Catalytic mapping of the vibriobactin biosynthetic enzyme VibF.

The iron-chelating catechol siderophore vibriobactin of the pathogenic Vibrio cholerae is assembled by a four-subunit, ten-domain nonribosomal peptide synthetase system, VibE, VibB, VibH, and VibF, using 2,3-dihydroxybenzoate and L-threonine as precursors to two (dihydroxyphenyl)methyloxazolinyl groups in amide linkage on a norspermidine scaffold. We have utilized site-specific and domain-deletion mutagenesis to map the heterocyclization and primary and secondary amine acylation activities of the six-domain (Cy1-Cy2-A-C1-PCP-C2) VibF subunit. We have found that Cy2 is capable of and limited to the condensation (amide bond formation) step of the three-step heterocyclization process, while Cy1 is capable of and limited to the final processing (cyclization/dehydration) steps to the completed heterocycle. Additionally, we have observed that the C2 domain functions in both N(9) (primary amine) acylation and N(5) (secondary amine) acylation of the (dihydroxybenzoyl)norspermidine substrate, leaving no catalytic role for the C1 domain, a conclusion confirmed with the formation of vibriobactin in a C1-deficient system. Thus VibF is an NRPS with two domains, Cy1 and Cy2, that perform a function otherwise performed by one and with one domain, C2, that performs a function otherwise performed by two. While C2 appeared to tolerate uncyclized threonine in place of the usual heterocycle in primary amine acylation, it refused this replacement in the corresponding donor substrate in secondary amine acylation.     

Reconstitution and characterization of the Vibrio cholerae vibriobactin synthetase from VibB, VibE, VibF, and VibH

Vibriobactin [N(1)-(2,3-dihydroxybenzoyl)-N(5),N(9)-bis[2-(2, 3-dihydroxyphenyl)-5-methyloxazolinyl-4-carboxamido]norspermidine] , is an iron chelator from the cholera-causing bacterium Vibrio cholerae. The six-domain, 270 kDa nonribosomal peptide synthetase (NRPS) VibF, a component of vibriobactin synthetase, has been heterologously expressed in Escherichia coli and purified. VibF has an unusual NRPS domain organization: cyclization-cyclization-adenylation-condensation-peptidyl carrier protein-condensation (Cy(1)-Cy(2)-A-C(1)-PCP-C(2)). VibF activates and covalently loads its PCP with L-threonine, and together with vibriobactin synthetase proteins VibE (adenylation) and VibB (aryl carrier protein) condenses and heterocyclizes 2, 3-dihydroxybenzoyl-VibB with L-Thr to 2-dihydroxyphenyl-5-methyloxazolinyl-4-carboxy-VibF in the first demonstration of oxazoline formation by an NRPS cyclization domain. This enzyme-bound aryl oxazoline can be transferred by VibF to various amine acceptors but most efficiently to N(1)-(2, 3-dihydroxybenzoyl)norspermidine (k(cat) = 122 min(-1), K(m) = 1.7 microM), the product of 2,3-dihydroxybenzoyl-VibB, norspermidine, and VibH. This diacylated product undergoes a second aryl oxazoline acylation on its remaining secondary amine, also catalyzed by VibF, to yield vibriobactin. Vibriobactin biosynthesis in vitro has thus been accomplished from four proteins, VibE, VibB, VibF, and VibH, with the substrates 2,3-dihydroxybenzoic acid, L-Thr, norspermidine, and ATP. Vibriobactin synthetase is an unusual NRPS in that all intermediates are not covalently tethered as PCP thioesters and in that it represents an NRPS pathway with two branch points.     

Dimeric structure of the six-domain VibF subunit of vibriobactin synthetase: mutant domain activity regain and ultracentrifugation studies

