Establishing a new methodology for genome mining and biosynthesis of polyketides and peptides through yeast molecular genetics

Fungal genome sequencing has revealed many genes coding for biosynthetic enzymes, including polyketide synthases and nonribosomal peptide synthetases. However, characterizing these enzymes and identifying the compounds they synthesize remains a challenge, whether the genes are expressed in their original hosts or in more tractable heterologous hosts, such as yeast. Here, we developed a streamlined method for isolating biosynthetic genes from fungal sources and producing bioactive molecules in an engineered Saccharomyces cerevisiae host strain. We used overlap extension PCR and yeast homologous recombination to clone desired fungal polyketide synthase or a nonribosomal peptide synthetase genes (5-20 kb) into a yeast expression vector quickly and efficiently. This approach was used successfully to clone five polyketide synthases and one nonribosomal peptide synthetase, from various fungal species. Subsequent detailed chemical characterizations of the resulting natural products identified six polyketide and two nonribosomal peptide products, one of which was a new compound. Our system should facilitate investigating uncharacterized fungal biosynthetic genes, identifying novel natural products, and rationally engineering biosynthetic pathways for the production of enzyme analogues possessing modified bioactivity.     

Current State-of-the-Art Toward Chemoenzymatic Synthesis of Polyketide Natural Products

Polyketide natural products have significant promise as pharmaceutical targets for human health and as molecular tools to probe disease and complex biological systems. While the biosynthetic logic of polyketide synthases (PKS) is well-understood, biosynthesis of designer polyketides remains challenging due to several bottlenecks, including substrate specificity constraints, disrupted protein-protein interactions, and protein solubility and folding issues. Focusing on substrate specificity, PKSs are typically interrogated using synthetic thioesters. PKS assembly lines and their products offer a wealth of information when studied in a chemoenzymatic fashion. This review provides an overview of the past two decades of polyketide chemoenzymatic synthesis and their contributions to the field of chemical biology. These synthetic strategies have successfully yielded natural product derivatives while providing critical insights into enzymatic promiscuity and mechanistic activity.     

Structure and biosynthesis of myxochromides S1-3 in Stigmatella aurantiaca: evidence for an iterative bacterial type I polyketide synthase and for module skipping in nonribosomal peptide biosynthesis

The myxobacterium Stigmatella aurantiaca DW4/3-1 harbours an astonishing variety of secondary metabolic gene clusters, at least two of which were found by gene inactivation experiments to be connected to the biosynthesis of previously unknown metabolites. In this study, we elucidate the structures of myxochromides S1-3, novel cyclic pentapeptide natural products possessing unsaturated polyketide side chains, and identify the corresponding biosynthetic gene locus, made up of six nonribosomal peptide synthetase modules. By analyzing the deduced substrate specificities of the adenylation domains, it is shown that module 4 is most probably skipped during the biosynthetic process. The polyketide synthase MchA harbours only one module and is presumably responsible for the formation of the variable complete polyketide side chains. These data indicate that MchA is responsible for an unusual iterative polyketide chain assembly.     

Synthetic Chain Terminators Off‐Load Intermediates from a Type I Polyketide Synthase

Modular biocatalysis is responsible for the generation of countless bioactive products and its mining remains a major focus for drug discovery purposes. One of the enduring hurdles is the isolation of biosynthetic intermediates in a readily‐analysed form. We prepared a series of nonhydrolysable pantetheine and N‐acetyl cysteamine mimics of the natural (methyl)malonyl extender units recruited for polyketide formation. Using these analogues as competitive substrates, we were able to trap and off‐load diketide and triketide species directly from an in vitro reconstituted type I polyketide synthase, the 6‐deoxyerythronolide B synthase 3 (DEBS3). The putative intermediates, which were extracted in organic solvent and characterised by LC‐HR‐ESI‐MS, are the first of their kind and prove that small‐molecule chain terminators can be used as convenient probes of the biosynthetic process.     

