Structure-based dissociation of a type I polyketide synthase module

Individual modules of modular polyketide synthases (PKSs) such as 6-deoxyerythronolide B synthase (DEBS) consist of conserved, covalently linked domains separated by unconserved intervening linker sequences. To better understand the protein-protein and enzyme-substrate interactions in modular catalysis, we have exploited recent structural insights to prepare stand-alone domains of selected DEBS modules. When combined in vitro, ketosynthase (KS), acyl transferase (AT), and acyl carrier protein (ACP) domains of DEBS module 3 catalyzed methylmalonyl transfer and diketide substrate elongation. When added to a minimal PKS, ketoreductase domains from DEBS modules 1, 2, and 6 showed specificity for the beta-ketoacylthioester substrate, but not for either the ACP domain carrying the polyketide substrate or the KS domain that synthesized the substrate. With insights into catalytic efficiency and specificity of PKS modules, our results provide guidelines for constructing optimal hybrid PKS systems.     

Knowledge-based design of bimodular and trimodular polyketide synthases based on domain and module swaps: a route to simple statin analogues.

BACKGROUND: Polyketides are structurally diverse natural products that have a range of medically useful activities. Nonaromatic bacterial polyketides are synthesised on modular polyketide synthase (PKS) multienzymes, in which each cycle of chain extension requires a different 'module' of enzymatic activities. Attempts to design and construct modular PKSs that synthesise specified novel polyketides provide a particularly stringent test of our understanding of PKS structure and function. RESULTS: We have constructed bimodular and trimodular PKSs based on DEBS1-TE, a derivative of the erythromycin PKS that contains only modules 1 and 2 and a thioesterase (TE), by substituting multiple domains with appropriate counterparts derived from the rapamycin PKS. Hybrid PKSs were obtained that synthesised the predicted target triketide lactones, which are simple analogues of cholesterol-lowering statins. In constructing intermodular fusions, whether between modules in the same or in different proteins, it was found advantageous to preserve intact the acyl carrier protein-ketosynthase (ACP-KS) didomain that spans the junction between successive modules. CONCLUSIONS: Relatively simple considerations govern the construction of functional hybrid PKSs. Fusion sites should be chosen either in the surface-accessible linker regions between enzymatic domains, as previously revealed, or just inside the conserved margins of domains. The interaction of an ACP domain with the adjacent KS domain, whether on the same polyketide or not, is of particular importance, both through conservation of appropriate protein-protein interactions, and through optimising molecular recognition of the altered polyketide chain in the key transfer of the acyl chain from the ACP of one module to the KS of the downstream module.     

Mechanistic analysis of acyl transferase domain exchange in polyketide synthase modules

Many polyketides are synthesized by a class of multifunctional enzymes called type I modular polyketide synthases (PKSs). Several reports have described the power of predictively altering polyketide structure by replacing individual PKS domains with homologues from other PKSs. For example, numerous erythromycin analogues have been generated by replacing individual methylmalonyl-specific acyl transferase (AT) domains of the 6-deoxyerythronolide B synthase (DEBS) with malonyl-, ethylmalonyl-, or methoxymalonyl-specific domains. However, the construction of hybrid PKS modules often attenuates product formation both kinetically and distributively. The molecular basis for this mechanistic imperfection is not understood. We have systematically analyzed the impact of replacing an AT domain of DEBS on acyl-AT formation, acyl-CoA:HS-NAc acyl transferase activity, acyl-CoA:ACP acyl transferase activity (nucleophile charging), acyl-SNAc:ketosynthase acyl transferase activity (electrophile charging), and beta-ketoacyl ACP synthase activity (condensation). As usual, domain junctions were located in interdomain regions flanking the AT domain. Kinetic analysis of hybrid modules containing either malonyl transferase or methylmalonyl transferase domains revealed a 15-20-fold decrease in overall turnover numbers of the hybrid modules as compared to the wild-type module. In contrast, both the activity and the specificity of the heterologous AT domains remained unaffected. Moreover, no defects could be detected in the ability of the heterologous AT domains to catalyze acyl-CoA:ACP acyl transfer. Single turnover studies aimed at directly probing the ketosynthase-catalyzed reaction led to two crucial findings. First, wild-type modules catalyzed chain elongation with comparable efficiency regardless of whether methylmalonyl-ACP or malonyl-ACP were the nucleophilic substrates. Second, chain elongation in all hybrid modules tested was seriously attenuated relative to the wild-type module. Our data suggest that, as currently practiced, the most deleterious impact of AT domain swapping is not on the substrate specificity. Rather, it is due to the impaired ability of the KS and ACP domains in the hybrid module to catalyze chain elongation. Consistent with this proposal, limited proteolysis of wild-type and hybrid modules showed major differences in cleavage patterns, especially in the region between the KR and ACP domains.     