Nonribosomal peptide synthetases (NRPS), fatty acid synthases (FAS), and polyketide sythases (PKS) are multimodular enzymatic assembly lines utilized in natural product biosynthesis. Previous data on FAS and PKS subunits have indicated that they are homodimers and that some of their catalytic functions can work in trans. When NRPS assembly lines have been probed for comparable formation of stable oligomers, no evidence had been forthcoming that species other than monomer forms were active. In this work we focus on the six-domain (Cy1-Cy2-A-C1-PCP-C2) enzyme VibF from the vibriobactin synthetase assembly line, which contains three other proteins, VibB, VibE, and VibH, that--when purified and mixed with VibF and the substrates ATP, threonine, 2,3-dihydroxybenzoate (DHB), and norspermidine--produce the iron chelator vibriobactin. Using a deletion of the Cy1 domain and separate inactivating mutations in the Cy2, A, PCP, and C2 domains of VibF, we report regain of catalytic activity upon mutant protein mixing that argues for heterodimer formation, stable for hundreds to thousands of catalytic cycles, with acyl chain processing and transfer around blocked domains. Ultracentrifugation data likewise confirm a dimeric structure for VibF and establish that domains within NRPS dimeric modules can act on acyl chains in trans. The results described here are the first indication for an NRPS subunit that homodimerization can occur and that there is a continuum of functional oligomerization states between monomers and dimers in nonribosomal peptide synthetases.     

Catalytically inactive condensation domain C1 is responsible for the dimerization of the VibF subunit of vibriobactin synthetase

Nonribosomal peptide synthetases (NRPS), fatty acid synthases (FAS), and polyketide synthases (PKS) are multimodular enzymatic assembly lines utilized in natural product biosynthesis. The oligomeric structure of these assembly line enzymes has been a topic of interest because higher order oligomeric quaternary structural arrangements allow for alternate paths of acyl intermediate elongation and present unique challenges for the chimeric engineering of hybrid assembly lines. Unlike other NRPS systems that in general appear to be monomeric, the six domain (Cy1-Cy2-A-C1-PCP-C2) VibF subunit of vibriobactin synthetase has previously been shown to be dimeric, the same oligomeric state as that observed for FAS and PKS assembly lines. It has been demonstrated that the C1 domain within VibF is catalytically inactive and is not required for vibriobactin production. Utilizing sedimentation equilibrium analytical ultracentrifugation experiments to determine the oligomeric states of several VibF subfragments, we report that the C1 domain is largely responsible for VibF dimerization. Comparative rates of vibriobactin production, coupled with dissociation constants for VibF subfragment pair heterocomplexes, suggest that the mere presence of C1 does not detectably enhance the catalytic rates of neighboring domains, but it may properly orient Cy1-Cy2-A relative to PCP-C2.     

Vibriobactin biosynthesis in Vibrio cholerae: VibH is an amide synthase homologous to nonribosomal peptide synthetase condensation domains

The Vibrio cholerae siderophore vibriobactin is biosynthesized from three molecules of 2,3-dihydroxybenzoate (DHB), two molecules of L-threonine, and one of norspermidine. Of the four genes positively implicated in vibriobactin biosynthesis, we have here expressed, purified, and assayed the products of three: vibE, vibB, and vibH. All three are homologous to nonribosomal peptide synthetase (NRPS) domains: VibE is a 2,3-dihydroxybenzoate-adenosyl monophosphate ligase, VibB is a bifunctional isochorismate lyase-aryl carrier protein (ArCP), and VibH is a novel amide synthase that represents a free-standing condensation (C) domain. VibE and VibB are homologous to EntE and EntB from Escherichia coli enterobactin synthetase; VibE activates DHB as the acyl adenylate and then transfers it to the free thiol of the phosphopantetheine arm of VibB's ArCP domain. VibH then condenses this DHB thioester (the donor) with the small molecule norspermidine (the acceptor), forming N(1)-(2, 3-dihydroxybenzoyl)norspermidine (DHB-NSPD) with a k(cat) of 600 min(-1) and a K(m) for acyl-VibB of 0.88 microM and for norspermidine of 1.5 mM. Exclusive monoacylation of a primary amine of norspermidine was observed. VibH also tolerates DHB-acylated EntB and 1,7-diaminoheptane, octylamine, and hexylamine as substrates, albeit at lowered catalytic efficiencies. DHB-NSPD possesses one of three acylations required for mature vibriobactin, and its formation confirms VibH's role in vibriobactin biosynthesis. VibH is a unique NRPS condensation domain that acts upon an upstream carrier-protein-bound donor and a downstream amine, turning over a soluble amide product, in contrast to an archetypal NRPS-embedded C domain that condenses two carrier protein thioesters.     

