Identification of Ligand Specificity Determinants in Lantibiotic Bovicin HJ50 and the Receptor BovK,a Multitransmembrane Histidine Kinase

Lantibiotic bovicin HJ50 is produced by Streptococcus bovis HJ50 and acts as the extracellular signal to autoregulate its own biosynthesis through BovK/R two-component system. Bovicin HJ50 shows a linear N-terminal and glubolar C-terminal structure, and the sensor histidine kinase BovK contains eight transmembrane segments lacking any extensive surface-exposed sensory domain. The signal recognition mechanism between bovicin HJ50 and BovK is still unknown. We performed saturated alanine scanning mutagenesis and other amino acid substitutions on bovicin HJ50 using a semi-in vitro biosynthesis. Results of the mutants inducing activities indicated that several charged and hydrophobic amino acids in ring B of bovicin HJ50, as well as two glycines were key residues to recognize BovK. Circular dichroism analyses indicated that both glycines contributed to bovicin HJ50 structural changes in the membrane. Biotin-labeled bovicin HJ50 could interact with the N-terminal sensor of BovK, and several charged residues and a conserved hydrophobic region in the N-terminal portion of BovK sensor domain were important for interacting with the signal bovicin HJ50. By combining the results, we suggested a mechanism of bovicin HJ50 recognizing and activating BovK mainly through electrostatic and hydrophobic interactions.     

Lantibiotics and microcins: polypeptides with unusual chemical diversity

Bacterial-derived antimicrobial polypeptides enjoy a large degree of structural and chemical diversity. Two well-studied examples of such polypeptides are the lanthionine-containing lantibiotics produced by a variety of Gram-positive bacteria, and their Gram-negative counterparts, the microcins. Both groups are produced as gene-encoded precursor peptides and undergo post-translational modification to generate the active moieties. Structure elucidation of novel lantibiotics and microcins has recently uncovered further novel structural and chemical features and, combined with the generation of analogue peptides by genetic manipulation, new insights into structure-function relationships have been gained. Furthermore, study of the mode of action of the lantibiotics nisin and mersacidin has revealed their use of a 'docking molecule' in the target cell to facilitate their biological activities. Meanwhile, in vitro studies with microcin B17 have helped to uncover the molecular mechanisms by which post-translational modification results in the formation of heterocyclic oxazole and thiazole rings. From a practical standpoint, both groups of polypeptides represent new lead structures for future development of antimicrobial agents, whilst the identification of the 'docking molecules' represents a step forward in the search for novel targets for future antibiosis.     

Venom peptides from solitary hunting wasps induce feeding disorder in lepidopteran larvae

The cell lytic activity and toxicity against lepidopteran larvae of 13 venom peptides (4 OdVPs and 9 EpVPs) from two solitary hunting wasps, Orancistrocerus drewseni and Eumenes pomiformis, were examined with mastoparan as a reference peptide. Of the 13 peptides, 7 were predicted to have α-helical structures that exhibit the typical character of amphipathic α-helical antimicrobial peptides. The remaining peptides exhibited coil structures; among these, EpVP5 possesses two Cys residues that form an internal disulfide bridge. All the helical peptides including mastoparan showed antimicrobial and insect cell lytic activities, whereas only two of them were hemolytic against human erythrocytes. The helical peptides induced a feeding disorder when injected into the vicinity of the head and thorax of Spodoptera exigua larvae, perhaps because their non-specific neurotoxic or myotoxic action induced cell lysis. At low concentrations, however, these helical peptides increased cell permeability without inducing cell lysis. These findings suggest that the helical venom peptides may function as non-specific neurotoxins or myotoxins and venom-spreading factors at low concentrations, as well as preservatives for long-term storage of the prey via antimicrobial, particularly antifungal, activities.     

