Cloning, E. coli overexpression, purification and binding properties of TraA and TraC, two proteins involved in the pheromone-dependent conjugation process in enterococci

The bacteriocin encoding plasmid pPD1 from Enterococcus faecalis is involved in a mating response to the sex pheromone cPD1 produced by recipient bacterial cells devoid of pPD1. Previous studies showed that cPD1 is internalized into donor cells in a process in which TraC plays the role of cell surface pheromone receptor. Inside the recipient cells, the pheromone binds to the plasmid-encoded cytoplasmic protein TraA, able to recognize specific DNA sequences and to modulate the conjugation process. To avoid self-induction of the conjugation process, donor cells produce the inhibitor iPD1, which competes with cPD1. This study was designed to produce recombinant TraA and TraC in a functionally active state and to evaluate their main functional properties. We have isolated the sequences encoding TraA and TraC from the plasmid pPD1 and cloned them in suitable expression vectors. The two recombinant proteins were successfully obtained in a soluble form using Escherichia coli as expression host and a T7 inducible expression system. TraC and TraA were purified to homogeneity by three or two chromatographic steps, respectively, leading to a final yield up to 4 mg/l of cell culture for TraC and up to 10 mg/l of cell culture for TraA. The ability of TraA and TraC to bind the specific pheromone and inhibitor peptides has been assessed by means of ESI-mass spectrometry. Moreover, the ability of recombinant TraA to bind DNA has been demonstrated by means of electrophoretic mobility shift assay. Overall these results are consistent with the heterologously expressed TraC and TraA being functionally active.     

Molecular Mechanism of Peptide-Specific Pheromone Signaling in Enterococcus faecalis: Functions of Pheromone Receptor TraA and Pheromone-Binding Protein TraC Encoded by Plasmid pPD1

Conjugative transfer of the Enterococcus faecalis plasmid pPD1 is activated by cPD1, one of several peptide sex pheromones secreted by plasmid-free recipient cells, and is blocked by a donor-produced peptide inhibitor, iPD1. Using a tritiated pheromone, [³H]cPD1, we investigated how pPD1-harboring donor cells receive these peptide signals. Donor cells rapidly incorporated [³H]cPD1. The cell extract but not the membrane fraction of the donor strain exhibited significant [³H]cPD1-binding activity. On the basis of these data and those of tracer studies, it was demonstrated that cPD1 was internalized, where it bound to a high-molecular-weight compound. The cell extract of a strain carrying the traA-bearing multicopy plasmid (pDLHH21) also exhibited high [³H]cPD1-binding activity. A recombinant TraA exhibited a dissociation constant of 0.49 ± 0.08 nM against [³H]cPD1. iPD1 competitively inhibited [³H]cPD1 binding to TraA, whereas pheromones and inhibitors relating to other plasmid systems did not. These results show that TraA is a specific intracellular receptor for cPD1 and that iPD1 acts as an antagonist for TraA. A strain carrying the traC-bearing multicopy plasmid (pDLES23) exhibited significant [³H]cPD1-binding activity. A strain carrying traC-disrupted pPD1 (pAM351CM) exhibited lower [³H]cPD1-binding activity as well as lower sensitivity to cPD1 than a wild-type donor strain. Some of the other pheromones and inhibitors inhibited [³H]cPD1 binding to the traC transformant like cPD1 and iPD1 did. These results show that TraC, as an extracellular less-specific pheromone-binding protein, supports donor cells to receive cPD1.     

Cloning and characterization of a region of Enterococcus faecalis plasmid pPD1 encoding pheromone inhibitor (ipd), pheromone sensitivity (traC), and pheromone shutdown (traB) genes.

Bacteriocin plasmid pPD1 in Enterococcus faecalis encodes a mating response to recipient-produced sex pheromone cPD1. Once a recipient acquires pPD1, transconjugants apparently shut off cPD1 activity in broth culture and no longer behave as recipients for pPD1. This event is performed by synthesis of the pheromone inhibitor iPD1 and also by repression of cPD1 production, the so-called "pheromone shutdown." A 5.4-kb EcoRV-HincII segment of pPD1, which expressed iPD1 in Escherichia coli, was sequenced and found to be organized as traC-traB-traA-ipd; each open reading frame is analogous to that found in other pheromone plasmids, pAD1 and pCF10, and thus is designated in accordance with the nomenclature in pAD1. The ipd gene encodes a peptide consisting of 21 amino acids, in which the C-terminal eight residues correspond to iPD1. The putative TraC product has a strong similarity to oligopeptide-binding proteins found in other bacterial species, as do pheromone-binding proteins of pCF10 and pAD1. A strain carrying traC-disrupted pPD1 required a concentration of cPD1 fourfold higher than that needed by the wild-type strain for induction of sexual aggregation. These results suggest that the TraC product contributes to pheromone sensitivity as a pheromone-binding protein. A strain transformed with traB-disrupted pPD1 produced a high level of cPD1 similar to that produced by plasmid-free recipients and underwent self-induction. Thus, the TraB product contributes to cPD1 shutdown.     

