Site-specific observation of acyl intermediate processing in thiotemplate biosynthesis by fourier transform mass spectrometry: the polyketide module of yersiniabactin synthetase

Complex arrays of thioester bound intermediates are present on 100-700 kDa enzymes during the biogenesis of diverse types of pharmacophores and natural product drugs. These multidomain enzymes, known as nonribosomal peptide synthetases and polyketide synthases (NRPSs and PKSs, respectively), synthesize from simple, physiologically available substrates bioactive compounds that can be further tailored by a host of modifying domains (e.g., methylation, cyclization, and epimerization) to increase the complexity of the mature final product. Interrogation of such covalent intermediates using mass spectrometry (MS) presents an underutilized method for understanding the covalent catalysis executed by NRPS and PKS enzymes. For the PKS module (205 kDa) from the yersiniabactin (Ybt) gene cluster of Yersinia pestis, limited proteolysis afforded a key 11 kDa peptide from the acyl-carrier protein (ACP) domain upon which at least five covalent intermediates could be detected (42, 70, 86, 330, and 358 Da). The isotopic resolution achieved by Fourier transform mass spectrometry (FTMS) allowed for the incorporation of substrates with stable isotopes to confirm the structural assignments of three intermediates (86, 330, and 358 Da) on the Ybt biosynthetic pathway to within 1 Da. Approximately 75% of the enzyme capacity is lost to unproductive decarboxylation of malonyl-S-ACP partly constraining the 1.4 min(-)(1) rate of Ybt production in vitro. Acyl transfer to the ACP domain (on the Ybt pathway) was promoted by a factor of approximately 10 over unproductive CO(2) loss in the presence of the cosubstrate S-adenosylmethionine (SAM), with S-adenosylhomocysteine unable to restore the condensation yield observed with SAM. The data are consistent with Claisen condensation from KS to the ACP carrier site being reversible, with the absence of downstream methylation providing more opportunity for unproductive CO(2) loss. Extension of such FTMS-based studies will allow the direct visualization of multiple intermediates in determining the catalytic order of events and kinetics of NRPS and PKS systems.     

The loading and initial elongation modules of rifamycin synthetase collaborate to produce mixed aryl ketide products

Rifamycin synthetase assembles the chemical backbone that members of the rifamycin family of antibiotics have in common. The synthetase contains a mixed biosynthetic interface between its loading module, which uses a nonribosomal peptide synthetase mechanism, and its initial elongation module, which uses a polyketide synthase mechanism. Biochemical studies of the loading and initial elongation modules of rifamycin synthetase reveal that this bimodular protein (LM-M1) catalyzes the formation of the phenyl ketide 3-hydroxy-2-methyl-3-phenylpropionate via a series of reactions that require benzoate, Mg.ATP, methylmalonyl-CoA, and NADPH. The overall rate of phenyl ketide production appears to be determined by the covalent loading of benzoate onto LM-M1, rather than by subsequent steps such as intermodular transfer of benzoate or condensation of benzoate and methylmalonate. Substituted benzoates that have previously been shown to be substrates for the loading module alone can also be incorporated into the corresponding aryl ketides by LM-M1, suggesting that the bimodular protein has a broad substrate tolerance. Discrimination between the substituted benzoates appears to reside in the benzoate loading reaction, and preincubation of LM-M1 with substituted benzoates and Mg.ATP allows faster downstream reactions to be unmasked. LM-M1 may be a useful biochemical system for exploring interactions between nonribosomal peptide synthetase and polyketide synthase modules.     

Quantitative analysis of the relative contributions of donor acyl carrier proteins, acceptor ketosynthases, and linker regions to intermodular transfer of intermediates in hybrid polyketide synthases

6-Deoxyerythronolide B synthase (DEBS) is the modular polyketide synthase (PKS) responsible for the biosynthesis of 6-dEB, the aglycon core of the antibiotic erythromycin. The biosynthesis of 6-dEB proceeds in an assembly-line fashion through the six modules of DEBS, each of which catalyzes a dedicated set of reactions, such that the structure of the final product is determined by the arrangement of modules along the assembly line. This transparent relationship between protein sequence and enzyme function is common to all modular PKSs and makes these enzymes an attractive scaffold for protein engineering through module swapping. One of the fundamental issues relating to module swapping that still needs to be addressed is the mechanism by which intermediates are channeled from one module to the next. While it has been previously shown that short linker regions at the N- and C-termini of adjacent polypeptides play an important role in mediating intermodular transfer, the contributions of other protein-protein interactions have not yet been probed. Here, we investigate the roles of the linker interactions as well as the interactions between the donor acyl carrier protein (ACP) domain and the downstream ketosynthase (KS) domain in various contexts. Linker interactions and ACP-KS interactions make relatively equal contributions at the module 2-module 3 and the module 4-module 5 interfaces in DEBS. In contrast, modules 2 and 6 are more tolerant toward substrates presented by nonnatural ACP domains. This tolerance was exploited for engineering hybrid PKS-PKS and PKS-NRPS (nonribosomal peptide synthetase) junctions and suggests fundamental ground rules for engineering novel chimeric PKSs in the future.     