Bioactivity‐Guided Genome Mining Reveals the Lomaiviticin Biosynthetic Gene Cluster in Salinispora tropica

The use of genome sequences has become routine in guiding the discovery and identification of microbial natural products and their biosynthetic pathways. In silico prediction of molecular features, such as metabolic building blocks, physico‐chemical properties or biological functions, from orphan gene clusters has opened up the characterization of many new chemo‐ and genotypes in genome mining approaches. Here, we guided our genome mining of two predicted enediyne pathways in Salinispora tropica CNB‐440 by a DNA interference bioassay to isolate DNA‐targeting enediyne polyketides. An organic extract of S. tropica showed DNA‐interference activity that surprisingly was not abolished in genetic mutants of the targeted enediyne pathways, ST_pks1 and spo. Instead we showed that the product of the orphan type II polyketide synthase pathway, ST_pks2, is solely responsible for the DNA‐interfering activity of the parent strain. Subsequent comparative metabolic profiling revealed the lomaiviticins, glycosylated diazofluorene polyketides, as the ST_pks2 products. This study marks the first report of the 59 open reading frame lomaiviticin gene cluster (lom) and supports the biochemical logic of their dimeric construction through a pathway related to the kinamycin monomer.     

Involvement of β-Alkylation Machinery and Two Sets of Ketosynthase-Chain-Length Factors in the Biosynthesis of Fogacin Polyketides in Actinoplanes missouriensis

Fogacin and two novel fogacin derivatives, fogacins B and C, were isolated from the rare actinomycete Actinoplanes missouriensis. Biosynthesis of fogacin C apparently requires β alkylation of a polyketide chain. The fogacin biosynthetic type II polyketide synthase (PKS) gene cluster contains a hydroxymethylglutaryl-coenzyme A synthase (HCS) cassette, which is usually responsible for β alkylation in the type I PKS system. Another characteristic of the fog cluster is that it encodes two sets of ketosynthase (KS) and chain-length factor (CLF). Inactivation of either of the two KS genes in A. missouriensis and heterologous expression of the HCS cassette with either of the two KS-CLF genes in Streptomyces albus indicated that each KS-CLF had a different starter substrate specificity: one preferred an unusual β-alkylated starter and the other preferred a normal acetyl starter. This study expands knowledge of HCS cassette-dependent β alkylation into the type II PKS system and provides a natural example of combinatorial biosynthesis for producing diverse polyketides from different starter substrates.     

Characterization of an Orphan Type III Polyketide Synthase Conserved in Uncultivated “Entotheonella” Sponge Symbionts

Uncultivated bacterial symbionts from the candidate genus “Entotheonella” have been shown to produce diverse natural products previously attributed to their sponge hosts. In addition to these known compounds, “Entotheonella” genomes contain rich sets of biosynthetic gene clusters that lack identified natural products. Among these is a small type III polyketide synthase (PKS) cluster, one of only three clusters present in all known “Entotheonella” genomes. This conserved “Entotheonella” PKS (cep) cluster encodes the type III PKS CepA and the putative methyltransferase CepB. Herein, the characterization of CepA as an enzyme involved in phenolic lipid biosynthesis is reported. In vitro analysis showed a specificity for alkyl starter substrates and the production of tri- and tetraketide pyrones and tetraketide resorcinols. The conserved distribution of the cep cluster suggests an important role for the phenolic lipid polyketides produced in “Entotheonella” variants.     

Unveiling Two Consecutive Hydroxylations: Mechanisms of Aromatic Hydroxylations Catalyzed by Flavin-Dependent Monooxygenases for the Biosynthesis of Actinorhodin and Related Antibiotics

Flavin-dependent monooxygenases are ubiquitous in living systems and are classified into single- or two-component systems. Actinorhodin, produced by Streptomyces coelicolor, is a representative polycyclic polyketide that is hydroxylated through the action of the two-component ActVA-5/ActVB hydroxylase system. These homologous systems are widely distributed in bacteria, but their reaction mechanisms remain unclear. This in vitro investigation has provided chemical proof of two consecutive hydroxylations via hydroxynaphthalene intermediates involved in actinorhodin biosynthesis. The ActVA-5 oxygenase component catalyzed a stepwise dihydroxylation of the substrate, whereas the ActVB flavin reductase not only supplied a reduced cofactor, but also regulated the quinone–hydroquinone interconversion of an intermediate. Our study provides clues for understanding the general biosynthetic mechanisms of highly functionalized aromatic natural products with structural diversity.     

