Tyrocidine synthetase system

Expanding the Chemical Diversity of Genetically Encoded Libraries

The power of ribosomes has increasingly been harnessed for the synthesis and selection of molecular libraries. Technologies, such as phage display, yeast display, and mRNA display, effectively couple genotype to phenotype for the molecular evolution of high affinity epitopes for many therapeutic targets. Genetic code expansion is central to the success of these technologies, allowing researchers to surpass the intrinsic capabilities of the ribosome and access new, genetically encoded materials for these selections. Here, we review techniques for the chemical expansion of genetically encoded libraries, their abilities and limits, and opportunities for further development. Importantly, we also discuss methods and metrics used to assess the efficiency of modification and library diversity with these new techniques.

The indigoidine synthetase BpsA provides a colorimetric ATP assay that can be adapted to quantify the substrate preferences of other NRPS enzymes

OBJECTIVES

To develop a colorimetric assay for ATP based on the blue-pigment synthesising non-ribosomal peptide synthetase (NRPS) BpsA, and to demonstrate its utility in defining the substrate specificity of other NRPS enzymes.

RESULTS

BpsA is able to convert two molecules of L-glutamine into the readily-detected blue pigment indigoidine, consuming two molecules of ATP in the process. We showed that the stoichiometry of this reaction is robust and that it can be performed in a microplate format to accurately quantify ATP concentrations to low micromolar levels in a variety of media, using a spectrophotometric plate-reader. We also demonstrated that the assay can be adapted to evaluate the amino acid substrate preferences of NRPS adenylation domains, by adding pyrophosphatase enzyme to drive consumption of ATP in the presence of the preferred substrate.

CONCLUSIONS

The robust nature and simplicity of the reaction protocol offers advantages over existing methods for ATP quantification and NRPS substrate analysis.

Specificity of Nonribosomal Peptide Synthetases in the Biosynthesis of the Pseudomonas virulence factor

The Pseudomonas virulence factor (pvf) biosynthetic operon has been implicated in bacterial virulence and signaling. We identified 308 bacterial strains containing pvf homologues that likely produce signaling molecules with distinct structures and biological activities. Several homologues of the nonribosomal peptide synthetase (NRPS), PvfC, were biochemically characterized and shown to activate l-Val or l-Leu. The amino acid selectivity of PvfC and its homologues likely direct pvf signaling activity. We explored the natural diversity of the active site residues present in 92% of the adenylation domains of PvfC homologues and identified key residues for substrate selection and catalysis. Sequence similarity network (SSN) analysis revealed grouping of PvfC homologues that harbor the same active site residues and activate the same amino acids. Our work identified PvfC as a gatekeeper for the structure and bioactivity of the pvf-produced signaling molecules. The combination of active site residue identification and SSN analysis can improve the prediction of aliphatic amino acid substrates for NRPS adenylation domains.

Dipeptide synthesis by internal adenylation domains of a multidomain enzyme involved in nonribosomal peptide synthesis

The adenylation domain of nonribosomal peptide synthetase (NRPS) is responsible for its selective substrate recognition and activation of the substrate (yielding an acyl-O-AMP intermediate) on ATP consumption. DhbF is an NRPS involved in bacillibactin synthesis and consists of multiple domains [adenylation domain, condensation domain, peptidyl carrier protein (PCP) domain, and thioesterase domain]; DhbFA1 and DhbFA2 (here named) are "internal" adenylation domains in the multidomain enzyme DhbF. We firstly succeeded in expressing and purifying the "internal" adenylation domains DhbFA1 and DhbFA2 separately. Furthermore, we initially demonstrated dipeptide synthesis by "internal" adenylation domains. When glycine and L-cysteine were used as substrates of DhbFA1, the formation of N-glycyl-L-cysteine (Gly-Cys) was observed. Furthermore, when L-threonine and L-cysteine were used as substrates of DhbFA2, N-L-threonyl-L-cysteine (Thr-Cys) was formed. These findings showed that both adenylation domains produced dipeptides by forming a carbon-nitrogen bond comprising the carboxyl group of an amino acid and the amino group of L-cysteine, although these adenylation domains are acid-thiol ligase using 4'-phosphopantetheine (bound to the PCP domain) as a substrate. Furthermore, DhbFA1 and DhbFA2 synthesized oligopeptides as well as dipeptides.

Identification and Characterization of the Sulfazecin Monobactam Biosynthetic Gene Cluster

The monobactams, exemplified by the natural product sulfazecin, are the only class of β-lactam antibiotics not inactivated by metallo-β-lactamases, which confer bacteria with extended-spectrum β-lactam resistance. We screened a transposon mutagenesis library from Pseudomonas acidophila ATCC 31363 and isolated a sulfazecin-deficient mutant that revealed a gene cluster encoding two non-ribosomal peptide synthetases (NRPSs), a methyltransferase, a sulfotransferase, and a dioxygenase. Three modules and an aberrant C-terminal thioesterase (TE) domain are distributed across the two NRPSs. Biochemical examination of the adenylation (A) domains provided evidence that L-2,3-diaminopropionate, not L-serine as previously thought, is the direct source of the β-lactam ring of sulfazecin. ATP/PPi exchange assay also revealed an unusual substrate selectivity shift of one A domain when expressed with or without the immediately upstream condensation domain. Gene inactivation analysis defined a cluster of 13 open reading frames sufficient for sulfazecin production, precursor synthesis, self-resistance, and regulation. The identification of a key intermediate supported a proposed NRPS-mediated mechanism of sulfazecin biosynthesis and β-lactam ring formation distinct from the nocardicins, another NRPS-derived subclass of monocyclic β-lactam. These findings will serve as the basis for further biosynthetic research and potential engineering of these important antibiotics.

