Potential of the enterocin regulatory system to control expression of heterologous genes in Enterococcus.

AIMS: To exploit the enterocin regulatory system for regulated expression of genes in Enterococcus. METHODS AND RESULTS: Production of some pediocin-like bacteriocins such as enterocin A in Enterococcus is regulated by a three-component system comprising a histidine kinase (entK ), a response regulator (entR) and an induction factor (entF ). Exposure to the induction factor results in the transcription of gene(s) under the control of the enterocin A promoter, including entA which encodes the bacteriocin. In an effort to exploit this system for expression of genes in Enterococcus, a number of vectors were constructed which contain the entA promoter followed by convenient cloning sites to introduce gene(s) of interest. These vectors were used in an enterococcal background which does not produce induction factor but does produce both the kinase and regulator proteins. The system was tested using the reporter genes ltnI (lacticin 3147 immunity) and gusA (beta-glucuronidase) under the control of the entA promoter. CONCLUSIONS: Upon addition of the induction factor, the beta-glucuronidase activity increased 20-fold when compared with uninduced cells. In addition, concentrations of as little as 0.2 nm synthetic EntF were sufficient to give maximal expression. SIGNIFICANCE AND IMPACT OF THE STUDY: The potential benefit of having an expression system based on EntF is that gene expression can be finely controlled upon addition of low concentrations of a peptide that can easily be artificially synthesized.

Exploitation of plasmid pMRC01 to direct transfer of mobilizable plasmids into commercial lactococcal starter strains.

Genetic analysis of the 60.2-kb lactococcal plasmid pMRC01 revealed a 19.6-kb region which includes putative genes for conjugal transfer of the plasmid and a sequence resembling an origin of transfer (oriT). This oriT-like sequence was amplified and cloned on a 312-bp segment into pCI372, allowing the resultant plasmid, pRH001, to be mobilized at a frequency of 3.4 x 10(-4) transconjugants/donor cell from an MG1363 (recA mutant) host containing pMRC01. All of the resultant chloramphenicol-resistant transconjugants contained both pRH001 and genetic determinants responsible for bacteriocin production and immunity of pMRC01. This result is expected, given that transconjugants lacking the lacticin 3147 immunity determinants (on pMRC01) would be killed by bacteriocin produced by the donor cells. Indeed, incorporation of proteinase K in the mating mixture resulted in the isolation of transformants, of which 47% were bacteriocin deficient. Using such an approach, the oriT-containing fragment was exploited to mobilize pRH001 alone to a number of lactococcal hosts. These results demonstrate that oriT of pMRC01 has the potential to be used in the development of mobilizable food-grade vectors for the genetic enhancement of lactococcal starter strains, some of which may be difficult to transform.

Naturally occurring lactococcal plasmid pAH90 links bacteriophage resistance and mobility functions to a food-grade selectable marker.

The bacteriophage resistance plasmid pAH90 (26,490 bp) is a natural cointegrate plasmid formed via homologous recombination between the type I restriction-modification specificity determinants (hsdS) of two smaller lactococcal plasmids, pAH33 (6,159 bp) and pAH82 (20,331 bp), giving rise to a bacteriophage-insensitive mutant following phage challenge (D. O'Sullivan, D. P. Twomey, A. Coffey, C. Hill, G. F. Fitzgerald, and R. P. Ross, Mol. Microbiol. 36:866-876; 2000). In this communication we provide evidence that the recombination event is favored by phage infection. The entire nucleotide sequence of plasmid pAH90 was determined and found to contain 24 open reading frames (ORFs) responsible for phenotypes which include restriction-modification, phage adsorption inhibition, plasmid replication, cadmium resistance, cobalt transport, and conjugative mobilization. The cadmium resistance property, encoded by the cadA gene, which has an associated regulatory gene (cadC), is of particular interest, as it facilitated the selection of pAH90 in other phage-sensitive lactococci after electroporation. In addition, we report the identification of a group II self-splicing intron bounded by two exons which have the capacity to encode a relaxase implicated in conjugation in gram-positive bacteria. The functionality of this intron was evident by demonstrating splicing in vivo. Given that pAH90 encodes potent phage defense systems which act at different stages in the phage lytic cycle, the linkage of these with a food-grade selectable marker on a replicon that can be mobilized among lactococci has significant potential for natural strain improvement for industrial dairy fermentations which are susceptible to phage inhibition.

