Characterization of type II thioesterases involved in natamycin biosynthesis in Streptomyces chattanoogensis L10

The known functions of type II thioesterases (TEIIs) in type I polyketide synthases (PKSs) include selecting of starter acyl units, removal of aberrant extender acyl units, releasing of final products, and dehydration of polyketide intermediates. In this study, we characterized two TEIIs (ScnI and PKSIaTEII) from Streptomyces chattanoogensis L10. Deletion of scnI in S. chattanoogensis L10 decreased the natamycin production by about 43%. Both ScnI and PKSIaTEII could remove acyl units from the acyl carrier proteins (ACPs) involved in the natamycin biosynthesis. Our results show that the TEII could play important roles in both the initiation step and the elongation steps of a polyketide biosynthesis; the intracellular TEIIs involved in different biosynthetic pathways could complement each other.     

Diversity and evolution of polyketide biosynthesis gene clusters in the Ceratocystidaceae

Polyketides are secondary metabolites with diverse biological activities. Polyketide synthases (PKS) are often encoded from genes clustered in the same genomic region. Functional analyses and genomic studies show that most fungi are capable of producing a repertoire of polyketides. We considered the potential of Ceratocystidaceae for producing polyketides using a comparative genomics approach. Our aims were to identify the putative polyketide biosynthesis gene clusters, to characterize them and predict the types of polyketide compounds they might produce. We used sequences from nineteen species in the genera, Ceratocystis, Endoconidiophora, Davidsoniella, Huntiella, Thielaviopsis and Bretziella, to identify and characterize PKS gene clusters, by employing a range of bioinformatics and phylogenetic tools. We showed that the genomes contained putative clusters containing a non-reducing type I PKS and a type III PKS. Phylogenetic analyses suggested that these genes were already present in the ancestor of the Ceratocystidaceae. By contrast, the various reducing type I PKS-containing clusters identified in these genomes appeared to have distinct evolutionary origins. Although one of the identified clusters potentially allows for the production of melanin, their functional characterization will undoubtedly reveal many novel and important compounds implicated in the biology of the Ceratocystidaceae.     

Cloning and characterization of a bacterial iterative type I polyketide synthase gene encoding the 6-methylsalicyclic acid synthase

Unusual polyketide synthases (PKSs), that are structurally type I but act in an iterative manner for aromatic polyketide biosynthesis, are a new family found in bacteria. Here we report the cloning of the iterative type I PKS gene chlB1 from the chlorothricin (CHL) producer Streptomyces antibioticus DSM 40725 by a rapid PCR approach, and characterization of the function of the gene product as a 6-methylsalicyclic acid synthase (6-MSAS). Sequence analysis of various iterative type I PKSs suggests that the resulting aromatic or aliphatic structure of the products might be intrinsically determined by a catalytic feature of the paired KR-DH domains in the control of the double bond geometry. The finding of ChlB1 as a 6-MSAS not only enriches the current knowledge of aromatic polyketide biosynthesis in bacteria, but will also contribute to the generation of novel polyketide analogs via combinatorial biosynthesis with engineered PKSs.     

Organization of the biosynthetic gene cluster for the polyketide macrolide mycinamicin in Micromonospora griseorubida

Mycinamicin, composed of a branched lactone and two sugars, desosamine and mycinose, at the C-5 and C-21 positions, is a 16-membered macrolide antibiotic produced by Micromonospora griseorubida A11725, which shows strong antimicrobial activity against Gram-positive bacteria. The nucleotide sequence (62 kb) of the mycinamicin biosynthetic gene cluster, in which there were 22 open reading frames (ORFs), was completely determined. All of the products from the 22 ORFs are responsible for the biosynthesis of mycinamicin II and self-protection against the compounds synthesized. Central to the cluster is a polyketide synthase locus (mycA), which encodes a seven-module system comprised of five multifunctional proteins. Immediately downstream of mycA, there is a set of genes for desosamine biosynthesis (mydA-G and mycB). Moreover, mydH, whose product is responsible for the biosynthesis of mycinose, lies between mydA and B. On the other hand, eight ORFs were detected upstream of the mycinamicin PKS gene. The myrB, mycG, and mycF genes had already been characterized by Inouye et al. The other five ORFs (mycCI, mycCII, mydI, mycE, and mycD) lie between mycA1 and mycF, and these five genes and mycF are responsible for the biosynthesis of mycinose. In the PKS gene, four regions of KS and AT domains in modules 1, 4, 5, and 6 indicated that it does not show the high GC content typical for Streptomyces genes, nor the unusual frame plot patterns for Streptomyces genes. Methylmalonyl-CoA was used as substrate in the functional units of those four modules. The relationship between the substrate and the unusual frame plot pattern of the KS and AT domains was observed in the other PKS genes, and it is suggested that the KS-AT original region was horizontally transferred into the PKS genes on the chromosomal DNA of several actinomycetes strains.     

