FinOP repression of the F plasmid involves extension of the half-life of FinP antisense RNA by FinO

FinO/ProQ-family proteins: an evolutionary perspective

RNA-binding proteins are key actors of post-transcriptional networks. Almost exclusively studied in the light of their interactions with RNA ligands and the associated functional events, they are still poorly understood as evolutionary units. In this review, we discuss the FinO/ProQ family of bacterial RNA chaperones, how they evolve and spread across bacterial populations and what properties and opportunities they provide to their host cells. We reflect on major conserved and divergent themes within the family, trying to understand how the same ancestral RNA-binding fold, augmented with additional structural elements, could yield either highly specialised proteins or, on the contrary, globally acting regulatory hubs with a pervasive impact on gene expression. We also consider dominant convergent evolutionary trends that shaped their RNA chaperone activity and recurrently implicated the FinO/ProQ-like proteins in bacterial DNA metabolism, translation and virulence. Finally, we offer a new perspective in which FinO/ProQ-family regulators emerge as active evolutionary players with both negative and positive roles, significantly impacting the evolutionary modes and trajectories of their bacterial hosts.

Protein Dynamics in F-like Bacterial Conjugation

Efficient in silico development of novel antibiotics requires high-resolution, dynamic models of drug targets. As conjugation is considered the prominent contributor to the spread of antibiotic resistance genes, targeted drug design to disrupt vital components of conjugative systems has been proposed to lessen the proliferation of bacterial antibiotic resistance. Advancements in structural imaging techniques of large macromolecular complexes has accelerated the discovery of novel protein-protein interactions in bacterial type IV secretion systems (T4SS). The known structural information regarding the F-like T4SS components and complexes has been summarized in the following review, revealing a complex network of protein-protein interactions involving domains with varying degrees of disorder. Structural predictions were performed to provide insight on the dynamicity of proteins within the F plasmid conjugative system that lack structural information.

RNA-binding activity and regulatory functions of the emerging sRNA-binding protein ProQ

Regulatory small RNAs (sRNAs) ubiquitously impact bacterial physiology through antisense-mediated control of mRNA translation and stability. In Gram negative bacteria, sRNAs often associate with RNA-binding proteins (RBPs), both to gain cellular stability and to enable regulatory efficiency. The Hfq and CsrA proteins were for long the only known global RBPs implicated in sRNA biology. During the last five years, the FinO domain-containing protein ProQ has emerged as another global RBP with a broad spectrum of sRNA and mRNA ligands. This review provides a summary of the current knowledge of enterobacterial ProQ, with a special focus on RNA binding activity, RNA ligand preferences, influence on RNA stability and gene expression, and impact on bacterial physiology. Considering that characterization of ProQ is still in its infancy, we highlight aspects that, when addressed, will provide important clues to the physiological functions and regulatory mechanisms of this globally acting RBP.

ProQ/FinO-domain proteins: another ubiquitous family of RNA matchmakers?

Small RNAs (sRNAs), particularly those that act by limited base pairing with mRNAs, are part of most regulatory networks in bacteria. In many cases, the base-pairing interaction is facilitated by the RNA chaperone Hfq. However, not all bacteria encode Hfq and some base-pairing sRNAs do not require Hfq raising the possibility of other RNA chaperones. Candidates are proteins with homology to FinO, a factor that promotes base pairing between the FinP antisense sRNA and the traJ mRNA to control F plasmid transfer. Recent papers have shown that the Salmonella enterica FinO-domain protein ProQ binds a large suite of sRNAs, including the RaiZ sRNA, which represses translation of the hupA mRNA, and the Legionella pneumophila protein RocC binds the RocR sRNA, which blocks expression of competence genes. Here we discuss what is known about FinO-domain structures, including the recently solved Escherichia coli ProQ structure, as well as the RNA binding properties of this family of proteins and evidence they act as chaperones. We compare these properties with those of Hfq. We further summarize what is known about the physiological roles of FinO-domain proteins and enumerate outstanding questions whose answers will establish whether they constitute a second major class of RNA chaperones.