Online Pyrophosphate Assay for Analyzing Adenylation Domains of Nonribosomal Peptide Synthetases

Nonribosomal peptide synthetases (NRPSs) produce many important and structurally complex natural products. Because of their architectures, reprogramming NRPSs has long been attempted to access new bioactive compounds. However, detailed characterization of NRPS catalysis and substrate selectivity by adenylation (A) domains is needed to support such efforts. We present a simple coupled NADH/pyrophosphate (PPi  ) detection assay for analyzing A domain catalysis in vitro. PPi formation is coupled to the consumption of NADH by four enzymatic steps and is detected spectroscopically (λ=340 nm) for simple analysis. We demonstrate the effectiveness of this assay with several adenylation domains, including a stand-alone A domain (DltA, cell wall biosynthesis) and an embedded A domain (Tcp10, teicoplanin biosynthesis). Substrate acceptance of the Tcp10 A domain was explored for the first time, thus demonstrating the applicability of the assay for complex, multi-domain NRPSs.

Peptide Bond Synthesis by a Mechanism Involving an Enzymatic Reaction and a Subsequent Chemical Reaction

We recently reported that an amide bond is unexpectedly formed by an acyl-CoA synthetase (which catalyzes the formation of a carbon-sulfur bond) when a suitable acid and l-cysteine are used as substrates. DltA, which is homologous to the adenylation domain of nonribosomal peptide synthetase, belongs to the same superfamily of adenylate-forming enzymes, which includes many kinds of enzymes, including the acyl-CoA synthetases. Here, we demonstrate that DltA synthesizes not only N-(d-alanyl)-l-cysteine (a dipeptide) but also various oligopeptides. We propose that this enzyme catalyzes peptide synthesis by the following unprecedented mechanism: (i) the formation of S-acyl-l-cysteine as an intermediate via its "enzymatic activity" and (ii) subsequent "chemical" S → N acyl transfer in the intermediate, resulting in peptide formation. Step ii is identical to the corresponding reaction in native chemical ligation, a method of chemical peptide synthesis, whereas step i is not. To the best of our knowledge, our discovery of this peptide synthesis mechanism involving an enzymatic reaction and a subsequent chemical reaction is the first such one to be reported. This new process yields peptides without the use of a thioesterified fragment, which is required in native chemical ligation. Together with these findings, the same mechanism-dependent formation of N-acyl compounds by other members of the above-mentioned superfamily demonstrated that all members most likely form peptide/amide compounds by using this novel mechanism. Each member enzyme acts on a specific substrate; thus, not only the corresponding peptides but also new types of amide compounds can be formed.

Profiling Nonribosomal Peptide Synthetase Activities Using Chemical Proteomic Probes for Adenylation Domains

Nonribosomal peptide synthetases (NRPSs) and polyketide synthases are large diverse families of biosynthetic enzymes that catalyze the synthesis of natural products that display biologically important activities. Genetic investigations have greatly contributed to our understanding of these biosynthetic enzymes; however, proteomic studies are limited. Here we describe the application of active site-directed proteomic probes for adenylation (A) domains to profile the activity of NRPSs directly in native proteomic environments. Derivatization of a 5'-O-N-(aminoacyl)sulfamoyladenosine appended clickable benzophenone functionality enabled activity-based protein profiling of the A-domains in NRPSs in proteomic extracts. These probes were used to identify natural product producing microorganisms, optimize culture conditions, and profile the activity dynamics of NRPSs. Our proteomic approach offers a simple and versatile method to monitor NRPS expression at the protein level and will facilitate the identification of orphan enzymatic pathways involved in secondary metabolite production.

Hydroxamate-based colorimetric assay to assess amide bond formation by adenylation domain of nonribosomal peptide synthetases

We demonstrated the usefulness of a hydroxamate-based colorimetric assay for predicting amide bond formation (through an aminoacyl-AMP intermediate) by the adenylation domain of nonribosomal peptide synthetases. By using a typical adenylation domain of tyrocidine synthetase (involved in tyrocidine biosynthesis), we confirmed the correlation between the absorbance at 490 nm of the l-Trp-hydroxamate-Fe(3+) complex and the formation of l-Trp-l-Pro, where l-Pro was used instead of hydroxylamine. Furthermore, this assay was adapted to the adenylation domains of surfactin synthetase (involved in surfactin biosynthesis) and bacitracin synthetase (involved in bacitracin biosynthesis). Consequently, the formation of various aminoacyl l-Pro formations was observed.

Drosophila Ebony: a novel type of nonribosomal peptide synthetase related enzyme with unusually fast peptide bond formation kinetics

Drosophila Ebony is a β-alanyl biogenic amine synthetase with proven function in cuticle and in glia of the nervous system. It is closely related to nonribosomal peptide synthetases (NRPSs), which typically consist of at least an adenylation, a peptidyl carrier protein and a peptide bond forming condensation domain. Besides its role in cuticle formation, Ebony is in most glia of the brain thought to convert biogenic amines to β-alanyl conjugates. If the metabolization of the neurotransmitter histamine to β-alanyl histamine requires a fast reaction in visual signal transduction, Ebony must be able to fulfill this requirement. Since NRPSs are in general slowly acting multi-modular protein machineries, the enigma of how Ebony quickly facilitates this inactivation remains a key question for understanding its role in vision. To quantitatively analyze the reaction kinetics, we used phosphopantetheinylated holo-Ebony prepared from Baculovirus infected Sf9 cells. Kinetic parameters for the loading reaction, e.g. the formation of β-alanyl-Ebony thioester, complied with those of slow NRPSs. In contrast, single-turnover analysis of the last reaction step, peptide bond formation between pre-activated β-alanyl Ebony thioester and histamine, revealed a very rapid conjugation reaction. This biphasic nature of activity identifies Ebony as a novel type of NRPS related molecule that combines a slow amino acid activation phase with a very fast product formation step.