Phylogenetic analysis of type I polyketide synthase and nonribosomal peptide synthetase genes in Antarctic sediment

The modular polyketide synthase (PKS) and nonribosomal peptide synthetase (NRPS) have been found to be involved in natural product synthesis in many microorganisms. Study on their diversities in natural environment may provide important ecological insights, in addition to opportunities for antibacterial drugs development. In this study, the PKS and NRPS gene diversities in two coast sediments near China Zhongshan Station were studied. The phylogenetic analysis of amino acid (AA) sequences indicated that the identified ketosynthase (KS) domains were clustered with those from diverse bacterial groups, including Proteobacteria, Firmicutes, Planctomycetes, Cyanobacteria, Actinobacteria, and some uncultured symbiotic bacteria. One new branch belonging to hybrid PKS/NRPS enzyme complexes and five independent clades were found on the phylogenetic tree. The obtained adenylation (A) domains were mainly clustered within the Cyanobacteria and Proteobacteria group. Most of the identified KS and A domains showed below 80 and 60% identities at the AA level to their closest matches in GenBank, respectively. The diversities of both KS and A domains in natural environmental sample were different from those in sewage-contaminated sample. These results revealed the great diversity and novelty of both PKS and NRPS genes in Antarctic sediment.     

Characterization of two polyketide synthase genes in Exophiala lecanii-corni, a melanized fungus with bioremediation potential

Exophiala lecanii-corni has significant bioremediation potential because it can degrade a wide range of volatile organic compounds. In order to identify sites for the insertion of genes that might enhance this potential, a genetic analysis of E. lecanii-corni was undertaken. Two polyketide synthase genes, ElPKS1 and ElPKS2, have now been discovered by a PCR-based strategy. ElPKS1 was isolated by a marker rescue technique. The nucleotide sequence of ElPKS1 consists of a 6576-bp open reading frame encoding a protein with 2192 amino acids, which was interrupted by a 60-bp intron near the 5' end and a 54-bp intron near the 3' end. Sequence analysis, results from disruption experiments, and physiological tests showed that ElPKS1 encoded a polyketide synthase required for melanin biosynthesis. Since ElPKS1 is non-essential, it is a desirable bioengineering target site for the insertion of native and foreign genes. The successful expression of these genes could enhance the bioremediation capability of the organism. ElPKS2 was cloned by colony hybridization screening of a partial genomic library with an ElPKS2 PCR product. ElPKS2 had a 6465-bp open reading frame that encoded 2155 amino acids and had introns of 56, 67, 54, and 71 bp. Although sequence analysis of the derived protein of ElPKS2 confirmed the polyketide synthase nature of its protein product, the function of that product remains unclear.     

Redesign, synthesis and functional expression of the 6-deoxyerythronolide B polyketide synthase gene cluster

A generic design of Type I polyketide synthase genes has been reported in which modules, and domains within modules, are flanked by sets of unique restriction sites that are repeated in every module [1]. Using the universal design, we synthesized the six-module DEBS gene cluster optimized for codon usage in E. coli, and cloned the three open reading frames into three compatible expression vectors. With one correctable exception, the amino acid substitutions required for restriction site placements were compatible with polyketide production. When expressed in E. coli the codon-optimized synthetic gene cluster produced significantly more protein than did the wild-type sequence. Indeed, for optimal polyketide production, PKS expression had to be down-regulated by promoter attenuation to achieve balance with expression of the accessory proteins needed to support polyketide biosynthesis.     

