Molecular recognition of diketide substrates by a beta-ketoacyl-acyl carrier protein synthase domain within a bimodular polyketide synthase

Insights into β-ketoacyl-chain recognition for β-ketoacyl-ACP utilizing AHL synthases

Beta-ketoacyl-ACP utilizing enzymes in fatty acid, polyketide and acyl-homoserine lactone biosynthetic pathways are important targets for developing antimicrobial, anticancer and antiparasitic compounds. Published reports on successful isolation of beta-ketoacyl-ACPs in a laboratory remain scarce to date and thus most beta-ketoacyl-ACP utilizing enzymes are routinely characterized using small molecule substrates in lieu of the bonafide 3-oxoacyl-ACPs. We report the systematic investigation into the electronic, geometric and spatial aspects of beta-ketoacyl-chain recognition to develop 3-oxoacyl-ACP substrate mimics for two beta-ketoacyl-ACP utilizing quorum signal synthases.

Broadening substrate specificity of a chain-extending ketosynthase through a single active-site mutation

An in vitro model system based on a ketosynthase domain of the erythromycin polyketide synthase was used to probe the apparent substrate tolerance of ketosynthase domains of the mycolactone polyketide synthase.

Coupled methyl group epimerization and reduction by polyketide synthase ketoreductase domains. Ketoreductase-catalyzed equilibrium isotope exchange

Incubation of [2-(2)H]-(2S,3R)-2-methyl-3-hydroxypentanoyl-SACP ([2-(2)H]-1a) with the epimerizing ketoreductase domain EryKR1 in the presence of a catalytic amount NADP(+) (0.05 equiv) resulted in time- and cofactor-dependent washout of deuterium from 1a, as a result of equilibrium isotope exchange of transiently generated [2-(2)H]-2-methyl-3-ketopentanoyl-ACP. Incubations of [2-(2)H]-(2S,3S)-2-methyl-3-hydroxy-pentanoyl-SACP with RifKR7 and with NysKR1 also resulted in time-dependent loss of deuterium. By contrast, incubations of [2-(2)H]-(2R,3S)-2-methyl-3-hydroxypentanoyl-SACP and [2-(2)H]-(2R,3R)-2-methyl-3-hydroxypentanoyl-SACP with the non-epimerizing ketoreductase domains EryKR6 and TylKR1, respectively, did not result in any significant washout of deuterium. The isotope exchange assay directly establishes that specific polyketide synthase ketoreductase domains also have an intrinsic epimerase activity, thus enabling mechanistic analysis of a key determinant of polyketide stereocomplexity.

Combinatorial biosynthesis of polyketides--a perspective

Since their discovery, polyketide synthases have been attractive targets of biosynthetic engineering to make 'unnatural' natural products. Although combinatorial biosynthesis has made encouraging advances over the past two decades, the field remains in its infancy. In this enzyme-centric perspective, we discuss the scientific and technological challenges that could accelerate the adoption of combinatorial biosynthesis as a method of choice for the preparation of encoded libraries of bioactive small molecules. Borrowing a page from the protein structure prediction community, we propose a periodic challenge program to vet the most promising methods in the field, and to foster the collective development of useful tools and algorithms.

Origin of the allyl group in FK506 biosynthesis

FK506 (tacrolimus) is a secondary metabolite with a potent immunosuppressive activity, currently registered for use as immunosuppressant after organ transplantation. FK506 and FK520 are biogenetically related natural products that are synthesized by combined polyketide synthase/nonribosomal peptide synthetase systems. The entire gene cluster for biosynthesis of FK520 from Streptomyces hygroscopicus var. ascomyceticus has been cloned and sequenced. On the other hand, the FK506 gene cluster from Streptomyces sp. MA6548 (ATCC55098) was sequenced only partially, and it was reasonable to expect that additional genes would be required for the provision of substrate supply. Here we report the identification of a previously unknown region of the FK506 gene cluster from Streptomyces tsukubaensis NRRL 18488 containing genes encoding the provision of unusual building blocks for FK506 biosynthesis as well as a regulatory gene. Among others, we identified a group of genes encoding biosynthesis of the extender unit that forms the allyl group at carbon 21 of FK506. Interestingly, we have identified a small independent diketide synthase system involved in the biosynthesis of the allyl group. Inactivation of one of these genes, encoding an unusual ketosynthase domain, resulted in an FK506 nonproducing strain, and the production was restored when a synthetic analog of the allylmalonyl-CoA extender unit was added to the cultivation medium. Based on our results, we propose a biosynthetic pathway for the provision of an unusual five-carbon extender unit, which is carried out by a novel diketide synthase complex.

