Determining sites of interaction between prenisin and its modification enzymes NisB and NisC

Although nisin is a model lantibiotic, our knowledge of the specific interactions of prenisin with its modification enzymes remains fragmentary. Here, we demonstrate that the nisin modification enzymes NisB and NisC can be pulled down in vitro from Lactococcus lactis by an engineered His-tagged prenisin. This approach enables us to determine important intermolecular interactions of prenisin with its modification machinery within L. lactis. We demonstrate that (i) NisB has stronger interactions with precursor nisin than NisC has, (ii) deletion of the propeptide part keeping the nisin leader intact leads to a lack of binding, (iii) NisB point mutants of highly conserved residues W616, F342A, Y346F and P639A are still able to dehydrate prenisin, (iv) NisB Δ(77-79)Y80F mutant decreased the levels of NisB-prenisin interactions and resulted in unmodified prenisin, (v) substitution of an active site residue H331A in NisC leads to higher amounts of the co-purified complex, (vi) NisB is present in the form of a dimer, and (vii) the region FNLD (-18 to -15) of the leader is an important site for binding not only to NisB, but also to NisC.     

Distinct Contributions of the Nisin Biosynthesis Enzymes NisB and NisC and Transporter NisT to Prenisin Production by Lactococcus lactis

Several Lactococcus lactis strains produce the lantibiotic nisin. The dedicated enzymes NisB and NisC and the transporter NisT modify and secrete the ribosomally synthesized nisin precursor peptide. NisB can function in the absence of the cyclase NisC, yielding the dehydrated prenisin that lacks the thioether rings. A kinetic analysis of nisin production by L. lactis NZ9700 demonstrated that the prenisin was released from the cell into the medium before the processing of the leader sequence occurred. Upon the deletion of nisC, the production of prenisin was reduced by 70%, while in the absence of nisB, the production of prenisin was nearly completely abolished. In cells lacking nisT, no secretion was observed, while the expression of nisABC in these cells resulted in considerable growth rate inhibition caused by the intracellular accumulation of active nisin. Overall, these data indicate that the efficiency of prenisin transport by NisT is markedly enhanced by NisB, suggesting a channeling mechanism of prenisin transfer between the nisin modification enzymes and the transporter.     

Post-translational modification of nisin. The involvement of NisB in the dehydration process.

The lantibiotic nisin is an antimicrobial peptide produced by Lactococcus lactis. As with all lantibiotics, nisin contains a number of dehydro-residues and thioether amino acids that introduce five lanthionine rings into the target peptide. These atypical amino acids are introduced by post-translational modification of a ribosomally synthesized precursor peptide. In certain cases, the serine residue, at position 33 of nisin, does not undergo dehydration to Dha33. With native nisin this partially processed form represents about 10% of the total peptide, whereas with the engineered variants, [Trp30]nisin A and [Lys27,Lys31]nisin A, the proportion of peptide that escapes full processing was found to be to approximately 50%. This feature of nisin biosynthesis was exploited in an investigation of the role of the NisB protein in pre-nisin maturation. Manipulation of the level of NisB was achieved by cloning and overexpressing the plasmid-encoded nisB gene in a range of different nisin-producing strains. The resulting fourfold increase in the level of NisB significantly increased the efficiency of the dehydration reaction at Ser33. The final secreted product of biosynthesis by these strains was the homogenous form of the fully processed nisin (or nisin variant) molecule. The results presented represent the first experimental evidence for the direct involvement of the NisB protein in the maturation process of nisin.     

Sec-mediated transport of posttranslationally dehydrated peptides in Lactococcus lactis

Nisin is a lanthionine-containing antimicrobial peptide produced by Lactococcus lactis. Its (methyl)lanthionines are introduced by two posttranslational enzymatic steps involving the dehydratase NisB, which dehydrates serine and threonine residues, and the cyclase NisC, which couples these dehydrated residues to cysteines, yielding thioether-bridged amino acids called lanthionines. The prenisin is subsequently exported by the ABC transporter NisT and extracellularly processed by the peptidase NisP. L. lactis expressing the nisBTC genes can modify and secrete a wide range of nonlantibiotic peptides. Here we demonstrate that in the absence of NisT and NisC, the Sec pathway of L. lactis can be exploited for the secretion of dehydrated variants of therapeutic peptides. Furthermore, posttranslational modifications by NisB and NisC still occur even when the nisin leader is preceded by a Sec signal peptide or a Tat signal peptide 27 or 44 amino acids long, respectively. However, transport of fully modified prenisin via the Sec pathway is impaired. The extent of NisB-mediated dehydration could be improved by raising the intracellular concentration NisB or by modulating the export efficiency through altering the signal sequence. These data demonstrate that besides the traditional lantibiotic transporter NisT, the Sec pathway with an established broad substrate range can be utilized for the improved export of lantibiotic enzyme-modified (poly)peptides.     