Isolation and structure of the sex pheromone inhibitor, iPD1, excreted by Streptococcus faecalis donor strains harboring plasmid pPD1.

The sex pheromone inhibitor iPD1, which is excreted by Streptococcus faecalis donor strains harboring bacteriocin plasmid pPD1 and which inhibits sex pheromone cPD1, was isolated, and its structure was determined. Its molecular weight is 828, and its amino acid sequence is H-Ala-Leu-Ile-Leu-Thr-Leu-Val-Ser-OH.     

Targeted disruption of the PD78 gene (traF) reduces pheromone-inducible conjugal transfer of the bacteriocin plasmid pPD1 in Enterococcus faecalis

Abstract Bacterial sex pheromone, cPD1, induces sexual aggregation of Enterococcus faecalis harboring the bacteriocin plasmid, pPD1, and enables pPD1 to transfer at high frequency in a liquid culture. PD78 is a cPD1-inducible cell surface protein encoded by pPD1. The PD78 gene, traF , was disrupted by homologous recombination between pPD1 and an artificial vector having a deletion in the middle portion of traF . The disruption of traF did not affect the cPD1-inducible aggregation but reduced the transfer frequency of pPD1 to 2% of the wild-type level.     

Identification of aggregation substances of Enterococcus faecalis cells after induction by sex pheromones

The sex pheromone system of Enterococcus faecalis is responsible for the clumping response of a plasmid carrying donor strain with a corresponding plasmid free recipient strain due to the production of sex pheromones by the recipient strain. The clumping response is mediated by a surface material (called aggregation substance) which is synthesized upon addition of sex pheromones to the cultures. Here we show that after induction a dense layer of hairlike structures is formed on the cell wall of the bacteria. These hairlike structures are responsible for the cell-cell contact which leads to the aggregation of cells. Formation of these structures was specific, only occurring after the addition of homologous sex pheromone.Abbreviations cAD1 sex pheromone specific for plasmid pAD1 - cPD1 sex pheromone specific for plasmid pPD1 - CW cell wall - pAD1 conjugative plasmid specifically transferred in the presence of cAD1 - pPD1 conjugative plasmid specifically transferred in the presence of cPD1 - PBS 10 mM Na-phosphate pH 7.5, 0.85% NaCl     

Genetic Analysis of Plasmid-specific Pheromone Signaling Encoded by pPD1 in Enterococcus faecalis

Certain plasmids in Enterococcus faecalis encode a mating response to recipient-produced peptide sex pheromones. Targeted disruption of tra genes on pPD1 suggested that TraA plays a central role in the plasmid-specific pheromone signaling pathway. TraA functioned as a negative regulator for the pheromone-inducible conjugal transfer. Complementation analysis of pPD1 tra gene mutants by pAD1 suggested that the pheromone binding function of TraC was non-specific between these plasmids, but the function of TraA and the pheromone shutdown function of TraB are plasmid-specific.     

pAM401-based shuttle vectors that enable overexpression of promoterless genes and one-step purification of tag fusion proteins directly from Enterococcus faecalis

Two novel Enterococcus faecalis-Escherichia coli shuttle vectors that utilize the promoter and ribosome binding site of bacA on the E. faecalis plasmid pPD1 were constructed. The vectors were named pMGS100 and pMGS101. pMGS100 was designed to overexpress cloned genes in E. coli and E. faecalis and encodes the bacA promoter followed by a cloning site and stop codon. pMGS101 was designed for the overexpression and purification of a cloned protein fused to a Strep-tag consisting of 9 amino acids at the carboxyl terminus. The Strep-tag provides the cloned protein with an affinity to immobilized streptavidin that facilitates protein purification. We cloned a promoterless beta-galactosidase gene from E. coli and cloned the traA gene of the E. faecalis plasmid pAD1 into the vectors to test gene expression and protein purification, respectively. beta-Galactosidase was expressed in E. coli and E. faecalis at levels of 10(3) and 10 Miller units, respectively. By cloning the pAD1 traA into pMGS101, the protein could be purified directly from a crude lysate of E. faecalis or E. coli with an immobilized streptavidin matrix by one-step affinity chromatography. The ability of TraA to bind DNA was demonstrated by the DNA-associated protein tag affinity chromatography method using lysates prepared from both E. coli and E. faecalis that overexpress TraA. The results demonstrated the usefulness of the vectors for the overexpression and cis/trans analysis of regulatory genes, purification and copurification of proteins from E. faecalis, DNA binding analysis, determination of translation initiation site, and other applications that require proteins purified from E. faecalis.     

Physical mapping of the conjugative bacteriocin plasmid pPD1 of Enterococcus faecalis and identification of the determinant related to the pheromone response.