Revisiting the modularity of modular polyketide synthases

Modularity is a highly sought after feature in engineering design. A modular catalyst is a multi-component system whose parts can be predictably interchanged for functional flexibility and variety. Nearly two decades after the discovery of the first modular polyketide synthase (PKS), we critically assess PKS modularity in the face of a growing body of atomic structural and in vitro biochemical investigations. Both the architectural modularity and the functional modularity of this family of enzymatic assembly lines are reviewed, and the fundamental challenges that lie ahead for the rational exploitation of their full biosynthetic potential are discussed.

Precursor-directed biosynthesis of 6-deoxyerythronolide B analogues is improved by removal of the initial catalytic sites of the polyketide synthase

Precursor-directed biosynthesis has been shown to be a powerful tool for the production of polyketide analogues that would be difficult or cost prohibitive to produce from medicinal chemistry efforts alone. It has been most extensively demonstrated using a KS1 null mutation (KS1(0)) to block the first round of condensation in the biosynthesis of the erythromycin polyketide synthase (DEBS) for the production of analogues of its aglycone, 6-deoxyerythronolide B (6-dEB). Here we show that removing the DEBS loading domain and first module (mod1Delta), rather than using the KS1(0) system, can lead to an increase in the utilization of some chemical precursors and production of 6-dEB analogues (R-6dEB) in both Streptomyces coelicolor and Saccharopolyspora erythraea. While the difference in utilization of the precursor was diketide specific, in strains fed (2R*, 3S*)-5-fluoro-3-hydroxy-2-methylpentanoate N-propionylcysteamine thioester, twofold increases in both utilization of the diketide and 15-fluoro-6dEB (15F-6dEB) production were observed in S. coelicolor, and S. erythraea exhibited a tenfold increase in production of 15-fluoro-erythromycin when utilizing the mod1Delta rather than the KS1(0) system.

Amplification of DNA encoding entire type I polyketide synthase domains and linkers from streptomyces species

Polyketides are a group of bioactive compounds from bacteria, plants, and fungi. To increase the availability of analogs for testing, the active sites of polyketide synthases are often substituted with homologous domains having altered substrate specificities. This study reports the design of polymerase chain reaction primers that enables isolation of entire active site domains from type I polyketide synthases with native interdomain linkers. This bypasses the need for further genetic screening to obtain functional units for use in genetic engineering. This is especially important in bioprospecting projects exploring new environments for bioresources.

Chemobiosynthesis of novel 6-deoxyerythronolide B analogues by mutation of the loading module of 6-deoxyerythronolide B synthase 1

Chemobiosynthesis (J. R. Jacobsen, C. R. Hutchinson, D. E. Cane, and C. Khosla, Science 277:367-369, 1997) is an important route for the production of polyketide analogues and has been used extensively for the production of analogues of 6-deoxyerythronolide B (6-dEB). Here we describe a new route for chemobiosynthesis using a version of 6-deoxyerythronolide B synthase (DEBS) that lacks the loading module. When the engineered DEBS was expressed in both Escherichia coli and Streptomyces coelicolor and fed a variety of acyl-thioesters, several novel 15-R-6-dEB analogues were produced. The simpler "monoketide" acyl-thioester substrates required for this route of 15-R-6-dEB chemobiosynthesis allow greater flexibility and provide a cost-effective alternative to diketide-thioester feeding to DEBS KS1(o) for the production of 15-R-6-dEB analogues. Moreover, the facile synthesis of the monoketide acyl-thioesters allowed investigation of alternative thioester carriers. Several alternatives to N-acetyl cysteamine were found to work efficiently, and one of these, methyl thioglycolate, was verified as a productive thioester carrier for mono- and diketide feeding in both E. coli and S. coelicolor.

Combinatorial polyketide biosynthesis by de novo design and rearrangement of modular polyketide synthase genes

Type I polyketide synthase (PKS) genes consist of modules approximately 3-6 kb long, which encode the structures of 2-carbon units in polyketide products. Alteration or replacement of individual PKS modules can lead to the biosynthesis of 'unnatural' natural products but existing techniques for this are time consuming. Here we describe a generic approach to the design of synthetic PKS genes where facile cassette assembly and interchange of modules and domains are facilitated by a repeated set of flanking restriction sites. To test the feasibility of this approach, we synthesized 14 modules from eight PKS clusters and associated them in 154 bimodular combinations spanning over 1.5-million bp of novel PKS gene sequences. Nearly half the combinations successfully mediated the biosynthesis of a polyketide in Escherichia coli, and all individual modules participated in productive bimodular combinations. This work provides a truly combinatorial approach for the production of polyketides.