NisT, the transporter of the lantibiotic nisin, can transport fully modified, dehydrated, and unmodified prenisin and fusions of the leader peptide with non-lantibiotic peptides

Lantibiotics are lanthionine-containing peptide antibiotics. Nisin, encoded by nisA, is a pentacyclic lantibiotic produced by some Lactococcus lactis strains. Its thioether rings are posttranslationally introduced by a membrane-bound enzyme complex. This complex is composed of three enzymes: NisB, which dehydrates serines and threonines; NisC, which couples these dehydrated residues to cysteines, thus forming thioether rings; and the transporter NisT. We followed the activity of various combinations of the nisin enzymes by measuring export of secreted peptides using antibodies against the leader peptide and mass spectroscopy for detection. L. lactis expressing the nisABTC genes efficiently produced fully posttranslationally modified prenisin. Strikingly, L. lactis expressing the nisBT genes could produce dehydrated prenisin without thioether rings and a dehydrated form of a non-lantibiotic peptide. In the absence of the biosynthetic NisBC enzymes, the NisT transporter was capable of excreting unmodified prenisin and fusions of the leader peptide with non-lantibiotic peptides. Our data show that NisT specifies a broad spectrum (poly)peptide transporter that can function either in conjunction with or independently from the biosynthetic genes. NisT secretes both unmodified and partially or fully posttranslationally modified forms of prenisin and non-lantibiotic peptides. These results open the way for efficient production of a wide range of peptides with increased stability or novel bioactivities.     

Requirements of the engineered leader peptide of nisin for inducing modification, export, and cleavage

Nisin A is a pentacyclic peptide antibiotic produced by Lactococcus lactis. The leader peptide of prenisin keeps nisin inactive and has a role in inducing NisB- and NisC-catalyzed modifications of the propeptide and NisT-mediated export. The highly specific NisP cleaves off the leader peptide from fully modified and exported prenisin. We present here a detailed mutagenesis analysis of the nisin leader peptide. For alternative cleavage, we successfully introduced a putative NisP autocleavage site and sites for thrombin, enterokinase, Glu-C, and factor Xa in the C-terminal part of the leader peptide. Replacing residue F-18 with Trp or Thr strongly reduced production. On the other hand, D-19A, F-18H, F-18M, L-16D, L-16K, and L-16A enhanced production. Substitutions within and outside the FNLD box enhanced or reduced the transport efficiency. None of the above substitutions nor even an internal 6His tag from positions -13 to -8 had any effect on the capacity of the leader peptide to induce NisB and NisC modifications. Therefore, these data demonstrate a large mutational freedom. However, simultaneous replacement of the FNLD amino acids by four alanines strongly reduced export and even led to a complete loss of the capacity to induce modifications. Reducing the leader peptide to MSTKDFNLDLR led to 3- or 4-fold dehydration. Taken together, the FNLD box is crucial for inducing posttranslational modifications.     

Sec-Mediated Transport of Posttranslationally Dehydrated Peptides in Lactococcus lactis

Nisin is a lanthionine-containing antimicrobial peptide produced by Lactococcus lactis. Its (methyl)lanthionines are introduced by two posttranslational enzymatic steps involving the dehydratase NisB, which dehydrates serine and threonine residues, and the cyclase NisC, which couples these dehydrated residues to cysteines, yielding thioether-bridged amino acids called lanthionines. The prenisin is subsequently exported by the ABC transporter NisT and extracellularly processed by the peptidase NisP. L. lactis expressing the nisBTC genes can modify and secrete a wide range of nonlantibiotic peptides. Here we demonstrate that in the absence of NisT and NisC, the Sec pathway of L. lactis can be exploited for the secretion of dehydrated variants of therapeutic peptides. Furthermore, posttranslational modifications by NisB and NisC still occur even when the nisin leader is preceded by a Sec signal peptide or a Tat signal peptide 27 or 44 amino acids long, respectively. However, transport of fully modified prenisin via the Sec pathway is impaired. The extent of NisB-mediated dehydration could be improved by raising the intracellular concentration NisB or by modulating the export efficiency through altering the signal sequence. These data demonstrate that besides the traditional lantibiotic transporter NisT, the Sec pathway with an established broad substrate range can be utilized for the improved export of lantibiotic enzyme-modified (poly)peptides.     