Characterization and Engineering of the Adenylation Domain of a NRPS-Like Protein: A Potential Biocatalyst for Aldehyde Generation

The adenylation (A) domain acts as the first "gate-keeper" to ensure the activation and thioesterification of the correct monomer to nonribosomal peptide synthetases (NRPSs). Our understanding of the specificity-conferring code and our ability to engineer A domains are critical for increasing the chemical diversity of nonribosomal peptides (NRPs). We recently discovered a novel NRPS-like protein (ATEG_03630) that can activate 5-methyl orsellinic acid (5-MOA) and reduce it to 2,4-dihydroxy-5,6-dimethyl benzaldehyde. A NRPS-like protein is much smaller than multidomain NRPSs, but it still represents the thioesterification half-reaction, which is otherwise missed from a stand-alone A domain. Therefore, a NRPS-like protein may serve as a better model system for A domain engineering. Here, we characterize the substrate specificity of ATEG_03630 and conclude that the hydrogen-bond donor at the 4-position is crucial for substrate recognition. Next, we show that the substrate specificity of ATEG_03630 can be engineered toward our target substrate anthranilate via bioinformatics analysis and mutagenesis. The resultant mutant H358A increased its activity toward anthranilate by 10.9-fold, which led to a 26-fold improvement in specificity. Finally, we demonstrate one-pot chemoenzymatic synthesis of 4-hydroxybenzaldoxime from 4-hydroxybenzoic acid with high yield.

The nonribosomal peptide synthetase enzyme DdaD tethers N(β)-fumaramoyl-l-2,3-diaminopropionate for Fe(II)/α-ketoglutarate-dependent epoxidation by DdaC during dapdiamide antibiotic biosynthesis

The gene cluster from Pantoea agglomerans responsible for biosynthesis of the dapdiamide antibiotics encodes an adenylation-thiolation didomain protein, DdaD, and an Fe(II)/α-ketoglutarate-dependent dioxygenase homologue, DdaC. Here we show that DdaD, a nonribosomal peptide synthetase module, activates and sequesters N(β)-fumaramoyl-l-2,3-diaminopropionate as a covalently tethered thioester for subsequent oxidative modification of the fumaramoyl group. DdaC catalyzes Fe(II)- and α-ketoglutarate-dependent epoxidation of the covalently bound N(β)-fumaramoyl-l-2,3-diaminopropionyl-S-DdaD species to generate N(β)-epoxysuccinamoyl-DAP (DAP = 2,3-diaminopropionate) in thioester linkage to DdaD. After hydrolytic release, N(β)-epoxysuccinamoyl-DAP can be ligated to l-valine by the ATP-dependent ligase DdaF to form the natural antibiotic N(β)-epoxysuccinamoyl-DAP-Val.

Functional dissection of surfactin synthetase initiation module reveals insights into the mechanism of lipoinitiation

Although the N-terminally attached fatty acids are key structural elements of nonribosomally assembled lipopeptide antibiotics, little is known about the mechanism of lipid transfer during the initial step of biosynthesis. In this study, we investigated the activity of the dissected initiation module (C-A(Glu)-PCP) of surfactin synthetase SrfAA in vitro to gain further insights into the lipoinitiation reaction. The dissected condensation (C) domain catalyzes the transfer of CoA-activated 3-hydroxy fatty acid with high substrate specificity at its donor site to the peptidyl carrier protein (PCP) bound amino acid glutamate (Glu(1)). Additionally, biochemical studies on four putative acyl CoA ligases in Bacillus subtilis revealed that two of them activate 3-hydroxy fatty acids for surfactin biosynthesis in vitro and that the disruption of corresponding genes has a significant influence on surfactin production.

Two enzymes involved in biosynthesis of the host-selective phytotoxin HC-toxin

Cochliobolus carbonum race 1 produces a cyclic tetrapeptide HC-toxin, which is necessary for its exceptional virulence on certain varieties of maize. Previous genetic analysis of HC-toxin production by the fungus has indicated that a single genetic locus controls HC-toxin production. Enzymes involved in the biosynthesis of HC-toxin have been sought by following the precedents established for the biosynthetic enzymes of cyclic peptide antibiotics. Two enzymatic activities from C. carbonum race 1 were found, a D-alanine- and an L-proline-dependent ATP/PP(i) exchange, which by biochemical and genetic criteria were shown to be involved in the biosynthesis of HC-toxin. These two activities were present in all tested race 1 isolates of C. carbonum, which produce HC-toxin, and in none of the tested race 2 and race 3 isolates, which do not produce the toxin. In a genetic cross between two isolates of C. carbonum differing at the tox locus, all tox(+) progeny had both activities, and all tox(-) progeny lacked both activities.

Recent advances in thiopeptide antibiotic biosynthesis

Thiopeptides, or thiazolylpeptides, are a family of highly modified peptide antibiotics first discovered several decades ago. Dozens of thiopeptides have since been identified, but, until recently, the biosynthetic genes responsible for their production remained elusive. The biosynthetic systems for a handful of thiopeptide metabolites were identified in the first portion of 2009. The surprising finding that these metabolites arise from the enzymatic tailoring of a simple, linear, ribosomally-synthesized precursor peptide led to a renewed appreciation of the architectural complexity accessible by posttranslational modification. This recent progress toward understanding thiopeptide antibiotic biosynthesis benefits the discovery of novel thiopeptides by either directed screening techniques or by mining available microbial genome sequences. Furthermore, access to the biosynthetic machinery now opens an avenue to the biosynthetic engineering of thiopeptide analogs. This Highlight discusses the genetic and biochemical insights revealed by these initial reports of the biosynthetic gene clusters for thiopeptide metabolites.

Adenylation enzyme characterization using gamma -(18)O(4)-ATP pyrophosphate exchange

We present here a rapid, highly sensitive nonradioactive assay for adenylation enzyme selectivity determination and characterization. This method measures the isotopic back exchange of unlabeled pyrophosphate into gamma-(18)O(4)-labeled ATP via matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MS), electrospray ionization liquid chromatography MS, or electrospray ionization liquid chromatography-tandem MS and is demonstrated for both nonribosomal (TycA, ValA) and ribosomal synthetases (TrpRS, LysRS) of known specificity. This low-volume (6 microl) method detects as little as 0.01% (600 fmol) exchange, comparable in sensitivity to previously reported radioactive assays and readily adaptable to kinetics measurements and high throughput analysis of a wide spectrum of synthetases. Finally, a previously uncharacterized A-T didomain from anthramycin biosynthesis in the thermophile S. refuinius was demonstrated to selectively activate 4-methyl-3-hydroxyanthranilic acid at 47 degrees C, providing biochemical evidence for a new aromatic beta-amino acid activating adenylation domain and the first functional analysis of the anthramycin biosynthetic gene cluster.

