A hemocyanin-derived antimicrobial peptide from the penaeid shrimp adopts an alpha-helical structure that specifically permeabilizes fungal membranes.

BACKGROUND: Hemocyanins are respiratory proteins with multiple functions. In diverse crustaceans hemocyanins can release histidine-rich antimicrobial peptides in response to microbial challenge. In penaeid shrimp, strictly antifungal peptides are released from the C-terminus of hemocyanins. METHODS: The three-dimensional structure of the antifungal peptide PvHCt from Litopenaeus vannamei was determined by NMR. Its mechanism of action against the shrimp pathogen Fusarium oxysporum was investigated using immunochemistry, fluorescence and transmission electron microscopy. RESULTS: PvHCt folded into an amphipathic α-helix in membrane-mimicking media and displayed a random conformation in aqueous environment. In contact with F. oxysporum, PvHCt bound massively to the surface of fungal hyphae without being imported into the cytoplasm. At minimal inhibitory concentrations, PvHCt made the fungal membrane permeable to SYTOX-green and fluorescent dextran beads of 4 kDa. Higher size beads could not enter the cytoplasm. Therefore, PvHCt likely creates local damages to the fungal membrane. While the fungal cell wall appeared preserved, gradual degeneration of the cytoplasm most often resulting in cell lysis was observed in fungal spores and hyphae. In the remaining fungal cells, PvHCt induced a protective response by the formation of daughter hyphae. CONCLUSION: The massive accumulation of PvHCt at the surface of fungal hyphae and subsequent insertion into the plasma membrane disrupt its integrity as a permeability barrier, leading to disruption of internal homeostasis and fungal death. GENERAL SIGNIFICANCE: The histidine-rich antimicrobial peptide PvHCt derived from shrimp hemocyanin is a strictly antifungal peptide, which adopts an amphipathic α-helical structure, and selectively binds to and permeabilizes fungal cells.

Halocin C8: an antimicrobial peptide distributed among four halophilic archaeal genera: Natrinema, Haloterrigena, Haloferax, and Halobacterium.

Halophilic archaea thrive in hypersaline ecosystems and produce antimicrobial peptides (AMPs) named halocins. AMPs are essential effectors of microbial interactions in natural ecosystems. Halocin C8 is a 7.4 kDa peptide produced by Natrinema sp. AS7092. Surrounded by genes involved in regulation and transport, the halC8 gene encodes a precursor, processed into the mature halocin and an immunity protein, protecting the producing strain against its halocin. This feature constitutes a unique property of halocin C8, as known AMPs and their immunity proteins are generally encoded on distinct ORFs in an operon. By complementary in silico and PCR-based approaches, the presence of halC8 in halophilic archaea collected from various parts of the world was evidenced. The full-length halC8 gene is restricted and consistently found in the genomes of strains belonging to the phylogenetically related genera Natrinema and Haloterrigena, along with transport and regulation genes. Functional expression of halC8 was demonstrated by RT-PCR and antimicrobial assays. Active halocin C8 was shown to contain five disulphide bridges, presumably conferring a compact structure resistant to harsh environmental conditions. In other archaeal genera, Haloferax and Halobacterium, genes encoding halocin C8 with diverging immunity protein moiety were evidenced. A phylogenetic analysis of halocin C8 sequences was conducted.

Structural basis for hijacking siderophore receptors by antimicrobial lasso peptides.

The lasso peptide microcin J25 is known to hijack the siderophore receptor FhuA for initiating internalization. Here, we provide what is to our knowledge the first structural evidence on the recognition mechanism, and our biochemical data show that another closely related lasso peptide cannot interact with FhuA. Our work provides an explanation on the narrow activity spectrum of lasso peptides and opens the path to the development of new antibacterials.

Sequence determinants governing the topology and biological activity of a lasso peptide, microcin J25.