Production of dehydroamino acid-containing peptides by Lactococcus lactis

Nisin is a pentacyclic peptide antibiotic produced by some Lactococcus lactis strains. Nisin contains dehydroresidues and thioether rings that are posttranslationally introduced by a membrane-associated enzyme complex, composed of a serine and threonine dehydratase NisB and the cyclase NisC. In addition, the transporter NisT is necessary for export of the modified peptide. We studied the potential of L. lactis expressing NisB and NisT to produce peptides whose serines and threonines are dehydrated. L. lactis containing the nisBT genes and a plasmid coding for a specific leader peptide fusion construct efficiently produced peptides with a series of non-naturally occurring multiple flanking dehydrobutyrines. We demonstrated NisB-mediated dehydration of serines and threonines in a C-terminal nisin(1-14) extension of nisin, which implies that also residues more distant from the leader peptide than those occurring in prenisin or any other lantibiotic can be modified. Furthermore, the feasibility and efficiency of generating a library of peptides containing dehydroresidues were demonstrated. In view of the particular shape and reactivity of dehydroamino acids, such a library provides a novel source for screening for peptides with desired biological and physicochemical properties.     

Production of Dehydroamino Acid-Containing Peptides by Lactococcus lactis

Nisin is a pentacyclic peptide antibiotic produced by some Lactococcus lactis strains. Nisin contains dehydroresidues and thioether rings that are posttranslationally introduced by a membrane-associated enzyme complex, composed of a serine and threonine dehydratase NisB and the cyclase NisC. In addition, the transporter NisT is necessary for export of the modified peptide. We studied the potential of L. lactis expressing NisB and NisT to produce peptides whose serines and threonines are dehydrated. L. lactis containing the nisBT genes and a plasmid coding for a specific leader peptide fusion construct efficiently produced peptides with a series of non-naturally occurring multiple flanking dehydrobutyrines. We demonstrated NisB-mediated dehydration of serines and threonines in a C-terminal nisin(1-14) extension of nisin, which implies that also residues more distant from the leader peptide than those occurring in prenisin or any other lantibiotic can be modified. Furthermore, the feasibility and efficiency of generating a library of peptides containing dehydroresidues were demonstrated. In view of the particular shape and reactivity of dehydroamino acids, such a library provides a novel source for screening for peptides with desired biological and physicochemical properties.     

Nisin biosynthesis in vitro

The lantibiotic nisin is produced by Lactococcus lactis. In the biosynthesis of nisin, the enzyme NisB dehydrates nisin precursor, and the enzyme NisC is needed for lanthionine formation. In this study, the nisA gene encoding the nisin precursor, and the genes nisB and nisC of the lantibiotic modification machinery were expressed together in vitro by the Rapid Translation System (RTS). Analysis of the RTS mixture showed that fully modified nisin precursor was formed. By treating the mixture with trypsin, active nisin was obtained. However, no nisin could be detected in the mixture without zinc supplementation, explained by the fact that NisC requires zinc for its function. The results revealed that the modification of nisin precursor, which is supposed to occur at the inner side of the membrane by an enzyme complex consisting of NisB, NisC, and the transporter NisT, can take place without membrane association and without NisT. This in vitro production system for nisin opens up the possibility to produce nisin variants that cannot be producedin vivo. Moreover, the system is a promising tool for utilizing the NisB and NisC enzymes for incorporation of thioether rings into medical peptides and hormones for increased stability.     

Directionality and Coordination of Dehydration and Ring Formation during Biosynthesis of the Lantibiotic Nisin