Yersiniabactin synthetase: probing the recognition of carrier protein domains by the catalytic heterocyclization domains, Cy1 and Cy2, in the chain-initiating HWMP2 subunit

The HMWP2 subunit of yersiniabactin (Ybt) synthetase, a 230 kDa nonribosomal peptide synthetase (NRPS) making the N-terminus of the Ybt siderophore of Yersinia pestis, has one cysteine-specific adenylation (A) domain, three carrier protein domains (ArCP, PCP1, PCP2), and two heterocyclization domains (Cy1, Cy2). The A domain loads the two PCP domains with cysteines that get heterocyclized by the Cy domains to yield a tricyclic hydroxyphenylthiazolinylthiazolinyl (HPTT) chain lodged in thioester linkage to the PCP2 domain. The interdomain recognition by the Cy1 and Cy2 domains for the three carrier proteins was tested using inactivating mutations at the conserved serine that is phosphopantetheinylated in each carrier domain (S52A, S1439A, and S1977A). These mutant forms of HMWP2 were tested for in trans complementation by carrier protein fragments: holo-ArCPs (S52A), holo-PCP1 and analogues (S1439A), and holo-PCP2 and analogues (S1977A). The S52A mutant tests the recognition of the Cy1 domain for donor acyl-ArCP substrates, while the S1439A mutant tests the specificity of the same Cy1 domain for downstream substrates presented by distinct PCPs. The S1439A likewise tests the recognition of Cy2 for its upstream PCP-tethered acyl donor. The S1977A mutant analogously tests the Cy2 domain for downstream Cys-PCP recognition. In all cases in trans complementation was successful with the carrier protein fragments, allowing kinetic probes of catalytic efficiency for PCP scaffolds and for uncoupling of the condensation and heterocyclization functions of Cy1 and Cy2. Overall, the Cy domains tested showed a definite selectivity for the upstream protein scaffold but were more relaxed toward the downstream acceptor protein. This work points to the importance of protein-protein interactions in mediating directional chain growth in NRPS and presents the first systematic exploration of how the protein scaffolds affect catalytic efficiency.     

Expression, purification, and characterization of HMWP2, a 229 kDa, six domain protein subunit of Yersiniabactin synthetase

The six domain, 229 kDa HMWP2 subunit of the Yersinia pestis yersiniabactin (Ybt) synthetase has been expressed in soluble, full-length form in E. coli as a C-terminal His8 construct at low growth temperatures and with attenuated induction. All six domains of this nonribosomal peptide synthetase subunit, three phosphopantetheinylatable carrier protein domains (ArCP, PCP1, PCP2), one adenylation (A) domain, and two cyclization domains (Cy1, Cy2), have been assayed and are functional. Mutants that convert the phosphopantetheinylatable serine residue to alanine in each of the carrier protein domains accumulate acyl-S-enzyme intermediates upstream of the blocked apo carrier protein site. The ArCP mutant cannot be salicylated by the adenylation protein YbtE; the PCP1 mutant releases salicyl-cysteine from thiolysis of the Sal-S-ArCP intermediate; and the PCP2 mutant releases hydroxyphenyl-thiazolinyl-cysteine from the HPT-S-PCP1 acyl enzyme intermediate, all of which demonstrates processivity and directionality of chain growth. Restoration of the ArCP mutant's function was accomplished with the native ArCP fragment added in trans. The wild-type HMWP2 subunit accumulates hydroxyphenyl-4, 2-bithiazolinyl-S-enzyme at its most downstream PCP2 carrier site, presumably for transfer to the next subunit, HMWP1. The A domain was found to activate and transfer to PCP1 and PCP2 not only the natural L-Cys but also S-2-aminobutyrate, L-beta-chloroalanine, and L-Ser, enabling testing of the substrate specificity of the Cy domain. Probes of Cy domain function include mutagenesis of the Cy1 domain's conserved signature motif DX(4)DX(2)S to show that both D residues but not the S are crucial for both amide bond formation and heterocyclization. Also the Cy1 domain would accept an alternate upstream electrophilic donor substrate (2,3-dihydroxybenzoyl-S-ArCP) but would not process any of the three alternate downstream nucleophilic acceptors in place of Cys-S-PCP1, even for the amide bond-forming step in chain elongation.     

