Natural antimicrobial peptides from bacteria: characteristics and potential applications to fight against antibiotic resistance.

Because of the emergence of antibiotic-resistant pathogens worldwide, a number of infectious diseases have become difficult to treat. This threatening situation is worsened by the fact that very limited progress has been made in developing new and potent antibiotics in recent years. However, a group of antimicrobials, the so-called bacteriocins, have been much studied lately because they hold a great potential in controlling antibiotic-resistant pathogens. Bacteriocins are small antimicrobial peptides (AMPs) produced by numerous bacteria. They often act toward species related to the producer with a very high potency (at pico- to nanomolar concentration) and specificity. The common mechanisms of killing by bacteriocins are destruction of target cells by pore formation and/or inhibition of cell wall synthesis. Several studies have revealed that bacteriocins display great potential in the medical sector as bacteriocinogenic probiotics and in the clinic as therapeutic agents. In this review, we discuss the emerging antibiotic resistance and strategies to control its dissemination, before we highlight the potential of AMPs from bacteria as a new genre of antimicrobial agents.

Transposition of IS10R in Lactococcus lactis.

AIMS: To characterize the transposition mechanism of the IS-element IS10R and study how this element is involved in gene disruption in Lactococcus lactis. METHODS AND RESULTS: The gene flciA confers immunity against lactococcin A in lactococci. However, the immunity function was lost when flciA was co-expressed with the regulator gene nisR on a plasmid in L. lactis NZ9000. By PCR and DNA sequencing, it was revealed that flciA in immune-negative transformants was disrupted by the IS-element IS10R. Such gene disruption did not occur when flciA was expressed alone nor when the plasmid-located nisR was mutated, suggesting that nisR is directly involved in the transposition. The sequence 5'-CACTTAACC-3', which was found in flciA and at both ends of the inserted IS10R, was identified as target site by site-directed mutagenesis. CONCLUSIONS: IS10R transposes in L. lactis NZ9000 in a nisR-dependent fashion and employs the sequence 5'-CACTTAACC-3' as integration site. SIGNIFICANCE AND IMPACT OF THE STUDY: To our knowledge, this is the first time IS10R and aspects of its transposition are described in the industrial important bacterium L. lactis. The highly controllable insertion of IS10R into a target site might present a great potential as a gene disruption system.

The paratransgenic potential of Lactobacillus kunkeei in the honey bee Apis mellifera.

The honey bee (Apis mellifera) is a domestic insect of high value to human societies, as a crop pollinator in agriculture and a model animal in scientific research. The honey bee, however, has experienced massive mortality worldwide due to the phenomenon Colony Collapse Disorder (CCD), resulting in alarming prospects for crop failure in Europe and the USA. The reasons for CCD are complex and much debated, but several honey bee pathogens are believed to be involved. Paratransgenesis is a Trojan horse strategy, where endogenous microorganisms are used to express effector molecules that antagonise pathogen development. For use in honey bees, paratransgenesis must rely on a set of criteria that the candidate paratransgenic microorganism must fulfil in order to obtain a successful outcome: (1) the candidate must be genetically modifiable to express effector molecules; (2) the modified organism should have no adverse effects on honey bee health upon reintroduction; and (3) it must survive together with other non-pathogenic bee-associated microorganisms. Lactic acid bacteria (LAB) are common gut bacteria in vertebrates and invertebrates, and some have naturally beneficial properties in their host. In the present work we aimed to find a potential paratransgenic candidate within this bacterial group for use in honey bees. Among isolated LAB associated with bee gut microbiota, we found the fructophilic Lactobacillus kunkeei to be the most predominant species during foraging seasons. Four genetically different strains of L. kunkeei were selected for further assessment. We demonstrated (1) that L. kunkeei is transformable; (2) that the transformed cells had no obvious adverse effect on honey bee survival; and (3) that transformed cells survived well in the gut environment of bees upon reintroduction. Our study demonstrates that L. kunkeei fulfils the three criteria for paratransgenesis and can be a suitable candidate for further research on this strategy in honey bees.

Efficient expansion and gene transduction of mouse neural stem/progenitor cells on recombinant fibronectin.