Mapping the limits of substrate specificity of the adenylation domain of TycA

The catalytic potential of tyrocidine synthetase 1 (TycA) was probed by the kinetic characterization of its adenylation activity. We observed reactions with 30 substrates, thus suggesting some substrate promiscuity. However, although the TycA adenylation (A) domain was able to accommodate alternative substrates, their k(cat)/K(M) values ranged over six orders of magnitude. A comparison of the activities allowed the systematic mapping of the substrate specificity determinants of the TycA A-domain. Hydrophobicity plays a major role in the recognition of substrate analogues but can be combined with shape complementarity, conferring higher activity, and/or steric exclusion, leading to substantial discrimination against larger substrates. A comparison of the k(cat)/K(M) values of the TycA A-domain and phenylalanyl-tRNA synthetase showed that the level of discrimination was comparable in the two enzymes for the adenylation reaction and suggested that TycA was also subjected to high selective pressure. The specificity patterns observed and the quantification of alternative activities provide a basis for exploring possible paths for the future directed evolution of A-domain specificity.

An optimized ATP/PP(i)-exchange assay in 96-well format for screening of adenylation domains for applications in combinatorial biosynthesis

We report a new format for measuring ATP/[(32)P]pyrophosphate exchange in a higher throughput assay of adenylation domains (A-domains) of non-ribosomal peptide synthetases. These enzymes are key specificity determinants in the assembly line biosynthesis of non-ribosomal peptides, an important class of natural products with an activity spectrum ranging from antibiotic to antitumor activities. Our assay in 96-well format allows the rapid measurement of approximately 1000 data points per week as a basis for precise assessment of the kinetics of A-domains. The assay also allows quantitative high-throughput screening of the substrate specificity of A-domains identifying alternative, promiscuous substrates. We show that our assay is able to give high quality data for the T278A mutant of the A-domain of the tyrocidine synthetase module TycA with a 330-fold lower k(cat)/K(M). The large dynamic range of this assay will be useful for the screening of libraries of mutant A-domains. Finally we describe and evaluate a procedure for the high-throughput purification of A-domains in 96-well format for the latter purpose. Our approach will be of utility for mechanistic analysis, substrate profiling and directed evolution of the A-domains, to ultimately enable the combinatorial biosynthesis of non-natural analogues of non-ribosomal peptides that may have potential as alternative drug candidates.

Functional analysis of fengycin synthetase FenD

Fengycin is a cyclic lipopeptidic antibiotic produced nonribosomally by Bacillus subtilis. A fengycin synthetase mutant of B. subtilis F29-3 was generated with Tn917lux, which contains a transposon inserted in a 7716-bp gene, fenD. The mutation can be genetically complemented by transforming a plasmid carrying a wild-type fenD, confirming the participation of the gene in fengycin synthesis. Sequencing and biochemical analysis reveal that this gene encodes an enzyme that includes two amino acid-activating modules, FenD1 and FenD2, which activate l-Tyr and l-Thr, the third and the fourth amino acids in fengycin, respectively.

Presence of D-alanine in an endopeptidase from Streptococcus pyogenes

D-amino acids are commonly found in peptide antibiotics and the cell wall peptidoglycan of bacterial cell walls but have not been identified in proteins or enzymes. Here we report the presence of 6-7 A-alanine residues in an endopeptidase of Streptococcus pyogenes, a unique enzyme involved in surface protein attachment that we term LPXTGase. Using D-amino acid oxidase coupled with catalase for the deamination of D-alanine to pyruvic acid (a conversion unique to D-alanine), we were able to identify [14C]pyruvic acid in a [14C]alanine-labeled preparation of purified LPXTGase, which represents 27% of the amino acid composition. Because D-amino acids are not accommodated in ribosomal peptide synthesis, these results suggest that the same process used in assembling peptide antibiotics or a yet unidentified mechanism may synthesize the core protein of this endopeptidase.

Substrate specificity of the nonribosomal peptide synthetase PvdD from Pseudomonas aeruginosa

Pseudomonas aeruginosa PAO1 secretes a siderophore, pyoverdine(PAO), which contains a short peptide attached to a dihydroxyquinoline moiety. Synthesis of this peptide is thought to be catalyzed by nonribosomal peptide synthetases, one of which is encoded by the pvdD gene. The first module of pvdD was overexpressed in Escherichia coli, and the protein product was purified. L-Threonine, one of the amino acid residues in pyoverdine(PAO), was an effective substrate for the recombinant protein in ATP-PP(i) exchange assays, showing that PvdD has peptide synthetase activity. Other amino acids, including D-threonine, L-serine, and L-allo-threonine, were not effective substrates, indicating that PvdD has a high degree of substrate specificity. A three-dimensional modeling approach enabled us to identify amino acids that are likely to be critical in determining the substrate specificity of PvdD and to explore the likely basis of the high substrate selectivity. The approach described here may be useful for analysis of other peptide synthetases.

Characterization of a unique glycosylated anchor endopeptidase that cleaves the LPXTG sequence motif of cell surface proteins of Gram-positive bacteria

The precursors of most surface proteins on Gram-positive bacteria have a C-terminal hydrophobic domain and charged tail, preceded by a conserved LPXTG motif that signals the anchoring process. This motif is the substrate for an enzyme, termed sortase, which has transpeptidation activity resulting in the cleavage of the LPXTG sequence and ultimate attachment of the protein to the peptidoglycan. While screening a group A streptococcal membrane extract for cleavage activity of the LPXTG motif, we identified an enzyme (which we term "LPXTGase") that differs significantly from sortase but also cleaves this motif. The enzyme is heavily glycosylated, which is required for its activity. Amino acid composition and sequence analysis revealed that LPXTGase differs from other enzymes, in that the molecule, which is about 14 kDa in size, has no aromatic amino acids, is rich in alanine, and is 30% composed of uncommon amino acids, suggesting a nonribosomal construction. A similar enzyme found in the membrane extract of Staphylococcus aureus, indicates that this unusual molecule may be common among Gram-positive bacteria. Whereas peptide antibiotics have been reported from bacillus species that also contain unusual amino acids and are synthesized non-ribosomally on amino acid-activating polyenzyme templates, this would be the first reported enzyme that may be similarly synthesized.