Thioesterase portability and peptidyl carrier protein swapping in yersiniabactin synthetase from Yersinia pestis

Multimodular enzymes, including polyketide synthases (PKSs), nonribosomal peptide synthetases (NRPSs), and mixed PKS/NRPS systems, contain functional domains with similar functions. Domain swapping and module fusion are potential powerful strategies for creating hybrid enzymes to synthesize modified natural products. To explore these strategies, yersiniabactin (Ybt) synthetase containing two subunits, HMWP2 [two NRPS modules (N-terminus-ArCP-Cy1-A-PCP1 and Cy2-PCP2-C-terminus)] and HMWP1 [one PKS (N-terminus-KS-AT-MT1-KR-ACP) one NRPS module (Cy3-MT2-PCP3-TE-C-terminus)], was used as a model system to study peptidyl carrier protein (PCP) domain swapping, thioesterase (TE) portability, and module-module fusion. The PCP1 domain of the N-terminal NRPS module of HMWP2 was swapped with either PCP2 or PCP3. The fusion proteins were 3-8-fold less active than the wild-type protein. The swapping of PCP2 of HMWP2 abolished the heterocyclization activity of the Cy2 domain while retaining its condensation function. When the two PCPs of HMWP2 were swapped by PCP3TE, it created two active fusion proteins: one or two NRPS modules fused to the TE domain. The internal TE domain of the two fusion proteins catalyzed the hydrolysis of enzyme-bound intermediates HPT-S-PCP3 to form HPT-COOH and HPTT-S-PCP3 to form HPTT-COOH. The TE activity was eliminated by the S2980A point mutation at its active site. Therefore, the three PCPs of the Ybt synthetase were swappable, and its lone TE domain was portable. The reasons for the observed low activities of the fusion proteins and lessons for protein engineering in generating novel modular enzymes were discussed.     

Excision of the epothilone synthetase B cyclization domain and demonstration of in trans condensation/cyclodehydration activity

The epothilones are potent anticancer natural products produced by a polyketide synthase (PKS)-nonribosomal peptide synthetase (NRPS) hybrid involving proteins EpoA-F. The single NRPS module of the epothilone assembly line, EpoB, is a distinct subunit of approximately 160 kDa and consists of four successive domains: cyclization, adenylation, oxidation, and peptidyl carrier protein (Cy-A-Ox-PCP). The cyclization domain is responsible for introduction of the thiazoline heterocycle into the growing polyketide/nonribosomal peptide chain from the precursors malonyl-CoA and cysteine through the multiple steps of condensation, cyclization, and dehydration. This enzyme-bound thiazoline intermediate is subsequently oxidized to a thiazole by the EpoB Ox domain. The EpoB module was dissected to provide 57 kDa EpoB(Cy) and 102 kDa EpoB(A-Ox-PCP) as subunit fragments to evaluate Cy as a free-standing domain. EpoB was reconstituted by these fragments in trans to generate the methylthiazole product. Using this system, apparent kinetic constants for the upstream acyl donor EpoA(ACP) and EpoB(Cy) were determined, providing a measure of affinity for the naturally occurring interface of the amino terminus of EpoB and the EpoA carboxy terminus. Site-directed mutants in excised EpoB(Cy) were prepared and used to examine residues involved in condensation and heterocycle formation. This work demonstrates the ability to define a functional Cy domain by excision from its native NRPS module, and examine both its protein-protein interactions and mechanism of activity.     

Dissection of the EntF condensation domain boundary and active site residues in nonribosomal peptide synthesis

Nonribosomal peptide synthetases (NRPSs) make many natural products of clinical importance, but a deeper understanding of the protein domains that compose NRPS assembly lines is required before these megasynthetases can be effectively engineered to produce novel drugs. The N-terminal amide bond-forming condensation (C) domain of the enterobactin NRPS EntF was excised from the multidomain synthetase using endpoints determined from sequence alignments and secondary structure predictions. The isolated domain was well-folded when compared by circular dichroism to the vibriobactin NRPS VibH, a naturally free-standing C domain. The EntF domain was also fully functional in an assay based on a synthetic small-molecule substrate, seryl N-acetylcysteamine. Active site mutants of the EntF C domain were surprisingly inactive in vitro as compared to their VibH counterparts, yet maintained the overall domain structure. An in vivo assay was developed in the context of the full-length EntF protein to more sensitively probe the activity level of the C domain mutants, and this supported strong effects for the active site mutations. The crucial role of histidine-138 was confirmed by assay of the full-length protein in vitro. These results suggest a strong resemblance of catalysis by the EntF C domain to chloramphenicol acetyltransferase, including an active site organized by an arginine-aspartate salt bridge, a key histidine acting as a general base, and an asparagine instead of a serine stabilizing the proposed tetrahedral intermediate by hydrogen bonding. The precise definition of a functional C domain excised from a NRPS should aid efforts at swapping NRPS domains between assembly lines.     