A type III polyketide synthase from Wachendorfia thyrsiflora and its role in diarylheptanoid and phenylphenalenone biosynthesis

Chalcone synthase (CHS) related type III plant polyketide synthases (PKSs) are likely to be involved in the biosynthesis of diarylheptanoids (e.g. curcumin and polycyclic phenylphenalenones), but no such activity has been reported. Root cultures from Wachendorfia thyrsiflora (Haemodoraceae) are a suitable source to search for such enzymes because they synthesize large amounts of phenylphenalenones, but no other products that are known to require CHSs or related enzymes (e.g. flavonoids or stilbenes). A homology-based RT-PCR strategy led to the identification of cDNAs for a type III PKS sharing only approximately 60% identity with typical CHSs. It was named WtPKS1 (W. thyrsiflora polyketide synthase 1). The purified recombinant protein accepted a large variety of aromatic and aliphatic starter CoA esters, including phenylpropionyl- and side-chain unsaturated phenylpropanoid-CoAs. The simplest model for the initial reaction in diarylheptanoid biosynthesis predicts a phenylpropanoid-CoA as starter and a single condensation reaction to a diketide. Benzalacetones, the expected release products, were observed only with unsaturated phenylpropanoid-CoAs, and the best results were obtained with 4-coumaroyl-CoA (80% of the products). With all other substrates, WtPKS1 performed two condensation reactions and released pyrones. We propose that WtPKS1 catalyses the first step in diarylheptanoid biosynthesis and that the observed pyrones are derailment products in the absence of downstream processing proteins.     

Engineering biodiversity with type II polyketide synthase genes

A very important task in the ongoing search for new clinically useful drugs is the generation of large numbers of structurally diverse compounds. The emerging field of combinatorial biosynthesis, in which nature's chemical capabilities are exploited in a combinatorial 'mix-and-match' fashion, has generated libraries of novel molecules representing great structural diversity which are not available naturally or readily generated through (combinatorial) synthesis. Novel polyketides have been generated by manipulating type II iterative polyketide synthase (PKS) systems that express a variety of combinations of a minimal PKS with ketoreductases, cyclases, and other tailoring enzymes, resulting in a set of design rules to rationally engineer new metabolites. Engineering studies with the Streptomyces coelicolor whiE (spore pigment) and the 'Streptomyces maritimus' enterocin type II PKS provide additional insight on designing diverse assemblies of aromatic, as well as nonaromatic, polyketides.     

Diversity of type I polyketide synthase genes in the wood-decay fungus Xylaria sp. BCC 1067

Fungal type I polyketide (PK) compounds are highly valuable for medical treatment and extremely diverse in structure, partly because of the enzymatic activities of reducing domains in polyketide synthases (PKSs). We have cloned several PKS genes from the fungus Xylaria sp. BCC 1067, which produces two polyketides: depudecin (reduced PK) and 19,20-epoxycytochalasin Q (PK-nonribosomal peptide (NRP) hybrid). Two new degenerate primer sets, KA-series and XKS, were designed to amplify reducing PKS and PKS-NRP synthetase hybrid genes, respectively. Five putative PKS genes were amplified in Xylaria using KA-series primers and two more with the XKS primers. All seven are predicted to encode proteins homologous to highly reduced (HR)-type PKSs. Previously designed primers in LC-, KS-, and MT-series identified four additional PKS gene fragments. Selected PKS fragments were used as probes to identify PKS genes from the genomic library of this fungus. Full-length sequences for five PKS genes were obtained: pks12, pks3, pksKA1, pksMT, and pksX1. They are structurally diverse with 1-9 putative introns and products ranging from 2162 to 3654 amino acids in length. The finding of 11 distinct PKS genes solely by means of PCR cloning supports that PKS genes are highly diverse in fungi. It also indicates that our KA-series primers can serve as powerful tools to reveal the genetic potential of fungi in production of multiple types of HR PKs, which the conventional compound screening could underestimate.     

Expression and characterization of the type III polyketide synthase 1,3,6,8-tetrahydroxynaphthalene synthase from<Emphasis Type="Italic"> Streptomyces coelicolor</Emphasis> A3(2)

Sequence analysis of the metabolically rich 8.7-Mbp genome of the model actinomycete Streptomyces coelicolor A3(2) revealed three genes encoding predicted type III polyketide synthases (PKSs). We report the inactivation, expression, and characterization of the type III PKS homologous SCO1206 gene product as 1,3,6,8-tetrahydroxynaphthalene synthase (THNS). Incubation of recombinant THNS with malonyl-CoA showed THN production, as demonstrated by UV and HPLC analyses. The K_m value for malonyl-CoA and the k_cat value for THN synthesis were determined spectrophotometrically to be 3.58±0.85 µM and 0.48±0.03 min^–1, respectively. The C-terminal region of S. coelicolor THNS, which is longer than most other bacterial and plant type III PKSs, was shortened by 25 amino acid residues and the resulting mutant was shown to be slightly more active (K_m=1.97±0.19 µM, k_cat=0.75±0.04 min^–1) than the wild-type enzyme.     

