Bacteriocins: mechanism of membrane insertion and pore formation

Lactic acid bacteria produce several types of pore forming peptides. Class I bacteriocins are lantibiotics that contain (methyl)lanthionine residues that may form intramolecular thioether rings. These peptides generally have a broad spectrum of activity and form unstable pores. Class II bacteriocins are small, heat stable peptides mostly with a narrow spectrum of activity. Most bacteriocins interact with anionic lipids that are abundantly present in the membranes of Gram-positive bacteria.'Docking molecules' may enhance the conductivity and stability of lantibiotic pores, while'receptors' in the target membrane may determine specificity of class II bacteriocins. Insertion into the membrane of many bacteriocins is proton motive force driven. Lantibiotics may form pores according to a'wedge-like' model, while class II bacteriocins may enhance membrane permeability either by the formation of a'barrel stave' pore or by a'carpet' mechanism.     

Cell Wall-active Bacteriocins and Their Applications Beyond Antibiotic Activity

Microorganisms synthesize several compounds with antimicrobial activity in order to compete or defend themselves against others and ensure their survival. In this line, the cell wall is a major protective barrier whose integrity is essential for many vital bacterial processes. Probably for this reason, it represents a ??hot spot?? as a target for many antibiotics and antimicrobial peptides such as bacteriocins. Bacteriocins have largely been recognized by their pore-forming ability that collapses the selective permeability of the cytoplasmic membrane. However, in the last few years, many bacteriocins have been shown to inhibit cell wall biosyntheis alone, or in a concerted action with pore formation like nisin. Examples of cell wall-active bacteriocins are found in both Gram-negative and Gram-positive bacteria and include a wide diversity of structures such as nisin-like and mersacidin-like lipid II-binding bacteriocins, two-peptide lantibiotics, and non-modified bacteriocins. In this review, we summarize the current knowledge on these antimicrobial peptides as well as the role, composition, and biosynthesis of the bacterial cell wall as their target. Moreover, even though bacteriocins have been a matter of interest as natural food antimicrobials, we propose them as suitable tools to provide new means to improve biotechnologically relevant microorganisms.     

Immunity to lantibiotics

Bacteria producing bacteriocins have to be protected from being killed by themselves. This mechanism of self-protection or immunity is especially important if the bacteriocin does not need a specific receptor for its action, as is the case for the type A lantibiotics forming pores in the cytoplasmic membrane. At least two different systems of immunity have evolved in this group of bacteriocins containing modified amino acids as a result of posttranslational modification. The immunity mechanism of Pep5 in Staphylococcus epidermidis is based on inhibition of pore formation by a small 69-amino acid protein weakly associated with the outer surface of the cytoplasmic membrane. In Lactococcus lactis and Bacillus subtilis the putative immunity lipoproteins NisI and SpaI, respectively, are also located at the outer surface of the cytoplasmic membrane, suggesting that a similar mechanism might be utilized by the producers of nisin and subtilin. In addition an ABC-transport system consisting of two membrane proteins, (NisEG, SpaG and the hydrophobic domain of SpaF, and EpiEG) and a cytoplasmic protein (NisF, the cytoplasmic domain of SpaF, and EpiF) play a role in immunity of nisin, subtilin and epidermin by import, export or inhibition of pore formation by the membrane components of the transport systems. Almost nothing is known of the immunity determinants of newly described and other type of lantibiotics.     

Two-peptide bacteriocins produced by lactic acid bacteria

Bacteriocins from lactic acid bacteria are ribosomally produced peptides (usually 30-60 amino acids) that display potent antimicrobial activity against certain other Gram-positive organisms. They function by disruption of the membrane of their targets, mediated in at least some cases by interaction of the peptide with a chiral receptor molecule (e.g., lipid II or sugar PTS proteins). Some bacteriocins are unmodified (except for disulfide bridges), whereas others (i.e. lantibiotics) possess extensive post-translational modifications which include multiple monosulfide (lanthionine) bridges and dehydro amino acids as well as possible keto amide residues at the N-terminus. Most known bacteriocins are biologically active as single peptides. However, there is a growing class of two peptide systems, both unmodified and lantibiotic, which are fully active only when both partners are present (usually 1:1). In some cases, neither peptide has activity by itself, whereas in others, the activity of one is enhanced by the other. This review discusses the classification, structure, production, regulation, biological activity, and potential applications of such two-peptide bacteriocins.     