Neural stem/progenitor cells (NSCs) are commonly grown as floating neurospheres in medium containing basic fibroblast growth factor and epidermal growth factor. Under these conditions, about 1% of the cells retain multipotentiality. We developed a protocol based on culture of NSCs in adherence on recombinant fibronectin (rFN) to transduce up to 90% NSCs at a multiplicity of infection of 2 with no need for viral concentration or production of serum-free retroviral supernatants. NSCs grew faster on rFN than as neurospheres on tissue culture plastic and did not lose their stem cell nature or multipotentiality. Furthermore, retroviral-mediated transgene expression was sustained with time in culture and upon differentiation into neurons and astrocytes. These experimental conditions may be utilized to study the function of various genes in NSCs, and to manipulate NSCs for gene and cell therapy of several neurological diseases.

Use of lactobacilli and their pheromone-based regulatory mechanism in gene expression and drug delivery.

Lactobacilli are common microorganisms in diverse vegetables and meat products and several of these are also indigenous inhabitants in the gastro-intestinal (GI) tract of humans and animals where they are believed to have health promoting effects on the host. One of the highly appreciated probiotic effects is their ability to inhibit the growth of pathogens by producing antimicrobial peptides, so-called bacteriocins. Production of some bacteriocins has been shown to be strictly regulated through a quorum-sensing based mechanism mediated by a secreted peptide-pheromone (also called induction peptide; IP), a membrane-located sensor (histidine protein kinase; HPK) and a cytoplasmic response regulator (RR). The interaction between an IP and its sensor, which is highly specific, leads to activation of the cognate RR which in turn binds to regulated promoters and activates gene expression. The HPKs and RRs are built up by conserved modules, and the signalling between them within a network is efficient and directional, and can easily be activated by exogenously added synthetic IPs. Consequently, components from such regulatory networks have successfully been exploited in construction of a number of inducible gene expression systems. In this review, we discuss some well-characterised quorum sensing networks involved in bacteriocin production in lactobacilli, with special focus on the use of the regulatory components in gene expression and on lactobacilli as potential delivery vehicle for therapeutic and vaccine purposes.

A family of bacteriocin ABC transporters carry out proteolytic processing of their substrates concomitant with export.

Lantibiotic and non-lantibiotic bacteriocins are synthesized as precursor peptides containing N-terminal extensions (leader peptides) which are cleaved off during maturation. Most non-lantibiotics and also some lantibiotics have leader peptides of the so-called double-glycine type. These leader peptides share consensus sequences and also a common processing site with two conserved glycine residues in positions -1 and -2. The double-glycine-type leader peptides are unrelated to the N-terminal signal sequences which direct proteins across the cytoplasmic membrane via the sec pathway. Their processing sites are also different from typical signal peptidase cleavage sites, suggesting that a different processing enzyme is involved. Peptide bacteriocins are exported across the cytoplasmic membrane by a dedicated ATP-binding cassette (ABC) transporter. Here we show that the ABC transporter is the maturation protease and that its proteolytic domain resides in the N-terminal part of the protein. This result demonstrates that the ABC transporter has a dual function: (i) removal of the leader peptide from its substrate, and (ii) translocation of its substrate across the cytoplasmic membrane. This represents a novel strategy for secretion of bacterial proteins.

A bacteriocin-like peptide induces bacteriocin synthesis in Lactobacillus plantarum C11.

In this study, we show that bacteriocin production in Lactobacillus plantarum C11 is an inducible process triggered by a secreted protein factor produced by the bacteriocin producer itself. The induction factor was identified to be plantaricin A, a bacteriocin-like peptide whose gene (plnA) is located in the same operon as a two-component regulatory system (plnBCD). When L. plantarum C11 cultures were depleted for plantaricin A, either by growing individual colonies on agar plates or by starting a new culture with a highly diluted inoculum, no bacteriocin was produced during the following growth. When chemically synthesized plantaricin A or purified bacterially produced plantaricin A was added to non-producing cultures, bacteriocin production was induced. Only 1 ng ml-1 plantaricin A is sufficient to induce the bacteriocin production in non-producing L. plantarum C11, and bacteriocin activity appears in the growth medium approximately 150 min after induction. Northern analyses, using a plnA-specific probe, demonstrated that plantaricin A is able to induce its own synthesis by transcription of the plnABCD operon, and this is observed approximately 15 min after adding plantaricin A. Furthermore, heterologous expression of the plnABCD operon in a Lactobacillus sake strain showed that the conditioned growth medium contained the active induction factor. Neither synthetic nor expressed plantaricin A from the heterologous system possesses any bacteriocin activity, suggesting that plantaricin A is primarily an induction factor and not a bacteriocin as claimed earlier.