Microcin J25 is a potent antibacterial peptide produced by Escherichia coli AY25. It displays a lasso structure, which consists of a knot involving an N-terminal macrolactam ring through which the C-terminal tail is threaded and sterically trapped. In this study, we rationally designed and performed site-specific mutations in order to pinpoint the sequence determinants of the lasso topology. Structures of the resulting variants were analysed by a combination of methods (mass spectrometry, NMR spectroscopy, enzymatic digestion), and correlated to the antibacterial activity. The selected mutations resulted in the production of branched-cyclic or lasso variants. The C-terminal residues below the ring (Tyr20, Gly21) and the size of the macrolactam ring were revealed to be critical for both the lasso scaffold and bioactivity, while shortening the loop region (Tyr9-Ser18) or extending the C-terminal tail below the ring did not alter the lasso structure, but differentially affected the antibacterial activity. These results provide new insights for the bioengineering of antibacterial agents using a lasso peptide as template.

Dissecting the maturation steps of the lasso peptide microcin J25 in vitro.

Microcin J25 is the archetype of a growing class of bacterial ribosomal peptides possessing a knotted topology (lasso peptides). It consists of an eight-residue macrolactam ring through which the C-terminal tail is threaded. It is biosynthesized as a precursor that is processed by two maturation enzymes (McjB/McjC). Insights into the mechanism of microcin J25 biosynthesis have been provided previously by mutagenesis of the precursor peptide in vivo. In this study we have demonstrated distinct functions of McjB and McjC in vitro for the first time, based on the detection of reaction intermediates. McjB was characterized as a new ATP-dependent cysteine protease, whereas McjC was confirmed to be a lactam synthetase. The two enzymes were functionally interdependent, likely forming a structural complex. Their substrate preference was directly investigated with the aid of mutated precursor peptides. Depending on the substitutions, microcin J25 variants with either a lasso or branched-cyclic topology could be generated in vitro.

Two enzymes catalyze the maturation of a lasso peptide in Escherichia coli.

Microcin J25 (MccJ25) is a gene-encoded lasso peptide secreted by Escherichia coli which exerts a potent antibacterial activity by blocking RNA polymerase. Here we demonstrate that McjB and McjC, encoded by genes in the MccJ25 gene cluster, catalyze the maturation of MccJ25. Requirement for both McjB and McjC was shown by gene inactivation and complementation assays. Furthermore, the conversion of the linear precursor McjA into mature MccJ25 was obtained in vitro in the presence of McjB and McjC, all proteins being produced by recombinant expression in E. coli. Analysis of the amino acid sequences revealed that McjB could possess proteolytic activity, whereas McjC would be the ATP/Mg(2+)-dependent enzyme responsible for the formation of the Gly1-Glu8 amide bond. Finally, we show that putative lasso peptides are widespread among Proteobacteria and Actinobacteria.

An orthogonal system for heterologous expression of actinobacterial lasso peptides in Streptomyces hosts.

Lasso peptides are ribosomally synthesized and post-translationally modified peptides produced by bacteria. They are characterized by an unusual lariat-knot structure. Targeted genome scanning revealed a wide diversity of lasso peptides encoded in actinobacterial genomes, but cloning and heterologous expression of these clusters turned out to be problematic. To circumvent this, we developed an orthogonal expression system for heterologous production of actinobacterial lasso peptides in Streptomyces hosts based on a newly-identified regulatory circuit from Actinoalloteichus fjordicus. Six lasso peptide gene clusters, mainly originating from marine Actinobacteria, were chosen for proof-of-concept studies. By varying the Streptomyces expression hosts and a small set of culture conditions, three new lasso peptides were successfully produced and characterized by tandem MS. The newly developed expression system thus sets the stage to uncover and bioengineer the chemo-diversity of actinobacterial lasso peptides. Moreover, our data provide some considerations for future bioprospecting efforts for such peptides.

The iron-siderophore transporter FhuA is the receptor for the antimicrobial peptide microcin J25: role of the microcin Val11-Pro16 beta-hairpin region in the recognition mechanism.