The pheromone-responding conjugative bacteriocin plasmid pPD1 (59 kb) of Enterococcus faecalis was mapped physically by using a relational clone approach, and transposon analysis with Tn917 (Emr) or Tn916 (Tcr) facilitated the location of the bacteriocin-related genes in a segment of about 6.7 kb. Tn917 insertions within a 3-kb region resulted in constitutive clumping. The nucleotide sequence of the region that included the insertions giving rise to constitutive clumping was determined. The region of pPD1 spanned about 8 kb and was found to contain a number of open reading frames, some of which were named on the basis of homologies with two other pheromone-responding plasmids, pAD1 and pCF10. The genes were arranged in the sequence repB-repA-traC-traB-traA-ipd-traE-traF- orfY-sea-1 with all but repB and traA oriented in the same (left-to-right) direction. traC and traB corresponded, respectively, to traC and traB of pAD1 and to prgY and prgZ of pCF10.     

Genetic analysis of the pAD1 pheromone response in Streptococcus faecalis, using transposon Tn917 as an insertional mutagen

The conjugative plasmid pAD1 (56.7 kilobases) in Streptococcus faecalis has been shown to confer a mating response to the sex pheromone cAD1 excreted by recipient strains. The response is characterized by the synthesis of a proteinaceous adhesin which coats the surface of the pAD1 -containing donor cell and facilitates the formation of mating aggregates. Donors exposed to cAD1 -containing filtrates of recipients undergo self-aggregation (clumping), an event believed to be associated with an interaction between the adhesin and a binding substance always present on the surface of both recipients and donors. To analyze the molecular processes involved in the mating response, mutants were generated by the erythromycin resistance transposon Tn917 . Transpositions to pAD1 in S. faecalis DS16 gave rise to a number of derivatives that exhibited "constitutive clumping" and the ability to transfer at high frequencies in short (10-min) matings. These mutants fell into two subclasses, which exhibited colony morphologies that were "dry" or "normal". The Tn917 insertions were mapped by restriction enzyme analysis to two separate clusters, designated traA and traB. The dry colony subclass corresponded to traA and represented a span of 1.5 kilobases, whereas the normal subclass corresponded to traB and spanned 1.3 kilobases. The two clusters were separated by 1.7 kilobases in which insertions of Tn917 did not affect the ability to respond normally to cAD1 . Neither type of constitutive clumper produced cAD1 . Another series of insertions exhibited reduced donor potential. In two cases, the reduction in transfer was three to four orders of magnitude; these mapped in traA . In two other cases, the reduction was one to two orders of magnitude. These mapped outside of traA and traB, and one was associated with an increase in plasmid copy number.     

Specific control of endogenous cCF10 pheromone by a conserved domain of the pCF10-encoded regulatory protein PrgY in Enterococcus faecalis

Conjugative transfer of Enterococcus faecalis plasmid pCF10 is induced by the heptapeptide pheromone cCF10. cCF10 produced by plasmid-free recipient cells is detected by pCF10-containing donor cells, which respond by induction of plasmid-encoded transfer functions. The pCF10-encoded membrane protein PrgY is essential to prevent donor cells from responding to endogenously produced pheromone while maintaining the ability to respond to pheromone from an exogenous source; this function has not been identified in any nonenterococcal prokaryotic signaling system. PrgY specifically inhibited endogenous cCF10 and cPD1 (a pheromone that induces transfer of closely related plasmid pPD1) but not cAD1 (which is specific for less-related plasmid pAD1). Ectopic expression of PrgY in plasmid-free recipient cells reduced pheromone activity in culture supernatants and reduced the ability of these cells to acquire pCF10 by conjugation but did not have any effect on the interaction of these cells with exogenously supplied cCF10. The cloned prgY gene could complement a pCF10 prgY null mutation, and complementation was used to identify point mutations impairing PrgY function. Such mutations also abolished the inhibitory effect of PrgY expression in recipients on pheromone production and on acquisition of pCF10. Most randomly generated point mutations identified in the genetic screen mapped to a predicted extracellular domain in the N terminus of PrgY that is conserved in a newly identified family of related proteins from disparate species including Borrelia burgdorferi, Archaeoglobus fulgidus, Arabidopsis thaliana, and Homo sapiens. The combined genetic and physiological data suggest that PrgY may sequester or inactivate cCF10 as it is released from the membrane.     

Analysis of the transfer region of the Streptomyces plasmid SCP2*

plJ903, a bifunctional derivative of the 31.4 kb low-copy number, conjugative Streptomyces plasmid SCP², was mutagenized in Streptomyces lividans using Tn4560. Mutant plasmids differing in their transfer frequencies, chromosome mobilization abilities, pock formation, and complementation properties were isolated. The mutations defined five transfer-related genes, traA, traB, traC, traD and spd, clustered in a region of 9 kb. The deduced sequences of the putative TraA and TraB proteins showed no overall similarity to known protein sequences, but the phenotype of traA mutant plasmids and sequence motifs in the putative TraA protein suggested that it might be a DNA helicase.