Control of directionality in nonribosomal peptide synthesis: role of the condensation domain in preventing misinitiation and timing of epimerization

Product assembly by nonribosomal peptide synthetases (NRPS) is initiated by starter modules that comprise an adenylation (A) and a peptidyl carrier protein (PCP) domain. Elongation modules of NRPS have in addition a condensation (C) domain that is located upstream of the A domain. They cannot initiate peptide bond formation. To understand the role of domain arrangements and the influence of the domains present upstream of the A domains of the elongation modules of TycB on the initiation and epimerization activities, we constructed a set of proteins derived from the tyrocidine synthetases of Bacillus brevis, which represent several N-terminal truncations of TycB and the first module of TycC. The latter was fused with the thioesterase domain (Te) to give TycC(1)-CAT-Te and to ensure product turnover. TycB(2)(-)(3)-AT.CATE and TycB(3)-ATE, lacking an N-terminal C domain, were capable of initiating peptide synthesis and epimerizing. In contrast, the corresponding constructs with a cognate N-terminal C domain, TycB(2)(-)(3)-T.CATE and TycB(3)-CATE, were strongly reduced in initiation and epimerization. Evidence is also provided that this reduction is due to substrate binding in an enantioselective binding pocket at the acceptor position of the C domains. By using TycB(2)(-)(3)-AT.CATE and TycB(3)-ATE, we were able to turn an elongation module into an initiation module, and to establish an in-trans system for the formation of new di- and tripeptides with recombinant NRPS modules. We also show that epimerization domains of elongation modules can in principle epimerize both aminoacyl-S-Ppant (TycB(3)-ATE) and peptidyl-S-Ppant (TycB(2)(-)(3)-AT.CATE) substrates, although the efficiency for epimerizing the noncognate aminoacyl-S-Ppant substrates appears to be lowered.     

Facile detection of acyl and peptidyl intermediates on thiotemplate carrier domains via phosphopantetheinyl elimination reactions during tandem mass spectrometry

With the emergence of drug resistance and the genomic revolution, there has been a renewed interest in the genes that are responsible for the generation of bioactive natural products. Secondary metabolites of one major class are biosynthesized at one or more sites by ultralarge enzymes that carry covalent intermediates on phosphopantetheine arms. Because such intermediates are difficult to characterize in vitro, we have developed a new approach for streamlined detection of substrates, intermediates, and products attached to a phosphopantetheinyl arm of the carrier site. During vibrational activation of gas-phase carrier domains, facile elimination occurs in benchtop and Fourier-transform mass spectrometers alike. Phosphopantetheinyl ejections quickly reduce >100 kDa megaenzymes to <1000 Da ions for structural assignment of intermediates at <0.007 Da mass accuracy without proteolytic digestion. This "top down" approach quickly illuminated diverse acyl intermediates on the carrier domains of the nonribosomal peptide synthetases (NRPSs) or polyketide synthases (PKSs) found in the biosynthetic pathways of prodigiosin, pyoluteorin, mycosubtilin, nikkomycin, enterobactin, gramicidin, and several proteins from the orphan pksX gene cluster from Bacillus subtilis. By focusing on just those regions undergoing covalent chemistry, the method delivered clean proof for the reversible dehydration of hydroxymethylglutaryl-S-PksL via incorporation of 2H or 18O from the buffer. The facile nature of this revised assay will allow diverse laboratories to spearhead their NRPS-PKS projects with benchtop mass spectrometers.     

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.     