The role of the outer-membrane iron transporter FhuA as a potential receptor for the antimicrobial peptide MccJ25 (microcin J25) was studied through a series of in vivo and in vitro experiments. The requirement for both FhuA and the inner-membrane TonB-ExbB-ExbD complex was demonstrated by antibacterial assays using complementation of an fhuA(-) strain and by using isogenic strains mutated in genes encoding the protein complex respectively. In addition, MccJ25 was shown to block phage T5 infection of Escherichia coli, in vivo, by inhibiting phage adhesion, which suggested that MccJ25 prevents the interaction between the phage and its receptor FhuA. This in vivo activity was confirmed in vitro, as MccJ25 inhibited phage T5 DNA ejection triggered by purified FhuA. Direct interaction of MccJ25 with FhuA was demonstrated for the first time by size-exclusion chromatography and isothermal titration calorimetry. MccJ25 bound to FhuA with a 2:1 stoichiometry and a K(d) of 1.2 microM. Taken together, our results demonstrate that FhuA is the receptor for MccJ25 and that the ligand-receptor interaction may occur in the absence of other components of the bacterial membrane. Finally, both differential scanning calorimetry and antimicrobial assays showed that MccJ25 binding involves external loops of FhuA. Unlike native MccJ25, a thermolysin-cleaved MccJ25 variant was unable to bind to FhuA and failed to prevent phage T5 infection of E. coli. Therefore the Val11-Pro16 beta-hairpin region of MccJ25, which is disrupted upon cleavage by thermolysin, is required for microcin recognition.

Characterization of Sviceucin from Streptomyces Provides Insight into Enzyme Exchangeability and Disulfide Bond Formation in Lasso Peptides.

Lasso peptides are bacterial ribosomally synthesized and post-translationally modified peptides. They have sparked increasing interest in peptide-based drug development because of their compact, interlocked structure, which offers superior stability and protein-binding capacity. Disulfide bond-containing lasso peptides are rare and exhibit highly sought-after activities. In an effort to expand the repertoire of such molecules, we heterologously expressed, in Streptomyces coelicolor, the gene cluster encoding sviceucin, a type I lasso peptide with two disulfide bridges originating from Streptomyces sviceus, which allowed it to be fully characterized. Sviceucin and its reduced forms were characterized by mass spectrometry and peptidase digestion. The three-dimensional structure of sviceucin was determined using NMR. Sviceucin displayed antimicrobial activity selectively against Gram-positive bacteria and inhibition of fsr quorum sensing in Enterococcus faecalis. This study adds sviceucin to the type I lasso peptide family as a new representative. Moreover, new clusters encoding disulfide-bond containing lasso peptides from Actinobacteria were identified by genome mining. Genetic and functional analyses revealed that the formation of disulfide bonds in sviceucin does not require a pathway-encoded thiol-disulfide oxidoreductase. Most importantly, we demonstrated the functional exchangeability of the sviceucin and microcin J25 (a non-disulfide-bridged lasso peptide) macrolactam synthetases in vitro, highlighting the potential of hybrid lasso synthetases in lasso peptide engineering.

Microcin J25, from the macrocyclic to the lasso structure: implications for biosynthetic, evolutionary and biotechnological perspectives.

Microcin J25 (MccJ25) is a cyclic antibacterial peptide secreted by a fecal isolate of Escherichia coli. It exerts highly potent activity on Salmonella and Escherichia species. The microcin is recognized at the outer membrane of sensitive strains by the FhuA multifunctional protein, which belongs to the iron/siderophore receptor family, and inhibits bacterial transcription through binding to the RNA-polymerase beta' subunit. The mcjABCD genetic system carried by the wild type 50-kb pTUC100 plasmid contains four genes involved in MccJ25 production and immunity. MccJ25 results from the proteolytic cleavage of a 58-residue precursor at a specific Lys-Gly bond. The resulting mature peptide consists of 21 unmodified amino acids, mostly hydrophobic and includes a single dehydration. The initially described macrocyclic structure of MccJ25, which mostly relied on manual Edman sequencing of the thermolysin-cleaved form (t-MccJ25), involved a head-to-tail cyclisation of the 21-residue precursor. This structure did not prove to be consistent with recent IT-MS CID experiments conducted either on the native microcin or on peptides resulting from acidic or enzymatic cleavages, which are in favour of an 8-residue ring followed by a 13-residue tail. Cyclisation thus occurs between the N-terminus (Gly1) and the Glu8 side chain carboxyl group. The solution three-dimensional structure shows threading of the tail into the ring, thus forming a highly stable lasso type structure. Such a structure was described previously for enzyme inhibitors from Actinobacteria and is consistent with the ability of MccJ25 to inhibit RNA polymerase. The lasso structure is discussed in terms of phylogenetical and biotechnological perspectives.

