Function of MbtH homologs in nonribosomal peptide biosynthesis and applications in secondary metabolite discovery

Mycobacterium tuberculosis encodes mycobactin, a peptide siderophore that is biosynthesized by a nonribosomal peptide synthetase (NRPS) mechanism. Within the mycobactin biosynthetic gene cluster is a gene that encodes a 71-amino-acid protein MbtH. Many other NRPS gene clusters harbor mbtH homologs, and recent genetic, biochemical, and structural studies have begun to shed light on the function(s) of these proteins. In some cases, MbtH-like proteins are required for biosynthesis of their cognate peptides, and non-cognate MbtH-like proteins have been shown to be partially complementary. Biochemical studies revealed that certain MbtH-like proteins participate in tight binding to NRPS proteins containing adenylation (A) domains where they stimulate adenylation reactions. Expression of MbtH-like proteins is important for a number of applications, including optimal production of native and genetically engineered secondary metabolites produced by mechanisms that employ NRPS enzymes. They also may serve as beacons to identify gifted actinomycetes and possibly other bacteria that encode multiple functional NRPS pathways for discovery of novel secondary metabolites by genome mining.     

Evolution of Chemical Diversity in Echinocandin Lipopeptide Antifungal Metabolites

The echinocandins are a class of antifungal drugs that includes caspofungin, micafungin, and anidulafungin. Gene clusters encoding most of the structural complexity of the echinocandins provided a framework for hypotheses about the evolutionary history and chemical logic of echinocandin biosynthesis. Gene orthologs among echinocandin-producing fungi were identified. Pathway genes, including the nonribosomal peptide synthetases (NRPSs), were analyzed phylogenetically to address the hypothesis that these pathways represent descent from a common ancestor. The clusters share cooperative gene contents and linkages among the different strains. Individual pathway genes analyzed in the context of similar genes formed unique echinocandin-exclusive phylogenetic lineages. The echinocandin NRPSs, along with the NRPS from the inp gene cluster in Aspergillus nidulans and its orthologs, comprise a novel lineage among fungal NRPSs. NRPS adenylation domains from different species exhibited a one-to-one correspondence between modules and amino acid specificity that is consistent with models of tandem duplication and subfunctionalization. Pathway gene trees and Ascomycota phylogenies are congruent and consistent with the hypothesis that the echinocandin gene clusters have a common origin. The disjunct Eurotiomycete-Leotiomycete distribution appears to be consistent with a scenario of vertical descent accompanied by incomplete lineage sorting and loss of the clusters from most lineages of the Ascomycota. We present evidence for a single evolutionary origin of the echinocandin family of gene clusters and a progression of structural diversification in two fungal classes that diverged approximately 290 to 390 million years ago. Lineage-specific gene cluster evolution driven by selection of new chemotypes contributed to diversification of the molecular functionalities.     

非核糖体肽合成酶(NRPSs)作用机理与应用的研究进展

许多微生物能利用非核糖体肽合成酶(NRPSs)合成结构复杂、种类繁多的的生物活性肽。非核糖体肽因其独特的理化特性和药理学特性已被广泛关注,极具商业开发潜力。NRPSs由多个模块组成,模块的不同空间排列顺序决定其多肽产物的氨基酸序列特异性。NRPSs以多载体巯基化模板机理进行多肽合成,其底物特异性由腺苷酰化结构域和缩合结构域共同实现。目前,人们已经利用天然的NRPSs、某些特定结构域、将已知NRPSs的模块或特定结构域进行组合甚至杂合组合而构建成的新的NRPSs来合成目的多肽。     

Prediction of the substrate for nonribosomal peptide synthetase (NRPS) adenylation domains by virtual screening