Characterization of the locus responsible for the bacteriocin production in Lactobacillus plantarum C11.

Lactobacillus plantarum C11 secretes a small cationic peptide, plantaricin A, that serves as induction signal for bacteriocin production as well as transcription of plnABCD. The plnABCD operon encodes the plantaricin A precursor (PlnA) itself and determinants (PlnBCD) for a signal transducing pathway. By Northern (RNA) and sequencing analyses, four new plantaricin A-induced operons were identified. All were highly activated in concert with plnABCD upon bacteriocin induction. Two of these operons (termed plnEFI and plnJKLR) each encompass a gene pair (plnEF and plnJK, respectively) encoding two small cationic bacteriocin-like peptides with double-glycine-type leaders. The open reading frames (ORFs) encoding the bacteriocin-like peptides are followed by ORFs (plnI and -L, respectively) encoding cationic hydrophobic proteins resembling bacteriocin immunity proteins. On the third operon (termed plnMNOP), a similar bacteriocin-like ORF (plnN) and a putative immunity ORF (either plnM or -P) were identified as well. These findings suggest that two bacteriocins of two-peptide type (mature PlnEF and PlnJK) and a bacteriocin of one-peptide type (mature PlnN) could be responsible for the observed bacteriocin activity. The last operon (termed plnGHSTUV) contains two ORFs (plnGH) apparently encoding an ABC transporter and its accessory protein, respectively, known to be involved in processing and export of peptides with precursor double-glycine-type leaders. Promoter structure was established. A conserved regulatory-like box encompassing two direct repeats was identified in the promoter regions of all five plantaricin A-induced operons. These repeats may serve as regulatory elements for gene expression.

Type II secretion by Aeromonas salmonicida: evidence for two periplasmic pools of proaerolysin.

Aeromonas salmonicida containing the cloned gene for proaerolysin secretes the protein via the type II secretory pathway. Here we show that altering a region near the beginning of aerA led to a dramatic increase in the amount of proaerolysin that was produced and that a large amount of the protein was cell associated. All of the cell-associated protein had crossed the cytoplasmic membrane, because the signal sequence had been removed, and all of it was accessible to processing by trypsin during osmotic shock. Enlargement of the periplasm was observed by electron microscopy in overproducing cells, likely caused by the osmotic effect of the very large concentrations of accumulated proaerolysin. Immunogold electron microscopy localized nearly all of the proaerolysin in the enlarged periplasm; however, only half of the protoxin was released from the cells by osmotic shocking. Cross-linking studies showed that this fraction contained normal dimeric proaerolysin but that proaerolysin in the fraction that was not shockable had not dimerized, although it appeared to be correctly folded. Both periplasmic fractions were secreted by the cells; however, the nonshockable fraction was secreted much more slowly than the shockable fraction. We estimated a rate for maximal secretion of proaerolysin from the bacteria that was much lower than the rates that have been estimated for inner membrane transit, which suggests that transit across the outer membrane is rate limiting and may account for the periplasmic accumulation of the protein. Finally, we show that overproduction of proaerolysin inhibited the release of the protease that is secreted by A. salmonicida.

The gene encoding plantaricin A, a bacteriocin from Lactobacillus plantarum C11, is located on the same transcription unit as an agr-like regulatory system.

Purification and amino acid sequencing of plantaricin A, a bacteriocin from Lactobacillus plantarum C11, revealed that maximum bacteriocin activity is associated with the complementary action of two almost-identical peptides, alpha and beta (J. Nissen-Meyer, A. G. Larsen, K. Sletten, M. Daeschel, and I. F. Nes, J. Gen. Microbiol. 139:1973-1978, 1993). A 5-kb chromosomal HindIII restriction fragment containing the structural gene of plantaricin A was cloned and sequenced. Only one gene encoding plantaricin A was found. The gene, termed plnA, encodes a 48-amino-acid precursor peptide, of which the 22 and 23 C-terminal amino acids correspond to the purified peptides. Northern (RNA) blot analysis demonstrated that a probe complementary to the coding strand of the plantaricin A gene hybridized to a 3.3-kb mRNA transcript. Further analysis of the 3.3-kb transcript demonstrated that it contains three additional open reading frames (plnB, plnC and plnD) downstream of plnA. The DNA sequences of plnB, plnC, and plnD revealed that their products closely resemble members of bacterial two-component signal transduction systems. The strongest homology was found to the accessory gene regulatory (agr) system, which controls expression of exoproteins during post-exponential growth in Staphylococcus aureus. The finding that plnABCD are transcribed from a common promoter suggests that the biological role played by the bacteriocin is somehow related to the regulatory function of the two-component system located on the same operon.