Chain initiation on type I modular polyketide synthases revealed by limited proteolysis and ion-trap mass spectrometry

Limited proteolysis in combination with liquid chromatography-ion trap mass spectrometry (LC-MS) was used to analyze engineered or natural proteins derived from a type I modular polyketide synthase (PKS), the 6-deoxyerythronolide B synthase (DEBS), and comprising either the first two extension modules linked to the chain-terminating thioesterase (TE) (DEBS1-TE); or the last two extension modules (DEBS3) or the first extension module linked to TE (diketide synthase, DKS). Functional domains were released by controlled proteolysis, and the exact boundaries of released domains were obtained through mass spectrometry and N-terminal sequencing analysis. The acyltransferase-acyl carrier protein required for chain initiation (AT(L)-ACP(L)), was released as a didomain from both DEBS1-TE and DKS, as well as the off-loading TE as a didomain with the adjacent ACP. Mass spectrometry was used successfully to monitor in detail both the release of individual domains, and the patterns of acylation of both intact and digested DKS when either propionyl-CoA or n-butyryl-CoA were used as initiation substrates. In particular, both loading domains and the ketosynthase domain of the first extension module (KS1) were directly observed to be simultaneously primed. The widely available and simple MS methodology used here offers a convenient approach to the proteolytic mapping of PKS multienzymes and to the direct monitoring of enzyme-bound intermediates.     

Mutational analysis of peptidyl carrier protein and acyl carrier protein synthase unveils residues involved in protein-protein recognition

4'-Phosphopantetheinyl transferases (PPTases) are essential for the production of fatty acids by fatty acid synthases (primary metabolism) and natural products by nonribosomal peptide synthetases and polyketide synthases (secondary metabolism). These systems contain carrier proteins (CPs) for the covalent binding of reaction intermediates during synthesis. PPTases transfer the 4'-phosphopantetheine moiety from coenzyme A (CoA) onto conserved serine residues of the apo-CPs to convert them to their functionally active holo form. In bacteria, two types of PPTases exist that are evolutionary related but differ in their substrate spectrum. Acyl carrier protein synthases (AcpSs) recognize CPs from primary metabolism, whereas Sfp- (surfactin production-) type PPTases have a preference for CPs of secondary metabolism. Previous investigations showed that a peptidyl carrier protein (PCP) of secondary metabolism can be altered to serve as substrate for AcpS. We demonstrate here that a single mutation in PCP suffices for the modification of this CP by AcpS, and we have identified by mutational analysis several other PCP residues and two AcpS residues involved in substrate discrimination by this PPTase. These altered PCPs were still capable of serving their designated function in NRPS modules, and selective use of AcpS or Sfp leads to production of two different products by a trimodular NRPS.     

The linear pentadecapeptide gramicidin is assembled by four multimodular nonribosomal peptide synthetases that comprise 16 modules with 56 catalytic domains

Linear gramicidin is a membrane channel forming pentadecapeptide that is produced via the nonribosomal pathway. It consists of 15 hydrophobic amino acids with alternating l- and d-configuration forming a beta-helix-like structure. It has an N-formylated valine and a C-terminal ethanolamine. Here we report cloning and sequencing of the entire biosynthetic gene cluster as well as initial biochemical analysis of a new reductase domain. The biosynthetic gene cluster was identified on two nonoverlapping fosmids and a 13-kilobase pair (kbp) interbridge fragment covering a region of 74 kbp. Four very large open reading frames, lgrA, lgrB, lgrC, and lgrD with 6.8, 15.5, 23.3, and 15.3 kbp, were identified and shown to encode nonribosomal peptide synthetases with two, four, six, and four modules, respectively. Within the 16 modules identified, seven epimerization domains in alternating positions were detected as well as a putative formylation domain fused to the first module LgrA and a putative reductase domain attached to the C-terminal module of LgrD. Analysis of the substrate specificity by phylogenetic studies using the residues of the substrate-binding pockets of all 16 adenylation domains revealed a good agreement of the substrate amino acids predicted with the sequence of linear gramicidin. Additional biochemical analysis of the three adenylation domains of modules 1, 2, and 3 confirmed the colinearity of this nonribosomal peptide synthetase assembly line. Module 16 was predicted to activate glycine, which would then, being the C-terminal residue of the peptide chain, be reduced by the adjacent reductase domain to give ethanolamine, thereby releasing the final product N-formyl-pentadecapeptide-ethanolamine. However, initial biochemical analysis of this reductase showed only a one-step reduction yielding the corresponding aldehyde in vitro.     