Peptide autoinducers in bacteria

The review classifies and analyzes the literature data on bacterial peptide autoinducers (AIs), responsible for intra- and interspecies communication (quorum sensing) between bacterial populations. The most important families of peptide AI are discussed, including a large group of bacteriocins, subdivided into lantibiotics (class I), unmodified heat-stable bacteriocins (II), large bacteriocins with M_r > 30 kDa (III), and “circular” bacteriocins (IV), as well as CSP peptides (Competence-Stimulating Peptides), peptides with thiolactone and lactone cycles, and short tryptophan-containing peptides with pheromone activity. The sensor systems are discussed, which recognize peptide AIs and regulate the activity of bacterial intracellular effector systems. For different families of peptide AIs, the typical features of structural organization are determined, which are responsible for their biological activity     

Mechanistic action of pediocin and nisin: recent progress and unresolved questions

Nisin and pediocin PA-1 are examples of bacteriocins from lactic acid bacteria (LAB) that have found practical applications as food preservatives. Like other natural antimicrobial peptides, LAB bacteriocins act primarily at the cytoplasmic membranes of susceptible microorganisms. Studies with in vivo as well as in␣vitro membrane systems are directed toward understanding how bacteriocins interact with membranes so as to provide a mechanistic basis for their rational applications. The dissipation of proton motive force was identified early on as the common mechanism for the lethal activity of LAB bacteriocin. Models for nisin/membrane interactions propose that the peptide forms poration complexes in the membrane through a multi-step process of binding, insertion, and pore formation. This review focuses on the current knowledge of: (1) the mechanistic action of nisin and pediocin-like bacteriocins, (2) the requirement for a cell factor such as a membrane protein, (3) the influence of membrane potential, pH, and lipid composition on the of specificity and efficacy of bacteriocins, and (4) the roles of specific amino acids and structural domains of the bacteriocins in their action. Received: 3 April 1998 / Received last revision: 27 July 1998 / Accepted: 29 July 1998     

New developments in non-post translationally modified microcins

Microcins are a family of low molecular weight antibiotic peptides produced by Enterobacteriaceae strains and active against related bacteria. According to some features we propose to classify these antibiotic substances into two distinct groups. The class I microcins contain Mcc B17, C7, J25 and D93 that are small molecules (molecular mass inferior to 5 kDa), largely post-translationally modified and with specific intracellular targets. The class II microcins, MccV, E492, H47, L and 24, share several common properties with class IIa Gram-positive bacteriocins: molecular mass ranging from 7 to 10 kDa, absence of modified amino acids, double-glycine type leader peptides, secretion mediated by an ABC transporter and antibacterial activity due to interaction with bacterial membrane. This review discusses common features of the class II microcins and provides new insights into these peptides.     

Aggregates of nisin with various bactoprenol-containing cell wall precursors differ in size and membrane permeation capacity