Combined use of LC/MS and a biological test for rapid identification of marine mycotoxins produced by Trichoderma koningii.

Trichoderma koningii Oudemans, a strain isolated from a shellfish farming area, was selected for its high frequency in samples and its ability to produce metabolites when cultured in natural seawater. Combined use of LC/MS and a biological test on blowfly larvae allowed the characterization of four compounds after purification in only two steps (VLC and HPLC). ESI/MS, a powerful tool for rapid identification and sequence determination of peptides, confirmed that these compounds were peptide, alpha-aminoisobutyric acid and amino alcohol (peptaibols), the usual metabolites of Trichoderma.

Identification of peptaibols from Trichoderma virens and cloning of a peptaibol synthetase.

The fungus Trichoderma virens is a ubiquitous soil saprophyte that has been applied as a biological control agent to protect plants from fungal pathogens. One mechanism of biocontrol is mycoparasitism, and T. virens produces antifungal compounds to assist in killing its fungal targets. Peptide synthetases produce a wide variety of peptide secondary metabolites in bacteria and fungi. Many of these are known to possess antibiotic activities. Peptaibols form a class of antibiotics known for their high alpha-aminoisobutyric acid content and their synthesis as a mixture of isoforms ranging from 7 to 20 amino acids in length. Here we report preliminary characterization of a 62.8-kb continuous open reading frame encoding a peptaibol synthetase from T. virens. The predicted protein structure consists of 18 peptide synthetase modules with additional modifying domains at the N- and C-termini. T. virens was shown to produce a mixture of peptaibols, with the largest peptides being 18 residues. Mutation of the gene eliminated production of all peptaibol isoforms. Identification of the gene responsible for peptaibol production will facilitate studies of the structure and function of peptaibol antibiotics and their contribution to biocontrol activity.

Thermolysin-linearized microcin J25 retains the structured core of the native macrocyclic peptide and displays antimicrobial activity.

Microcin J25 (MccJ25) is the single macrocyclic antimicrobial peptide belonging to the ribosomally synthesized class of microcins that are secreted by Enterobacteriaceae. It showed potent antibacterial activity against several Salmonella and Escherichia strains and exhibited a compact three-dimensional structure [Blond et al. (2001) Eur. J. Biochem., 268, 2124-2133]. The molecular mechanisms involved in the biosynthesis, folding and mode of action of MccJ25 are still unknown. We have investigated the structure and the antimicrobial activity of thermolysin-linearized MccJ25 (MccJ25-L1-21: VGIGTPISFY10GGGAGHVPEY20F), as well as two synthetic analogs, sMccJ25-L1-21 (sequence of the thermolysin-cleaved MccJ25) and sMccJ25-L12-11 (C-terminal sequence of the MccJ25 precursor: G12GAGHVPEYF21V1GIGTPISFYG11). The three-dimensional solution structure of MccJ25-L1-21, determined by two-dimensional NMR, consists of a boot-shaped hairpin-like well-defined 8-19 region flanked by disordered N and C termini. This structure is remarkably similar to that of cyclic MccJ25, and includes a short double-stranded antiparallel beta-sheet (8-10/17-19) perpendicular to a loop (Gly11-His16). The thermolysin-linearized MccJ25-L1-21 had antibacterial activity against E. coli and S. enteritidis strains, while both synthetic analogues lacked activity and organized structure. We show that the 8-10/17-19 beta-sheet, as well as the Gly11-His16 loop are required for moderate antibacterial activity and that the Phe21-Pro6 loop and the MccJ25 macrocyclic backbone are necessary for complete antibacterial activity. We also reveal a highly stable 8-19 structured core present in both the native MccJ25 and the thermolysin-linearized peptide, which is maintained under thermolysin treatment and resists highly denaturing conditions.

Siderophore peptide, a new type of post-translationally modified antibacterial peptide with potent activity.