Dual Role of GdmH in Producer Immunity and Secretion of the Staphylococcal Lantibiotics Gallidermin and Epidermin

The biosynthetic gene clusters of the staphylococcal lantibiotics epidermin and gallidermin are distinguished by the presence of the unique genes epiH and gdmH, respectively. They encode accessory factors for the ATP-binding cassette transporters that mediate secretion of the antimicrobial peptides. Here, we show that gdmH also contributes to immunity to gallidermin but not to nisin. gdmH alone affected susceptibility to gallidermin only moderately, but it led to a multiplication of the immunity level mediated by the FEG immunity genes when cloned together with the gdmT gene, suggesting a synergistic activity of the H and FEG systems. gdmH-related genes were identified in the genomes of several bacteria, indicating an involvement in further cellular functions.     

A Conserved Streptococcal Membrane Protein,LsrS, Exhibits a Receptor-Like Function for Lantibiotics

Streptococcus mutans strain GS-5 produces a two-peptide lantibiotic, Smb, which displays inhibitory activity against a broad spectrum of bacteria, including other streptococci. For inhibition, lantibiotics must recognize specific receptor molecules present on the sensitive bacterial cells. However, so far no such receptor proteins have been identified for any lantibiotics. In this study, using a powerful transposon mutagenesis approach, we have identified in Streptococcus pyogenes a gene that exhibits a receptor-like function for Smb. The protein encoded by that gene, which we named LsrS, is a membrane protein belonging to the CAAX protease family. We also found that nisin, a monopeptide lantibiotic, requires LsrS for its optimum inhibitory activity. However, we found that LsrS is not required for inhibition by haloduracin and galolacticin, both of which are two-peptide lantibiotics closely related to Smb. LsrS appears to be a well-conserved protein that is present in many streptococci, including S. mutans. Inactivation of SMU.662, an LsrS homolog, in S. mutans strains UA159 and V403 rendered the cells refractory to Smb-mediated killing. Furthermore, overexpression of LsrS in S. mutans created cells more susceptible to Smb. Although LsrS and its homolog contain the CAAX protease domain, we demonstrate that inactivation of the putative active sites on the LsrS protein has no effect on its receptor-like function. This is the first report describing a highly conserved membrane protein that displays a receptor-like function for lantibiotics.     

Characterization of a bacteriocin, Thermophilin 1277, produced by Streptococcus thermophilus SBT1277

AIMS: To assess the inhibitory activity and the influence of culture condition on the growth and bacteriocin, Thermophilin 1277, production by Streptococcus thermophilus SBT1277. METHODS AND RESULTS: Thermophilin 1277, which was produced by S. thermophilus SBT1277, showed an antimicrobial activity against several lactic acid bacteria and food spoilage bacteria including Clostridium butylicum, C. sprogenes and Bacillus cereus. Thermophilin 1277 was inactivated by proteinase K. Heating treatment did not affect the antimicrobial activity. The partially purified Thermophilin 1277 had an apparent molecular mass of 3.7 kDa. N-terminal sequence analysis revealed 15 amino acid residues that correspond with amino acid sequence of the lantibiotics bovicin HJ50 produced by Streptococcus bovis HJ50. The effects of culture condition for the bacteriocin production by S. thermophilus SBT1277 were studied. During the batch fermentation, Thermophilin 1277 was produced in M17 broth, but no bacteriocin production occurred in the sucrose-tryptone (ST) broth. Bacteriocin production was detected in pH controlled ST broth at pH values of 5.5-6.5. CONCLUSIONS: Thermophilin 1277 production from S. thermophilus strain depended on the culture conditions. Some characters and N-terminal amino acid sequence of Thermophilin 1277 differed from bacteriocins produced by S. thermophilus reported previously. SIGNIFICANCE AND IMPACT OF THE STUDY: Streptococcus thermophilus SBT1277 or its bacteriocin which has a wide inhibitory spectrum has a potential use as a biopreservative in dairy products.     