Nonribosomal peptide synthetases-evidence for a second ATP-binding site

delta-(L-alpha-Aminoadipyl)-L-cysteinyl-D-valine synthetase (ACVS) catalyses, via the protein thiotemplate mechanism, the nonribosomal biosynthesis of the penicillin and cephalosporin precursor tripeptide delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine (ACV). The complete and fully saturated biosynthetic system approaches maximum rate of product generation with increasing ATP concentration. Nonproductive adenylation of ACVS, monitored utilising the ATP-[32P]PP(i) exchange reaction, has revealed substrate inhibition with ATP. The kinetic inhibition pattern provides evidence for the existence of a second nucleotide-binding site with possible implication in the regulatory mechanism. Under suboptimal reaction conditions, in the presence of MgATP(2-), L-Cys and inorganic pyrophosphatase, ACVS forms adenosine(5')tetraphospho(5')adenosine (Ap(4)A) from the reverse reaction of adenylate formation involving a second ATP molecule. The potential location of the second ATP binding site was deduced from sequence comparisons and molecular visualisation in conjunction to data obtained from biochemical analysis.

Amino acids activated by fengycin synthetase FenE

Fengycin is a lipopeptidic antibiotic produced nonribosomally by Bacillus subtilis F29-3. Synthesis of this antibiotic requires five fengycin synthetases encoded by fenC, fenD, fenE, fenA, and fenB. In this study, we analyze the functions of the enzyme encoded by fenE, which contains two amino acid activation modules, FenE1 and FenE2. ATP-PP(i) exchange assay revealed that FenE1 activates l-Glu and FenE2 activates l-Ala, l-Val, and l-2-aminobutyric acid, indicating that FenE activates the fifth and the sixth amino acids in fengycin. Furthermore, l-Val is a better substrate than l-Ala for FenE2 in vitro, explaining why B. subtilis F29-3 normally produces twice as much of fengycin B than fengycin A, which contains d-Val and d-Ala at the sixth amino acid position, respectively. Results presented herein suggest that fengycin synthetase genes and amino acids in fengycin are colinear.

Biosynthesis of PF1022A and related cyclooctadepsipeptides

PF1022A belongs to a recently identified class of N-methylated cyclooctadepsipeptides (CODPs) with strong anthelmintic properties. Described here is the cell-free synthesis of this CODP and related structures, as well as the purification and enzymatic characterization of the responsible synthetase. For PF1022A synthesis extracts of Mycelia sterilia were incubated with the precursors L-leucine, D-lactate, D-phenyllactate, and S-adenosyl-L-methionine in the presence of ATP and MgCl(2). A 350-kDa depsipeptide synthetase, PFSYN, responsible for PF1022A synthesis was purified to electrophoretic homogeneity. Like other peptide synthetases, PFSYN follows a thiotemplate mechanism in which the substrates are activated as thioesters via adenylation. N-Methylation of the substrate L-leucine takes place after covalent binding prior to peptide bond formation. The enzyme is capable of synthesizing all known natural cyclooctadepsipeptides of the PF1022 type (A, B, C, and D) differing in the content of D-lactate and D-phenyllactate. In addition to PF1022 types A, B, C, and D, the in vitro incubations produced PF1022F (a CODP consisting of D-lactate and N-methyl-L-leucine), as well as di-, tetra-, and hexa-PF1022 homologs. PFSYN strongly resembles the well documented enniatin synthetase in size and mechanism. Our results suggest that PFSYN, like enniatin synthetase, is an enzyme with two peptide synthetase domains and forms CODP by repeated condensation of dipeptidol building blocks. Due to the low specificity of the d-hydroxy acid binding site, D-lactate or D-phenyllactate can be incorporated into the dipeptidols depending on the concentration of these substrates in the reaction mixture.

Thioesterase domain of delta-(l-alpha-Aminoadipyl)-l-cysteinyl-d-valine synthetase: alteration of stereospecificity by site-directed mutagenesis

The carboxy-terminal thioesterase domain of delta-(l-alpha-aminoadipyl)-l-cysteinyl-d-valine synthetase catalyzes the hydrolytic release of the tripeptide product (LLD-ACV). By site-directed mutagenesis an S3599A change was introduced into the highly conserved GXSXG motif, resulting in a more than 95 % decrease of penicillin production. Purification of the modified multienzyme showed surprisingly only a 50 % reduction of the peptide formation rate, with the stereoisomer delta-(l-alpha-aminoadipyl)-l-cysteinyl-l-valine (LLL-ACV) as the dominating product. Thioesterases of ACV synthetases differ from other thioesterases integrated in non-ribosomal peptide synthetases in their direct association with an epimerase domain, and their respective GXSXG-seryl residue is apparently not essential in acyl transfer leading to peptide release. Instead, this motif may be involved in the control of tripeptide epimerization by selection of the isomer to be released, and the construct supports the presence of LLL-ACV as an intermediate in penicillin biosynthesis.