Highly efficient integration of foreign DNA into the genome of the green sulfur bacterium,Chlorobium vibrioforme by homologous recombination.

Highly efficient and reproducible transformation ofChlorobium vibrioforme with plasmid DNA has been achieved by electroporation. Specific parameters have been optimized for the electrotransformation procedure. The method was developed using a construct containing a full copy of thepscC gene encoding the cytochromec 551 subunit of the photosynthetic reaction center complex and theaadA gene encoding streptomycin resistance as selectable marker. Southern blotting analysis showed that the tested colonies were true transformants with the plasmid integrated into the genome by single homologous recombination. No transformants were obtained using the vector without thepscC gene showing that this vector does not replicate inC. vibrioforme. Thus transformation is possible only by homologous recombination. When using constructs designed to inactivate thepscC gene by insertion no transformants were obtained, indicating that the gene is indispensable for growth. The vector pVS2 carrying genes for erythromycin and chloramphenicol resistance was shown to replicate inC. vibrioforme. The two transformations shown here, provide an important genetical tool in the further analysis of structure and function of the photosynthetic apparatus in green sulfur bacteria.

Secretion and properties of the large and small lobes of the channel-forming toxin aerolysin.

Aerolysin is a dimeric protein secreted by Aeromonas spp. that binds to glycosylphosphatidylinositol-anchored receptors on target cells and becomes insertion competent by oligomerizing. The protein comprises two lobes joined by a short arm. The large lobe is thought to be responsible for channel formation, whereas the small lobe is believed to stabilize the dimer, and it may also contain the receptor binding site. We cloned and expressed the DNA for both lobes of the toxin separately and together in A. salmonicida. The large lobe produced alone was secreted, although more poorly than native protein. The small lobe with the arm produced by itself was not secreted. When the large lobe without the arm was co-produced with the small lobe with the arm, both were secreted, and they co-purified as a stoichiometric complex. Analytical ultracentrifugation showed that they form a heterotetramer corresponding to the native dimer. The purified product was nearly as active as aerolysin, but lost activity and became trypsin sensitive above 25 degreesC. The large lobe with the arm was also purified. It was shown to be monomeric, confirming that the small lobe is responsible for dimer stabilization. The large lobe had very low channel-forming activity, although it was correctly processed by trypsin, and it could form stable oligomers. Surprisingly, the large lobe was found to bind to several glycosylphosphatidylinositol-anchored proteins, indicating that it contains at least part of the receptor-binding domain.

Identification of the DNA-binding sites for two response regulators involved in control of bacteriocin synthesis in Lactobacillus plantarum C11.

In Lactobacillus plantarum C11, bacteriocin production has previously been shown to be an inducible process, in which a secreted peptide, produced by the host itself, is involved. The inducing factor, designated plantaricin A (PlnA), is a bacteriocin-like peptide encoded by a gene (plnA) located on the same operon as the genes for a two-component regulatory system (plnBCD). This system consists of a histidine kinase (PlnB) and two response regulators (PlnC,D), and belongs to a recently defined subfamily of two-component regulatory systems, which are activated by secreted peptide pheromones through a quorum-sensing mechanism. We show here that the two response regulators PlnC and PlnD bind specifically to imperfect direct repeats found within the adjacent promoter of the plnABCD operon, and to similar sequences found within the promoter regions of two nearby operons containing bacteriocin structural genes (plnEFI and plnJKLR). Binding of PlnC and PlnD was increased two to three fold in the presence of acetyl phosphate. The results suggest that bacteriocin synthesis in L. plantarum C11 is regulated by the DNA-binding activity of the two response regulators PlnC and PlnD.

Evidence for dual functionality of the operon plnABCD in the regulation of bacteriocin production in Lactobacillus plantarum.