A gene cluster involved in nogalamycin biosynthesis fromStreptomyces nogalater: sequence analysis and complementation of early-block mutations in the anthracycline pathway

We have analyzed an anthracycline biosynthesis gene cluster fromStreptomyces nogalater. Based on sequence analysis, a contiguous region of 11 kb is deduced to include genes for the early steps in anthracycline biosynthesis, a regulatory gene (snoA) promoting the expression of the biosynthetic genes, and at least one gene whose product might have a role in modification of the glycoside moiety. The three ORFs encoding a minimal polyketide synthase (PKS) are separated from the regulatory gene (snoA) by a comparatively AT-rich region (GC content 60%). Subfragments of the DNA region were transferred toStreptomyces galilaeus mutants blocked in aclacinomycin biosynthesis, and to a regulatory mutant ofS. nogalater. TheS. galilaeus mutants carrying theS. nogalater minimal PKS genes produced auramycinone glycosides, demonstrating replacement of the starter unit for polyketide biosynthesis. The product ofsnoA seems to be needed for expression of at least the genes for the minimal PKS.     

A family of polyketide synthase genes expressed in ripening Rubus fruits

Quality traits of raspberry fruits such as aroma and color derive in part from the polyketide derivatives, benzalacetone and dihydrochalcone, respectively. The formation of these metabolites during fruit ripening is the result of the activity of polyketide synthases (PKS), benzalcetone synthase and chalcone synthase (CHS), during fruit development. To gain an understanding of the regulation of these multiple PKSs during fruit ripening, we have characterized the repertoire of Rubus PKS genes and studied their expression patterns during fruit ripening. Using a PCR-based homology search, a family of ten PKS genes (Ripks1-10) sharing 82-98% nucleotide sequence identity was identified in the Rubus idaeus genome. Low stringency screening of a ripening fruit-specific cDNA library, identified three groups of PKS cDNAs. Group 1 and 2 cDNAs were also represented in the PCR amplified products, while group 3 represented a new class of Rubus PKS gene. The Rubus PKS gene-family thus consists of at least eleven members. The three cDNAs exhibit distinct tissue-specific and developmentally regulated patterns of expression. RiPKS5 has high constitutive levels of expression in all organs, including developing flowers and fruits, while RiPKS6 and RiPKS11 expression is consistent with developmental and tissue-specific regulation in various organs. The recombinant proteins encoded by the three RiPKS cDNAs showed a typical CHS-type PKS activity. While phylogenetic analysis placed the three Rubus PKSs in one cluster, suggesting a recent duplication event, their distinct expression patterns suggest that their regulation, and thus function(s), has evolved independently of the structural genes themselves.     

A melanin polyketide synthase (PKS) gene from Nodulisporium sp. that shows homology to the pks1 gene of Colletotrichum lagenarium

The melanin polyketide synthase (pks) gene of Nodulisporium sp. MF5954 (ATCC74245) was cloned by exploiting its homology to the Colletotrichum lagenarium pks1 gene. Sequence analysis demonstrated that this gene is 70% identical to the C. lagenarium pks1 gene. A gene disruption construct, designed to replace both the ketoacyl synthase and acyl transferase domains with a hygromycin resistance (Hy^r) gene, was synthesized, and used to disrupt the Nodulisporium melanin pks1 gene via homologous recombination, resulting in a mel(−) phenotype. Sequence analyses of the gene and of cDNA segments generated by RT-PCR indicate that there are three introns in the 5′ half of the gene. The proposed 2159-amino acid product is 72% identical and 78% similar to the 2187-amino acid sequence deduced from the C. lagenarium pks1 gene. This similarity is notable, considering that C. lagenarium is a member of the order Phyllachoales or Sordariales, whereas Nodulisporium is generally believed to be member of the order Xylariales. However, despite the strong resemblance between the amino acid sequences in the acyl transferase domains of the two proteins, only one in five codons are conserved in the DNA sequences that encode this motif. The Nodulisporium sp. pks1 gene sequence and the amino acid sequence deduced from its coding region have been deposited in Genbank under Accession No. AF151533. Received: 15 May 1999 / Accepted: 26 July 1999     

Functional characterization of the promiscuous prenyltransferase responsible for furaquinocin biosynthesis: identification of a physiological polyketide substrate and its prenylated reaction products