Functional and transcriptional analyses of a fengycin synthetase gene, fenC, from Bacillus subtilis

A 37-kb DNA fragment containing five fengycin synthetase genes, including fenC, fenD, fenE, fenA, and fenB, was cloned and sequenced. Among these genes, fenC encodes a fengycin synthetase 2,560 amino acids long with an estimated molecular mass of 287 kDa. This protein contains two amino acid activation modules, FenC1 and FenC2, which activate L-glutamic acid and L-ornithine, respectively. Primer extension, using mRNA isolated from the log-phase cells, identified a transcription start site located 86 nucleotides upstream from the initiation codon of fenC, implying that a promoter is located upstream from the start site. Primer extension using total RNA isolated from stationary-phase cells also identified a transcription start site located 61 nucleotides upstream from the initiation codon of fenC. Gene fusion studies demonstrated that in nHA medium, the cells transcribe the fengycin synthetase genes at two different stages of cell growth. The promoter is active during the log phase, and the activity reaches the highest level during the late log phase. The activity decreases sharply but is maintained at a low level for approximately 24 h after cells enter the early stationary phase. The results of this investigation also suggest that the transcription of fenC is positively regulated during the late log phase. Results presented herein provide further insight into fengycin synthesis by B. subtilis F29-3.

Identification and characterization of a type II peptidyl carrier protein from the bleomycin producer Streptomyces verticillus ATCC 15003

BACKGROUND

Nonribosomal peptide synthetases (NRPSs) catalyze the assembly of a structurally diverse group of peptides by the multiple-carrier thiotemplate mechanism. All NRPSs known to date are exclusively type I modular enzymes that consist of domains, such as adenylation (A), peptidyl carrier protein (PCP) and condensation (C) domains, for individual enzyme activities. Although several A and PCP domains have been demonstrated to function independently, aminoacylation in trans has been successful only between PCPs and their cognate A domains.

RESULTS

We have identified within the bleomycin-biosynthesis gene cluster from Streptomyces verticillus ATCC15003 the blmI gene that encodes a discrete PCP protein. We overexpressed the blmI gene in Escherichia coli, purified the BlmI protein, and demonstrated that apo-BlmI can be efficiently modified into holo-BlmI either in vivo or in vitro by PCP-specific 4'-phosphopantetheine transferases (PPTases). Unlike the PCP domains in type I NRPSs, BlmI lacks its cognate A domain and can be aminoacylated by Val-A, an A domain from a completely unrelated type I NRPS.

CONCLUSIONS

BlmI represents the first characterized type II PCP. The BlmI type II PCP, like the PCP domains of type I NRPSs, can be 4'-phospho-pantetheinylated by PCP-specific PPTases but is biochemically distinct in that it can be aminoacylated by an A domain from a completely unrelated type I NRPS. Our results provide for the first time the genetic and biochemical evidence to support the existence of a type II NRPS, which might be useful in the combinatorial manipulation of NRPS proteins to generate novel peptides.

Molecular cloning and characterization of fengycin synthetase gene fenB from Bacillus subtilis

A fengycin synthetase gene, fenB, has been cloned and sequenced. The protein (FenB) encoded by this gene has a predicted molecular mass of 143.6 kDa. This protein was overexpressed in Escherichia coli and was purified to near homogeneity by affinity chromatography. Experimental results indicated that the recombinant FenB has a substrate specificity toward isoleucine with an optimum temperature of 25 degrees C, an optimum pH of 4.5, a Km value of 922 microM, and a turnover number of 236 s(-1). FenB also consists of a thioesterase domain, suggesting that this protein may be involved in the activation of the last amino acid of fengycin.

The tyrocidine biosynthesis operon of Bacillus brevis: complete nucleotide sequence and biochemical characterization of functional internal adenylation domains

The cyclic decapeptide antibiotic tyrocidine is produced by Bacillus brevis ATCC 8185 on an enzyme complex comprising three peptide synthetases, TycA, TycB, and TycC (tyrocidine synthetases 1, 2, and 3), via the nonribosomal pathway. However, previous molecular characterization of the tyrocidine synthetase-encoding operon was restricted to tycA, the gene that encodes the first one-module-bearing peptide synthetase. Here, we report the cloning and sequencing of the entire tyrocidine biosynthesis operon (39.5 kb) containing the tycA, tycB, and tycC genes. As deduced from the sequence data, TycB (404,562 Da) consists of three modules, including an epimerization domain, whereas TycC (723,577 Da) is composed of six modules and harbors a putative thioesterase domain at its C-terminal end. Each module incorporates one amino acid into the peptide product and can be further subdivided into domains responsible for substrate adenylation, thiolation, condensation, and epimerization (optional). We defined, cloned, and expressed in Escherichia coli five internal adenylation domains of TycB and TycC. Soluble His6-tagged proteins, ranging from 536 to 559 amino acids, were affinity purified and found to be active by amino acid-dependent ATP-PPi exchange assay. The detected amino acid specificities of the investigated domains manifested the colinear arrangement of the peptide product with the respective module in the corresponding peptide synthetases and explain the production of the four known naturally occurring tyrocidine variants. The Km values of the investigated adenylation domains for their amino acid substrates were found to be comparable to those published for undissected wild-type enzymes. These findings strongly support the functional integrities of single domains within multifunctional peptide synthetases. Directly downstream of the 3' end of the tycC gene, and probably transcribed in the tyrocidine operon, two tandem ABC transporters, which may be involved in conferring resistance against tyrocidine, and a putative thioesterase were found.

Biosynthesis of acylpeptidolactones of the daptomycin type. A comparative analysis of peptide synthetases forming A21978C and A54145