Protection against Staphylococcus aureus mastitis in dairy cows using a bismuth-based teat seal containing the bacteriocin, lacticin 3147.

We assessed the effectiveness of a novel dry cow treatment containing lacticin 3147 using deliberate challenge studies in lactating cows. Infection-free quarters of lactating cows were infused with Teat seal (Cross Vetpharm Group, Ltd., Dublin, Ireland) combined with the food-grade bacteriocin, lacticin 3147. Natural infection of the teat was simulated by deliberately introducing Staphylococcus aureus into the teat duct and teat sinus. Relative to control quarters, teat seal plus lacticin 3147 reduced the number of teats shedding viable cells when an inoculum of either approximately 1.7 x 10(3) or approximately 6.8 x 10(3) cfu per teat was used. In addition, the numbers of challenge organisms in those teats from which S. aureus was subsequently recovered were also reduced. However, when the concentration of bacteriocin in the teat seal formulation was reduced by approximately 50%, the number of teats shedding S. aureus cells was not reduced. These data indicate the potential for lacticin 3147 to prevent staphylococcal mastitis infections when a sufficient concentration of the bacteriocin is present. This study also highlights the application of a lactating-cow model to assess the effectiveness of antimicrobial intramammary products on mastitic cell populations.

Characterization of AbiR, a novel multicomponent abortive infection mechanism encoded by plasmid pKR223 of Lactococcus lactis subsp. lactis KR2.

The native lactococcal plasmid pKR223 encodes two distinct phage resistance mechanisms, a restriction and modification (R/M) system designated LlaKR2I and an abortive infection mechanism (Abi) which affects prolate-headed-phage proliferation. The nucleotide sequence of a 16,174-bp segment of pKR223 encompassing both the R/M and Abi determinants has been determined, and sequence analysis has validated the novelty of the Abi system, which has now been designated AbiR. Analysis of deletion and insertion clones demonstrated that AbiR was encoded by two genetic loci, separated by the LlaKR2I R/M genes. Mechanistic studies on the AbiR phenotype indicated that it was heat sensitive and that it impeded phage DNA replication. These data indicated that AbiR is a novel multicomponent, heat-sensitive, "early"-functioning Abi system and is the first lactococcal Abi system described which is encoded by two separated genetic loci.

Novel type I restriction specificities through domain shuffling of HsdS subunits in Lactococcus lactis.

This study identifies a natural system in Lactococcus lactis, in which a restriction modification specificity subunit resident on a 6159 bp plasmid (pAH33) alters the specificity of a functional R/M mechanism encoded by a 20.3 kb plasmid, pAH82. The new specificity was identified after phenotypic and molecular analysis of a 26.5 kb co-integrate plasmid (pAH90), which was detected after bacteriophage challenge of the parent strain. Analysis of the regions involved in the co-integration revealed that two novel hybrid hsdS genes had been formed during the co-integration event. The HsdS chimeras had interchanged the C- and N-terminal variable domains of the parent subunits, generating two new restriction specificities. Comparison of the parent hsdS genes with other type I specificity determinants revealed that the region of the hsdS genes responsible for the co-integration event is highly conserved among lactococcal type I hsdS determinants. Thus, as hsdS determinants are widespread in the genus Lactococcus, new restriction specificities may evolve rapidly after homologous recombination between these genes. This study demonstrates that, similar to previous observations in Gram-negative bacteria, a Gram-positive bacterium can acquire novel restriction specificities naturally through domain shuffling of resident HsdS subunits.

Developing applications for lactococcal bacteriocins.

While much of the applied research carried out to date with bacteriocins has concerned nisin, lactococci produce other bacteriocins with economic potential. An example is the two component bacteriocin lacticin 3147, which is active over a wide pH range and has a broad spectrum of activity against gram-positive bacteria. Since the genetic determinants for lacticin 3147 are encoded on a large self-transmissible plasmid, the bacteriocin genes may be conveniently transferred to different lactococcal starters. The resulting food-grade strains can then be used to make a significant impact on the safety and quality of a variety of fermented foods, through the inhibition of undesirable microflora. The bacteriocin is heat stable so it can also be used as an ingredient in a powdered form such as a spray-dried fermentate. Given the observation that lacticin 3147 is effective at physiological pH, there is also considerable potential for biomedical applications. Field trials have demonstrated its efficacy in the prevention of mastitis infections in dairy cows. In contrast to lacticin 3147, the lactococcin bacteriocins A, B and M have a narrow spectrum of activity limited to lactococci. Strains which produce these inhibitors can be exploited in the acceleration of cheese ripening by assisting the premature lysis of starter cultures.