Pictet-Spenglerase involved in tetrahydroisoquinoline antibiotic biosynthesis

Nonribosomal peptide synthetase (NRPS) is a programmable modular machinery that produces a number of biologically active small-molecule peptides. Saframycin A is a potent antitumor antibiotic with a unique pentacyclic tetrahydroisoquinoline scaffold. We found that the nonribosomal peptide synthetase SfmC catalyzes a seven-step transformation of readily synthesized dipeptidyl substrates with long acyl chains into a complex saframycin scaffold. Based on a series of enzymatic reactions, we proposed a detailed mechanism involving the reduction of various peptidyl thioesters by a single R domain followed by iterative C domain-mediated Pictet-Spengler reactions. This shows that NRPSs possess a remarkable capability to acquire novel function for diversifying structures of peptide natural products.     

The architecture of the animal fatty acid synthetase complex. IV. Mapping of active centers and model for the mechanism of action

The fatty acid synthetase of animal tissue consists of two subunits, each containing seven catalytic centers and an acyl carrier site. Proteolytic cleavage patterns indicate that the subunit is arranged into three major domains, I, II, and III. Domain I contains the NH2-terminal end of the polypeptide and the catalytic sites of beta-ketoacyl synthetase (condensing enzyme) and the acetyl-and malonyl-transacylases. This domain, therefore, functions as a site for acetyl and malonyl substrate entry into the process of fatty acid synthesis and acts in part as the site of carbon-carbon condensation, resulting in chain elongation. Domain II is the medial domain and contains the beta-ketoacyl and enoyl reductases, probably the dehydratase, and the 4'-phosphopantetheine prosthetic group of the acyl carrier protein site. Domain II, therefore, is designated as the reduction domain where the keto carbon is reduced to methylene carbon by sequential processes of reduction, dehydration, and reduction again. Throughout these processes, the acyl group is attached to the pantetheine-SH of the acyl carrier protein. The latter site is distal to the cysteine-SH of the beta-ketoacyl synthetase, constitutes the 15000-dalton polypeptide at the COOH-terminal end of Domain II, and connects to Domain III. When the growing chain reaches C16 carbon length, the fatty acyl group is released by the thioesterase activity, which is contained in Domain III. A functional model is proposed based on the aforementioned results and the recent evidence that the synthetase subunits are arranged in a head-to-tail fashion, such that the pantetheine-SH of the acyl carrier protein of one subunit and the cysteine-SH of the beta-ketoacyl synthetase of the second subunit are juxtaposed. In this model, a palmitate synthesizing site contains Domain I of one subunit and Domains II and III of the second subunit. Therefore, even though each subunit contains all of the partial activities of the reaction sequence, the actual palmitate synthesizing unit consists of one-half of a subunit interacting with the complementary half of the other subunit.     

The mtaA gene of the myxothiazol biosynthetic gene cluster from Stigmatella aurantiaca DW4/3-1 encodes a phosphopantetheinyl transferase that activates polyketide synthases and polypeptide synthetases

Myxothiazol is synthesized by the myxobacterium Stigmatella aurantiaca DW4/3-1 via a combined polyketide synthase/polypeptide synthetase. The biosynthesis of this secondary metabolite is also dependent on the gene product of mtaA. The deduced amino acid sequence of mtaA shows similarity to 4'-phosphopantetheinyl transferases (4'-PP transferase). This points to an enzyme activity that converts inactive forms of the acyl carrier protein domains of polyketide synthetases (PKSs) and/or the peptidyl carrier protein domains of nonribosomal polypeptide synthetases (NRPSs) of the myxothiazol synthetase complex to their corresponding holo-forms. Heterologous co-expression of MtaA with an acyl carrier protein domain of the myxothiazol synthetase was performed in Escherichia coli. The proposed function as a 4'-PP transferase was confirmed and emphasizes the significance of MtaA for the formation of a catalytically active myxothiazol synthetase complex. Additionally, it is shown that MtaA has a relaxed substrate specificity: it processes an aryl carrier protein domain derived from the enterobactin synthetase of E. coli (ArCP) as well as a peptidyl carrier protein domain from a polypeptide synthetase of yet unknown function from Sorangium cellulosum. Therefore, MtaA should be a useful tool for activating heterologously expressed PKS and NRPS systems.     