Plasmids in the driving seat: The regulatory RNA Rcd gives plasmid ColE1 control over division and growth of its E. coli host

Regulation by non-coding RNAs was found to be widespread among plasmids and other mobile elements of bacteria well before its ubiquity in the eukaryotic world was suspected. As an increasing number of examples was characterised, a common mechanism began to emerge. Non-coding RNAs, such as CopA and Sok from plasmid R1, or RNAI from ColE1, exerted regulation by refolding the secondary structures of their target RNAs or modifying their translation. One regulatory RNA that seemed to swim against the tide was Rcd, encoded within the multimer resolution site of ColE1. Required for high fidelity maintenance of the plasmid in recombination-proficient hosts, Rcd was found to have a protein target, elevating indole production by stimulating tryptophanase. Rcd production is up-regulated in dimer-containing cells and the consequent increase in indole is part of the response to the rapid accumulation of dimers by over-replication (known as the dimer catastrophe). It is proposed that indole simultaneously inhibits cell division and plasmid replication, stopping the catastrophe and allowing time for the resolution of dimers to monomers. The idea of a plasmid-mediated cell division checkpoint, proposed but then discarded in the 1980s, appears to be enjoying a revival.

The FinO family of bacterial RNA chaperones

Antisense RNAs have long been known to regulate diverse aspects of plasmid biology. Here we review the FinOP system that modulates F plasmid gene expression through regulation of the F plasmid transcription factor, TraJ. FinOP is a two component system composed of an antisense RNA, FinP, which represses TraJ translation, and a protein, FinO, which is required to stabilize FinP and facilitate its interactions with its traJ mRNA target. We review the evidence that FinO acts as an RNA chaperone to bind and destabilize internal stem-loop structures within the individual RNAs that would otherwise block intermolecular RNA duplexing. Recent structural studies have provided mechanistic insights into how FinO may facilitate interactions between FinP and traJ mRNA. We also review recent findings that two other proteins, Escherichia coli ProQ and Neisseria meningitidis NMB1681, may represent FinO-like RNA chaperones.

ProQ is an RNA chaperone that controls ProP levels in Escherichia coli

Transporter ProP mediates osmolyte accumulation in Escherichia coli cells exposed to high osmolality media. The cytoplasmic ProQ protein amplifies ProP activity by an unknown mechanism. The N- and C-terminal domains of ProQ are predicted to be structurally similar to known RNA chaperone proteins FinO and Hfq from E. coli. Here we demonstrate that ProQ is an RNA chaperone, binding RNA and facilitating both RNA strand exchange and RNA duplexing. Experiments performed with the isolated ProQ domains showed that the FinO-like domain serves as a high-affinity RNA-binding domain, whereas the Hfq-like domain is largely responsible for RNA strand exchange and duplexing. These data suggest that ProQ may regulate ProP production. Transcription of proP proceeds from RpoD- and RpoS-dependent promoters. Lesions at proQ affected ProP levels in an osmolality- and growth phase-dependent manner, decreasing ProP levels when proP was expressed from its own chromosomal promoters or from a heterologous plasmid-based promoter. Small RNA molecules are known to regulate cellular levels of sigma factor RpoS. ProQ did not act by changing RpoS levels since proQ lesions did not influence RpoS-dependent stationary phase thermotolerance and they affected ProP production and activity similarly in bacteria without and with an rpoS defect. Taken together, these results suggest that ProQ does not regulate proP transcription. It may act as an RNA-binding protein to regulate proP translation.

Mapping interactions between the RNA chaperone FinO and its RNA targets

Bacterial conjugation is regulated by two-component repression comprising the antisense RNA FinP, and its protein co-factor FinO. FinO mediates base-pairing of FinP to the 5′-untranslated region (UTR) of traJ mRNA, which leads to translational inhibition of the transcriptional activator TraJ and subsequent down regulation of conjugation genes. Yet, little is known about how FinO binds to its RNA targets or how this interaction facilitates FinP and traJ mRNA pairing. Here, we use solution methods to determine how FinO binds specifically to its minimal high affinity target, FinP stem–loop II (SLII), and its complement SLIIc from traJ mRNA. Ribonuclease footprinting reveals that FinO contacts the base of the stem and the 3′ single-stranded tails of these RNAs. The phosphorylation or oxidation of the 3′-nucleotide blocks FinO binding, suggesting FinO binds the 3′-hydroxyl of its RNA targets. The collective results allow the generation of an energy-minimized model of the FinO–SLII complex, consistent with small-angle X-ray scattering data. The repression complex model was constrained using previously reported cross-linking data and newly developed footprinting results. Together, these data lead us to propose a model of how FinO mediates FinP/traJ mRNA pairing to down regulate bacterial conjugation.

