasmids as well as phage-like sequences that have been integrated into the bacterial chromosome, such as integrative and conjugative elements (ICEs) that now include conjugative transposons. Both conjugative plasmids and ICEs can mediate the transfer of mobilizable elements by sharing their conjugative machinery. Conjugation can either be induced, usually by small molecules or peptides or by excision of the ICE from the host chromosome, or it can be tightly regulated by plasmid- and host-encoded factors. The transfer potential of these transfer regions depends on the integration of many signals in response to environmental and physiological cues. This review will focus on the mechanisms that influence transfer potential in these systems, particularly those of the IncF incompatibility group.

Increased expression of the type IV secretion system in piliated Neisseria gonorrhoeae variants

Neisseria gonorrhoeae produces a type IV secretion system that secretes chromosomal DNA. The secreted DNA is active in the transformation of other gonococci in the population and may act to transfer antibiotic resistance genes and variant alleles for surface antigens, as well as other genes. We observed that gonococcal variants that produced type IV pili secreted more DNA than variants that were nonpiliated, suggesting that the process may be regulated. Using microarray analysis, we found that a piliated strain showed increased expression of the gene for the putative type IV secretion coupling protein TraD, whereas a nonpiliated variant showed increased expression of genes for transcriptional and translational machinery, consistent with its higher growth rate compared to that of the piliated strain. These results suggested that type IV secretion might be controlled by either traD expression or growth rate. A mutant with a deletion in traD was found to be deficient in DNA secretion. Further mutation and complementation analysis indicated that traD is transcriptionally and translationally coupled to traI, which encodes the type IV secretion relaxase. We were able to increase DNA secretion in a nonpiliated strain by inserting a gene cassette with a strong promoter to drive the expression of the putative operon containing traI and traD. Together, these data suggest a model in which the type IV secretion system apparatus is made constitutively, while its activity is controlled through regulation of traD and traI.

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.

The role of H-NS in silencing F transfer gene expression during entry into stationary phase

The conjugative ability of the F plasmid of Escherichia coli is highly growth phase dependent, with plasmid transfer efficiency dropping rapidly as donor cells progress through the growth cycle towards stationary phase. Transfer is dependent on the expression of the plasmid transfer (tra) genes, which are controlled by three plasmid-encoded regulatory proteins: TraJ, TraY and TraM. Here, we show that the nucleoid-associated host protein, H-NS, acts to repress the expression of traM and traJ as cells enter stationary phase, thereby decreasing mating ability to barely detectable levels. Sequence analysis identified regions of predicted intrinsic curvature, to which H-NS preferentially binds, at the promoters of both traM and traJ. H-NS binding at these regions was then confirmed by electrophoretic mobility shift and DNase I protection footprinting assays. Immunoblot assays displayed a significant increase in TraJ and TraM levels in an hns mutant strain. These findings were further supported by Northern and primer extension analyses which showed that whereas both genes were only expressed in early exponential phase in wild-type cells, hns mutant cells exhibited drastic derepression throughout the growth cycle. Transcriptional fusion studies of the individual promoters demonstrated that H-NS-mediated repression was observed when the promoters of both traM and traJ were present in cis to each other. This suggests that H-NS may bind to an extended region of the F plasmid, acting as a regional silencer of promoters for traJ and traM.

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).

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.

Transfer protein TraM stimulates TraI-catalyzed cleavage of the transfer origin of plasmid R1 in vivo

Factors contributing directly to the cleavage of the conjugative transfer origin of plasmid R1 in Escherichia coli were investigated. The essential transfer protein TraM was identified as a necessary positive effector of the catalytic activity of TraI relaxase at the R1 transfer origin in the absence of protein TraY. The stimulatory effect of TraM on the cleavage reaction in vivo correlated with the capacity of TraM to bind origin DNA. TraM was shown to be essential for heterologous mobilization of recombinant origin DNA. The requirement for TraM to promote mobilization was distinct from the protein's positive effect on transfer gene regulation. Chimeric traM alleles, fusing heterologous amino and carboxyl coding sequences from the traM genes of the R1 and the IncFI plasmid P307, were used to localize the specificity determinant of TraM's DNA binding activity. Use of the chimeric alleles also revealed that the requirement for TraM in mobilization is origin specific but transfer system independent. No evidence was found for a plasmid specific activity of TraM at a stage in the transfer process subsequent to the initial cleavage of origin DNA. In light of TraM's regulatory functions in transfer gene expression, we propose that TraM could control conjugative DNA processing in response to intracellular levels of transfer proteins.

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.

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.

Expression of gene 19 of the conjugative plasmid R1 is controlled by RNase III

Specific cleavage of mRNAs by RNase III has been shown to control the expression of several Escherichia coli genes. We show here that the expression of gene 19 of the conjugative resistance plasmid R1 is controlled in its expression by the same endoribonuclease. In vivo studies revealed that a DNA fragment of 150 nucleotides including a perfect 22 nucleotide inverted repeat in the gene 19 coding region is responsible for the low expression of the gene both at the protein and the RNA levels. By using a translational gene 19-lacZ fusion in isogenic RNase III+ and RNase III- strains we could identify RNase III as the key element in the down-regulation of gene 19 expression. The sequencing of in vitro generated and RNase III-digested transcripts confirmed the in vivo studies and revealed the exact positions of the RNase III cleavage sites within the coding part of the gene 19 transcript. The in vitro determined RNase III cleavage of gene 19 mRNA was confirmed by in vivo primer extension analysis. Finally, we could show that an exchange of three nucleotides within the RNase III recognition site abolished RNase III cleavage in vitro.

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.

The TraM protein of the conjugative plasmid F binds to the origin of transfer of the F and ColE1 plasmids

The gene encoding the TraM protein of the conjugative plasmid F was cloned, overexpressed and the gene product was purified. The TraM protein was found in the cytoplasm of cells carrying the F plasmid with a smaller amount in the inner membrane. DNase I footprinting experiments showed that the purified protein protects three regions in the F oriT locus with different affinity for the upper and lower strands of DNA. A 15-nucleotide motif was identified within the protected regions that represented the DNA-binding site. The TraM protein was also found to bind to a sequence in the oriT region of the non-conjugative plasmid ColE1 that resembles the three binding sites in the F oriT region.

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.

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.