The regulatory operon (plnABCD) involved in bacteriocin production in Lactobacillus plantarum C11 encodes four different proteins: a cationic prepeptide (PlnA); a histidine protein kinase (PlnB); and two highly homologous response regulators (PlnC and PlnD; over 75% sequence similarity). The mature product of PlnA, plantaricin A, serves as an extracellular pheromone that induces bacteriocin production. The exact roles of plnBCD in bacteriocin production have not been established experimentally. A reporter system containing the gusA gene fused with the plnA promoter was used to study plnABCD. We demonstrated that the plnABCD operon codes for an autoregulatory unit capable of activating its own promoter. Deletion analyses, performed in a heterologous expression host to define the roles of the individual genes, confirmed that both the inducer gene (plnA) and the kinase gene (plnB) are required for autoactivation. Apparently, the latter gene encodes a protein that serves as a receptor for the pheromone peptide. It was also demonstrated conclusively that the two regulators PlnC and PlnD, which have been shown previously to bind specifically to the DNA regulatory repeats of the plnA promoter, possess differential activities on the plnA promoter, with PlnC being much more active than PlnD. The functions of the response regulators were investigated further in the bacteriocin producer strain C11 in order to reveal their roles in bacteriocin production. Surprisingly, the two response regulators display totally opposite functions: although overexpression of plnC activated transcription and bacteriocin production, the overexpression of plnD repressed both processes, thus strongly suggesting that PlnD plays a role in the downregulation of bacteriocin synthesis. To our knowledge, this is the first evidence for a protein involved directly in negative regulation of bacteriocin production, and also it was shown for the first time that two highly homologous response regulators, with opposite functions, are encoded by genes located on the same operon.

Biosynthesis of bacteriocins in lactic acid bacteria.

A large number of new bacteriocins in lactic acid bacteria (LAB) has been characterized in recent years. Most of the new bacteriocins belong to the class II bacteriocins which are small (30-100 amino acids) heat- stable and commonly not post-translationally modified. While most bacteriocin producers synthesize only one bacteriocin, it has been shown that several LAB produce multiple bacteriocins (2-3 bacteriocins). Based on common features, some of the class II bacteriocins can be divided into separate groups such as the pediocin-like and strong anti-listeria bacteriocins, the two-peptide bacteriocins, and bacteriocins with a sec-dependent signal sequence. With the exception of the very few bacteriocins containing a sec-dependent signal sequence, class II bacteriocins are synthesized in a preform containing an N-terminal double-glycine leader. The double-glycine leader-containing bacteriocins are processed concomitant with externalization by a dedicated ABC-transporter which has been shown to possess an N-terminal proteolytic domain. The production of some class II bacteriocins (plantaricins of Lactobacillus plantarum C11 and sakacin P of Lactobacillus sake) have been shown to be transcriptionally regulated through a signal transduction system which consists of three components: an induction factor (IF), histidine protein kinase (HK) and a response regulator (RR). An identical regulatory system is probably regulating the transcription of the sakacin A and carnobacteriocin B2 operons. The regulation of bacteriocin production is unique, since the IF is a bacteriocin-like peptide with a double-glycine leader processed and externalized most probably by the dedicated ABC-transporter associated with the bacteriocin. However, IF is not constituting the bacteriocin activity of the bacterium, IF is only activating the transcription of the regulated class II bacteriocin gene(s). The present review discusses recent findings concerning biosynthesis, genetics, and regulation of class II bacteriocins.

Expression and properties of an aerolysin--Clostridium septicum alpha toxin hybrid protein.

Aerolysin is a bilobal channel-forming toxin secreted by Aeromonas hydrophila. The alpha toxin produced by Clostridium septicum is homologous to the large lobe of aerolysin. However, it does not contain a region corresponding to the small lobe of the Aeromonas toxin, leading us to ask what the function of the small lobe is. We fused the small lobe of aerolysin to alpha toxin, producing a hybrid protein that should structurally resemble aerolysin. Unlike aerolysin, the hybrid was not secreted when expressed in Aeromonas salmonicida. The purified hybrid was activated by proteolytic processing in the same way as both parent proteins and, after activation, it formed oligomers that corresponded to the aerolysin heptamer. Like aerolysin, the hybrid was far more active than alpha toxin against human erythrocytes and mouse T lymphocytes. Both aerolysin and the hybrid bound to human glycophorin, and both were inhibited by preincubation with this erythrocyte glycoprotein, whereas alpha toxin was unaffected. We conclude that aerolysin contains two receptor binding sites, one for glycosyl-phosphatidylinositol-anchored proteins that is located in the large lobe and is also found in alpha toxin, and a second site, located in the small lobe, that binds a surface carbohydrate determinant.