The lantibiotic nisin is a potent antimicrobial substance, which contains unusual lanthionine rings and dehydrated amino acid residues and is produced by Lactococcus lactis. Recently, the nisin biosynthetic machinery has been applied to introduce lanthionine rings in peptides other than nisin with potential therapeutic use. Due to difficulties in the isolation of the proposed synthetase complex (NisBTC), mechanistic information concerning the enzymatic biosynthesis of nisin is scarce. Here, we present the molecular characterization of a number of nisin mutants that affect ring formation. We have investigated in a systematic manner how these mutations influence dehydration events, which are performed enzymatically by the dehydratase NisB. Specific mutations that hampered ring formation allowed for the dehydration of serine residues that directly follow the rings and are normally unmodified. The combined information leads to the conclusion that 1) nisin biosynthesis is an organized directional process that starts at the N terminus of the molecule and continues toward the C terminus, and 2) NisB and NisC are alternating enzymes, whose activities follow one after another in a repetitive way. Thus, the dehydration and cyclization processes are not separated in time and space. On the basis of these results and previous knowledge, a working model for the sequence of events in the maturation of nisin is proposed.Nisin is a lantibiotic produced by Lactococcus lactis, which has been known since 1928 (1, 2). This antimicrobial peptide is active against various Gram-positive bacteria and has attained commercial success as a food preservative (3). In addition to the wide industrial applications of nisin, it became also a model system to study various aspects of lantibiotic biosynthesis, regulation, and mode of action (2). Furthermore, recently, other applications of nisin have emerged. Its biosynthetic machinery can be successfully used to install dehydrated amino acids and lanthionine rings in peptides, which are either related or totally unrelated to nisin (4–11). This offers great opportunities to modulate the stability and activity of peptides that are used as therapeutics (8).The post-translational modified nisin molecule is classified as a member of the Group A lantibiotics (12). Mature nisin contains 34 amino acids, three of which are posttranslationally modified, and five thioether rings that are enzymatically formed upon cyclization of five free cysteines and five dehydroamino acid residues (Fig. 1). These peculiar modifications, which are very rare in nature, give nisin its exceptional stability against proteolysis and contribute greatly to its antimicrobial activity.Open in a separate windowFIGURE 1.Primary structure of prenisin and generated mutants. Dehydrated residues are shaded gray; serine 33 sometimes escapes dehydration and is shaded light gray. Serine at position 29 is never dehydrated in wild type prenisin. The impact of mutations on the dehydration pattern of new prenisin species is schematically depicted. Mutated residues are indicated by filled red circles. Newly formed dehydrated residues are pointed to by a black arrow. Letters A–E correspond to the five consecutive lanthionine rings in nisin.Nisin is synthesized ribosomally as a 57-amino acid residue-long polypeptide. Subsequently, it is directed to a putative synthetase complex that probably consists of three different proteins that include the dehydratase NisB, responsible for dehydration of serines and threonines to dehydroalanines and dehydrobutyrines, respectively; the cyclase NisC, which forms (methyl) lanthionine bridges between cysteines and dehydroamino acids; and the ABC transporter NisT, which performs transport across the lipid bilayer by consuming ATP. Newly synthesized and modified prenisin is still antimicrobially inactive. Only upon cleavage of the leader sequence that encompasses the first 23 amino acids by the dedicated protease NisP, an active molecule is liberated.Although there are data pointing to the existence of a synthetase complex that modifies nisin, such a complex has not been isolated so far. However, both NisB (13, 14) and NisC (13) were shown by specific antibody detection to localize at the cytoplasmic membrane, although some soluble signal was also detected. This localization gives NisBC the opportunity to interact with the transporter NisT, which is an integral membrane protein. Furthermore, co-immunoprecipitation and yeast two-hybrid studies suggested an interaction between members of the nisin modification machinery and nisin itself (13). The function of each member of the putative multimeric synthetase has been investigated in vivo by knock-out studies. It also has been demonstrated that subsequent steps in nisin biosynthesis can be performed separately. Dehydration, cyclization, and transport of the modified product were dissected in vivo, and also the dehydratase has been shown to perform enzymatic reactions without the presence of other members of the complex in vivo (7) although with very low efficiency. The cyclization activity of NisC was demonstrated in vitro (15), and the ABC transporter NisT was shown to be capable of transport of unmodified prenisin in vivo (10). Based on the available data, it is difficult to assess whether multimeric lanthionine complexes are indispensable for efficient nisin production and modification. However, in vivo localization studies and interaction experiments suggest that these proteins work in a concerted manner.Here, we present data that indicates a strong coordination between members of the nisin modification machinery. The analysis of sets of nisin mutants, where key residues that take part in ring formation as well as substitutions of residues that directly follow lanthionine structures, suggests a strong interdependency of dehydratase and cyclase activity. Moreover, the data indicate that these enzymes alternate during catalysis and that they are intertwined in time and space. Our data also suggest that nisin modification is an ordered process that proceeds consecutively from the N terminus of prenisin toward its C terminus. Based on the available literature data and the data presented here, we propose a model wherein nisin is being posttranslationally modified in consecutive steps from its N terminus toward its C terminus.     