Elucidating the substrate specificity and condensation domain activity of FkbP, the FK520 pipecolate-incorporating enzyme

Rapamycin, FK506, and FK520 are potent immunosuppressant natural product macrocycles generated by hybrid polyketide synthase (PKS)/nonribosomal peptide synthetase (NRPS) systems in streptomycetes. An important functional element within these molecules is an l-pipecolate moiety that is incorporated into the completed polyketide chain by the action of RapP/FkbP, a four-domain NRPS that also putatively serves to cyclize the chain after amino acid insertion. Here we report the expression and purification of recombinant FkbP from the FK520 biosynthetic pathway. Using a combination of radioassays and Fourier transform mass spectrometry, we demonstrate that once FkbP has been phosphopantetheinylated in vitro, its peptidyl carrier protein domain can be successfully loaded with l-pipecolic acid and, to a lesser extent, l-proline. The first condensation domain of FkbP is shown to be active through the successful acetylation of aminoacyl-S-FkbP using the appropriately loaded terminal acyl carrier protein from the PKS array, FkbA, as the chain donor. Site-directed mutagenesis confirmed that the N-terminal condensation domain catalyzes the transfer reaction. Acetylation of prolyl-S-FkbP was more rapid and occurred to a greater extent than that of pipecolyl-S-FkbP, a trend which was also observed with alternative acyl chain donors. These observations suggest that the adenylation domain of FkbP serves as the primary selectivity filter for pipecolate incorporation.     

Functional cross-talk between fatty acid synthesis and nonribosomal peptide synthesis in quinoxaline antibiotic-producing streptomycetes

Quinoxaline antibiotics are chromopeptide lactones embracing the two families of triostins and quinomycins, each having characteristic sulfur-containing cross-bridges. Interest in these compounds stems from their antineoplastic activities and their specific binding to DNA via bifunctional intercalation of the twin chromophores represented by quinoxaline-2-carboxylic acid (QA). Enzymatic analysis of triostin A-producing Streptomyces triostinicus and quinomycin A-producing Streptomyces echinatus revealed four nonribosomal peptide synthetase modules for the assembly of the quinoxalinoyl tetrapeptide backbone of the quinoxaline antibiotics. The modules were contained in three protein fractions, referred to as triostin synthetases (TrsII, III, and IV). TrsII is a 245-kDa bimodular nonribosomal peptide synthetase activating as thioesters for both serine and alanine, the first two amino acids of the quinoxalinoyl tetrapeptide chain. TrsIII, represented by a protein of 250 kDa, activates cysteine as a thioester. TrsIV, an unstable protein of apparent Mr about 280,000, was identified by its ability to activate and N-methylate valine, the last amino acid. QA, the chromophore, was shown to be recruited by a free-standing adenylation domain, TrsI, in conjunction with a QA-binding protein, AcpPSE. Cloning of the gene for the QA-binding protein revealed that it is the fatty acyl carrier protein, AcpPSE, of the fatty acid synthase of S. echinatus and S. triostinicus. Analysis of the acylation reaction of AcpPSE by TrsI along with other A-domains and the aroyl carrier protein AcmACP from actinomycin biosynthesis revealed a specific requirement for AcpPSE in the activation and also in the condensation of QA with serine in the initiation step of QA tetrapeptide assembly on TrsII. These data show for the first time a functional interaction between nonribosomal peptide synthesis and fatty acid synthesis.     

Fatty acid synthesis. Role of active site histidines and lysine in Cys-His-His-type beta-ketoacyl-acyl carrier protein synthases

Beta-ketoacyl-acyl carrier protein (ACP) synthase enzymes join short carbon units to construct fatty acyl chains by a three-step Claisen condensation reaction. The reaction starts with a trans thioesterification of the acyl primer substrate from ACP to the enzyme. Subsequently, the donor substrate malonyl-ACP is decarboxylated to form a carbanion intermediate, which in the third step attacks C1 of the primer substrate giving rise to an elongated acyl chain. A subgroup of beta-ketoacyl-ACP synthases, including mitochondrial beta-ketoacyl-ACP synthase, bacterial plus plastid beta-ketoacyl-ACP synthases I and II, and a domain of human fatty acid synthase, have a Cys-His-His triad and also a completely conserved Lys in the active site. To examine the role of these residues in catalysis, H298Q, H298E and six K328 mutants of Escherichia colibeta-ketoacyl-ACP synthase I were constructed and their ability to carry out the trans thioesterification, decarboxylation and/or condensation steps of the reaction was ascertained. The crystal structures of wild-type and eight mutant enzymes with and/or without bound substrate were determined. The H298E enzyme shows residual decarboxylase activity in the pH range 6-8, whereas the H298Q enzyme appears to be completely decarboxylation deficient, showing that H298 serves as a catalytic base in the decarboxylation step. Lys328 has a dual role in catalysis: its charge influences acyl transfer to the active site Cys, and the steric restraint imposed on H333 is of critical importance for decarboxylation activity. This restraint makes H333 an obligate hydrogen bond donor at Nepsilon, directed only towards the active site and malonyl-ACP binding area in the fatty acid complex.     