Three new antimicrobial peptides from the scorpion Pandinus imperator

Three novel cysteine-free venom peptides, which were referred to as Pantinin-1, Pantinin-2 and Pantinin-3, respectively, have been identified from the scorpion Pandinus imperator by cDNA cloning strategy. The precursor of each peptide consists of a signal peptide, a mature peptide with no disulfide bridges, and an acidic propeptide with a typical processing signal. Each of the three peptides is an α-helical, cationic and amphipathic molecule with 13 or 14 amino acid residues. Their amino acid sequences are homologous to those of some 13-mer antimicrobial peptides isolated from scorpions. Antimicrobial assay showed that all the three peptides possess relatively strong activities against Gram-positive bacteria and a fungus, but have very weak antimicrobial activities against Gram-negative bacteria. Toxicity assay showed that the three peptides exhibit very low or mild hemolytic activities against human red blood cells. It is interesting to see that Pantinin-3 is able to potently inhibit the growth of vancomycin-resistant Enterococcus (VRE) S13, a pathogen that can cause a number of human infections; this suggests that Pantinin-3 has great potential to be applied in the treatment of VRE infections. Our findings gain new insights into the structure/function relationships of the small linear cationic antimicrobial peptides from scorpions, and provide new templates for designing of antimicrobial agents targeting antibiotic-resistant pathogenic bacteria.     

Autoinduction Specificities of the Lantibiotics Subtilin and Nisin

The biosynthesis of the lantibiotics subtilin and nisin is regulated by autoinduction via two-component systems. Although subtilin is structurally closely related to nisin and contains the same lanthionine ring structure, both lantibiotics specifically autoinduce their biosynthesis. Subtilin and also the subtilin-like lantibiotics entianin and ericin autoinduce the two-component system SpaRK of Bacillus subtilis, whereas the biosynthesis of nisin is autoinduced via the two-component system NisRK of Lactococcus lactis. Autoinduction is highly specific for the respective lantibiotic and therefore of major importance for the functional expression of genetically engineered subtilin-like lantibiotics. To identify the structural features required for subtilin autoinduction, subtilin-nisin hybrids and specific point mutations of amino acid position 1 were generated. For subtilin autoinduction, the N-terminal tryptophan is the most important for full SpaK activation. The failure of subtilin to autoinduce the histidine kinase NisK mainly depends on the N-terminal tryptophan, as its single exchange to the aliphatic amino acid residues isoleucine, leucine, and valine provided NisK autoinduction. In addition, the production of subtilin variants which did not autoinduce their own biosynthesis could be rescued upon heterologous coexpression in B. subtilis DSM15029 by the autoinducing subtilin-like lantibiotic entianin.     

Synthesis and Succinylation of Subtilin-Like Lantibiotics Are Strongly Influenced by Glucose and Transition State Regulator AbrB

Subtilin and the closely related entianin are class I lantibiotics produced by different subspecies of Bacillus subtilis. Both molecules are ribosomally synthesized peptide antibiotics with unusual ring structures. Subtilin-like lantibiotics develop strong antibiotic activities against various Gram-positive organisms with an efficiency similar to that of nisin from Lactococcus lactis. In contrast to nisin, subtilin-like lantibiotics partially undergo an additional posttranslational modification, where the N-terminal tryptophan residue becomes succinylated, resulting in drastically reduced antibiotic activities. A highly sensitive high-performance liquid chromatography (HPLC)-based quantification method enabled us to determine entianin and succinylated entianin (S-entianin) concentrations in the supernatant during growth. We show that entianin synthesis and the degree of succinylation drastically change with culture conditions. In particular, increasing glucose concentrations resulted in higher entianin amounts and lower proportions of S-entianin in Landy-based media. In contrast, no succinylation was observed in medium A with 10% glucose. Interestingly, glucose retarded the expression of entianin biosynthesis genes. Furthermore, deletion of the transition state regulator AbrB resulted in a 6-fold increased entianin production in medium A with 10% glucose. This shows that entianin biosynthesis in B. subtilis is strongly influenced by glucose, in addition to its regulation by the transition state regulator AbrB. Our results suggest that the mechanism underlying the succinylation of subtilin-like lantibiotics is enzymatically catalyzed and occurs in the extracellular space or at the cellular membrane.     