Exploring the biosynthetic potential of bimodular aromatic polyketide synthases

Polycyclic aromatic polyketides such as actinorhodin and tetracenomycin are synthesized from acetate equivalents by type II polyketide synthases (PKS). Their carbon chain backbones are derived from malonyl-CoA building blocks through the action of a minimal PKS module consisting of a ketosynthase, a chain length factor, an acyl carrier protein (ACP) and a malonyl-CoA/ACP transacylase. In contrast to these acetogenic polyketides, the backbones of a few aromatic polyketide natural products, such as the R1128 antibiotics, are primed by non-acetate building blocks. These polyketides are synthesized by bimodular PKSs comprising of a dedicated initiation module, which includes a ketosynthase, acyl transferase and ACP, as well as a minimal PKS module. Recently we showed that regioselectively modified polyketides could be synthesized through the genetic recombination of initiation modules and minimal PKS modules from different polyketide biosynthetic pathways (Tang et al. PLoS Biol. 2004, 2, 227-238). For example, the actinorhodin and tetracenomycin minimal PKSs could accept and elongate unnatural primer units from the R1128 initiation module. In this report we provide further examples of using heterologous bimodular PKSs for the engineered biosynthesis of new aromatic polyketides. In addition to providing insights into the biosynthetic mechanisms of aromatic PKSs, our findings also highlight considerable potential for crosstalk between amino acid catabolism and aromatic polyketide biosynthesis. For example, exogenously supplied unnatural amino acids are efficiently incorporated into bioactive anthraquinone antibiotics.     

Rational design and assembly of synthetic trimodular polyketide synthases

Type I polyketide synthases (PKSs) consist of modules that add two-carbon units in polyketide backbones. Rearranging modules from different sources can yield novel enzymes that produce unnatural products, but the rules that govern module-module communication are still not well known. The construction and assay of hybrid bimodular units with synthetic PKS genes were recently reported. Here, we describe the rational design of trimodular PKSs by combining bimodular units. A cloning-expression system was developed to assemble and test 54 unnatural trimodular PKSs flanked by the loading module and the thioesterase from the erythromycin synthase. Remarkably, 96% of them produced the expected polyketide. The obtained results represent an important milestone toward the ultimate goal of making new bioactive polyketides by rational design. Additionally, these results show a path for the production of customized tetraketides by fermentation, which can be an important source of advanced intermediates to facilitate the synthesis of complex products.     

Chain initiation on the soraphen-producing modular polyketide synthase from Sorangium cellulosum.