N. meningitidis 1681 is a member of the FinO family of RNA chaperones

The conjugative transfer of F-like plasmids between bacteria is regulated by the plasmid-encoded RNA chaperone, FinO, which facilitates sense - antisense RNA interactions to regulate plasmid gene expression. FinO was thought to adopt a unique structure, however many putative homologs have been identified in microbial genomes and are considered members of the FinO_conjugation_repressor superfamily. We were interested in determining whether other members were also able to bind RNA and promote duplex formation, suggesting that this motif does indeed identify a putative RNA chaperone. We determined the crystal structure of the N. meningitidis MC58 protein NMB1681. It revealed striking similarity to FinO, with a conserved fold and a large, positively charged surface that could function in RNA interactions. Using assays developed to study FinO-FinP sRNA interactions, NMB1681, like FinO, bound tightly to FinP RNA stem-loops with short 5' and 3' single-stranded tails but not to ssRNA. It also was able to catalyze strand exchange between an RNA duplex and a complementary single-strand, and facilitated duplexing between complementary RNA hairpins. Finally, NMB1681 was able to rescue a finO deficiency and repress F plasmid conjugation. This study strongly suggests that NMB1681 is a FinO-like RNA chaperone that likely regulates gene expression through RNA-based mechanisms in N. meningitidis.

Hfq is a regulator of F-plasmid TraJ and TraM synthesis in Escherichia coli

The F plasmid of Escherichia coli allows horizontal DNA transfer between an F(+) donor cell and an F(-) recipient. Expression of the transfer genes is tightly controlled by a number of factors, including the following plasmid-encoded regulatory proteins: TraJ, the primary activator of the 33-kb tra operon, and the autoregulators TraM and TraY. Here, we demonstrate that the host RNA binding protein, Hfq, represses TraJ and TraM synthesis by destabilizing their respective mRNAs. Mating assays and immunoblot analyses for TraM and TraJ showed that transfer efficiency and protein levels increased in host cells containing a disruption in hfq compared to wild-type cells in stationary phase. The stability of transcripts containing a putative Hfq binding site located in the intergenic untranslated region between traM and traJ was increased in hfq mutant donor cells, suggesting that Hfq destabilizes these transcripts. Electrophoretic mobility shift assays demonstrated that Hfq specifically binds this region but not the antisense RNA, FinP, encoded on the opposite strand. Together, these findings indicate that Hfq regulates traM and traJ transcript stability by a mechanism separate from FinOP-mediated repression.

Regulation of traJ transcription in the Salmonella virulence plasmid by strand-specific DNA adenine hemimethylation

The traJ gene of the virulence plasmid of Salmonella enterica serovar Typhimurium (pSLT) encodes a transcriptional activator of the transfer operon. The leucine-responsive regulatory protein (Lrp) is an activator of traJ transcription. The upstream-activating-sequence of the pSLT traJ promoter contains two Lrp binding sites (LRP-1 and LRP-2), both necessary for transcriptional activation. The promoter-proximal site (LRP-2) contains a GATC site (GATC-II) whose methylation state affects Lrp binding: GATC-II methylation in both DNA strands decreases the affinity of Lrp for the LRP-2 site, while efficient Lrp binding occurs to a non-methylated GATC-II site. The effect of GATC-II hemimethylation on Lrp binding is strand-specific: methylation of the traJ non-coding strand permits formation of the major Lrp-DNA retardation complex, but methylation of the coding strand does not. This asymmetry supports a model in which passage of the replication fork may permit Lrp-mediated activation of conjugal transfer in one daughter plasmid molecule but not in the other. A remarkable trait of this regulatory design is that hemimethylation of a single GATC site can generate distinct epigenetic signals in otherwise identical plasmid DNA molecules.

Regulation of finP transcription by DNA adenine methylation in the virulence plasmid of Salmonella enterica

DNA adenine methylase (Dam(-)) mutants of Salmonella enterica serovar Typhimurium contain reduced levels of FinP RNA encoded on the virulence plasmid. Dam methylation appears to regulate finP transcription, rather than FinP RNA stability or turnover. The finP promoter includes canonical -10 and -35 modules and depends on the sigma(70) factor. Regulation of finP transcription by Dam methylation does not require DNA sequences upstream from the -35 module, indicating that Dam acts at the promoter itself or downstream. Unexpectedly, a GATC site overlapping with the -10 module is likewise dispensable for Dam-mediated regulation. These observations indicate that Dam methylation regulates finP transcription indirectly and suggest the involvement of a host factor(s) responsive to the Dam methylation state of the cell. We provide evidence that one such factor is the nucleoid protein H-NS, which acts as a repressor of finP transcription in a Dam(-) background. H-NS also restrains transcription of the overlapping traJ gene, albeit in a Dam-independent fashion. Hence, the decreased FinP RNA content found in Dam(-) hosts of S. enterica appears to result from H-NS-mediated repression of finP transcription.