Many lantibiotics use the membrane bound cell wall precursor Lipid II as a specific target for killing Gram-positive bacteria. Binding of Lipid II usually impedes cell wall biosynthesis, however, some elongated lantibiotics such as nisin, use Lipid II also as a docking molecule for pore formation in bacterial membranes. Although the unique nisin pore formation can be analyzed in Lipid II-doped vesicles, mechanistic details remain elusive. We used optical sectioning microscopy to directly visualize the interaction of fluorescently labeled nisin with membranes of giant unilamellar vesicles containing Lipid II and its various bactoprenol precursors. We quantitatively analyzed the binding and permeation capacity of nisin when applied at nanomolar concentrations. Specific interactions with Lipid I, Lipid II and bactoprenol-diphosphate (C₅₅-PP), but not bactoprenol-phosphate (C₅₅-P), resulted in the formation of large molecular aggregates. For Lipid II, we demonstrated the presence of both nisin and Lipid II in these aggregates. Membrane permeation induced by nisin was observed in the presence of Lipid I and Lipid II, but not in the presence of C₅₅-PP. Notably, the size of the C₅₅-PP–nisin aggregates was significantly smaller than that of the aggregates formed with Lipid I and Lipid II. We conclude that the membrane permeation capacity of nisin is determined by the size of the bactoprenol-containing aggregates in the membrane. Notably, transmitted light images indicated that the formation of large aggregates led to a pinch-off of small vesicles, a mechanism, which probably limits the growth of aggregates and induces membrane leakage.     

Bacteriocin detection from whole bacteria by matrix-assisted laser desorption ionization-time of flight mass spectrometry

Class I bacteriocins (lantibiotics) and class II bacteriocins are antimicrobial peptides secreted by gram-positive bacteria. Using two lantibiotics, lacticin 481 and nisin, and the class II bacteriocin coagulin, we showed that bacteriocins can be detected without any purification from whole producer bacteria grown on plates by matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF-MS). When we compared the results of MALDI-TOF-MS performed with samples of whole cells and with samples of crude supernatants of liquid cultures, the former samples led to more efficient bacteriocin detection and required less handling. Nisin and lacticin 481 were both detected from a mixture of their producer strains, but such a mixture can yield additional signals. We used this method to determine the masses of two lacticin 481 variants, which confirmed at the peptide level the effect of mutations in the corresponding structural gene.     

Bacteriocins: perspective for the development of novel anticancer drugs

Antimicrobial peptides (AMPs) from prokaryotic source also known as bacteriocins are ribosomally synthesized by bacteria belonging to different eubacterial taxonomic branches. Most of these AMPs are low molecular weight cationic membrane active peptides that disrupt membrane by forming pores in target cell membranes resulting in cell death. While these peptides known to exhibit broad-spectrum antimicrobial activity, including antibacterial and antifungal, they displayed minimal cytotoxicity to the host cells. Their antimicrobial efficacy has been demonstrated in vivo using diverse animal infection models. Therefore, we have discussed some of the promising peptides for their ability towards potential therapeutic applications. Further, some of these bacteriocins have also been reported to exhibit significant biological activity against various types of cancer cells in different experimental studies. In fact, differential cytotoxicity towards cancer cells as compared to normal cells by certain bacteriocins directs for a much focused research to utilize these compounds as novel therapeutic agents. In this review, bacteriocins that demonstrated antitumor activity against diverse cancer cell lines have been discussed emphasizing their biochemical features, selectivity against extra targets and molecular mechanisms of action.

     

The continuing story of class IIa bacteriocins.

Many bacteria produce antimicrobial peptides, which are also referred to as peptide bacteriocins. The class IIa bacteriocins, often designated pediocin-like bacteriocins, constitute the most dominant group of antimicrobial peptides produced by lactic acid bacteria. The bacteriocins that belong to this class are structurally related and kill target cells by membrane permeabilization. Despite their structural similarity, class IIa bacteriocins display different target cell specificities. In the search for new antibiotic substances, the class IIa bacteriocins have been identified as promising new candidates and have thus received much attention. They kill some pathogenic bacteria (e.g., Listeria) with high efficiency, and they constitute a good model system for structure-function analyses of antimicrobial peptides in general. This review focuses on class IIa bacteriocins, especially on their structure, function, mode of action, biosynthesis, bacteriocin immunity, and current food applications. The genetics and biosynthesis of class IIa bacteriocins are well understood. The bacteriocins are ribosomally synthesized with an N-terminal leader sequence, which is cleaved off upon secretion. After externalization, the class IIa bacteriocins attach to potential target cells and, through electrostatic and hydrophobic interactions, subsequently permeabilize the cell membrane of sensitive cells. Recent observations suggest that a chiral interaction and possibly the presence of a mannose permease protein on the target cell surface are required for a bacteria to be sensitive to class IIa bacteriocins. There is also substantial evidence that the C-terminal half penetrates into the target cell membrane, and it plays an important role in determining the target cell specificity of these bacteriocins. Immunity proteins protect the bacteriocin producer from the bacteriocin it secretes. The three-dimensional structures of two class IIa immunity proteins have been determined, and it has been shown that the C-terminal halves of these cytosolic four-helix bundle proteins specify which class IIa bacteriocin they protect against.     