Influence of Shifting Positions of Ser, Thr, and Cys Residues in Prenisin on the Efficiency of Modification Reactions and on the Antimicrobial Activities of the Modified Prepeptides

Since the recent discovery that the nisin modification and transport machinery can be used to produce and modify peptides unrelated to nisin, specific questions arose concerning the specificity of the modification enzymes involved and the limits of their promiscuity with respect to the dehydration and cyclization processes. The nisin leader peptide has been postulated to fulfill a recognition and binding function required for these modifications. Here, we investigated whether the relative positions of the modifiable residues in the nisin prepeptide, with respect to the leader peptide, could influence the efficiency of their modification. We conducted a systematic study on the insertion of one to four alanines in front of either ring A or ring D to change the “reading frame” of modifiable residues, resulting in altered distance and topology of the modifiable residues relative to the leader. The insertion of N-terminal and hinge-located Ala residues had only a modest influence on the modification efficiency, demonstrating that the “phasing” of these residues relative to the leader peptide is not a critical factor in determining modification. However, in all cases, but especially with the N-terminal insertions, the antimicrobial activities of the fully modified nisin species were decreased.     

Heterologous expression and purification of NisA, the precursor peptide of lantibiotic nisin from Lactococcus lactis

The lantibiotic nisin is a ribosomally synthesised and post-translationally modified antimicrobial peptide produced by strains of Lactococcus lactis, and used as safe and natural preservative in food industry. The nisA structural gene encodes ribosomally synthesised and biologically inactive a 57 amino acid precursor peptide (NisA) which undergoes several post-translational modifications. In this study, we report the expression of precursor nisin as a His6-tagged peptide in Escherichia coli and its purification using a nickel affinity column. The technique of spliced-overlap extension PCR was used to amplify the nisA gene and the T7 promoter region of pET-15b vector. This approach was used to introduce six histidine residues at the C-terminus of prenisin. The identity of the expressed peptide was confirmed by N-terminal sequencing. The expressed His-tagged prenisin was purified under denaturing conditions, and named as prenisin-His6. The purified prenisin-His6 was analyzed by SDS-PAGE, Western blotting and mass spectroscopy. These results showed that the nisin precursor peptide can be successfully produced using an E. coli expression system.     

Semi-microbiological synthesis of an active lysinoalanine-bridged analog of glucagon-like-peptide-1

Some modified glucagon-like-peptide-1 (GLP-1) analogs are highly important for treating type 2 diabetes. Here we investigated whether GLP-1 analogs expressed in Lactococcus lactis could be substrates for modification and export by the nisin dehydratase and transporter enzyme. Subsequently we introduced a lysinoalanine by coupling a formed dehydroalanine with a lysine and investigated the structure and activity of the formed lysinoalanine-bridged GLP-1 analog. Our data show: (i) GLP-1 fused to the nisin leader peptide is very well exported via the nisin transporter NisT, (ii) production of leader-GLP-1 via NisT is higher than via the SEC system, (iii) leader-GLP-1 exported via NisT was more efficiently dehydrated by the nisin dehydratase NisB than when exported via the SEC system, (iv) individual serines and threonines in GLP-1 are dehydrated by NisB to a significantly different extent, (v) an introduced Ser30 is well dehydrated and can be coupled to Lys34 to form a lysinoalanine-bridged GLP-1 analog, (vi) a lysinoalanine(30-34) variant's conformation shifts in the presence of 25% trifluoroethanol towards a higher alpha helix content than observed for wild type GLP-1 under identical condition, (vii) a lysinoalanine(30-34) GLP-1 variant has retained significant activity. Taken together the data extend knowledge on the substrate specificities of NisT and NisB and their combined activity relative to export via the Sec system, and demonstrate that introducing a lysinoalanine bridge is an option for modifying therapeutic peptides.     

The lantibiotic nisin, a special case or not?

Nisin is a 34-residue-long peptide belonging to the group A lantibiotics with antimicrobial activity against Gram-positive bacteria. The presence of dehydrated residues and lanthionine rings (thioether bonds) in nisin, imposing structural restrains on the peptide, make it an interesting case for studying the mode of action. In addition, the relatively high activity (nM range) of nisin against Gram-positive bacteria indicates that nisin may be a special case in the large family of pore-forming peptides antibiotics. In this review, we attempted to dissect the mode of action of nisin concentrating on studies that used model membranes or biological membranes. The picture that emerges suggests that in model membrane systems, composed of only phospholipids, nisin behaves similar to the antimicrobial peptide magainin, albeit with an activity that is much lower as compared to its activity towards biological membranes. This difference can be contributed to a missing factor which nisin needs for its high activity. Novel results have identified the factor as Lipid II, a precursor in the bacterial cell wall synthesis. The special high affinity interaction of nisin with Lipid II resulting in high activity and the active role of Lipid II in the pore-formation process make nisin a special case.     