Nonribosomal peptide synthetases (NRPSs) synthesize a diverse array of bioactive small peptides, many of which are used in medicine. There is considerable interest in predicting NRPS substrate specificity in order to facilitate investigation of the many “cryptic” NRPS genes that have not been linked to any known product. However, the current sequence similarity‐based methods are unable to produce reliable predictions when there is a lack of prior specificity data, which is a particular problem for fungal NRPSs. We conducted virtual screening on the specificity‐determining domain of NRPSs, the adenylation domain, and found that virtual screening using experimentally determined structures results in good enrichment of the cognate substrate. Our results indicate that the conformation of the adenylation domain and in particular the conformation of a key conserved aromatic residue is important in determining the success of the virtual screening. When homology models of NRPS adenylation domains of known specificity, rather than experimentally determined structures, were built and used for virtual screening, good enrichment of the cognate substrate was also achieved in many cases. However, the accuracy of the models was key to the reliability of the predictions and there was a large variation in the results when different models of the same domain were used. This virtual screening approach is promising and is able to produce enrichment of the cognate substrates in many cases, but improvements in building and assessing homology models are required before the approach can be reliably applied to these models. Proteins 2015; 83:2052–2066. © 2015 Wiley Periodicals, Inc.     

Analysis of the linker region joining the adenylation and carrier protein domains of the modular nonribosomal peptide synthetases

Nonribosomal peptide synthetases (NRPSs) are multimodular proteins capable of producing important peptide natural products. Using an assembly line process, the amino acid substrate and peptide intermediates are passed between the active sites of different catalytic domains of the NRPS while bound covalently to a peptidyl carrier protein (PCP) domain. Examination of the linker sequences that join the NRPS adenylation and PCP domains identified several conserved proline residues that are not found in standalone adenylation domains. We examined the roles of these proline residues and neighboring conserved sequences through mutagenesis and biochemical analysis of the reaction catalyzed by the adenylation domain and the fully reconstituted NRPS pathway. In particular, we identified a conserved LPxP motif at the start of the adenylation‐PCP linker. The LPxP motif interacts with a region on the adenylation domain to stabilize a critical catalytic lysine residue belonging to the A10 motif that immediately precedes the linker. Further, this interaction with the C‐terminal subdomain of the adenylation domain may coordinate movement of the PCP with the conformational change of the adenylation domain. Through this work, we extend the conserved A10 motif of the adenylation domain and identify residues that enable proper adenylation domain function. Proteins 2014; 82:2691–2702. © 2014 Wiley Periodicals, Inc.     

Structure of PA1221, a nonribosomal peptide synthetase containing adenylation and peptidyl carrier protein domains

Many bacteria use large modular enzymes for the synthesis of polyketide and peptide natural products. These multidomain enzymes contain integrated carrier domains that deliver bound substrates to multiple catalytic domains, requiring coordination of these chemical steps. Nonribosomal peptide synthetases (NRPSs) load amino acids onto carrier domains through the activity of an upstream adenylation domain. Our lab recently determined the structure of an engineered two-domain NRPS containing fused adenylation and carrier domains. This structure adopted a domain-swapped dimer that illustrated the interface between these two domains. To continue our investigation, we now examine PA1221, a natural two-domain protein from Pseudomonas aeruginosa. We have determined the amino acid specificity of this new enzyme and used domain specific mutations to demonstrate that loading the downstream carrier domain within a single protein molecule occurs more quickly than loading of a nonfused carrier domain intermolecularly. Finally, we have determined crystal structures of both apo- and holo-PA1221 proteins, the latter using a valine-adenosine vinylsulfonamide inhibitor that traps the adenylation domain-carrier domain interaction. The protein adopts an interface similar to that seen with the prior adenylation domain-carrier protein construct. A comparison of these structures with previous structures of multidomain NRPSs suggests that a large conformational change within the NRPS adenylation domains guides the carrier domain into the active site for thioester formation.     