Synthesis of linear gramicidin requires the cooperation of two independent reductases

The linear pentadecapeptide gramicidin has been reported to be assembled by four large multimodular nonribosomal peptide synthetases (NRPSs), LgrABCD, that comprise 16 modules. During biosynthesis, the N-formylated 16mer peptide is bound to the peptidyl carrier protein (PCP) of the terminal module via a thioester bond to the carboxyl group of the last amino acid glycine(16). In a first reaction the peptide is released from the protein template in an NAD(P)H-dependent reduction step catalyzed by the adjacent reductase forming an aldehyde intermediate. Here we present the biochemical proof that this aldehyde intermediate is further reduced by an aldoreductase, LgrE, in an NADPH-dependent manner to form the final product gramicidin A, N-formyl-pentadecapeptide-ethanolamine. To determine the potential use of the two reductases in the construction of hybrid NRPSs, we have tested their ability to accept a variety of different substrates in vitro. The results obtained give way to a broad spectrum of possible use.     

The loading module of rifamycin synthetase is an adenylation-thiolation didomain with substrate tolerance for substituted benzoates

The rifamycin synthetase is primed with a 3-amino-5-hydroxybenzoate starter unit by a loading module that contains domains homologous to the adenylation and thiolation domains of nonribosomal peptide synthetases. Adenylation and thiolation activities of the loading module were reconstituted in vitro and shown to be independent of coenzyme A, countering literature proposals that the loading module is a coenzyme A ligase. Kinetic parameters for covalent arylation of the loading module were measured directly for the unnatural substrates benzoate and 3-hydroxybenzoate. This analysis was extended through competition experiments to determine the relative rates of incorporation of a series of substituted benzoates. Our results show that the loading module can accept a variety of substituted benzoates, although it exhibits a preference for the 3-, 5-, and 3,5-disubstituted benzoates that most closely resemble its biological substrate. The considerable substrate tolerance of the loading module of rifamycin synthetase suggests that the module has potential as a tool for generating substituted derivatives of natural products.     

Substrate-binding properties of the family 54 module of <Emphasis Type="Italic">Clostridium thermocellum</Emphasis> Lic16A laminarinase

Endo-β-1.3–1.4-glucanase Lic16A of the moderate thermophilic anaerobe Clostridium thermocellum has a complex multimodular structure. In addition to the catalytic module, Lic16A contains eight auxiliary modules, five of which are substrate-binding modules. The new family 54 substrate-binding module CBM54 (25.2 kDa), which is at the N terminus of the enzyme, has a cleavage site in its N-terminal part, and its cleavage yields a shortened module CBM54C (17.2 kDa) in vivo and in vitro. CBM54C was cloned in Escherichia coli and purified to electrophoretic homogeneity. The binding constants of CBM54C to xylan, chitin, insoluble yeast cell wall β-glucan, and bacterial crystalline cellulose were of the same order of magnitude as for CBM54. However, CBM54C did not bind pustulan, avicel, and chitosan, in contrast to CBM54. Calcium ions restored the ability of CBM54C to bind these three carbohydrates. CBM54 substrate binding promiscuity suggested multiple binding sites, some of them being Ca²⁺ dependent. The Ca²⁺-independent sites for avicel, pustulan and chitosan were localized to the spontaneously split-off N-terminal part (8 kDa) of CBM54. The arrangement of Ca²⁺-dependent and Ca²⁺-independent binding sites for various substrates was suggested.     

New lessons for combinatorial biosynthesis from myxobacteria. The myxothiazol biosynthetic gene cluster of Stigmatella aurantiaca DW4/3-1

The biosynthetic mta gene cluster responsible for myxothiazol formation from the fruiting body forming myxobacterium Stigmatella aurantiaca DW4/3-1 was sequenced and analyzed. Myxothiazol, an inhibitor of the electron transport via the bc(1)-complex of the respiratory chain, is biosynthesized by a unique combination of several polyketide synthases (PKS) and nonribosomal peptide synthetases (NRPS), which are activated by the 4'-phosphopantetheinyl transferase MtaA. Genomic replacement of a fragment of mtaB and insertion of a kanamycin resistance gene into mtaA both impaired myxothiazol synthesis. Genes mtaC and mtaD encode the enzymes for bis-thiazol(ine) formation and chain extension on one pure NRPS (MtaC) and on a unique combination of PKS and NRPS (MtaD). The genes mtaE and mtaF encode PKSs including peptide fragments with homology to methyltransferases. These methyltransferase modules are assumed to be necessary for the formation of the proposed methoxy- and beta-methoxy-acrylate intermediates of myxothiazol biosynthesis. The last gene of the cluster, mtaG, again resembles a NRPS and provides insight into the mechanism of the formation of the terminal amide of myxothiazol. The carbon backbone of an amino acid added to the myxothiazol-acid is assumed to be removed via an unprecedented module with homology to monooxygenases within MtaG.     