Furaquinocin is a natural polyketide-isoprenoid hybrid (meroterpenoid) that exhibits antitumor activity and is produced by the Streptomyces sp. strain KO-3988. Bioinformatic analysis of furaquinocin biosynthesis has identified Fur7 as a possible prenyltransferase that attaches a geranyl group to an unidentified polyketide scaffold. Here, we report the identification of a physiological polyketide substrate for Fur7, as well as its reaction product and the biochemical characterization of Fur7. A Streptomyces albus transformant (S. albus/pWHM-Fur2_del7) harboring the furaquinocin biosynthetic gene cluster lacking the fur7 gene did not produce furaquinocin but synthesized the novel intermediate 2-methoxy-3-methyl-flaviolin. After expression and purification from Escherichia coli, the recombinant Fur7 enzyme catalyzed the transfer of a geranyl group to 2-methoxy-3-methyl-flaviolin to yield 6-prenyl-2-methoxy-3-methyl-flaviolin and 7-O-geranyl-2-methoxy-3-methyl-flaviolin in a 10:1 ratio. The reaction proceeded independently of divalent cations. When 6-prenyl-2-methoxy-3-methyl-flaviolin was added to the culture medium of S. albus/pWHM-Fur2_del7, furaquinocin production was restored. The promiscuous substrate specificity of Fur7 was demonstrated with respect to prenyl acceptor substrates and prenyl donor substrates. The steady-state kinetic constants of Fur7 with each prenyl acceptor substrate were also calculated.     

Identification of a gene cluster encoding meilingmycin biosynthesis among multiple polyketide synthase contigs isolated from<Emphasis Type="Italic"> Streptomyces nanchangensis</Emphasis> NS3226

A cluster encoding genes for the biosynthesis of meilingmycin, a macrolide antibiotic structurally similar to avermectin and milbemycin 11, was identified among seven uncharacterized polyketide synthase gene clusters isolated from Streptomyces nanchangensis NS3226 by hybridization with PCR products using primers derived from the sequences of aveE, aveF and a thioesterase domain of the avermectin biosynthetic gene cluster. Introduction of a 24.1-kb deletion by targeted gene replacement resulted in a loss of meilingmycin production, confirming that the gene cluster encodes biosynthesis of this important anthelminthic antibiotic compound. A sequenced 8.6-kb fragment had aveC and aveE homologues (meiC and meiE) linked together, as in the avermectin gene cluster, but the arrangement of aveF (meiF) and the thioesterase homologues differed. The results should pave the way to producing novel insecticidal compounds by generating hybrids between the two pathways.     

A cryptic type I polyketide synthase (cpk) gene cluster in Streptomyces coelicolor A3(2)

The chromosome of Streptomyces coelicolor A3(2), a model organism for the genus Streptomyces, contains a cryptic type I polyketide synthase (PKS) gene cluster which was revealed when the genome was sequenced. The ca. 54-kb cluster contains three large genes, cpkA, cpkB and cpkC, encoding the PKS subunits. In silico analysis showed that the synthase consists of a loading module, five extension modules and a unique reductase as a terminal domain instead of a typical thioesterase. All acyltransferase domains are specific for a malonyl extender, and have a B-type ketoreductase. Tailoring and regulatory genes were also identified within the gene cluster. Surprisingly, some genes show high similarity to primary metabolite genes not commonly identified in any antibiotic biosynthesis cluster. Using western blot analysis with a PKS subunit (CpkC) antibody, CpkC was shown to be expressed in S. coelicolor at transition phase. Disruption of cpkC gave no obvious phenotype.     

Localization of polyketide synthase encoding genes to the toxic dinoflagellate Karenia brevis

Karenia brevis is a toxic marine dinoflagellate endemic to the Gulf of Mexico. Blooms of this harmful alga cause fish kills, marine mammal mortalities and neurotoxic shellfish poisonings. These harmful effects are attributed to a suite of polyketide secondary metabolites known as the brevetoxins. The carbon framework of all polyketides is assembled by a polyketide synthase (PKS). Previously, PKS encoding genes were amplified from K. brevis culture and their similarity to a PKS gene from the closely related protist, Cryptosporidium parvum, suggested that these genes originate from the dinoflagellate. However, K. brevis has not been grown axenically. The associated bacteria might be the source of the toxins or the PKS genes. Herein we report the localization of PKS encoding genes by a combination of flow cytometry/PCR and fluorescence in situ hybridization (FISH). Two genes localized exclusively to K. brevis cells while a third localized to both K. brevis and associated bacteria. While these genes have not yet been linked to toxin production, the work describes the first definitive evidence of resident PKS genes in any dinoflagellate.     