BACKGROUND: Polyketides are structurally diverse natural products with a wide range of useful activities. Bacterial modular polyketide synthases (PKSs) catalyse the production of non-aromatic polyketides using a different set of enzymes for each successive cycle of chain extension. The choice of starter unit is governed by the substrate specificity of a distinct loading module. The unusual loading module of the soraphen modular PKS, from the myxobacterium Sorangium cellulosum, specifies a benzoic acid starter unit. Attempts to design functional hybrid PKSs using this loading module provide a stringent test of our understanding of PKS structure and function, since the order of the domains in the loading and first extension module is non-canonical in the soraphen PKS, and the producing strain is not an actinomycete. RESULTS: We have constructed bimodular PKSs based on DEBS1-TE, a derivative of the erythromycin PKS that contains only extension modules 1 and 2 and a thioesterase (TE) domain, by substituting one or more domains from the soraphen PKS. A hybrid PKS containing the soraphen acyltransferase domain AT1b instead of extension acyltransferase domain AT1 produced triketide lactones lacking a methyl group at C-4, as expected if AT1b catalyses the addition of malonyl-CoA during the first extension cycle on the soraphen PKS. Substitution of the DEBS1-TE loading module AT domain by the soraphen AT1a domain led to the production of 5-phenyl-substituted triketide lactone, as well as the normal products of DEBS1-TE. This 5-phenyl triketide lactone was also the product of a hybrid PKS containing the entire soraphen PKS loading module as well as part of its first extension module. Phenyl-substituted lactone was only produced when measures were simultaneously taken to increase the intracellular supply of benzoyl-CoA in the host strain of Saccharopolyspora erythraea. CONCLUSIONS: These results demonstrate that the ability to recruit a benzoate starter unit can be conferred on a modular PKS by the transfer either of a single AT domain, or of multiple domains to produce a chimaeric first extension module, from the soraphen PKS. However, benzoyl-CoA needs to be provided within the cell as a specific precursor. The data also support the respective roles previously assigned to the adjacent AT domains of the soraphen loading/first extension module. Construction of such hybrid actinomycete-myxobacterial enzymes should significantly extend the synthetic repertoire of modular PKSs.     

The stereochemistry of complex polyketide biosynthesis by modular polyketide synthases

Polyketides are a diverse class of medically important natural products whose biosynthesis is catalysed by polyketide synthases (PKSs), in a fashion highly analogous to fatty acid biosynthesis. In modular PKSs, the polyketide chain is assembled by the successive condensation of activated carboxylic acid-derived units, where chain extension occurs with the intermediates remaining covalently bound to the enzyme, with the growing polyketide tethered to an acyl carrier domain (ACP). Carboxylated acyl-CoA precursors serve as activated donors that are selected by the acyltransferase domain (AT) providing extender units that are added to the growing chain by condensation catalysed by the ketosynthase domain (KS). The action of ketoreductase (KR), dehydratase (DH), and enoylreductase (ER) activities can result in unreduced, partially reduced, or fully reduced centres within the polyketide chain depending on which of these enzymes are present and active. The PKS-catalysed assembly process generates stereochemical diversity, because carbon-carbon double bonds may have either cis- or trans- geometry, and because of the chirality of centres bearing hydroxyl groups (where they are retained) and branching methyl groups (the latter arising from use of propionate extender units). This review shall cover the studies that have determined the stereochemistry in many of the reactions involved in polyketide biosynthesis by modular PKSs.     

Chain initiation on the soraphen-producing modular polyketide synthase from Sorangium cellulosum