Towards engineered polyketides

Rapid advances have been made over the past 10 years in the identification of the biosynthetic machinery that carries out the biosynthesis of polyketide natural products. Many such compounds are used in various therapeutic areas, including antibacterials, anticancer, antifungals and cholesterol lowering. It is now possible to alter the biosynthetic machinery to produce radically altered structural analogues that are not accessible by conventional technologies, such as total synthesis or semi synthesis. The most rapid progress has been achieved in the antibiotic field through the production of a large number of novel erythromycins.

Biochemical Investigation of Pikromycin Biosynthesis Employing Native Penta- and Hexaketide Chain Elongation Intermediates

The unique ability of the pikromycin (Pik) polyketide synthase to generate 12- and 14-membered ring macrolactones presents an opportunity to explore the fundamental processes underlying polyketide synthesis, specifically the mechanistic details of chain extension, keto group processing, acyl chain release, and macrocyclization. We have synthesized the natural pentaketide and hexaketide chain elongation intermediates as N-acetyl cysteamine (NAC) thioesters and have used them as substrates for in vitro conversions with engineered PikAIII+TE and in combination with native PikAIII (module 5) and PikAIV (module 6) multifunctional proteins. This investigation demonstrates directly the remarkable ability of these monomodules to catalyze one or two chain extension reactions, keto group processing steps, acyl-ACP release, and cyclization to generate 10-deoxymethynolide and narbonolide. The results reveal the enormous preference of Pik monomodules for their natural polyketide substrates and provide an important comparative analysis with previous studies using unnatural diketide NAC thioester substrates.

The enzymology of combinatorial biosynthesis

Combinatorial biosynthesis involves the genetic manipulation of natural product biosynthetic enzymes to produce potential new drug candidates that would otherwise be difficult to obtain. In either a theoretical or practical sense, the number of combinations possible from different types of natural product pathways ranges widely. Enzymes that have been the most amenable to this technology synthesize the polyketides, nonribosomal peptides, and hybrids of the two. The number of polyketide or peptide natural products theoretically possible is huge, but considerable work remains before these large numbers can be realized. Nevertheless, many analogs have been created by this technology, providing useful structure-activity relationship data and leading to a few compounds that may reach the clinic in the next few years. In this review the focus is on recent advances in our understanding of how different enzymes for natural product biosynthesis can be used successfully in this technology.

Substrate recognition and channeling of monomodules from the pikromycin polyketide synthase

The unique ability of the pikromycin (Pik) polyketide synthase to generate 12- and 14-membered ring macrolactones presents an opportunity to explore the fundamental processes underlying polyketide synthesis, specifically the mechanistic details of the chain extension process. We have overexpressed and purified PikAIII (module 5) and PikAIV (module 6) and assessed the ability of these proteins to generate tri- and tetraketide lactone products using N-acetylcysteamine-activated diketides and (14)C-methylmalonyl-CoA as substrates. Comparison of the stereochemical specificities for PikAIII and PikAIV and the reported values for the DEBS modules reveals significant differences between these systems.

Expression and kinetic analysis of the substrate specificity of modules 5 and 6 of the picromycin/methymycin polyketide synthase

Picromycin synthase (PICS) is a multifunctional, modular polyketide synthase (PKS) that catalyzes the conversion of methylmalonyl-CoA to narbonolide and 10-deoxymethynolide, the macrolide aglycone precursors of the antibiotics picromycin and methymycin, respectively. PICS modules 5 and 6 were each expressed in Escherichia coli with a thioesterase domain at the C-terminus to allow release of polyketide products. The substrate specificity of PICS modules 5+TE and 6+TE was investigated using N-acetylcysteamine thioesters of 2-methyl-3-hydroxy-pentanoic acid as diketide analogues of the natural polyketide chain elongation substrates. PICS module 5+TE could catalyze the chain elongation of only the syn diketide (2S,3R)-4, while PICS module 6+TE processed both syn diastereomers, (2S,3R)-4 and (2R,3S)-5, with a 2.5:1 preference in k(cat)/K(m) for 5 but did not turn over either of the two anti diketides. The observed substrate specificity patterns are in contrast to the 15-100:1 preference for 4 over 5 previously established for several modules of the closely related erythromycin PKS, 6-deoxyerythronolide B synthase (DEBS).