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.

FinO is an RNA chaperone that facilitates sense-antisense RNA interactions

The protein FinO represses F-plasmid conjugative transfer by facilitating interactions between the mRNA of the major F-plasmid transcriptional activator, TraJ, and an antisense RNA, FinP. FinO is known to bind stem-loop structures in both FinP and traJ RNAs; however, the mechanism by which FinO facilitates sense-antisense pairing is poorly understood. Here we show that FinO acts as an RNA chaperone to promote strand exchange and duplexing between minimal RNA targets derived from FinP. This strongly suggests that FinO may function to destabilize internal secondary structures within FinP and traJ RNAs that would otherwise act as a kinetic trap to sense-antisense pairing. The energy for FinO-catalyzed base-pair destabilization does not arise from ATP hydrolysis but appears to be supplied directly from FinO RNA binding free energy. An analysis of the activities of mutants that are specifically deficient in strand exchange but not RNA-binding activity demonstrates that strand exchange is essential to the ability of FinO to mediate sense-antisense RNA recognition, and that this function also plays a role in repression of conjugation in vivo.

Characterizing the structural features of RNA/RNA interactions of the F-plasmid FinOP fertility inhibition system

F-like plasmid transfer is mediated by the FinOP fertility inhibition system. Expression of the F positive regulatory protein, TraJ, is controlled by the action of the antisense RNA, FinP, and the RNA-binding protein FinO. FinO binds to and protects FinP from degradation and promotes duplex formation between FinP and traJ mRNA, leading to repression of both traJ expression and conjugative F transfer. FinP antisense RNA secondary structure is composed of two stem-loops separated by a 4-base single-stranded spacer and flanked on each side by single-stranded tails. Here we show that disruption of the expected Watson-Crick base pairing between the loops of FinP stem-loop I and its cognate RNA binding partner, traJ mRNA stem-loop Ic, led to a moderate reduction in the rate of duplex formation in vitro. In vivo, alterations of the anti-ribosome binding site region in the loop of FinP stem-loop I reduced the ability of the mutant FinP to mediate fertility inhibition and to inhibit TraJ expression when expressed in trans at an elevated copy number. Alterations of intermolecular complementarity between the stems of these RNAs reduced the rate of duplex formation. Our results suggest that successful interaction between stem-loop I of FinP and stem-loop Ic of traJ mRNA requires that base pairing must proceed from an initial loop-loop interaction through the top portion of the stems for stable duplex formation to occur.

Plasmids spread very fast in heterogeneous bacterial communities

Conjugative plasmids can mediate gene transfer between bacterial taxa in diverse environments. The ability to donate the F-type conjugative plasmid R1 greatly varies among enteric bacteria due to the interaction of the system that represses sex-pili formations (products of finOP) of plasmids already harbored by a bacterial strain with those of the R1 plasmid. The presence of efficient donors in heterogeneous bacterial populations can accelerate plasmid transfer and can spread by several orders of magnitude. Such donors allow millions of other bacteria to acquire the plasmid in a matter of days whereas, in the absence of such strains, plasmid dissemination would take years. This "amplification effect" could have an impact on the evolution of bacterial pathogens that exist in heterogeneous bacterial communities because conjugative plasmids can carry virulence or antibiotic-resistance genes.

The positive regulator, TraJ, of the Escherichia coli F plasmid is unstable in a cpxA* background

The Cpx (conjugative plasmid expression) stress response of Escherichia coli is induced in response to extracytoplasmic signals generated in the cell envelope, such as misfolded proteins in the periplasm. Detection of stress is mediated by the membrane-bound histidine kinase, CpxA. Signaling of the response regulator CpxR by activated CpxA results in the expression of several factors required for responding to cell envelope stress. CpxA was originally thought to be required for the expression of the positive regulator of the F plasmid transfer (tra) operon, TraJ. It was later determined that constitutive gain-of-function mutations in cpxA led to activation of the Cpx envelope stress response and decreased TraJ expression. In order to determine the nature of the downregulation of TraJ, the level of expression of TraJ, TraM, and TraY, the F-encoded regulatory proteins of the F tra region, was determined both in a cpxA* background and in a wild-type background in which the Cpx stress response was induced by overexpression of the outer membrane lipoprotein, NlpE. Our results suggest that TraJ downregulation is controlled by a posttranscriptional mechanism that operates in the cytoplasm in response to upregulation of the Cpx stress response by both the cpxA* gain-of-function mutation and the overexpression of NlpE.