Posttranslationally modified bacteriocins--the lantibiotics

Lantibiotics are a subgroup of bacteriocins that are characterized by the presence of the unusual thioether amino acids lanthionine and 3-methyllanthionine generated through posttranslational modification. The biosynthesis of lantibiotics follows a defined pathway comprising modifications of the prepeptide, proteolytic activation, and export. The genes encoding the biosynthesis apparatus and the lantibiotic prepeptide are organized in clusters, which also include information for proteins involved in regulation and producer self-protection. The elongated cationic lantibiotics primarily act through the formation of pores and recent progress with nisin and epidermin has shown that specific docking molecules such as lipid II play an essential role in this mechanism. Mersacidin and actagardine inhibit cell wall biosynthesis by complexing the precursor lipid II, whereas the cinnamycin-like peptides bind to phosphoethanolamine thus inhibiting phospholipase A2.     

Mapping the targeted membrane pore formation mechanism by solution NMR: the nisin Z and lipid II interaction in SDS micelles

Nisin is an example of type-A lantibiotics that contain cyclic lanthionine rings and unusual dehydrated amino acids. Among the numerous pore-forming antimicrobial peptides, type-A lantibiotics form an unique family of post-translationally modified peptides. Via the recognition of cell wall precursor lipid II, nisin has the capacity to form pores against Gram-positive bacteria with an extremely high activity in the nanomolar (nM) range. Here we report a high-resolution NMR spectroscopy study of nisin/lipid II interactions in SDS micelles as a model membrane system in order to elucidate the mechanism of molecular recognition at residue level. The binding to lipid II was studied through (15)N-(1)H HSQC titration, backbone amide proton temperature coefficient analysis, and heteronuclear (15)N[(1)H]-NOE relaxation dynamics experiments. Upon the addition of lipid II, significant changes were monitored in the N-terminal part of nisin. An extremely low amide proton temperature coefficient (Delta delta/Delta T) was found for the amide proton of Ala3 (> -0.1 ppb/K) in the complex form. This suggests tight hydrogen bonding and/or isolation from the bulk solvent for this residue. Large chemical shift perturbations were also observed in the first two rings. In contrast, the C-terminal part of nisin was almost unaffected. This part of the molecule remains flexible and solvent-exposed. On the basis of our results, a multistep pore-forming mechanism is proposed. The N-terminal part of nisin first binds to lipid II, and a subsequent structural rearrangement takes place. The C-terminal part of nisin is possibly responsible for the activation of the pore formation. In light of the emerging antibiotic resistance problems, an understanding of the specific recognition mechanism of nisin with lipid II at the residue specific level may therefore aid in the development of novel antibiotics.     