Intermodular communication in modular polyketide synthases: structural and mutational analysis of linker mediated protein-protein recognition

Modular polyketide synthases (PKSs) present an attractive scaffold for the engineered biosynthesis of novel polyketide products via recombination of naturally occurring enzyme modules with desired catalytic properties. Recent studies have highlighted the pivotal role of short intermodular "linker pairs" in the selective channeling of biosynthetic intermediates between adjacent PKS modules. Using a combination of computer modeling, NMR spectroscopy, cross-linking, and site-directed mutagenesis, we have investigated the mechanism by which a linker pair from the 6-deoxyerythronolide B synthase promotes chain transfer. Our studies support a "coiled-coil" model in which the individual peptides comprising this linker pair adopt helical conformations that associate through a combination of hydrophobic and electrostatic interactions in an antiparallel fashion. Given the important contribution of such linker pair interactions to the kinetics of chain transfer between PKS modules, the ability to rationally modulate linker pair affinity by site-directed mutagenesis could be useful in the construction of optimized hybrid PKSs.

Precursor-directed biosynthesis: biochemical basis of the remarkable selectivity of the erythromycin polyketide synthase toward unsaturated triketides

The structural basis for the striking stereochemical discrimination among triketide analogs has been investigated by incubating a series of N-acetyl cysteamine (-SNAC) esters of unsaturated triketides with DEBS module 2+TE. The triketide analogs were first screened under a standard set of short-term incubation conditions in the presence of the extender substrate methylmalonyl-CoA and NADPH. For those triketide analogs that served as substrates for module 2+TE, the relative specificity, represented by the k(cat)/K(M) values, was quantitated. Triketide diastereomers that were converted in precursor-directed biosynthesis experiments to unsaturated 16-membered ring macrolides by DEBS(KS1(0)) were good to excellent substrates for DEBS module 2+TE, whereas analogs that were converted to the 14-membered ring analogs of 10,11-dehydro-6-deoxyerythronolide B by DEBS(KS1(0)) were not turned over at all by module 2+TE.

Tolerance and specificity of polyketide synthases

Polyketide synthases catalyze the assembly of complex natural products from simple precursors such as propionyl-CoA and methylmalonyl-CoA in a biosynthetic process that closely parallels fatty acid biosynthesis. Like fatty acids, polyketides are assembled by successive decarboxylative condensations of simple precursors. But whereas the intermediates in fatty acid biosynthesis are fully reduced to generate unfunctionalized alkyl chains, the intermediates in polyketide biosynthesis may be only partially processed, giving rise to complex patterns of functional groups. Additional complexity arises from the use of different starter and chain extension substrates, the generation of chiral centers, and further functional group modifications, such as cyclizations. The structural and functional modularity of these multienzyme systems has raised the possibility that polyketide biosynthetic pathways might be rationally reprogrammed by combinatorial manipulation. An essential prerequisite for harnessing this biosynthetic potential is a better understanding of the molecular recognition features of polyketide synthases. Within this decade, a variety of genetic, biochemical, and chemical investigations have yielded insights into the tolerance and specificity of several architecturally different polyketide synthases. The results of these studies, together with their implications for biosynthetic engineering, are summarized in this review.

Efficient purification and kinetic characterization of a bimodular derivative of the erythromycin polyketide synthase

Modular polyketide synthases (PKSs), such as the 6-deoxyerythronolide B synthase (DEBS), are giant multienzymes that biosynthesize a number of clinically important natural products. The modular nature of PKSs suggests the possibility of a combinatorial approach to the synthesis of novel bioactive polyketides, but the efficacy of such a strategy depends critically on gaining fundamental insight into PKS structure and function, most directly through experiments with purified PKS proteins. Several recent investigations into important aspects of the activity of these enzymes have used only partially purified proteins (often 3-4% of total protein), reflecting how difficult it is to purify these multienzymes in amounts adequate for kinetic and structural analysis. We report here the steady-state kinetic analysis of a typical bimodular PKS, 6-deoxyerythronolide B synthase 1-thioesterase (DEBS 1-TE), purified from recombinant Saccharopolyspora erythraea JCB101 by a new, high-yielding procedure consisting of three steps: ammonium sulfate precipitation, hydrophobic interaction chromatography and size-exclusion chromatography. The method provides 13-fold purification with a recovery of 11% of the applied PKS activity. The essentially homogeneous synthase exhibits an intrinsic methylmalonyl-CoA hydrolase activity, which competes with polyketide chain extension. The most reliable value for the kcat for synthesis of (3S,5R)-dihydroxy-(2R,4R)-dimethyl-n-heptanoic acid-delta-lactone is 0.84 min-1, and the apparent Km for (2RS)-methylmalonyl-CoA is 17 microM. This kcat is approximately 10-fold lower than the value reported previously for a differently engineered version of the truncated PKS, DEBS 1+TE. The difference likely reflects the fact that the DEBS 1-TE contains a hybrid acyl carrier protein (ACP) domain in its second module, which lowers its catalytic efficiency.