Interactions of Escherichia coli RNA with bacteriophage MS2 coat protein: genomic SELEX

Genomic SELEX is a method for studying the network of nucleic acid-protein interactions within any organism. Here we report the discovery of several interesting and potentially biologically important interactions using genomic SELEX. We have found that bacteriophage MS2 coat protein binds several Escherichia coli mRNA fragments more tightly than it binds the natural, well-studied, phage mRNA site. MS2 coat protein binds mRNA fragments from rffG (involved in formation of lipopolysaccharide in the bacterial outer membrane), ebgR (lactose utilization repressor), as well as from several other genes. Genomic SELEX may yield experimentally induced artifacts, such as molecules in which the fixed sequences participate in binding. We describe several methods (annealing of oligonucleotides complementary to fixed sequences or switching fixed sequences) to eliminate some, or almost all, of these artifacts. Such methods may be useful tools for both randomized sequence SELEX and genomic SELEX.

Synthesis of FinP RNA by plasmids F and pSLT is regulated by DNA adenine methylation

DNA adenine methylase mutants of Salmonella typhimurium contain reduced amounts of FinP, an antisense RNA encoded by the virulence plasmid pSLT. Lowered FinP levels are detected in both Dam- FinO+ and Dam- FinO- backgrounds, suggesting that Dam methylation regulates FinP production rather than FinP half-life. Reduced amounts of F-encoded FinP RNA are likewise found in Dam- mutants of Escherichia coli. A consequence of FinP RNA scarcity in the absence of DNA adenine methylation is that Dam- mutants of both S. typhimurium and E. coli show elevated levels of F plasmid transfer. Inhibition of F fertility by the S. typhimurium virulence plasmid is also impaired in a Dam- background.

In vitro analysis of the interaction between the FinO protein and FinP antisense RNA of F-like conjugative plasmids

The FinO protein regulates the transfer potential of F-like conjugative plasmids through its interaction with FinP antisense RNA and its target, traJ mRNA. FinO binds to and protects FinP from degradation and promotes duplex formation between FinP and traJ mRNA in vitro. The FinP secondary structure consists of two stem-loop domains separated by a 4-base spacer and terminated by a 6-base tail. Previous studies suggested FinO bound to the smooth 14-base pair helix of stem-loop II. In this investigation, RNA mobility shift analysis was used to study the interaction between a glutathione S-transferase (GST)-FinO fusion protein and a series of synthetic FinP and traJ mRNA variants. Mutations in 16 of the 28 bases in stem II of FinP that are predicted to disrupt base pairing did not significantly alter the GST-FinO binding affinity. Removal of the single-stranded regions on either side of stem-loop II led to a dramatic decrease in GST-FinO binding to FinP and to the complementary region of the traJ mRNA leader. While no evidence for sequence-specific contacts was found, the results suggest that FinO recognizes the overall shape of the RNA and is influenced by the length of the single-stranded regions flanking the stem-loop.

Degradation of FinP antisense RNA from F-like plasmids: the RNA-binding protein, FinO, protects FinP from ribonuclease E

Transfer of F-like plasmids is regulated by the FinOP system, which controls the expression of traJ, a positive regulator of the transfer operon. F FinP is a 79 base antisense RNA, composed of two stem-loops, complementary to the 5' untranslated leader of traJ mRNA. Binding of FinP to the traJ leader sequesters the traJ ribosome binding site, preventing its translation and repressing plasmid transfer. The FinO protein binds stem-loop II of FinP and traJ mRNA and promotes duplex formation in vitro. FinO stabilizes FinP, increasing its effective concentration in vivo. To determine how FinO protects FinP from decay, the degradation of FinP was examined in a series of ribonuclease-deficient strains. Using Northern blot analysis, full-length FinP was found to be stabilized sevenfold in an RNase E-deficient strain. The major site of RNase E cleavage was mapped on synthetic FinP, to the single-stranded region between stem-loops I and II. A secondary site near the 5' end ( approximately 10 bases) was also observed. A GST-FinO fusion protein protected FinP from RNase E cleavage at both sites in vitro. Two duplexes between FinP and traJ mRNA were detected in an RNase III-deficient strain. The larger duplex resulted from extension of the FinP transcript at its 3' end, suggesting readthrough at the terminator that corresponds to FinP stem-loop II. A point mutant of finP (finP305; C30U) that is unable to repress traJ in the presence of FinO was also characterized. The pattern of RNase E digestion of finP305 RNA differed from FinP, and GST-FinO did not protect finP305 RNA from cleavage in vitro. The half-life of finP305 RNA decreased more than tenfold in vivo, such that the steady-state levels of finP305 RNA, in the presence of FinO, were insufficient to significantly reduce the level of traJ mRNA available for translation, allowing derepressed levels of transfer.