Lipid II-based antimicrobial activity of the lantibiotic plantaricin C

We analyzed the mode of action of the lantibiotic plantaricin C (PlnC), produced by Lactobacillus plantarum LL441. Compared to the well-characterized type A lantibiotic nisin and type B lantibiotic mersacidin, which are both able to interact with the cell wall precursor lipid II, PlnC displays structural features of both prototypes. In this regard, we found that lipid II plays a key role in the antimicrobial activity of PlnC besides that of pore formation. The pore forming activity of PlnC in whole cells was prevented by shielding lipid II on the cell surface. However, in contrast to nisin, PlnC was not able to permeabilize Lactococcus lactis cells or to form pores in 1,2-dioleoyl-sn-glycero-3-phosphocholine liposomes supplemented with 0.1 mol% purified lipid II. This emphasized the different requirements of these lantibiotics for pore formation. Using cell wall synthesis assays, we identified PlnC as a potent inhibitor of (i) lipid II synthesis and (ii) the FemX reaction, i.e., the addition of the first Gly to the pentapeptide side chain of lipid II. As revealed by thin-layer chromatography, both reactions were clearly blocked by the formation of a PlnC-lipid I and/or PlnC-lipid II complex. On the basis of the in vivo and in vitro activities of PlnC shown in this study and the structural lipid II binding motifs described for other lantibiotics, the specific interaction of PlnC with lipid II is discussed.     

Influence of Ca2+ Ions on the Activity of Lantibiotics Containing a Mersacidin-Like Lipid II Binding Motif

Mersacidin binds to lipid II and thus blocks the transglycosylation step of the cell wall biosynthesis. Binding of lipid II involves a special motif, the so-called mersacidin-lipid II binding motif, which is conserved in a major subgroup of lantibiotics. We analyzed the role of Ca²⁺ ions in the mode of action of mersacidin and some related peptides containing a mersacidin-like lipid II binding motif. We found that the stimulating effect of Ca²⁺ ions on the antimicrobial activity known for mersacidin also applies to plantaricin C and lacticin 3147. Ca²⁺ ions appear to facilitate the interaction of the lantibiotics with the bacterial membrane and with lipid II rather than being an essential part of a peptide-lipid II complex. In the case of lacticin 481, both the interaction with lipid II and the antimicrobial activity were Ca²⁺ independent.Bacteriocins are a heterogeneous group of ribosomally synthesized antibiotic peptides and proteins which were proposed to fall into three classes, the lanthionine-containing bacteriocins (class I), the non-lanthionine-containing bacteriocins (class II), and the bacteriolysins, respectively (for a review, see reference 12).The lanthionine-containing bacteriocins (lantibiotics) are produced by and are effective against a broad spectrum of gram-positive bacteria. They are small, posttranslationally modified antimicrobial peptides containing characteristic thioether ring structures (lanthionine and 3-methyllanthionine) and other unusual amino acids, e.g., d-Ala (3, 49).Mersacidin was the first lantibiotic shown to interact with a defined target molecule, the ultimate cell wall precursor lipid II (6) (Fig. ​(Fig.1).1). Further studies revealed that this molecule is also the target of nisin and many other lantibiotics (19). Lipid II is synthesized on the cytoplasmic side of the membrane and translocated to the outside of the bacterial cell membrane, where the disaccharide pentapeptide part of lipid II is incorporated into the growing peptidoglycan network by the cell wall biosynthesis machinery (for reviews, see references 5 and 45).Open in a separate windowFIG. 