Two antimicrobial and nematicidal peptides derived from sequences encoded Picea sitchensis

Two antimicrobial peptides (piceain 1 and 2) derived from sequences encoded Picea sitchensis are identified. Their amino acid sequences are KSLRPRCWIKIKFRCKSLKF and RPRCWIKIKFRCKSLKF, respectively. One intra‐molecular disulfide bridge is formed by these two half‐cysteines in both piceain 1 and 2. Antimicrobial activities of synthesized piceains against several kinds of microorganisms were tested. They showed antimicrobial activities against Escherichia coli, Pseudomonas aeruginosa, Staphylococcus aureus, and fungus Candida albicans but little antimicrobial activity against Bacillus subtilis. The results of nematicidal test showed they exerted strong nematicidal activities against Caenorhabditis elegans, following exposure for 5 h at concentrations as low as 10 µg/ml. They had weak hemolytic abilities against human and rabbit red cells. At the concentration of 250 µg/ml, they induced red cell hemolysis of less than 5%. Circular dichroism spectra of the two antimicrobial peptides were investigated in several solutions. Their main secondary structure components are β‐sheet and random. The current work provides a novel family of antimicrobial and nematicidal peptides with unique disulfided loop containing nine amino acid residues. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Antimicrobial activity and conformation of gaegurin-6 amide and its analogs

A function of the intra-disulfide bridge located at the C-terminal of Rana peptides has not been extensively studied. To investigate the function of the disulfide bridge related to the activity and the structure, we chose Gaegurin-6, isolated from Rana rugosa as a model peptide and synthesized linear analogs. The reduction of the disulfide bridge resulted in the complete loss of antimicrobial activity while replacements of cysteines by serines retained antimicrobial activity. Circular dichroism spectra from a titration of the peptides in sodium dodecyl sulfate indicated that the disulfide bridge of Gaegurin-6 might stabilize the induction of an helical structure in lipid membranes and the helical forming propensity of the peptides correlated with antimicrobial activity.     

Three novel antimicrobial peptides from the skin of Rana shuchinae

Intensive studies have demonstrated that there are many antimicrobial peptides in amphibian skins. Three novel antimicrobial peptides were identified from the skin of the frog, Rana shuchinae. They are named shuchins 3–5. Their sequences were determined as KAYSMPRCKGGFRAVMCWL-NH₂, KAYSTPRCKGLFRALMCWL-NH₂, and KAYSMPRCKYLFRAVLCWL-NH₂ by Edman degradation and mass spectrometry analysis, respectively. They are composed of 19 amino acids (aa) with unique sequences. BLAST search indicated that they showed no similarity to any known peptides or proteins. They are a novel family of antimicrobial peptide. These peptides showed antimicrobial activities against all of tested microorganisms including Gram-positive bacteria, Gram-negative bacteria and fungi. The cDNAs encoding precursors of these peptides were cloned from the skin cDNA library of R. shuchinae. The precursors are composed of 64 amino acid residues including predicted signal peptides, acidic spacer peptides, and mature antimicrobial peptides. The current work identified a novel antimicrobial peptide family.     

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.     

Lantibiotics biosynthesis genes and bacteriocinogenic activity of <Emphasis Type="Italic">Lactobacillus</Emphasis> spp. isolated from raw milk and cheese