Cofactor requirements and reconstitution of microcin B17 synthetase: a multienzyme complex that catalyzes the formation of oxazoles and thiazoles in the antibiotic microcin B17

In the maturation of the Escherichia coli antibiotic Microcin B17 (MccB17), the McbA prepro-antibiotic is modified post-translationally by the multimeric microcin synthetase complex (composed of the McbB, -C, and -D proteins), which cyclizes four cysteines and four serines to thiazoles and oxazoles, respectively. Herein, we report the purification of individual subunits of MccB17 synthetase as fusions to maltose binding protein (MBP), and the in vitro reconstitution of heterocyclization activity. Preliminary characterization of each subunit reveals McbB to be a zinc-containing protein that may catalyze the initial cyclodehydration step, and McbC to contain flavin, consistent with an anticipated role for a dehydrogenase. We have previously demonstrated that McbD is a regulated ATPase/GTPase that may function as a conformational switch. Photolabeling experiments with the McbA propeptide now identify McbD as the initial site of substrate recognition. Heterocyclization activity was reconstituted only by combining all three subunits, demonstrating that each protein is required for heterocycle formation. Titration assays indicate that the subunits bind to each other with at least micromolar affinities, although McbD affords activity only after the MBP tag is proteolytically removed. Subunit competition assays with an McbDD147A mutant, which yields a catalytically deficient synthetase in vivo, show it to be defective in complex formation, whereas the McbBC181A/C184A double mutant, which is also inactive, competitively inhibits reconstitution by native McbB. Addition of the HtpG chaperone (originally shown to copurify with MccB17 synthetase), does not stimulate synthetase reconstitution or heterocyclization activity in vitro. A model for synthetase activity is proposed.     

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.     

Probing intra- versus interchain kinetic preferences of L-Thr acylation on dimeric VibF with mass spectrometry

We present a method to probe intra- and interchain activities within dimeric nonribosomal peptide synthetases. Utilizing domain inactivation and analytical mass mutants in conjunction with rapid-quench, mass spectrometry, and a probabilistic kinetic model, we have elucidated the pre-steady-state intra- and interchain rates and the corresponding flux of the acylation of L-Thr onto VibF. Although the intra rate is significantly faster than the inter rate, the data are most consistent with an even flux of covalent substrate loading where neither pathway dominates. These pre-steady-state results confirm previous steady-state in vitro mutant complementation studies of VibF. Extension of this methodology to other dimeric nonribosomal peptide synthetases, and to the related fatty acid and polyketide synthases, will further our biophysical understanding of their acyl-intermediate-processing pathways.     

Colorimetric inorganic pyrophosphate assay using a double cycling enzymatic method

The biosynthesis of aminocoumarin antibiotics involves the action of amide synthetases which construct amide bonds between aminocoumarins and various acyl moieties. Libraries of aminocoumarin analogues have been generated by in vivo fermentation, via feeding known amide synthetase substrates into producing microbial strains. Critically, such feeding studies rely on the inherent or engineered substrate promiscuity of each amide synthetase. We have initiated a program of directed evolution in order to create mutant amide synthetases for the synthesis of new nonnatural amino coumarin analogues. We used the clorobiocin enzyme CloL as a model amide synthetase to design and validate a fluorimetric high-throughput screen, which can be used to report the activity of mutant amide synthetases toward a broad range of coumarin and acyl donor substrates. Our assay monitors the decrease in fluorescence of aminocoumarins on acylation. The utility of the assay was illustrated by screening a library of amide synthetase mutants created by error-prone PCR. The substrate specificity of an amide synthetase was also rapidly probed using this assay, affording several newly identified substrates. It is anticipated that this high-throughput screen will accelerate the creation of amide synthetase mutants with new specificities by directed evolution.