Substrate selection of adenylation domains for nonribosomal peptide synthetase (NRPS) in bacillamide C biosynthesis by marine <Emphasis Type="Italic">Bacillus atrophaeus</Emphasis> C89

Nonribosomal peptide synthetases (NRPSs) are multi-modular enzymes involved in the biosynthesis of natural products. Bacillamide C was synthesized by Bacillus atrophaeus C89. A nonribosomal peptide synthetase (NRPS) cluster found in the genome of B. atrophaeus C89 was hypothesized to be responsible for the biosynthesis of bacillamide C using alanine and cysteine as substrates. Here, the structure analysis of adenylation domains based on homologous proteins with known crystal structures indicated locations of the substrate-binding pockets. Molecular docking suggested alanine and cysteine as the potential substrates for the two adenylation domains in the NRPS cluster. Furthermore, biochemical characterization of the purified recombinant adenylation domains proved that alanine and cysteine were the optimum substrates for the two adenylation domains. The results provided the in vitro evidence for the hypothesis that the two adenylation domains in the NRPS of B. atrophaeus C89 preferentially select alanine and cysteine, respectively, as a substrate to synthesize bacillamide C. Furthermore, this study on substrates selectivity of adenylation domains provided basis for rational design of bacillamide analogs.     

Epsilon-poly-L-lysine dispersity is controlled by a highly unusual nonribosomal peptide synthetase

Epsilon-Poly-L-lysine (epsilon-PL) consists of 25-35 L-lysine residues in isopeptide linkages and is one of only two amino acid homopolymers known in nature. Elucidating the biosynthetic mechanism of epsilon-PL should open new avenues for creating novel classes of biopolymers. Here we report the purification of an epsilon-PL synthetase (Pls; 130 kDa) and the cloning of its gene from an epsilon-PL-producing strain of Streptomyces albulus. Pls was found to be a membrane protein with adenylation and thiolation domains characteristic of the nonribosomal peptide synthetases (NRPSs). It had no traditional condensation or thioesterase domain; instead, it had six transmembrane domains surrounding three tandem soluble domains. These tandem domains iteratively catalyzed L-lysine polymerization using free L-lysine polymer (or monomer in the initial reaction) as acceptor and Pls-bound L-lysine as donor, directly yielding chains of diverse length. Thus, Pls is a new single-module NRPS having an amino acid ligase-like catalytic activity for peptide bond formation.     

A beta-lysine adenylating enzyme and a beta-lysine binding protein involved in poly beta-lysine chain assembly in nourseothricin synthesis in Streptomyces noursei.

Nourseothricins (syn. Streptothricins), a group of nucleoside peptides produced by several streptomycete strains, contain a poly beta-lysine chain of variable length attached in amide linkage to the amino sugar moiety gulosamine of the nucleoside portion. We show that the nourseothricin-producing Streptomyces noursei contains an enzyme (NpsA) of an apparent M(r) 56,000 that specifically activates beta-lysine by adenylation but does not bind to it as a thioester. Cloning and sequencing of npsA from S. noursei including its flanking DNA regions revealed that it is closely linked to the nourseothricin resistance gene nat1 and some other genes on the chromosome possibly involved in nourseothricin biosynthesis. The deduced amino-acid sequence revealed that NpsA is a stand-alone adenylation domain with similarity to the adenylation domains of nonribosomal peptide synthetases (NRPS). Further analysis revealed that S. noursei contains a beta-lysine binding enzyme (NpsB) of about M(r) 64,100 which can be loaded by NpsA with beta-lysine as a thioester. Analysis of the deduced amino-acid sequence from the gene (npsB) of NpsB showed that it consists of two domains. The N-terminal domain of approximately 100 amino-acid residues has high similarity to PCP domains of NRPSs whereas the 450-amino-acid C-terminal domain has a high similarity to epimerization (E)-domains of NRPSs. Remarkably, in this E-domain the conserved H-H-motif is changed to H-Q, which suggests that either the domain is nonfunctional or has a specialized function. The presence of one single adenylating beta-lysine activating enzyme in nourseothricin-producing streptomycete and a separate binding protein suggests an iteratively operating NRPS-module catalyses synthesis of the poly beta-lysine chain.     