A21978C and A54145 are antibacterial 13-residue peptides with a medium-chain-acylated amino terminus and a 10-residue lactone ring; they are produced by strains of Streptomyces roseosporus and Streptomyces fradiae, respectively. The structural differences in their peptide chains, which include amino acid replacements and modifications (L-Glu2-->L-Asn, L-Asn(OH)3-->L-Asp, Sar5-->Gly, L-Ala6-->L-Orn, L-Lys8-->D-Ala, L-Asp(OMe)9-->L-Asp, L-Asn11-->D-Ser, and L-lle13-->L-Kyn; Sar = sarcosine; L-Orn = L-ornithine, L-Kyn = L-kynurenine), reside in the multienzymatic templates directing their biosynthesis. We have examined the peptide synthetases employing immunodetection and substrate activation detected by the amino-acid-dependent ATP-PP1-exchange reaction. Two different antibodies specific for actinomycin synthetase 2 and a peptide sequence characteristic of acyl-CoA-synthetases/peptide synthetases were applied. For the A21978 system two peptide synthetases of 670 and 240 kDa were detected, together with two similar proteins of 630 and 440 kDa occurring in varying amounts. The latter are suggested to be degradation products of an unstable multienzyme. Activation of L-Asp, L-Thr, Gly, L-Orn, L-Ala and L-Ser were assigned to the high-molecular-mass components of 670, 630 and 440 kDa. The 240-kDa protein was purified to homogeneity and shown to catalyse activation of L-kynurenine. The A54145 system consisted of three peptide synthetases of 690, 590 and 250 kDa. Activations of L-Asn. L-Thr and Gly were found. The 250-kDa synthetase was capable of activating isoleucine and valine. Both systems thus show a comparable organisation; implications for the modular construction of their peptide synthetases are discussed.

Determination of the chemical pathway for 4-chlorobenzoate:coenzyme A ligase catalysis

4-Chlorobenzoate:coenzyme A ligase (4-CBA:CoA ligase) catalyzes the first step of the 4-CBA degradation pathway of Pseudomonas sp. strain CBS3. In this reaction, 4-CBA-CoA thioester synthesis is coupled to ATP cleavage. The studies described in this paper examine the intermediacy of 4-chlorobenzoyl-adenosine 5'phosphate diester (4-CBA-AMP) in the ligase reaction. The 4-CBA-AMP adduct was isolated from the ligase reaction mixture generated from magnesium adenosine 5-triphosphate (MgATP) and 4-CBA in the absence of CoA. The structure of the 4-CBA-AMP was verified by 1H- 13C-, and 31P-nuclear magnetic resonance analysis. Single-turnover reactions carried out with 14C-labeled 4-CBA in a rapid quench apparatus demonstrated formation of the enzyme. 4-CBA-AMP.MgPPi complex from the enzyme.4-CBA.MgATP complex at a rate of 135 s-1. The rate of ligand release from the enzyme.4-CBA-AMP.MgPPi complex was measured at 0.013 s-1. Single-turnover reactions of [14C]-4-CBA, MgATP, and CoA catalyzed by the ligase revealed that the 4-CBA-AMP intermediate formed reaches a maximum level of 25% of the starting 4-CBA within 10 ms and then declines with the formation of the 4-CBA-CoA. The rates of the adenylation and thioesterification partial reactions, determined by kinetic simulation of the rate data, are nearly equal (135 and 100 s-1). Substitution of CoA with the slow substrate pantetheine did not significantly alter the rate of the adenylation step but did reduce the rate of the thioesterification step to 2 s-1. The maximum level of 4-CBA-AMP reached during the single-turnover reaction of 4-CBA, MgATP, and pantetheine corresponded to one-half of the starting 4-CBA.

The biosynthetic gene cluster for the polyketide immunosuppressant rapamycin

The macrocyclic polyketides rapamycin and FK506 are potent immunosuppressants that prevent T-cell proliferation through specific binding to intracellular protein receptors (immunophilins). The cloning and specific alteration of the biosynthetic genes for these polyketides might allow the biosynthesis of clinically valuable analogues. We report here that three clustered polyketide synthase genes responsible for rapamycin biosynthesis in Streptomyces hygroscopicus together encode 14 homologous sets of enzyme activities (modules), each catalyzing a specific round of chain elongation. An adjacent gene encodes a pipecolate-incorporating enzyme, which completes the macrocycle. The total of 70 constituent active sites makes this the most complex multienzyme system identified so far. The DNA region sequenced (107.3 kbp) contains 24 additional open reading frames, some of which code for proteins governing other key steps in rapamycin biosynthesis.

Arrangement of catalytic sites in the multifunctional enzyme enniatin synthetase

Enniatin synthetase is an N-methyl peptide synthetase comprising 3131 amino acids. Catalytic sites of the 347-kDa multifunctional enzyme were mapped by N-terminal sequencing of substrate affinity-labelled enzyme fragments formed by proteolysis, and functional studies of purified enniatin synthetase fragments. An N-terminal 200-kDa fragment containing the cofactor 4'-phosphopantetheine was able to activate D-hydroxyisovaleric acid (D-HOiVl) as a thioester. The N-termini of two [14C]HOiVl-labelled enzyme fragments could be assigned to amino acid position 429 within the N-terminal conserved enniatin synthetase portion named EA. This portion of about 600 amino acids shares high similarity to microbial peptide synthetase regions. A 68-kDa L-[14C]Val-labelled enniatin synthetase fragment was localized at amino acid position 2294 within the second C-terminal conserved protein portion EB. Additionally enniatin synthetase was labelled with isovaleryl-L-[14C]Val, an analogue of the D-hydroxyisovaleryl-L-Val intermediate in enniatin biosynthesis. The N-terminus of a 30-kDa isovaleryl-L-[14C]Val-labelled enniatin synthetase fragment was mapped in a C-terminal segment of the protein portion EA. The same N-terminal sequence was obtained from a 60-kDa enniatin synthetase fragment modified with [3H]beta Ala, a constituent of the cofactor 4'-phosphopantetheine. This indicates the presence of the cofactor in this protein fragment. Localization of the methyltransferase function of enniatin synthetase in an amino acid portion integrated into region EB was achieved by N-terminal sequencing of a photolabelled S-[methyl-14C]adenosyl methionine 45-kDa fragment and the identification of a photolabelled peptide Asn-Leu-Asn-Pro-Gly-Leu-Asn-Ser-Tyr.