Antagonistic activity of Lactobacillus plantarum C11: two new two-peptide bacteriocins, plantaricins EF and JK, and the induction factor plantaricin A.

Six bacteriocinlike peptides (plantaricin A [PlnA], PlnE, PlnF, PlnJ, PlnK, and PlnN) produced by Lactobacillus plantarum C11 were detected by amino acid sequencing and mass spectrometry. Since purification to homogeneity was problematic, all six peptides were obtained by solid-phase peptide synthesis and were tested for bacteriocin activity. It was found that L. plantarum C11 produces two two-peptide bacteriocins (PlnEF and PlnJK); a strain-specific antagonistic activity was detected at nanomolar concentrations when PlnE and PlnF were combined and when PlnJ and PlnK were combined. Complementary peptides were at least 10(3) times more active when they were combined than when they were present individually, and optimal activity was obtained when the complementary peptides were present in approximately equal amounts. The interaction between complementary peptides was specific, since neither PlnE nor PlnF could complement PlnJ or PlnK, and none of these peptides could complement the peptides constituting the two-peptide bacteriocin lactococcin G. Interestingly, PlnA, which acts as an extracellular signal (pheromone) that triggers bacteriocin production, also possessed a strain-specific antagonistic activity. No bacteriocin activity could be detected for PlnN.

Glycosylphosphatidylinositol anchors of membrane glycoproteins are binding determinants for the channel-forming toxin aerolysin.

Cells that are sensitive to the channel-forming toxin aerolysin contain surface glycoproteins that bind the toxin with high affinity. Here we show that a common feature of aerolysin receptors is the presence of a glycosylphosphatidylinositol anchor, and we present evidence that the anchor itself is an essential part of the toxin binding determinant. The glycosylphosphatidylinositol (GPI)-anchored T-lymphocyte protein Thy-1 is an example of a protein that acts as an aerolysin receptor. This protein retained its ability to bind aerolysin when it was expressed in Chinese hamster ovary cells, but could not bind the toxin when expressed in Escherichia coli, where the GPI anchor is absent. An unrelated GPI-anchored protein, the variant surface glycoprotein of trypanosomes, was shown to bind aerolysin with similar affinity to Thy-1, and this binding ability was significantly reduced when the anchor was removed chemically. Cathepsin D, a protein with no affinity for aerolysin, was converted to an aerolysin binding form when it was expressed as a GPI-anchored hybrid in COS cells. Not all GPI-anchored proteins bind aerolysin. In some cases this may be due to differences in the structure of the anchor itself. Thus the GPI-anchored proteins procyclin of Trypanosoma congolense and gp63 of Leishmania major did not bind aerolysin, but when gp63 was expressed with a mammalian GPI anchor in Chinese hamster ovary cells, it bound the toxin.

Regulation of bacteriocin production in Lactobacillus plantarum depends on a conserved promoter arrangement with consensus binding sequence.

Bacteriocin production in Lactobacillus plantarum C11 is regulated by a three-component signal transduction system comprising a peptide pheromone (PlnA), a histidine protein kinase (PlnB), and two homologous response regulators (RRs; PlnC and PlnD). Both RRs are DNA-binding proteins that bind to promoter-proximal elements in the pln regulon. The binding site for the two regulators consists of two 9-bp direct repeats, that conform to the consensus sequence 5'-TACGTTAAT-3', and the repeats are separated by an intervening 12-bp AT-rich spacer region. In the present work, the plhA promoter was used as a model to evaluate the significance of the binding sequence and conserved promoter arrangement. Point substitutions in the consensus sequence, particularly those in invariant positions, either abolished or significantly reduced binding of PlnC and PlnD. Both regulators bind as homodimers to DNA fragments containing a complete set of regulatory elements, while removal of either repeat, or alterations in the length of the spacer region, significantly weakened binding of both protein dimers. DNase I footprinting demonstrated that PlnC and PlnD both bind to, and protect, the direct repeats. By fusing the plnA promoter region to the beta-glucuronidase (GUS) gene, it was shown that promoter activity is dependent on an intact set of accurately organized repeats. The in vitro and in vivo results presented here confirm the involvement of the repeats as regulatory elements in the regulation of bacteriocin production.