Structure of a Eukaryotic Nonribosomal Peptide Synthetase Adenylation Domain That Activates a Large Hydroxamate Amino Acid in Siderophore Biosynthesis

Nonribosomal peptide synthetases (NRPSs) are large, multidomain proteins that are involved in the biosynthesis of an array of secondary metabolites. We report the structure of the third adenylation domain from the siderophore-synthesizing NRPS, SidN, from the endophytic fungus Neotyphodium lolii. This is the first structure of a eukaryotic NRPS domain, and it reveals a large binding pocket required to accommodate the unusual amino acid substrate, N^δ-cis-anhydromevalonyl-N^δ-hydroxy-l-ornithine (cis-AMHO). The specific activation of cis-AMHO was confirmed biochemically, and an AMHO moiety was unambiguously identified as a component of the fungal siderophore using mass spectroscopy. The protein structure shows that the substrate binding pocket is defined by 17 amino acid residues, in contrast to both prokaryotic adenylation domains and to previous predictions based on modeling. Existing substrate prediction methods for NRPS adenylation domains fail for domains from eukaryotes due to the divergence of their signature sequences from those of prokaryotes. Thus, this new structure will provide a basis for improving prediction methods for eukaryotic NRPS enzymes that play important and diverse roles in the biology of fungi.     

非核糖体肽合成酶基因腺苷酰化结构域序列克隆及分析

微生物许多非核糖体肽类次生代谢产物主要是由非核糖体肽合成酶(NRPS)催化合成。参考Gontang发布的非核糖体肽合成酶(NRPS)通用引物设计扩增NRPS腺苷酰化结构域基因序列的特异引物,从海洋链霉菌L1的基因组DNA中扩增获得一个715 bp的NRPS基因序列。测序结果及比对分析表明该片段属于NRPS腺苷酰化结构域部分序列。对其拟翻译的氨基酸序列组成成分、理化性质进行分析,显示其包含AFD class I超基因家族核心结合区,为NRPS腺苷酰化结构域(A结构域)所在区域。对氨基酸序列的二级结构预测和三级结构模拟,发现与数据库中肠菌素合酶F组分的结构相似。为后续研究A结构域的特异性及完整NRPS基因簇克隆提供了参考。     

Exploitation of the selectivity-conferring code of nonribosomal peptide synthetases for the rational design of novel peptide antibiotics

Recently, the solved crystal structure of a phenylalanine-activating adenylation (A) domain enlightened the structural basis for the specific recognition of the cognate substrate amino acid in nonribosomal peptide synthetases (NRPSs). By adding sequence comparisons and homology modeling, we successfully used this information to decipher the selectivity-conferring code of NRPSs. Each codon combines the 10 amino residues of a NRPS A domain that are presumed to build up the substrate-binding pocket. In this study, the deciphered code was exploited for the first time to rationally alter the substrate specificity of whole NRPS modules in vitro and in vivo. First, the single-residue Lys239 of the L-Glu-activating initiation module C-A(Glu)-PCP of the surfactin synthetase A was mutated to Gln239 to achieve a perfect match to the postulated L-Gln-activating binding pocket. Biochemical characterization of the mutant protein C-A(Glu)-PCP(Lys239 --> Gln) revealed the postulated alteration in substrate specificity from L-Glu to L-Gln without decrease in catalytic efficiency. Second, according to the selectivity-conferring code, the binding pockets of L-Asp and L-Asn-activating A domains differs in three positions: Val299 versus Ile, His322 versus Glu, and Ile330 versus Val, respectively. Thus, the binding pocket of the recombinant A domain AspA, derived from the second module of the surfactin synthetases B, was stepwisely adapted for the recognition of L-Asn. Biochemical characterization of single, double, and triple mutants revealed that His322 represents a key position, whose mutation was sufficient to give rise to the intended selectivity-switch. Subsequently, the gene fragment encoding the single-mutant AspA(His322 --> Glu) was introduced back into the surfactin biosynthetic gene cluster. The resulting Bacillus subtilis strain was found to produce the expected so far unknown lipoheptapeptide [Asn(5)]surfactin. This indicates that site-directed mutagenesis, guided by the selectivity-conferring code of NRPS A domains, represents a powerful alternative for the genetic manipulation of NRPS biosynthetic templates and the rational design of novel peptide antibiotics.     