The chemical versatility of natural-product assembly lines

Microbial natural products of both polyketide and nonribosomal peptide origin have been and continue to be important therapeutic agents as antibiotics, immunosupressants, and antitumor drugs. Because the biosynthetic genes for these metabolites are clustered for coordinate regulation, the sequencing of bacterial genomes continues to reveal unanticipated biosynthetic capacity for novel natural products. The re-engineering of pathways for such secondary metabolites to make novel molecular variants will be enabled by understanding of the chemical logic and protein machinery in the producer microbes. This Account analyzes the chemical principles and molecular logic that allows simple primary metabolite building blocks to be converted to complex architectural scaffolds of polyketides (PK), nonribosomal peptides (NRP), and NRP-PK hybrids. The first guiding principle is that PK and NRP chains are assembled as thioseters tethered to phosphopantetheinyl arms of carrier proteins that serve as thiotemplates for chain elongation. The second principle is that gate keeper protein domains select distinct monomers to be activated and incorporated with positional specificity into the growing natural product chains. Chain growth is via thioclaisen condensations for PK and via amide bond formation for elongating NRP chains. Release of the full length acyl/peptidyl chains is mediated by thioesterases, some of which catalyze hydrolysis while others catalyze regiospecific macrocyclization to build in conformational constraints. Tailoring of PK and NRP chains, by acylation, alkylation, glycosylation, and oxidoreduction, occurs both during tethered chain growth and after thioesterase-mediated release. Analysis of the types of protein domains that carry out chain initiation, elongation, tailoring, and termination steps gives insight into how NRP and PK biosynthetic assembly lines can be redirected to make novel molecules.     

A type I/type III polyketide synthase hybrid biosynthetic pathway for the structurally unique ansa compound kendomycin

Kendomycin is a bioactive polyketide that is produced by various Streptomyces strains. It displays strong antibiotic activities against a wide range of bacteria and exhibits remarkable cytotoxic effects on the growth of several human cancer cell lines. In this study we cloned the corresponding biosynthetic locus from the producer Streptomyces violaceoruber (strain 3844-33C). Our analysis shows that a mixed type I/type III polyketide synthase pathway is responsible for the formation of the fully carbogenic macrocyclic scaffold of kendomycin, which is unprecedented among all of the ansa compounds that have been isolated so far. Heterologous expression of a gene set in Streptomyces coelicolor shows that 3,5-dihydroxybenzoic acid is an intermediate in the starter unit biosynthesis that is initiated by the type III polyketide synthase. The identification of the kendomycin biosynthetic gene cluster sets the stage to study a novel chain termination mechanism by a type I PKS that leads to carbocycle formation and provides the starting material for the heterologous expression of the entire pathway, and the production of novel derivatives by genetic engineering.     

In Vitro Investigation of Crosstalk between Fatty Acid and Polyketide Synthases in the Andrimid Biosynthetic Assembly Line

Andrimid (Adm) synthase, which belongs to the type II system of enzymes, produces Adm in Pantoea agglomerans. The adm biosynthetic gene cluster lacks canonical acyltransferases (ATs) to load the malonyl group to acyl carrier proteins (ACPs), thus suggesting that a malonyl‐CoA ACP transacylase (MCAT) from the fatty acid synthase (FAS) complex provides the essential AT activity in Adm biosynthesis. Here we report that an MCAT is essential for catalysis of the transacylation of malonate from malonyl‐CoA to AdmA polyketide synthase (PKS) ACP in vitro. Catalytic self‐malonylation of AdmA (PKS ACP) was not observed in reactions without MCAT, although many type II PKS ACPs are capable of catalyzing self‐acylation. This lack of self‐malonylation was explained by amino acid sequence analysis of the AdmA PKS ACP and the type II PKS ACPs. The results show that MCAT from the organism's FAS complex can provide the missing AT activity in trans, thus suggesting a protein–protein interaction between the fatty acid and polyketide synthases in the Adm assembly line.     

Identification and Characterization of the Cuevaene A Biosynthetic Gene Cluster in Streptomyces sp. LZ35

Genome sequence analysis of Streptomyces sp. LZ35 has revealed a large number of secondary metabolite pathways, including one encoded in an orphan type I polyketide synthase gene cluster that contains a putative chorismatase/3‐hydroxybenzoate synthase gene. Mutagenesis and comparative metabolic profiling led to the identification of cuevaene A as the metabolic product of the gene cluster, thus making it the first 3‐HBA containing polyketide biosynthetic gene cluster described to date. Cuv10 was proven to be responsible for the conversion of chorismate into 3‐HBA; Cuv18 is speculated to be responsible for the 6‐hydroxylation of 3‐HBA during polyketide chain elongation. Additionally, several pathway‐specific regulatory factors that affect the production of cuevaene A were identified. Our results indicate that targeted inactivation of a gene followed by comparative metabolic profiling is a useful approach to identify and characterize cryptic biosynthetic gene clusters.     