Background: Polyketides are structurally diverse natural products with a wide range of useful activities. Bacterial modular polyketide synthases (PKSs) catalyse the production of non-aromatic polyketides using a different set of enzymes for each successive cycle of chain extension. The choice of starter unit is governed by the substrate specificity of a distinct loading module. The unusual loading module of the soraphen modular PKS, from the myxobacterium Sorangium cellulosum, specifies a benzoic acid starter unit. Attempts to design functional hybrid PKSs using this loading module provide a stringent test of our understanding of PKS structure and function, since the order of the domains in the loading and first extension module is non-canonical in the soraphen PKS, and the producing strain is not an actinomycete.Results: We have constructed bimodular PKSs based on DEBS1-TE, a derivative of the erythromycin PKS that contains only extension modules 1 and 2 and a thioesterase (TE) domain, by substituting one or more domains from the soraphen PKS. A hybrid PKS containing the soraphen acyltransferase domain AT1b instead of extension acyltransferase domain AT1 produced triketide lactones lacking a methyl group at C-4, as expected if AT1b catalyses the addition of malonyl-CoA during the first extension cycle on the soraphen PKS. Substitution of the DEBS1-TE loading module AT domain by the soraphen AT1a domain led to the production of 5-phenyl-substituted triketide lactone, as well as the normal products of DEBS1-TE. This 5-phenyl triketide lactone was also the product of a hybrid PKS containing the entire soraphen PKS loading module as well as part of its first extension module. Phenyl-substituted lactone was only produced when measures were simultaneously taken to increase the intracellular supply of benzoyl-CoA in the host strain of Saccharopolyspora erythraea.Conclusions: These results demonstrate that the ability to recruit a benzoate starter unit can be conferred on a modular PKS by the transfer either of a single AT domain, or of multiple domains to produce a chimaeric first extension module, from the soraphen PKS. However, benzoyl-CoA needs to be provided within the cell as a specific precursor. The data also support the respective roles previously assigned to the adjacent AT domains of the soraphen loading/first extension module. Construction of such hybrid actinomycete–myxobacterial enzymes should significantly extend the synthetic repertoire of modular PKSs.     

Mechanisms of molecular recognition in the pikromycin polyketide synthase

BACKGROUND: Modular polyketide synthases (PKSs) produce a wide range of medically significant compounds. In the case of the pikromycin PKS of Streptomyces venezuelae, four separate polypeptides (PikAI-PikAIV), comprising a total of one loading domain and six extension modules, generate the 14-membered ring macrolactone narbonolide. The polypeptide PikAIV contains a thioesterase (TE) domain and is responsible for catalyzing both the last elongation step with methylmalonyl CoA, and subsequent release of the final polyketide chain elongation intermediate from the PKS. Under certain growth conditions this polypeptide is synthesized from an alternative translational start site, giving rise to an N-terminal truncated form of PikAIV, containing only half of the ketosynthase (KS(6)) domain. The truncated form of PikAIV is unable to catalyze the final elongation step, but is able to cleave a polyketide chain from the preceding module on PikAIII (ACP(5)), giving rise to the 12-membered ring product 10-deoxymethynolide. RESULTS: S. venezuelae mutants expressing hybrid PikAIV polypeptides containing acyl carrier protein (ACP) and malonyl CoA specific acyltransferase (AT) domains from the rapamycin PKS were unable to catalyze production of 12- or 14-membered ring macrolactone products. Plasmid-based expression of a hybrid PikAIV containing the native KS(6) and TE domains, however, restored production of both narbonolide and 10-deoxymethynolide in the S. venezuelae AX912 mutant that generates a TE-deleted form of PikAIV. Use of alternative KS domains or deletion of the KS(6) domain within the hybrid PikAIV resulted in loss of both products. Plasmid-based expression of a TE domain of PikAIV as a separate polypeptide in the AX912 mutant resulted in greater than 50% restoration of 10-deoxymethynolide, but not in mutants expressing a hybrid PikAIV bearing an unnatural AT domain. Mutants expressing hybrid PikAIV polypeptides containing the natural AT(6) domains and different ACP domains efficiently produced polyketide products, but with a significantly higher 10-deoxymethynolide/narbonolide ratio than observed with native PikAIV. CONCLUSIONS: Dimerization of KS(6) modules allows in vivo formation of a PKS heterodimer using PikAIV polypeptides containing different AT and ACP domains. In such heterodimers, the TE domain and the AT(6) domain responsible for formation of the narbonolide product are located on different polypeptide chains. The AT(6) domain of PikAIV plays an important role in facilitating TE-catalyzed chain termination (10-deoxymethynolide formation) at the proceeding module in PikAIII. The pikromycin PKS can tolerate the presence of multiple forms (active and inactive) of PikAIV, and decreased efficiency of elongation by PikAIV can result in increased levels of 10-deoxymethynolide. These results provide new insight into functional molecular interactions and interdomain recognition in modular PKSs.     