Engineering a disulfide bond and free thiols in the lantibiotic nisin Z.

The antimicrobial peptide nisin contains the uncommon amino acid residues lanthionine and methyl-lanthionine, which are post-translationally formed from Ser, Thr and Cys residues. To investigate the importance of these uncommon residues for nisin activity, a mutant was designed in which Thr13 was replaced by a Cys residue, which prevents the formation of the thioether bond of ring C. Instead, Cys13 couples with Cys19 via an intramolecular disulfide bridge, a bond that is very unusual in lantibiotics. NMR analysis of this mutant showed a structure very similar to that of wild-type nisin, except for the configuration of ring C. The modification was accompanied by a dramatic reduction in antimicrobial activity to less than 1% of wild-type activity, indicating that the lanthionine of ring C is very important for this activity. The nisin Z mutants S5C and M17C were also isolated and characterized; they are the first lantibiotics known that contain an additional Cys residue that is not involved in bridge formation but is present as a free thiol. Secretion of these peptides by the lactococcal producer cells, as well as their antimicrobial activity, was found to be strongly dependent on a reducing environment. Their ability to permeabilize lipid vesicles was not thiol-dependent. Labeling of M17C nisin Z with iodoacetamide abolished the thiol-dependence of the peptide. These results show that the presence of a reactive Cys residue in nisin has a strong effect on the antimicrobial properties of the peptide, which is probably the result of interaction of these residues with thiol groups on the outside of bacterial cells.     

乳链菌肽作用机制及其应用

乳链菌肽作为高效、安全的天然食品防腐剂已得到广泛应用。成熟的乳链菌肽含有34个氨基酸残基,由5个硫醚桥组成独特的内环结构,是研究蛋白质结构与功能的一个很好的材料。本文论述了乳链菌肽的分子结构及其与细胞膜作用的分子机制,详细阐述了乳链菌肽的作用模型。     

Lanthionine introduction into nukacin ISK-1 prepeptide by co-expression with modification enzyme NukM in Escherichia coli

We demonstrated lanthionine introduction into hexa-histidine-tagged (His-tagged) nukacin ISK-1 prepeptide NukA by modification enzyme NukM in Escherichia coli. Co-expression of nukA and nukM, purification of the resulting His-tagged prepeptide by affinity chromatography, and subsequent mass spectrometry analysis showed that the prepeptide was converted into a postulated peptide with decrease in mass of 72Da which resulted from dehydration of four amino acids. Characterization of the resultant prepeptide indicated the presence of unusual amino acids, such as dehydrated amino acid, lanthionine or 3-methyllanthionine, in its C-terminal propeptide moiety. The modified prepeptide encompassing the leader peptide attached to the post-translationally modified propeptide moiety was readily obtained by one-step purification. Our findings will thus be a powerful tool for introducing unusual amino acids aimed at peptide engineering and also helpful to provide new insight for further understanding of lanthionine-forming enzymes for lantibiotics.     

NisC, the cyclase of the lantibiotic nisin, can catalyze cyclization of designed nonlantibiotic peptides

Nisin is a pentacyclic peptide antibiotic active against Gram-positive bacteria. Its thioether rings are formed by two enzymatic steps: nisin dehydratase (NisB)-mediated dehydration of serines and threonines followed by nisin cyclase (NisC)-catalyzed enantioselective coupling of cysteines to the formed dehydroresidues. Here, we report the in vivo activity of NisC to cyclize a wide array of unrelated and designed peptides that were fused to the nisin leader peptide. To assess the role of NisC, leader peptide fusions, secreted by Lactococcus lactis cells containing NisBT with or without NisC were compared. In hexapeptides, a dehydroalanine could spontaneously react with a more C-terminally located cysteine. In contrast, peptides containing dehydrobutyrines require NisC for cyclization. In agreement with in silico predictions NisC could efficiently cyclize the hexapeptides ADhbVECK and IDhbPGCK, but ADhbVWCE was not cyclized. Interestingly, NisC could efficiently catalyze the synthesis of peptides with intertwined rings and of a designed polyhexapeptide containing four thioether rings. Taken together the data demonstrate that NisC can be widely applied for the cyclization and stabilization of nonlantibiotic peptides.