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.

Control of genes for conjugative transfer of plasmids and other mobile elements

Conjugative transfer is a primary means of spread of mobile genetic elements (plasmids and transposons) between bacteria.It leads to the dissemination and evolution of the genes (such as those conferring resistance to antibiotics) which are carried by the plasmid. Expression of the plasmid genes needed for conjugative transfer is tightly regulated so as to minimise the burden on the host. For plasmids such as those belonging to the IncP group this results in downregulation of the transfer genes once all bacteria have a functional conjugative apparatus. For F-like plasmids (apart from F itself which is a derepressed mutant) tight control results in very few bacteria having a conjugative apparatus. Chance encounters between the rare transfer-proficient bacteria and a potential recipient initiate a cascade of transfer which can continue until all potential recipients have acquired the plasmid. Other systems express their transfer genes in response to specific stimuli. For the pheromone-responsive plasmids of Enterococcus it is small peptide signals from potential recipients which trigger the conjugative transfer genes. For the Ti plasmids of Agrobacterium it is the presence of wounded plants which are susceptible to infection which stimulates T-DNA transfer to plants. Transfer and integration of T-DNA induces production of opines which the plasmid-positive bacteria can utilise. They multiply and when they reach an appropriate density their plasmid transfer system is switched on to allow transfer of the Ti plasmid to other bacteria. Finally some conjugative transfer systems are induced by the antibiotics to which the elements confer resistance. Understanding these control circuits may help to modify management of microbial communities where plasmid transfer is either desirable or undesirable. z 1998 Published by Elsevier Science B.V.

The FinO protein of IncF plasmids binds FinP antisense RNA and its target, traJ mRNA, and promotes duplex formation

Most of the genes required for the conjugative transfer of DNA are encoded by the 33 kb transfer (tra) operon of F-like conjugative plasmids. Transcription of the tra operon is positively regulated by the TraJ transcriptional activator which, in turn, is negatively regulated by the FinOP fertility inhibition system. The FinOP system consists of an antisense RNA, FinP, and a 21.2 kDa protein, FinO, which together inhibit TraJ expression. Previously, it has been demonstrated that FinO increases the in vivo stability of the FinP RNA in the absence of the traJ mRNA target. Using electrophoretic mobility shift assays, we have shown that FinO is an RNA-binding protein that binds to one of the two stem-loops in FinP and to its complementary structure in traJ mRNA. This interaction presumably protects FinP RNA from degradation in vivo and increases the rate of formation of the FinP-traJ mRNA duplex fivefold. Thus, TraJ expression appears to be influenced by a unique RNA-protein interaction that precedes duplex formation between the FinP antisense RNA and its target traJ mRNA.

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.

Structural and functional analyses of the FinP antisense RNA regulatory system of the F conjugative plasmid

The efficiency of conjugation of F-like plasmids is regulated by the FinOP fertility inhibition system. The transfer (tra) operon is under the direct control of the TraJ transcriptional activator which, in turn, is negatively regulated by FinP, an antisense RNA, and FinO, a 22 kDa protein. Recently, FinO has been shown to extend the chemical stability of FinP in vivo in the absence of traJ mRNA. The in vitro secondary structures of both the FinP and TraJ RNAs were determined by the use of single- and double-strand-specific nucleases; both RNAs were found to have double stem-loop structures that are complementary to each other and, therefore, FinP RNA and TraJ RNA have the potential to form a duplex with each other. This was verified by in vitro binding experiments. The reaction was shown to be biomolecular with an apparent rate constant (kapp) of 5 x 10(5)M-1s-1, a value that is similar to those found for other natural antisense RNA systems. Preliminary evidence for the in vivo formation of the FinP-TraJ RNA duplex was obtained by primer extension of the traJ mRNA; the presence of both FinO and FinP was required to cause a dramatic reduction in the steady-state level of traJ mRNA, perhaps as a result of RNase III degradation of the resulting RNA duplex.