Biochemical and structural characterization of germicidin synthase: analysis of a type III polyketide synthase that employs acyl-ACP as a starter unit donor

Germicidin synthase (Gcs) from Streptomyces coelicolor is a type III polyketide synthase (PKS) with broad substrate flexibility for acyl groups linked through a thioester bond to either coenzyme A (CoA) or acyl carrier protein (ACP). Germicidin synthesis was reconstituted in vitro by coupling Gcs with fatty acid biosynthesis. Since Gcs has broad substrate flexibility, we directly compared the kinetic properties of Gcs with both acyl-ACP and acyl-CoA. The catalytic efficiency of Gcs for acyl-ACP was 10-fold higher than for acyl-CoA, suggesting a strong preference toward carrier protein starter unit transfer. The 2.9 ? germicidin synthase crystal structure revealed canonical type III PKS architecture along with an unusual helical bundle of unknown function that appears to extend the dimerization interface. A pair of arginine residues adjacent to the active site affect catalytic activity but not ACP binding. This investigation provides new and surprising information about the interactions between type III PKSs and ACPs that will facilitate the construction of engineered systems for production of novel polyketides.     

Heterologous expression, purification, reconstitution and kinetic analysis of an extended type II polyketide synthase.

BACKGROUND: Polyketide synthases (PKSs) are bacterial multienzyme systems that synthesize a broad range of natural products. The 'minimal' PKS consists of a ketosynthase, a chain length factor, an acyl carrier protein and a malonyl transferase. Auxiliary components (ketoreductases, aromatases and cyclases are involved in controlling the oxidation level and cyclization of the nascent polyketide chain. We describe the heterologous expression and reconstitution of several auxiliary PKS components including the actinorhodin ketoreductase (act KR), the griseusin aromatase/cyclase (gris ARO/CYC), and the tetracenomycin aromatase/cyclase (tcm ARO/CYC). RESULTS: The polyketide products of reconstituted act and tcm PKSs were identical to those identified in previous in vivo studies. Although stable protein-protein interactions were not detected between minimal and auxiliary PKS components, kinetic analysis revealed that the extended PKS comprised of the act minimal PKS, the act KR and the gris ARO/CYC had a higher turnover number than the act minimal PKS plus the act KR or the act minimal PKS alone. Adding the tcm ARO/CYC to the tcm minimal PKS also increased the overall rate. CONCLUSIONS: Until recently the principal strategy for functional analysis of PKS subunits was through heterologous expression of recombinant PKSs in Streptomyces. Our results corroborate the implicit assumption that the product isolated from whole-cell systems is the dominant product of the PKS. They also suggest that an intermediate is channeled between the various subunits, and pave the way for more detailed structural and mechanistic analysis of these multienzyme systems.     

Enzymatic extender unit generation for in vitro polyketide synthase reactions: structural and functional showcasing of Streptomyces coelicolor MatB

In vitro experiments with modular polyketide synthases (PKSs) are often limited by the availability of polyketide extender units. To determine the polyketide extender units that can be biocatalytically accessed via promiscuous malonyl-CoA ligases, structural and functional studies were conducted on Streptomyces coelicolor MatB. We demonstrate that this adenylate-forming enzyme is capable of producing most CoA-linked polyketide extender units as well as pantetheine- and N-acetylcysteamine-linked analogs useful for in?vitro PKS studies. Two ternary product complex structures, one containing malonyl-CoA and AMP and the other containing (2R)-methylmalonyl-CoA and AMP, were solved to 1.45?? and 1.43?? resolution, respectively. MatB crystallized in the thioester-forming conformation, making extensive interactions with the bound extender unit products. This first structural characterization of an adenylate-forming enzyme that activates diacids reveals the molecular details for how malonate and its derivatives are accepted. The orientation of the α-methyl group of bound (2R)-methylmalonyl-CoA, indicates that it is necessary to epimerize α-substituted extender units formed by MatB before they can be accepted by PKS acyltransferase domains. We demonstrate the in?vitro incorporation of methylmalonyl groups ligated by MatB to CoA, pantetheine, or N-acetylcysteamine into a triketide pyrone by the terminal module of the 6-deoxyerythronolide B synthase. Additionally, a means for quantitatively monitoring certain in?vitro PKS reactions using MatB is presented.     