Characterization of the locus of genes encoding enzymes producing heptadepsipeptide micropeptin in the unicellular cyanobacterium Microcystis

The gene cluster involved in producing the cyclic heptadepsipeptide micropeptin was cloned from the genome of the unicellular cyanobacterium Microcystis aeruginosa K-139. Sequencing revealed four genes encoding non-ribosomal peptide synthetases (NRPSs) that are highly similar to the gene cluster involved in cyanopeptolins biosynthesis. According to predictions based on the non-ribosomal consensus code, the order of the mcnABCE NPRS modules was well consistent with that of the biosynthetic assembly of cyclic peptides. The biochemical analysis of a McnB(K-139) adenylation domain and the knock-out of mcnC in a micropeptin-producing strain, M. viridis S-70, revealed that the mcn gene clusters were responsible for the production of heptadepsipeptide micropeptins. A detailed comparison of nucleotide sequences also showed that the regions between the mcnC and mcnE genes of M. aeruginosa K-139 retained short stretches of DNA homologous to halogenase genes involved in the synthesis of halogenated cyclic peptides of the cyanopeptolin class including anabaenopeptilides. This suggests that the mcn clusters of M. aeruginosa K-139 have lost the halogenase genes during evolution. Finally, a comparative bioinformatics analysis of the congenial gene cluster for depsipetide biosynthesis suggested the diversification and propagation of the NRPS genes in cyanobacteria.     

Specific enrichment of nonribosomal peptide synthetase module by an affinity probe for adenylation domains

We targeted the development of an affinity probe for adenylation (A) domains that can facilitate enrichment, identification, and quantification of A domain-containing modules in nonribosomal peptide synthetase (NRPS)-polyketide synthase (PKS) hybrids and NRPSs. A 5′-O-sulfamoyladenosine (AMS) non-hydrolyzable analogue of adenosine monophosphate (AMP) has been reported as a scaffold for the design of inhibitors exhibiting tight binding of adenylation enzymes. Here we describe the application of an affinity probe for A domains. Our synthetic probe, a biotinylated l-Phe-AMS (l-Phe-AMS-biotin) specifically targets the A domains in NRPS modules that activates l-Phe to an aminoacyladenylate intermediate in both recombinant NRPS enzyme systems and whole proteomes.     

Biosynthetic Pathway of Cephabacins in Lysobacter lactamgenus: Molecular and Biochemical Characterization of the Upstream Region of the Gene Clusters for Engineering of Novel Antibiotics

The cephabacins, one of the beta-lactam antibiotics, are produced by Lysobacter lactamgenus. The previous studies the cephabacin biosynthesis were limited to a gene cluster that encodes the gene products responsible for the biosynthesis of the cephem nucleus. The long-term goal of this research is to elucidate the metabolic diversity and biosynthetic pathway of cephabacins and to design and/or discover new pharmacologically active compounds by engineering the cephabacin biosynthetic pathway in L. lactamgenus. In this study, we have cloned and sequenced a 24-kb fragment of a DNA locus upstream of the previously reported but incomplete putative ORF9 of L. lactamgenus. This contains three putative ORFs (the complete ORF9, ORF10, and ORF11) transcribed in the same direction and one putative ORF (ORF12) in the opposite direction. The isolated DNA locus extends the previously cloned part of the DNA locus containing the genes responsible for biosynthesis of the cephem nucleus up to 45 kb. The 42-kb fragment of the 45-kb gene cluster is located between a potential TATA box just upstream of the ORF11 and a termination loop just downstream of the previously reported bla gene. The complete ORF9 contains three nonribosomal peptide synthetase (NRPS) modules and one polyketide synthase (PKS) module and the ORF11 contains one NRPS module. The complete ORF9 also contains a putative thioesterase domain at the C-terminal end. We predicted the amino acid specificity of the four NRPSs by generating specificity binding pockets and expressed one of the NRPSs to confirm the amino acid specificity. The adenylation domain of the NRPS1, which is the last module of the NRPSs, showed significant amino acid specificity for L-arginine. These findings are in perfect agreement with the composition that was expected for the structure of cephabacins which contain an acetate residue, an L-arginine, and one to three L-alanines at the C-3' position of the cephem nucleus of cephabacins. The ORF10, encoding a putative ABC transporter which might be involved in conferring resistance against cephabacins, was identified between the complete ORF9 and the ORF11. Therefore, the complete ORF9, ORF10, ORF11 reported here and the other genes previously reported constitute an operon for the biosynthesis of cephabacins in L. lactamgenus. Based on our results, the biosynthetic pathways of acetate and elongated peptide moieties and a mechanism by which cephabacins are assembled by connecting the peptide moiety synthesized by the gene products of the complete ORF9 and the ORF11 to the C-3' position of the cephem nucleus synthesized by the gene products of pcbAB, pcbC, cefE, cefF, and cefD have been elucidated.     