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.     

Functional and structural analysis of the siderophore synthetase AsbB through reconstitution of the petrobactin biosynthetic pathway from Bacillus anthracis

Petrobactin, a mixed catechol-carboxylate siderophore, is required for full virulence of Bacillus anthracis, the causative agent of anthrax. The asbABCDEF operon encodes the biosynthetic machinery for this secondary metabolite. Here, we show that the function of five gene products encoded by the asb operon is necessary and sufficient for conversion of endogenous precursors to petrobactin using an in vitro system. In this pathway, the siderophore synthetase AsbB catalyzes formation of amide bonds crucial for petrobactin assembly through use of biosynthetic intermediates, as opposed to primary metabolites, as carboxylate donors. In solving the crystal structure of the B. anthracis siderophore biosynthesis protein B (AsbB), we disclose a three-dimensional model of a nonribosomal peptide synthetase-independent siderophore (NIS) synthetase. Structural characteristics provide new insight into how this bifunctional condensing enzyme can bind and adenylate multiple citrate-containing substrates followed by incorporation of both natural and unnatural polyamine nucleophiles. This activity enables formation of multiple end-stage products leading to final assembly of petrobactin. Subsequent enzymatic assays with the nonribosomal peptide synthetase-like AsbC, AsbD, and AsbE polypeptides show that the alternative products of AsbB are further converted to petrobactin, verifying previously proposed convergent routes to formation of this siderophore. These studies identify potential therapeutic targets to halt deadly infections caused by B. anthracis and other pathogenic bacteria and suggest new avenues for the chemoenzymatic synthesis of novel compounds.     

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.     

Initiation, elongation, and termination strategies in polyketide and polypeptide antibiotic biosynthesis.

Progress in sequence analysis of biosynthetic gene clusters encoding polyketides and nonribosomal peptides and in the reconstitution of in vitro activities continues to reveal new insights into the growth of these natural products' acyl chains, which have been revealed as a series of elongating, covalent, acyl enzyme intermediates on their multimodular scaffolds. Studies that focus on the three stages of natural product biosynthesis - initiation, elongation, and termination - have yielded crucial information on monomer substrate specificity, domain and module portability, and product release mechanisms, all of which are important not only for an understanding of this exquisite enzymatic machinery, but also for the rational construction of new, functional synthetases and synthases that are a goal of combinatorial biosynthesis.     

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.     

Biochemical and genetic characterization of ChiA,the major enzyme component for the solubilization of chitin by<Emphasis Type="Italic"> Cellulomonas uda</Emphasis>

Cellulomonas uda efficiently solubilized chitinous substrates with a simple chitinase system composed of an endochitinase, designated ChiA, which hydrolyzed insoluble substrates into long-chain chitooligosaccharides, and an as yet uncharacterized exochitinase activity. ChiA, isolated from culture supernatant fluids, was found to be a glycosylated endochitinase with an apparent molecular mass of approximately 70 kDa and pI of 8.5. The gene encoding ChiA was cloned in Escherichia coli and sequenced, revealing an open reading frame of 1,716 bp encoding a 571-amino-acid protein with a predicted molecular mass of 59.2 kDa. The region upstream of chiA included a conserved –35 hexamer flanked by two direct repeats analogous to those found in many Streptomyces chitinase promoters, and thought to function as binding sequences for regulatory proteins. Analysis of the deduced amino acid sequence showed a modular protein consisting of a signal peptide at its N terminus, a family 2 carbohydrate-binding module (CBM2) that was closely related to the substrate-binding domains of glycosyl hydrolases from distantly related bacteria, and a family 18 glycosyl hydrolase catalytic module related to Streptomyces chitinases. In contrast to the fibronectin type III domains of Streptomyces chitinases, the linker region between modules in ChiA consisted of a long proline- and threonine-rich module, thought to contribute to the glycosylation and flexibility of the mature protein.Abbreviations CBM Carbohydrate-binding module - P-T Proline- and threonine-rich domain - Fn3 Type III repetitive sequences of fibronectin domain - PKD Polycystic kidney disease I domain