1.Primary structure of lantibiotics containing the mersacidin-lipid II binding motif (A) and the structure of the cell wall precursor lipid II (B). The binding motif of mersacidin and identical amino acids in the mersacidin-like lantibiotics are highlighted in gray. Dha, dehydroalanine; Dhb, dehydrobutyrine; Ala-S-Ala, lanthionine; Abu-S-Ala, methyllanthionine; DAla, d-alanine.To date, two different lipid II binding motifs in lantibiotics have been identified, referred to as the nisin-lipid II and mersacidin-lipid II binding motifs, and a classification regarding their interaction with the cell wall precursor was recently proposed by Bierbaum and Sahl (3).The nisin-lipid II binding motif is also found in related lantibiotics, e.g., gallidermin, epidermin (4), mutacin 1140 (40), and subtilin (30). Nisin displays a dual mode of action by binding to lipid II. It prevents lipid II incorporation into the growing murein layer, thereby blocking cell wall biosynthesis (8), and it uses lipid II as an anchor molecule for subsequent pore formation (48). The nisin/lipid II interaction was analyzed by nuclear magnetic resonance spectroscopy and it was shown that the N-terminal part of the peptide forms a cage-like structure encompassing the pyrophosphate group of the lipid II molecule, leading to the formation of five intermolecular hydrogen bonds between the backbone amids of the lantibiotic and pyrophosphate groups (22).The second binding motif occurs in mersacidin and related lantibiotics (Fig. ​(Fig.1).1). The interaction of mersacidin with lipid II leads to inhibition of the peptidoglycan biosynthesis at the level of transglycosylation (7). In contrast to nisin, the activity of mersacidin is influenced by Ca²⁺ ions, since its antimicrobial activity increased twofold in Ca²⁺-containing medium (2). When a Ca²⁺ binding pocket was identified in the mersacidin-like lantibiotic actagardine by crystal structure determination, it was suggested that the deprotonated Glu17 in the mersacidin-lipid II binding motif (Fig. ​(Fig.1)1) is involved in Ca²⁺ binding (24). Furthermore, nuclear magnetic resonance studies revealed that, upon binding of lipid II, mersacidin effectively alters its overall backbone geometry with Ala-12 and Abu-13, acting as a hinge region. The conformational change exposes the amino group of Lys1 and the carboxyl group of Glu17 to the lipid II molecule (21). It was speculated that Ca²⁺ is needed to bridge the mersacidin Glu17 side chain to the negatively charged groups of lipid II; alternatively, a direct salt bridge with the positively charged side chain of Lys3 in lipid II is formed (21). This hypothesis is in good agreement with the observation that replacement of Glu17 by Ala abolished the antimicrobial activity of mersacidin (43).To analyze the impact of Ca²⁺ on the activity of mersacidin-like lantibiotics, we selected four peptides which possess the respective lipid II-binding motif, yet show significant differences in primary structures (Fig. ​(Fig.1).1). Like mersacidin, plantaricin C and the two-component lantibiotic lacticin 3147 have been shown to inhibit cell wall biosynthesis at the level of transglycosylation (46, 47). Additionally, lacticin 3147 shows a dual mode of action and is able to form lipid II-dependent pores (28, 47). The mode of action of lacticin 481 so far has not been characterized in sufficient detail.We found that Ca²⁺ increases the antimicrobial activity of all peptides containing the mersacidin-lipid II binding motif, except for lacticin 481, however, which was also found to bind to lipid II.     