Redirecting the cyclization steps of fungal polyketide synthase

Regiospecific cyclizations of the nascent poly-beta-ketone backbones dictate the structures of polyketide natural products. The fungal iterative megasynthases use terminal thioesterase/claisen cyclase (TE/CLC) domains to direct the fate of the polyketide chains. In this work, we present two strategies toward redirecting the cyclization steps of fungal PKSs using the Gibberella fujikuroi PKS4. First, inactivation or removal of the TE/CLC domain resulted in the synthesis of the new polyketide SMA93 2. Complementation of the mutant PKS4 with a standalone TE/CLC domain restored the regioselective cyclization steps of PKS4 and led to the synthesis of SMA76 1, demonstrating that cyclization enzymes can interact with the megasynthase in trans. This led to the second approach in which various dissociated, bacterial tailoring enzymes were added to the megasynthase in trans. Addition of the act KR led to the synthesis of mutactin 3, while the addition of first ring and second ring cyclases yielded anthraquinone compounds DMAC 5 and SEK26 6. The cooperative activities of fungal and bacterial PKS components are especially important and enable synthesis of polyketides utilizing enzymes from two distinct families of PKSs.     

Molecular basis of Celmer's rules: stereochemistry of catalysis by isolated ketoreductase domains from modular polyketide synthases

A system is reported for the recombinant expression of individual ketoreductase (KR) domains from modular polyketide synthases (PKSs) and scrutiny of their intrinsic specificity and stereospecificity toward surrogate diketide substrates. The eryKR(1) and the tylKR(1) domains, derived from the first extension module of the erythromycin PKS and the tylosin PKS, respectively, both catalyzed reduction of (2R, S)-2-methyl-3-oxopentanoic acid N-acetylcysteamine thioester, with complete stereoselectivity and stereospecificity, even though the substrate is not tethered to an acyl carrier protein or an intact PKS multienzyme. In contrast, and to varying degrees, the isolated enzymes eryKR(2), eryKR(5), and eryKR(6) exercised poorer control over substrate selection and the stereochemical course of ketoreduction. These data, together with modeling of diketide binding to KR(1) and KR(2), demonstrate the fine energetic balance between alternative modes of presentation of ketoacylthioester substrates to KR active sites.     

Genome Mining of Oxidation Modules in trans‐Acyltransferase Polyketide Synthases Reveals a Culturable Source for Lobatamides

Bacterial trans‐acyltransferase polyketide synthases (trans‐AT PKSs) are multimodular megaenzymes that biosynthesize many bioactive natural products. They contain a remarkable range of domains and module types that introduce different substituents into growing polyketide chains. As one such modification, we recently reported Baeyer–Villiger‐type oxygen insertion into nascent polyketide backbones, thereby generating malonyl thioester intermediates. In this work, genome mining focusing on architecturally diverse oxidation modules in trans‐AT PKSs led us to the culturable plant symbiont Gynuella sunshinyii, which harbors two distinct modules in one orphan PKS. The PKS product was revealed to be lobatamide A, a potent cytotoxin previously only known from a marine tunicate. Biochemical studies show that one module generates glycolyl thioester intermediates, while the other is proposed to be involved in oxime formation. The data suggest varied roles of oxygenation modules in the biosynthesis of polyketide scaffolds and support the importance of trans‐AT PKSs in the specialized metabolism of symbiotic bacteria.     