SorF: a glycosyltransferase with promiscuous donor substrate specificity in vitro

Glycosylations are well-established steps in numerous biosynthetic pathways, and the attached sugar moieties often influence the specificity or pharmacology of the modified compounds. The sorangicins belong to the polyketide family of natural products, and exhibit antibiotic activity through inhibition of bacterial RNA polymerase. We have identified the sorangicin biosynthetic gene cluster in the producing myxobacterium Sorangium cellulosum So ce12. Within the cluster, sorF encodes a putative glycosyltransferase. To determine its function in sorangicin biosynthesis, SorF was heterologously expressed as a fusion protein in Escherichia coli. After purification by affinity chromatography, SorF was found to glucosylate sorangicin A in vitro, utilizing UDP-alpha-D-glucose as the natural donor substrate. Additionally, SorF showed high flexibility towards further UDP- and dTDP-sugars and was able to transfer several other sugar moieties-alpha-D-galactose, alpha-D-xylose, beta-L-rhamnose, and 6-deoxy-4-keto-alpha-D-glucose-onto the aglycon. SorF is therefore one of the rare glycosyltransferases able to transfer both D- and L-sugars, and could thus be used to generate novel sorangiosides.     

Glyceryl-S-acyl carrier protein as an intermediate in the biosynthesis of tetronate antibiotics

The biosynthetic pathway to the unusual tetronate ring of certain polyketide natural products, including the antibiotics abyssomicin and tetronomycin (TMN) and the antitumour compound chlorothricin (CHL), is presently unknown. The gene clusters governing chlorothricin and tetronomycin biosynthesis both contain a gene encoding an atypical member of the FkbH family of enzymes, which has previously been shown to synthesise glyceryl-S-acyl carrier protein (ACP) as the first step in production of unusual extender units for modular polyketide biosynthesis. We show here that purified recombinant FkbH-like protein, Tmn16, from the TMN gene cluster catalyses the efficient transfer of a glyceryl moiety from D-1,3-bisphosphoglycerate (1,3-BPG) to either of the dedicated ACPs, Tmn7a and ChlD2, to form glyceryl-S-ACP, which directly implicates this compound as an intermediate in tetronate biosynthesis as well. Neither Tmn16 nor Tmn7a produced glyceryl-S-ACP when incubated, respectively, with analogous ACP and FkbH-like proteins from a known extender-unit pathway; this indicates a highly selective channelling of glycolytic metabolites into tetronate biosynthesis.     

Marine tannins: the importance of a mechanistic framework for predicting ecological roles

Since chemical ecology emerged as a field of marine science, it has been strongly influenced by studies of chemically mediated interactions in land-based systems. Marine chemical ecologists, like their terrestrial counterparts, initially focused on identifying natural products and evaluating the potential ecological roles of these products as defenses, attractants, or other cues. Now, like our land-based colleagues, we must increase our focus on the physiological and biochemical mechanisms that underlie the chemical interactions, paying particular attention to regulation of biosynthetic pathways, within-plant and between-plant signaling cues, and comparative and functional genomics. Here, we review the current state of knowledge regarding a heterogenous group of macrophyte natural products, the marine tannins and simple phenolics, to illustrate how such information is critical to future attempts to predict their ecological roles.     

Characterization of the Calicheamicin Orsellinate C2‐O‐Methyltransferase CalO6

Although bacterial iterative type I polyketide synthases are now known to participate in the biosynthesis of a small set of diverse natural products, the subsequent downstream modification of the resulting polyketide products is poorly understood. We report the functional characterization of the putative orsellinic acid C2‐O‐methyltransferase, which is involved in calicheamicin biosynthesis. This study suggests that C2‐O‐methylation precedes C3‐hydroxylation/methylation and C5‐iodination and requires a coenzyme A‐ or acyl carrier protein‐bound substrate.     

Substitution of Two Active‐Site Residues Alters C9‐Hydroxylation in a Class II Diterpene Synthase

Diterpenes form a vast and diverse class of natural products of both ecological and economic importance. Class II diterpene synthase (diTPS) enzymes control the committed biosynthetic reactions underlying diterpene chemical diversity. Homology modelling with site‐directed mutagenesis identified two active‐site residues in the horehound (Marrubium vulgare) class II diTPS peregrinol diphosphate synthase (MvCPS1); residue substitutions abolished the unique MvCPS1‐catalysed water‐capture reaction at C9 and redirected enzyme activity toward formation of an alternative product, halima‐5(10),13‐dienyl diphosphate. These findings contributed new insight into the steric interactions that govern diTPS‐catalysed regiospecific oxygenation reactions and highlight the feasibility of diTPS engineering to provide a broader spectrum of bioactive diterpene natural products.