Discovery of a new peptide natural product by Streptomyces coelicolor genome mining

Analyses of microbial genome sequences reveal numerous examples of gene clusters encoding proteins typically involved in complex natural product biosynthesis but not associated with the production of known natural products. In Streptomyces coelicolor M145 there are several gene clusters encoding new nonribosomal peptide synthetase (NRPS) systems not associated with known metabolites. Application of structure-based models for substrate recognition by NRPS adenylation domains predicts the amino acids incorporated into the putative peptide products of these systems, but the accuracy of these predictions is untested. Here we report the isolation and structure determination of the new tris-hydroxamate tetrapeptide iron chelator coelichelin from S. coelicolor using a genome mining approach guided by substrate predictions for the trimodular NRPS CchH, and we show that this enzyme, which lacks a C-terminal thioesterase domain, together with a homolog of enterobactin esterase (CchJ), are required for coelichelin biosynthesis. These results demonstrate that accurate prediction of adenylation domain substrate selectivity is possible and raise intriguing mechanistic questions regarding the assembly of a tetrapeptide by a trimodular NRPS.     

Ebony,a novel nonribosomal peptide synthetase for beta-alanine conjugation with biogenic amines in Drosophila

Using Ebony protein either expressed in Escherichia coli or in Schneider S2 cells, we provide evidence for its substrate specificity and reaction mechanism. Ebony activates beta-alanine to aminoacyladenylate by an adenylation domain and covalently attaches it as a thioester to a thiolation domain in a nonribosomal peptide synthetase (NRPS) related mechanism. In a second reaction, biogenic amines act as external nucleophiles on beta-alanyl-S-pantetheine-Ebony, thereby releasing in a fast reaction the dipeptide (peptidoamine) in a process that is novel in higher eucaryotes. Therefore, we define Ebony as a beta-alanyl-biogenic amine synthetase. Insight into the reaction mechanism stems from mutational analysis of an invariant serine that disclosed Ebony as a multienzyme with functional analogy to the starting modules of NRPSs. In light of a putative biogenic amine-deactivating capacity, Ebony function in the nervous system must be reconsidered. We propose that in the Drosophila eye Ebony is involved in the transmission process by inactivation of histamine through beta-alanyl conjugation.     

Chain initiation in the leinamycin-producing hybrid nonribosomal peptide/polyketide synthetase from Streptomyces atroolivaceus S-140. Discrete, monofunctional adenylation enzyme and peptidyl carrier protein that directly load D-alanine

Nonribosomal peptide natural products are biosynthesized from amino acid precursors by nonribosomal peptide synthetases (NRPSs), which are organized into modules. For a typical NRPS initiation module, an adenylation (A) domain activates an amino acid and installs it onto a peptidyl carrier protein (PCP) domain as a thioester; an elongation module, which has a condensation (C) domain located between every consecutive pair of A and PCP domains, catalyzes the formation of the peptide bond between the upstream aminoacyl/peptidyl-S-PCP and the free amino group of the downstream aminoacyl-S-PCP. D-amino acid constituents in peptide natural products usually arise from the L-enantiomers through the action of integral epimerization (E) domains of an NRPS. The biosynthetic gene cluster for leinamycin, a hybrid nonribosomal peptide/polyketide containing a D-alanine moiety, does not encode a typical NRPS initiation module with the expected A-PCP-E domains; instead, it has only an A protein (LnmQ) and a PCP (LnmP), both of which are encoded by separate genes. Here we show the results of biochemical experiments as follows: (i) we demonstrate that LnmQ directly activates D-alanine as D-alaninyl-AMP and installs it onto LnmP to generate a D-alaninyl-S-PCP intermediate; (ii) we confirm that aminoacylation of LnmP by LnmQ in trans is the result of specific communication between the separate A and PCP proteins; and (iii) we reveal that leinamycin production can be improved by supplementation of exogenous D-alanine in the fermentation broth of Streptomyces atroolivaceous S-140. These findings unveil an unprecedented NRPS initiation module structure that is characterized by a discrete D-alanine-specific A protein and a PCP.     