Identification of Claisen cyclase domain in fungal polyketide synthase WA, a naphthopyrone synthase of Aspergillus nidulans

BACKGROUND: Based on the homology with fatty acid synthases and bacterial polyketide synthases (PKSs), thioesterase domains have been assigned at the C-terminus regions of fungal iterative type I PKSs. We previously overexpressed Aspergillus nidulans wA PKS gene in a heterologous fungal host and identified it to encode a heptaketide naphthopyrone synthase. In addition, expression of C-terminus-modified WA PKS gave heptaketide isocoumarins suggesting that the C-terminus region of WA PKS is involved in the cyclization of the second aromatic ring of naphthopyrone. To unravel the actual function of the C-terminus region, we carried out functional analysis of WA PKS mutants by C-terminus deletion and site-directed mutagenesis. RESULTS: Only the 32 amino acid deletion from the C-terminus of WA PKS caused product change to heptaketide isocoumarins from heptaketide naphthopyrone, YWA1 1, a product of intact WA PKS. Further C-terminus deletion mutant of WA PKS up to Ser(1967), an active site residue of so far called thioesterase, still produced isocoumarins. Site-directed mutagenesis of amino acid residues in this C-terminus region showed that even a single mutation of S1967A or H2129Q caused production of isocoumarin instead of naphthopyrone. Furthermore, the role of tandem acyl carrier proteins (ACPs), a typical feature of fungal aromatic PKSs, was examined by site-directed mutagenesis and the results indicated that both ACPs can function as ACP independently. CONCLUSIONS: Claisen-type cyclization is assumed to be involved in formation of aromatic compounds by some fungal type I PKSs. These PKSs have a quite identical architecture of active site domain organization, beta-ketoacyl synthase, acyltransferase, tandem ACPs and thioesterase (TE) domains. Since the C-terminus region of WA PKS of this type was determined to be involved in Claisen-type cyclization of the second ring of naphthopyrone, we propose that the so far called TE of these PKSs work not just as TE but as Claisen cyclase.     

Iterative type II polyketide synthases,cyclases and ketoreductases exhibit context-dependent behavior in the biosynthesis of linear and angular decapolyketides

Background: Iterative type II polyketide synthases (PKSs) produce polyketide chains of variable but defined length from a specific starter unit and a number of extender units. They also specify the initial regiospecific folding and cyclization pattern of nascent polyketides either through the action of a cyclase (CYC) subunit or through the combined action of site-specific ketoreductase (KR) CYC CYC subunits. Additional CYCs and other modifications may be necessary to produce linear aromatic polyketides. The principles of the assembly of the linear aromatic polyketides, several of which are medically important, are well understood, but it is not clear whether the assembly of the angular aromatic (angucyclic) polyketides follows the same rules.Results: We performed an in vivo evaluation of the subunits of the PKS responsible for the production of the angucyclic polyketide jadomycin (jad), in comparison with their counterparts from the daunorubicin (dps) and tetracenomycin (tcm) PKSs which produce linear aromatic polyketides. No matter which minimal PKS was used to produce the initial polyketide chain, the JadD and DpsF CYCs produced the same two polyketides, in the same ratio; neither product was angularly fused. The set of jadABCED PKS plus putative jadl CYC genes behaved similarly. Furthermore, no angular polyketides were isolated when the entire set of jad PKS enzymes and Jadl or the jad minimal PKS, Jadl and the TcmN CYC were present. The DpsE KR was able to reduce decaketides but not octaketides; in contrast, the KRs from the jad PKS (JadE) or the actinorhodin PKS (ActIII) could reduce octaketide chains, giving three distinct products.Conclusions: It appears that the biosynthesis of angucyclic polyketides cannot be simply accomplished by expressing the known PKS subunits from artificial gene cassettes under the control of a non-native promoter. The characteristic structure of the angucycline ring system may arise from a kinked precursor during later cyclization reactions involving additional, but so far unknown, components of the extended decaketide PKS. Our results also suggest that some KRs have a minimal chain length requirement and that CYC enzymes may act aberrantly as first-ring aromatases that are unable to perform all of the sequential cyclization steps. Both of these characteristics may limit the widespread application of CYC or KR enzymes in the synthesis of novel polyketides.     