Modular structure of peptide synthetases revealed by dissection of the multifunctional enzyme GrsA

Analysis of the primary structure of peptide synthetases involved in non-ribosomal synthesis of peptide antibiotics revealed a highly conserved and ordered domain structure. These functional units, which are about 1000 amino acids in length, are believed to be essential for amino acid activation and thioester formation. To delineate the minimal extension of such a domain, we have amplified and cloned truncated fragments of the grsA gene, encoding the 1098-amino acid multifunctional gramicidin S synthetase 1, GrsA. The overexpressed His6-tagged GrsA derivatives were affinity-purified, and the catalytic properties of the deletion mutants were examined by biochemical studies including ATP-dependent amino acid activation, carboxyl thioester formation, and the ability to racemize the covalently bound phenylalanine from L- to the D-isomer. These studies revealed a core fragment (PheAT-His) that comprises the first 656 amino acid residues of GrsA, which restored all activities of the native protein, except racemization of phenylalanine. A further deletion of about 100 amino acids at the C-terminal end of the GrsA core fragment (PheAT-His), including the putative thioester binding motif LGGHSL, produced a 556-amino acid fragment (PheA-His) that shows a phenylalanine-dependent aminoacyl adenylation, but almost no thioester formation. A 291-amino acid deletion at the C terminus of the native GrsA, that contains a putative racemization site resulted in complete loss of racemization ability (PheATS-His). However, it retained the functions of specific amino acid activation and thioester formation. The results presented defined biochemically the minimum size of a peptide synthetase domain and revealed the locations of the functional modules involved in substrate recognition and ATP-dependent activation as well as in thioester formation and racemization.

Analysis of core sequences in the D-Phe activating domain of the multifunctional peptide synthetase TycA by site-directed mutagenesis

The D-phenylalanine-activating enzyme tyrocidine synthetase I (TycA) from Bacillus brevis ATCC 8185 was overexpressed in Escherichia coli, purified to homogeneity, and assayed for ATP-PPi exchange and covalent binding of phenylalanine by the thiotemplate mechanism. Amino acid exchanges in four different cores of TycA created by site-directed mutagenesis revealed the amino acid residues involved in aminoacyladenylate formation and in covalent thioester formation. Mutations in the putative ATP-binding site SGTTGKPKG caused a decreased phenylalanine-dependent ATP-PPi exchange activity to 10% of the wild-type level for a Lys-186-to-Arg substitution and an almost complete loss of activity (< 1%) for a Lys-186-to-Thr exchange. Alteration of Asp-401 to Asn in the ATPase motif TGDL of TycA decreased the phenylalanine-dependent ATP-PPi exchange activity to 75% of wild type, while an Asp-401-to-Ser mutation decreased the activity to 10% of the wild-type level. Replacement of Ser-562 in the putative thioester-binding motif LGGDSI to Ala or Gly caused a reduction in trichloroacetic acid-precipitable TycA-[14C]phenylalanine complex to one-third of the wild-type level. However, no cleavable [14C]phenylalanine could be detected after treatment with performic acid, indicating that the resulting mutant was unable to form thioester with phenylalanine. In E. coli, TycA was labeled with beta-[3H]alanine, a precursor of 4'-phosphopantetheine, indicating that TycA is modified with a beta-alanine-containing cofactor.

[Molecular biology and regulatory mechanisms of antibiotic production in Bacillus]

Several species of the genus Bacillus produce linear and cyclic peptide antibiotics nonribosomally through multienzyme complexes by the so-called thiotemplate mechanism. Molecular genetic studies have shown that some peptide antibiotic biosynthesis genes are organized in operons and that they are expressed postexponentially under conditions that also activate the process of endospore formation in Bacillus. Furthermore, DNA-sequence analysis of some multifunctional peptide synthetase genes revealed that they contain a highly conserved and repeated domain structure. The same domain was also found to be conserved within a superfamily of peptide synthetases and adenylate-forming enzymes of diverse origins. Based on sequence homology and functional similarity I conclude that those enzymes bearing domain(s) represent a family of superenzymes which may have a common evolutionary origin.

Nonribosomal biosynthesis of peptide antibiotics

Peptide antibiotics are known to contain non-protein amino acids, D-amino acids, hydroxy acids, and other unusual constituents. In addition they may be modified by N-methylation and cyclization reactions. Their biosynthetic origin has been connected in many cases to an enzymatic system referred to as the 'thiotemplate multienzymic mechanism'. This mechanism includes the activation of the constituent residues as adenylates on the enzymic template, the acylation of specific template thiol groups, epimerization or N-methylation at this thioester stage, and polymerization in the sequence directed by the multienzymic structure with the aid of 4'-phosphopantetheine as a cofactor, including possible cyclization or terminal modification reactions. The reaction sequences leading to gramicidin S, tyrocidine, cyclosporine, bacitracin, polymyxin, actinomycin, enniatin, beauvericin, delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine and linear gramicidin are discussed. The structures of the multienzymes, their genetic organization, the biological functions of these peptides and results on related systems are discussed.

Streptomyces genes involved in biosynthesis of the peptide antibiotic valinomycin

We have identified genes from Streptomyces levoris A-9 involved in the biosynthesis of the peptide antibiotic valinomycin. Two segments of chromosomal DNA were recovered from genomic libraries, constructed by using the low-copy-number plasmid pIJ922, by complementation of valinomycin-deficient (vlm) mutants of S. levoris A-9. One set of plasmids restored valinomycin production to only one mutant, that carrying vlm-1, whereas a second set of plasmids restored productivity to seven vlm mutants, those carrying vlm-2 through vlm-8. Additional complementation studies using subcloned restriction enzyme fragments showed that the vlm-1+ gene was contained within a 2.5-kilobase (kb) DNA region, whereas alleles vlm-2+ through vlm-8+ were contained in a 12-kb region, representing at least three genes. Physical mapping experiments based on the isolation of cosmid clones showed that the two vlm loci were 50 to 70 kb apart. Southern hybridization experiments demonstrated that the vlm-2+ gene cluster was highly conserved among other valinomycin-producing Streptomyces strains, whereas the vlm-1+ gene was ubiquitous among Streptomyces species tested. Increasing the copy number of the vlm-2+ gene cluster in S. levoris A-9 by the introduction of low-copy-number recombinant plasmids resulted in a concomitant increase in the level of valinomycin production.