The mode of action of the lantibiotic lacticin 3147--a complex mechanism involving specific interaction of two peptides and the cell wall precursor lipid II

Lacticin 3147 is a two-peptide lantibiotic produced by Lactococcus lactis in which both peptides, LtnA1 and LtnA2, interact synergistically to produce antibiotic activities in the nanomolar concentration range; the individual peptides possess marginal (LtnA1) or no activity (LtnA2). We analysed the molecular basis for the synergism and found the cell wall precursor lipid II to play a crucial role as a target molecule. Tryptophan fluorescence measurements identified LtnA1, which is structurally similar to the lantibiotic mersacidin, as the lipid II binding component. However, LtnA1 on its own was not able to substantially inhibit cell wall biosynthesis in vitro; for full inhibition, LtnA2 was necessary. Both peptides together caused rapid K(+) leakage from intact cells; in model membranes supplemented with lipid II, the formation of defined pores with a diameter of 0.6 nm was observed. We propose a mode of action model in which LtnA1 first interacts specifically with lipid II in the outer leaflet of the bacterial cytoplasmic membrane. The resulting lipid II:LtnA1 complex is then able to recruit LtnA2 which leads to a high-affinity, three-component complex and subsequently inhibition of cell wall biosynthesis combined with pore formation.     

Production of class II bacteriocins by lactic acid bacteria; an example of biological warfare and communication

Lactic acid bacteria (LAB) fight competing Gram-positive microorganisms by secreting anti-microbial peptides called bacteriocins. Peptide bacteriocins are usually divided into lantibiotics (class I) and non-lantibiotics (class II), the latter being the main topic of this review. During the past decade many of these bacteriocins have been isolated and characterized, and elements of the genetic mechanisms behind bacteriocin production have been unravelled. Bacteriocins often have a narrow inhibitory spectrum, and are normally most active towards closely related bacteria likely to occur in the same ecological niche. Lactic acid bacteria seem to compensate for these narrow inhibitory spectra by producing several bacteriocins belonging to different classes and having different inhibitory spectra. The latter may also help in counteracting the possible development of resistance mechanisms in target organisms. In many strains, bacteriocin production is controlled in a cell-density dependent manner, using a secreted peptide-pheromone for quorum-sensing. The sensing of its own growth, which is likely to be comparable to that of related species, enables the producing organism to switch on bacteriocin production at times when competition for nutrients is likely to become more severe. Although today a lot is known about LAB bacteriocins and the regulation of their production, several fundamental questions remain to be solved. These include questions regarding mechanisms of immunity and resistance, as well as the molecular basis of target-cell specificity. This revised version was published online in August 2006 with corrections to the Cover Date.     

Sensitivity to the two‐peptide bacteriocin lactococcin G is dependent on UppP,an enzyme involved in cell‐wall synthesis

Most bacterially produced antimicrobial peptides (bacteriocins) are thought to kill target cells by a receptor‐mediated mechanism. However, for most bacteriocins the receptor is unknown. For instance, no target receptor has been identified for the two‐peptide bacteriocins (class IIb), whose activity requires the combined action of two individual peptides. To identify the receptor for the class IIb bacteriocin lactococcin G, which targets strains of Lactococcus lactis, we generated 12 lactococcin G‐resistant mutants and performed whole‐genome sequencing to identify mutations causing the resistant phenotype. Remarkably, all had a mutation in or near the gene uppP (bacA), encoding an undecaprenyl pyrophosphate phosphatase; a membrane protein involved in peptidoglycan synthesis. Nine mutants had stop codons or frameshifts in the uppP gene, two had point mutations in putative regulatory regions and one caused an amino acid substitution in UppP. To verify the receptor function of UppP, it was shown that growth of non‐sensitive Streptococcus pneumoniae could be inhibited by lactococcin G when L. lactis uppP was expressed in this bacterium. Furthermore, we show that the related class IIb bacteriocin enterocin 1071 also uses UppP as receptor. The approach used here should be broadly applicable to identify receptors for other bacteriocins as well.     

Lipid II-Based Antimicrobial Activity of the Lantibiotic Plantaricin C

We analyzed the mode of action of the lantibiotic plantaricin C (PlnC), produced by Lactobacillus plantarum LL441. Compared to the well-characterized type A lantibiotic nisin and type B lantibiotic mersacidin, which are both able to interact with the cell wall precursor lipid II, PlnC displays structural features of both prototypes. In this regard, we found that lipid II plays a key role in the antimicrobial activity of PlnC besides that of pore formation. The pore forming activity of PlnC in whole cells was prevented by shielding lipid II on the cell surface. However, in contrast to nisin, PlnC was not able to permeabilize Lactococcus lactis cells or to form pores in 1,2-dioleoyl-sn-glycero-3-phosphocholine liposomes supplemented with 0.1 mol% purified lipid II. This emphasized the different requirements of these lantibiotics for pore formation. Using cell wall synthesis assays, we identified PlnC as a potent inhibitor of (i) lipid II synthesis and (ii) the FemX reaction, i.e., the addition of the first Gly to the pentapeptide side chain of lipid II. As revealed by thin-layer chromatography, both reactions were clearly blocked by the formation of a PlnC-lipid I and/or PlnC-lipid II complex. On the basis of the in vivo and in vitro activities of PlnC shown in this study and the structural lipid II binding motifs described for other lantibiotics, the specific interaction of PlnC with lipid II is discussed.