Molecular characterization of the Lactococcus lactis LlaKR2I restriction-modification system and effect of an IS982 element positioned between the restriction and modification genes.

The nucleotide sequence of the plasmid-encoded LlaKR2I restriction-modification (R-M) system of Lactococcus lactis subsp. lactis biovar diacetylactis KR2 was determined. This R-M system comprises divergently transcribed endonuclease (llaKR2IR) and methyltransferase (llaKR2IM) genes; located in the intergenic region is a copy of the insertion element IS982, whose putative transposase gene is codirectionally transcribed with llaKR2IM. The deduced sequence of the LlaKR2I endonuclease shared homology with the type II endonuclease Sau3AI and with the MutH mismatch repair protein, both of which recognize and cleave the sequence 5' GATC 3'. In addition, M. LlaKR2I displayed homology with the 5-methylcytosine methyltransferase family of proteins, exhibiting greatest identity with M. Sau3AI. Both of these proteins shared notable homology throughout their putative target recognition domains. Furthermore, subclones of the native parental lactococcal plasmid pKR223, which encode M. LlaKR2I, all remained undigested after treatment with Sau3AI despite the presence of multiple 5' GATC 3' sites. The combination of these data suggested that the specificity of the LlaKR2I R-M system was likely to be 5' GATC 3', with the cytosine residue being modified to 5-methylcytosine. The IS982 element located within the LlaKR2I R-M system contained at its extremities two 16-bp perfect inverted repeats flanked by two 7-bp direct repeats. A perfect extended promoter consensus, which represented the likely original promoter of the llaKR2IR gene, was shown to overlap the direct repeat sequence on the other side of IS982. Specific deletion of IS982 and one of these direct repeats via a PCR strategy indicated that the LlaKR2I R-M determinants do not rely on elements within IS982 for expression and that the efficiency of bacteriophage restriction was not impaired.

Evidence that thrombin-stimulated DNA synthesis in pulmonary arterial fibroblasts involves phosphatidylinositol 3-kinase-dependent p70 ribosomal S6 kinase activation.

We have examined the regulation of the 70 kDa ribosomal S6 kinase (p70s6k) by the G-protein-coupled receptor agonist alpha-thrombin and the role of this signalling molecule in the mitogenic effect of thrombin in cultured bovine pulmonary arterial (PA) fibroblasts. Thrombin stimulated p70s6k activity in a time and concentration-dependent manner which was abolished by the macrolide rapamycin. The phosphatidylinositol (PI) 3-kinase inhibitor wortmannin also completely blocked p70s6k activity in response to thrombin but did not affect p70s6k activity evoked by platelet-derived growth factor (PDGF) at a concentration that abrogated PDGF-stimulated PI 3-kinase activity. Activation of p70s6k by thrombin, but not PDGF, was also inhibited (by 48.3 +/- 5.4%) by pre-incubation of cells with pertussis toxin (PTX). Downregulation of protein kinase C (PKC) alpha and epsilon isoforms by pretreatment of fibroblasts for 48 h with phorbol 12-myristate 13-acetate (PMA), markedly attenuated both thrombin and PDGF-stimulated p70s6k activation (by 74.8 +/- 4.4% and 82.3 +/- 7.9% respectively). Thrombin also strongly stimulated (over 100 fold) the incorporation of [3H]thymidine into growth arrested PA fibroblasts which was inhibited by rapamycin (by 33.6 +/- 2.0%). From these results we propose that in PA fibroblasts: 1) thrombin stimulates the activation of p70s6k in a manner consistent with an involvement of a heterotrimeric G protein of the G(i) family, a PI 3-kinase other than the PI 3-kinase involved in signalling by PDGF, and PKC. 2) a p70s6k-dependent pathway plays a role in mitogenic signalling by thrombin.