Carrier protein recognition in siderophore-producing nonribosomal peptide synthetases

Nonribosomal peptide synthetases (NRPSs) use phosphopantetheine (pPant) bearing carrier proteins to chaperone activated aminoacyl and peptidyl intermediates to the various enzymes that effect peptide synthesis. Using components from siderophore NRPSs that synthesize vibriobactin, enterobactin, yersiniabactin, pyochelin, and anguibactin, we examined the nature of the interaction of such cofactor-carrier proteins with acyl-activating adenylation (A) domains. While VibE, EntE, and PchD were all able to utilize "carrier protein-free" pPant derivatives, the pattern of usage indicated diversity in the binding mechanism, and even the best substrates were down at least 3 log units relative to the native cofactor-carrier protein. When tested with four noncognate carrier proteins, EntE and VibE differed both in the range of substrate utilization efficiency and in the distribution of the efficiencies across this range. Correlating sequence alignments to kinetic efficiency allowed for the construction of eight point mutants of VibE's worst substrate, HMWP2 ArCP, to the corresponding residue in its native VibB. Mutants S49D and H66E combined to increase activity 6.2-fold and had similar enhancing effects on the downstream condensation domain VibH, indicating that the two NRPS enzymes share carrier protein recognition determinants. Similar mutations of HMWP2 ArCP toward EntB had little effect on EntE, suggesting that the position of recognition determinants varies across NRPS systems.     

Pyridinyl polythiazole class peptide antibiotic micrococcin P1, secreted by foodborne Staphylococcus equorum WS2733, is biosynthesized nonribosomally.

Recently, foodborne Staphylococcus equorum WS2733 was isolated from a French red smear cheese on account of its strong inhibitory activity against Gram-positive pathogens such as Listeria. The antagonistic substance was identified as macrocyclic peptide antibiotic micrococcin P1, which had previously not been reported for the genus Staphylococcus. Micrococcin P1, also a potent inhibitor of the malaria parasite Plasmodium falciparum, is structurally related to thiostrepton, thiocillins and nosiheptide. Although all of these peptide antibiotics have been known for quite a long time, their mode of biosynthesis had not been determined in detail yet. By using degenerated PCR, a gene fragment encoding a nonribosomal peptide synthetase (NRPS) could be amplified from S. equorum. The corresponding chromosomal locus was disrupted by insertional mutagenesis, and it could be shown that all mutants obtained displayed a micrococcin P1-deficient phenotype. Sequence analysis of a coherent 2.8-kb fragment revealed extensive homology to known NRPSs, and allowed the assignment of the domain organization 'condensation-adenylation-thiolation-condensation'; an arrangement predicted only for two loci within the presumably 14-modular, 1.6-MDa biosynthetic NRPS template. Biochemical characterization of the adenylation domain exhibited selectivity for the substrate amino-acid threonine. All of these data substantiate that the macrocyclic peptide antibiotic is biosynthesized nonribosomally, and provide the basis for the characterization of the entire biosynthetic gene cluster. The biosynthetic machinery of micrococcin will serve as a model system for structurally related, pharmacologically important pyridinyl polythiazole class peptide antibiotics. Furthermore, this knowledge will enable the manipulation of its NRPS template, which in turn may grant the targeted engineering of even more potent anti-listerial and anti-malaria drugs.