Microcin E492 (MccE492, 7886 Da), the 84-amino acid antimicrobial peptide from Klebsiella pneumoniae, was purified in a post-translationally modified form, MccE492m (8717 Da), from culture supernatants of either the recombinant Escherichia coli VCS257 strain harboring the pJAM229 plasmid or the K. pneumoniae RYC492 strain. Chymotrypsin digestion of MccE492m led to the MccE492m-(74-84) C-terminal fragment that carries the modification and that was analyzed by mass spectrometry and nuclear magnetic resonance at natural abundance. The 831-Da post-translational modification consists of a trimer of N-(2,3-dihydroxybenzoyl)-l-serine linked via a C-glycosidic linkage to a beta-d-glucose moiety, itself linked to the MccE492m Ser-84-carboxyl through an O-glycosidic bond. This modification, which mimics a catechol-type siderophore, was shown to bind ferric ions by analysis of the collision-induced dissociation pattern obtained for MccE492m-(74-84) by electrospray ion trap mass spectrometry experiments in the presence of FeCl(3). By using a series of wild-type and mutant isogenic strains, the three catechol-type siderophore receptors Fiu, Cir, and FepA were shown to be responsible for the recognition of MccE492m at the outer membrane of sensitive bacteria. Because MccE492m shows a broader spectrum of antibacterial activity and is more potent than MccE492, we propose that by increasing the microcin/receptor affinity, the modification leads to a better recognition and subsequently to a higher antimicrobial activity of the microcin. Therefore, MccE492m is the first member of a new class of antimicrobial peptides carrying a siderophore-like post-translational modification and showing potent activity, which we term siderophore-peptides.

Microcin C51 plasmid genes: possible source of horizontal gene transfer.

Microcin C51 (MccC51) is an antimicrobial nucleotide-heptapeptide produced by a natural Escherichia coli strain. A 5.7-kb fragment of the pC51 plasmid carrying the genes involved in MccC51 production, secretion, and self-immunity was sequenced, and the genes were characterized. The sequence of the MccC51 gene cluster is highly similar to that of the MccC7 gene. Recombinant plasmids carrying different combinations of the mcc genes involved in the MccC51 production or immunity were constructed to characterize their functional roles. The mccA, mccB, mccD, and mccE genes are involved in MccC51 production, while the mccC and mccE genes are responsible for immunity to MccC51. The mcc gene cluster is flanked by 44-bp direct repeats. Amino acid sequence comparisons allowed us to propose functions for each Mcc polypeptide in MccC51 biosynthesis. Plasmid pUHN containing the cloned mccA, mccB, mccC, and mccE genes, but lacking mccD, directed the synthesis of MccC51p, a substance chemically related to MccC51. MccC51p exhibited weak antibiotic activity against E. coli and was toxic to the producing cells. The immunity to exogenous MccC51 determined by the mccC and mccE genes did not overcome the toxic action of MccC51p on the producing cells. The G+C content of the MccC51 operon, markedly lower than that of the E. coli genome, and the presence of direct repeats suggest the possibility of horizontal transfer of this gene cluster.

Microcin E492 antibacterial activity: evidence for a TonB-dependent inner membrane permeabilization on Escherichia coli.

The mechanism of action of microcin E492 (MccE492) was investigated for the first time in live bacteria. MccE492 was expressed and purified to homogeneity through an optimized large-scale procedure. Highly purified MccE492 showed potent antibacterial activity at minimal inhibitory concentrations in the range of 0.02-1.2 microM. The microcin bactericidal spectrum of activity was found to be restricted to Enterobacteriaceae and specifically directed against Escherichia and Salmonella species. Isogenic bacteria that possessed mutations in membrane proteins, particularly of the TonB-ExbB-ExbD complex, were assayed. The microcin bactericidal activity was shown to be TonB- and energy-dependent, supporting the hypothesis that the mechanism of action is receptor mediated. In addition, MccE492 depolarized and permeabilized the E. coli cytoplasmic membrane. The membrane depolarization was TonB dependent. From this study, we propose that MccE492 is recognized by iron-siderophore receptors, including FepA, which promote its import across the outer membrane via a TonB- and energy-dependent pathway. MccE492 then inserts into the inner membrane, whereupon the potential becomes destabilized by pore formation. Because cytoplasmic membrane permeabilization of MccE492 occurs beneath the threshold of the bactericidal concentration and does not result in cell lysis, the cytoplasmic membrane is not hypothesized to be the sole target of MccE492.