Lactobacillus species are usually used as starters for the production of fermented products, and some strains are capable of producing antimicrobial substances, such as bacteriocins. Because these characteristics are highly desirable, research are continually being performed for novel Lactobacillus strains with bacteriocinogenic potential for use by food industries. The aim of this study was to characterise the bacteriocinogenic potential and activity of Lactobacillus isolates. From a lactic acid bacteria culture collection obtained from raw milk and cheese, 27 isolates were identified by 16S rDNA as Lactobacillus spp. and selected for the detection of lantibiotics biosynthesis genes, bacteriocin production, antimicrobial spectra, and ideal incubation conditions for bacteriocin production. Based on the obtained results, 21 isolates presented at least one of the three lantibiotics biosynthesis genes (lanB, lanC or lamM), and 23 isolates also produced antimicrobial substances with sensitivity to at least one proteinase, indicating their bacteriocinogenic activity. In general, the isolates had broad inhibitory activity, mainly against Listeria spp. and Staphylococcus spp. strains, and the best antimicrobial performance of the isolates occurred when they were cultivated at 25 °C for 24 or 48 h or at 35 °C for 12 h. The present study identified the bacteriocinogenic potential of Lactobacillus isolates obtained from raw milk and cheese, suggesting their potential use as biopreservatives in foods.     

Novel antimicrobial peptides isolated from the skin secretions of Hainan odorous frog, Odorrana hainanensis

Long time geographical isolation of Hainan Island from the China continent has resulted in appearance of many novel frog species. As one of them, Hainan odorous frog, Odorrana hainanensis possesses some special antimicrobial peptides distinct from those found in other Odorrana. In this study, three antimicrobial peptides have been purified and characterized from the skin secretion of O. hainanensis. With the similarity to the temporin family, two peptides are characterized by amidated C-terminals, so they are named as temporin-HN1 (AILTTLANWARKFL-NH₂) and temporin-HN2 (NILNTIINLAKKIL-NH₂). The third antimicrobial peptide belongs to the brevinin-1 family which is widely distributed in Eurasian ranids, and thus, it is named as brevinin-1HN1 (FLPLIASLAANFVPKIFCKITKKC). Furthermore, after sequencing 68 clones, eight cDNAs encoding antimicrobial peptide precursors were cloned from the skin-derived cDNA library of O. hainanensis. These eight cDNAs can encode seven mature antimicrobial peptides including the above three, as well as brevinin-1V, brevinin-2HS2, odorranain-A6, and odorranain-B1. Twelve different species of microorganisms were chosen, including Gram-positive, Gram-negative and fungi, to test the antimicrobial activities of temporin-HN1, temporin-HN2, brevinin-1HN1, brevinin-1V, and brevinin-2HS2. The result shows that, in addition to their activities against Gram-positive bacteria, temporin-HN1 and temporin-HN2 also possess activities against some Gram-negative bacteria and fungi. However, the two antimicrobial peptides, brevinin-1HN1 and brevinin-1V of the brevinin-1 family have stronger antimicrobial activities than temporin-HN1 and temporin-HN2 of the temporin family. Brevinin-1HN1 possesses activity against Staphylococcus aureus (ATCC25923), Rhodococcus rhodochrous X15, and Slime mould 090223 at the concentration of 1.2 μM.     

Characterization of putative class II bacteriocins identified from a non-bacteriocin-producing strain Lactobacillus casei ATCC 334

Several putative class II bacteriocin-like genes were identified in Lactobacillus casei ATCC 334, all of which might encode peptides with a double-glycine leader. Six peptides encoded by these genes were heterologously expressed in Escherichia coli and then partially purified in order to test their bacteriocin activity. The results revealed that the mature LSEI_2163 peptide was a class IId bacteriocin that exhibited antimicrobial activity against some lactobacilli and several Listeria species. Similarly, mature LSEI_2386 was a putative pheromone peptide that also had significant bacteriocin activity against several Listeria species. The activities of both peptides tolerated 121°C for 30 min but not treatment with proteinase K or trypsin. The two Cys residues located at positions 4 and 24 in the mature LSEI_2163 peptide were shown by mass spectrometry to form a disulfide bridge, which was required for optimal antibacterial activity. However, replacement of one or both Cys with Ser would cause significant reduction of the antibacterial activity, the reduction being greater when only one of the Cys residues (C4S) was replaced than when both (C4S/C24S) were replaced.