The FK520 gene cluster of Streptomyces hygroscopicus var. ascomyceticus (ATCC 14891) contains genes for biosynthesis of unusual polyketide extender units

FK520 (ascomycin) is a macrolide produced by Streptomyces hygroscopicus var. ascomyceticus (ATCC 14891) that has immunosuppressive, neurotrophic and antifungal activities. To further elucidate the biosynthesis of this and related macrolides, we cloned and sequenced an 80kb region encompassing the FK520 gene cluster. Genes encoding the three polyketide synthase (PKS) subunits (fkbB, fkbC and fkbA), the peptide synthetase (fkbP), the 31-O-methyltransferase (fkbM), the C-9 hydroxylase (fkbD) and the 9-hydroxyl oxidase (fkbO) had the same organization as the genes reported in the FK506 gene cluster of Streptomyces sp. MA6548 (Motamedi, H., Shafiee, A., 1998. The biosynthetic gene cluster for the macrolactone ring of the immunosuppressant FK506. Eur. J. Biochem. 256, 528-534). Disruption of a PKS gene in the cluster using the φC31 phage vector, KC515, led to antibiotic non-producing strains, proving the identity of the cluster. Previous labeling data have indicated that FK520 biosynthesis uses novel polyketide extender units (Byrne, K.M., Shafiee, A., Nielson, J., Arison, B., Monaghan, R.L., Kaplan, L., 1993. The biosynthesis and enzymology of an immunosuppressant, immunomycin, produced by Streptomyces hygroscopicus var, ascomyceticus. Dev. Ind. Microbiol. 32, 29-45). Genes in the flanking regions of the FK520 cluster were identified that appear to be involved in synthesis of these extender units. All but two of these genes were homologous to genes with known function. In addition to a crotonyl-CoA reductase gene (fkbS), at least two other genes are proposed to be involved in biosynthesis of the atypical PKS extender unit ethylmalonyl-CoA, which accounts for the ethyl side chain on C-21 of FK520. A set of five contiguous genes (fkbGHIJK) is proposed to be involved in biosynthesis of an unusual PKS extender unit bearing an oxygen on the alpha-carbon, and leading to the 13- and 15-methoxy side chains. These putative precursor synthesis genes in the flanking regions of the FK520 cluster are not found in the flanking regions of the rapamycin cluster (Molnár, I., Aparicio, J.F., Haydock, S.F., Khaw, L.E., Schwecke, T., K?nig, A., Staunton, J., Leadlay, P.F., 1996. Organisation of the biosynthetic gene cluster for rapamycin in Streptomyces hygroscopicus: analysis of genes flanking the polyketide synthase. Gene 169, 1-7), consistent with labeling data showing that rapamycin biosynthesis uses only malonyl and methylmalonyl extender units.     

Functional replacement of the ketosynthase domain of FUM1 for the biosynthesis of fumonisins, a group of fungal reduced polyketides

The genetic manipulation of the biosynthesis of fungal reduced polyketides has been challenging due to the lack of knowledge on the biosynthetic mechanism, the difficulties in the detection of the acyclic, non-aromatic metabolites, and the complexity in genetically manipulating filamentous fungi. Fumonisins are a group of economically important mycotoxins that contaminate maize-based food and feed products worldwide. Fumonisins contain a linear dimethylated C₁₈ chain that is synthesized by Fum1p, which is a single module polyketide synthase (PKS). Using a genetic system that allows the specific manipulation of PKS domains in filamentous fungus Fusarium verticillioides, we replaced the KS domain of fumonisin FUM1 with the KS domain of T-toxin PKS1 from Cochliobolus heterostrophus. Although PKS1 synthesizes different polyketides, the F. verticillioides strain carrying the chimeric PKS produced fumonisins. This represents the first successful domain swapping in PKSs for fungal reduced polyketides and suggests that KS domain alone may not be sufficient to control the product’s structure. To further test if the whole fumonisin PKS could be functionally replaced by a PKS that has a similar domain architecture, we replaced entire FUM1 with PKS1. This strain did not produce any fumonisin or new metabolites, suggesting that the intrinsic interactions between the intact PKS and downstream enzymes in the biosynthetic pathway may play a role in the control of fungal reduced polyketides.