A Polyketide Synthase Component for Oxygen Insertion into Polyketide Backbones

Enzymatic core components from trans‐acyltransferase polyketide synthases (trans‐AT PKSs) catalyze exceptionally diverse biosynthetic transformations to generate structurally complex bioactive compounds. Here we focus on a group of oxygenases identified in various trans‐AT PKS pathways, including those for pederin, oocydins, and toblerols. Using the oocydin pathway homologue (OocK) from Serratia plymuthica 4Rx13 and N‐acetylcysteamine (SNAC) thioesters as test surrogates for acyl carrier protein (ACP)‐tethered intermediates, we show that the enzyme inserts oxygen into β‐ketoacyl moieties to yield malonyl ester SNAC products. Based on these data and the identification of a non‐hydrolyzed oocydin congener with retained ester moiety, we propose a unified biosynthetic pathway of oocydins, haterumalides, and biselides. By providing access to internal ester, carboxylate pseudostarter, and terminal hydroxyl functions, oxygen insertion into polyketide backbones greatly expands the biosynthetic scope of PKSs.     

Role of type II thioesterases: evidence for removal of short acyl chains produced by aberrant decarboxylation of chain extender units

BACKGROUND: Modular polyketide synthases (PKSs) function as molecular assembly lines in which polyketide chains are assembled by successive addition of chain extension units. At the end of the assembly line, there is usually a covalently linked type I thioesterase domain (TE I), which is responsible for release of the completed acyl chain from its covalent link to the synthase. Additionally, some PKS clusters contain a second thioesterase gene (TE II) for which there is no established role. Disruption of the TE II genes from several PKS clusters has shown that the TE II plays an important role in maintaining normal levels of antibiotic production. It has been suggested that the TE II fulfils this role by removing aberrant intermediates that might otherwise block the PKS complex. RESULS: We show that recombinant tylosin TE II behaves in vitro as a TE towards a variety of N-acetylcysteamine and p-nitrophenyl esters. The trends of hydrolytic activity determined by the kinetic parameter k(cat)/K(M) for the analogues tested indicates that simple fatty acyl chains are effective substrates. Analogues that modelled aberrant forms of putative tylosin biosynthetic intermediates were hydrolysed at low rates. CONCLUSIONS: The behaviour of tylosin TE II in vitro is consistent with its proposed role as an editing enzyme. Aberrant decarboxylation of a malonate-derived moiety attached to an acyl carrier protein (ACP) domain may generate an acetate, propionate or butyrate residue on the ACP thiol. Our results suggest that removal of such groups is a significant role of TE II.     

Structural and Biochemical Analysis of Protein–Protein Interactions Between the Acyl‐Carrier Protein and Product Template Domain

In fungal non‐reducing polyketide synthases (NR‐PKS) the acyl‐carrier protein (ACP) carries the growing polyketide intermediate through iterative rounds of elongation, cyclization and product release. This process occurs through a controlled, yet enigmatic coordination of the ACP with its partner enzymes. The transient nature of ACP interactions with these catalytic domains imposes a major obstacle for investigation of the influence of protein–protein interactions on polyketide product outcome. To further our understanding about how the ACP interacts with the product template (PT) domain that catalyzes polyketide cyclization, we developed the first mechanism‐based crosslinkers for NR‐PKSs. Through in vitro assays, in silico docking and bioinformatics, ACP residues involved in ACP–PT recognition were identified. We used this information to improve ACP compatibility with non‐cognate PT domains, which resulted in the first gain‐of‐function ACP with improved interactions with its partner enzymes. This advance will aid in future combinatorial biosynthesis of new polyketides.