Structural elucidation studies of polyketide tetrasubstituted delta-lactones by gas chromatography/tandem mass spectrometry and electrospray mass spectrometry

A series of tetrasubstituted polyketide delta-lactones were used to evaluate whether gas chromatography/tandem mass spectrometry (GC/MS/MS) and electrospray mass spectrometry (ESI-MS) are useful techniques for probing the structure and stereochemistry of such highly functionalised molecules. Analyses were performed with two commercially available mass spectrometers: a Finnigan/MAT GCQ instrument (CI source) and a Q-TOF Hybrid quadrupole time-of-flight instrument (ESI source). The analyses revealed that a range of variation in the structure and stereochemistry of the lactones did not affect the fragmentation pathway common to these molecules. By accurate mass determination (ESI-MS), the first two fragmentations were assigned to losses of water. Although it was anticipated that the initial dehydration would include the hydroxyl group at the 3-position of the lactones, evidence from deuterium- and (18)O-labelling studies suggests that the losses of water instead involve the oxygen atoms in the ester bond. Attempts to identify further the structures of daughter ions by GC/MS/MS were complicated by extensive rearrangements and non-specific hydrogen/deuterium migrations within the lactones. Together, these results illustrate the limitations of mass spectrometry in the structural elucidation of complex molecules. Copyright 1999 John Wiley & Sons, Ltd.

Evaluating precursor-directed biosynthesis towards novel erythromycins through in vitro studies on a bimodular polyketide synthase

BACKGROUND

Modular polyketide synthases (PKSs) catalyse the biosynthesis of complex polyketides using a different set of enzymes for each successive cycle of chain extension. Directed biosynthesis starting from synthetic diketides is a potentially valuable route to novel polyketides. We have used a purified bimodular derivative of the erythromycin-producing polyketide synthase (DEBS 1-TE) to study chain extension starting from a variety of diketide analogues and, in some cases, from the alternative acyl-CoA thioester substrates.

RESULTS

Chain initiation in vitro by DEBS 1-TE module 2 using a synthetic diketide analogue as a substrate was tolerant of significant structural variation in the starter unit of the synthetic diketide, but other changes completely abolished activity. Interestingly, a racemic beta-keto diketide was found to be reduced in situ on the PKS and utilised in place of its more complex hydroxy analogue as a substrate for chain extension. The presence of a diketide analogue strongly inhibited chain initiation via the loading module. Significantly higher concentrations of diketide N-acetylcysteamine analogues than their corresponding acyl-CoA thioesters are required to achieve comparable yields of triketide lactones.

CONCLUSIONS

Although a broad range of variation in the starter residue is acceptable, the substrate specificity of module 2 of a typical modular PKS in vitro is relatively intolerant of changes at C-2 and C-3. This will restrict the usefulness of approaches to synthesise novel erythromycins using synthetic diketides in vivo. The use of synthetic beta-keto diketides in vivo deserves to be explored.

Combinatorial biosynthesis for new drug discovery

Combinatorial biosynthesis involves interchanging secondary metabolism genes between antibiotic-producing microorganisms to create unnatural gene combinations or hybrid genes if only part of a gene is exchanged. Novel metabolites can be made by both approaches, due to the effect of a new enzyme on a metabolic pathway or to the formation of proteins with new enzymatic properties. The method has been particularly successful with polyketide synthase (PKS) genes: derivatives of medically important macrolide antibiotics and unusual polycyclic aromatic compounds have been produced by novel combinations of the type I and type II PKS genes, respectively. Recent extensions of the approach to include deoxysugar biosynthesis genes have expanded the possibilities for making new microbial metabolites and discovering valuable drugs through the genetic engineering of bacteria.

Combinatorial biosynthesis of erythromycin and complex polyketides

Modular polyketide synthases that produce many clinically important natural products such as erythromycins and lovastatins have been engineered in many ways to produce novel natural products. The structural variations have included alterations to the substituents on the macrolide ring, including the starter acid residue, using either semi-synthetic methodology or genetic engineering. It is now also possible to produce shorter polyketide chains that are released either as lactone rings (6-, 8-, 12- and 14-membered rings) or linear products. The strategies for engineering polyketide synthases to produce specific natural products are now well established. Several of the macrolides produced recently have been elaborated to produce novel antibiotics.