Discovery of a novel superfamily of type III polyketide synthases in Aspergillus oryzae

Identification of genes encoding type III polyketide synthase (PKS) superfamily members in the industrially useful filamentous fungus, Aspergillus oryzae, revealed that their distribution is not specific to plants or bacteria. Among other Aspergilli (Aspergillus nidulans and Aspergillus fumigatus), A. oryzae was unique in possessing four chalcone synthase (CHS)-like genes (csyA, csyB, csyC, and csyD). Expression of csyA, csyB, and csyD genes was confirmed by RT-PCR. Comparative genome analyses revealed single putative type III PKS in Neurospora crassa and Fusarium graminearum, two each in Magnaporthe grisea and Podospora anserina, and three in Phenarocheate chrysosporium, with a phylogenic distinction from bacteria and plants. Conservation of catalytic residues in the CHSs across species implicated enzymatically active nature of these newly discovered homologs.     

Type III polyketide synthases in lichen mycobionts

Lichenized and non-lichenized fungi produce a wide range of secondary metabolites. So far, type I polyketide synthases (PKSs) are the suggested catalysts for the biosynthesis of lichen compounds. We were interested whether lichen mycobionts also contain type III PKSs, representing a class that was only recently discovered in fungi. With an alignment of known type III CHS-like genes we applied the CODEHOP strategy to design degenerate PCR primers. We further screened available fungal genomes for type III PKS genes and aligned these sequences for a phylogenetic analysis. Type III-like genes from lichen mycobionts are closely related to those known from non-lichenized fungi, but not to those of bacteria and/or plants. We conclude that type III PKS genes are ubiquitous in fungi. They are present in diverse unrelated lichen mycobionts, but their function in lichens is so far unclear.     

A new family of type III polyketide synthases in Mycobacterium tuberculosis

The Mycobacterium tuberculosis genome has revealed a remarkable array of polyketide synthases (PKSs); however, no polyketide product has been isolated thus far. Most of the PKS genes have been implicated in the biosynthesis of complex lipids. We report here the characterization of two novel type III PKSs from M. tuberculosis that are involved in the biosynthesis of long-chain alpha-pyrones. Measurement of steady-state kinetic parameters demonstrated that the catalytic efficiency of PKS18 protein was severalfold higher for long-chain acyl-coenzyme A substrates as compared with the small-chain precursors. The specificity of PKS18 and PKS11 proteins toward long-chain aliphatic acyl-coenzyme A (C12 to C20) substrates is unprecedented in the chalcone synthase (CHS) family of condensing enzymes. Based on comparative modeling studies, we propose that these proteins might have evolved by fusing the catalytic machinery of CHS and beta-ketoacyl synthases, the two evolutionarily related members with conserved thiolase fold. The mechanistic and structural importance of several active site residues, as predicted by our structural model, was investigated by performing site-directed mutagenesis. The functional identification of diverse catalytic activity in mycobacterial type III PKSs provide a fascinating example of metabolite divergence in CHS-like proteins.     

In silicio expression analysis of PKS genes isolated from Cannabis sativa L

Cannabinoids, flavonoids, and stilbenoids have been identified in the annual dioecious plant Cannabis sativa L. Of these, the cannabinoids are the best known group of this plant's natural products. Polyketide synthases (PKSs) are responsible for the biosynthesis of diverse secondary metabolites, including flavonoids and stilbenoids. Biosynthetically, the cannabinoids are polyketide substituted with terpenoid moiety. Using an RT-PCR homology search, PKS cDNAs were isolated from cannabis plants. The deduced amino acid sequences showed 51%-73% identity to other CHS/STS type sequences of the PKS family. Further, phylogenetic analysis revealed that these PKS cDNAs grouped with other non-chalcone-producing PKSs. Homology modeling analysis of these cannabis PKSs predicts a 3D overall fold, similar to alfalfa CHS2, with small steric differences on the residues that shape the active site of the cannabis PKSs.     

Interkingdom gene transfer of a hybrid NPS/PKS from bacteria to filamentous Ascomycota

Nonribosomal peptides (NRPs) and polyketides (PKs) are ecologically important secondary metabolites produced by bacteria and fungi using multidomain enzymes called nonribosomal peptide synthetases (NRPSs) and polyketide synthases (PKSs), respectively. Previous phylogenetic analyses of fungal NRPSs and PKSs have suggested that a few of these genes were acquired by fungi via horizontal gene transfer (HGT) from bacteria, including a hybrid NPS/PKS found in Cochliobolus heterostrophus (Dothideomycetes, Ascomycota). Here, we identify this hybrid gene in fungi representing two additional classes of Ascomycota (Aspergillus spp., Microsporum canis, Arthroderma spp., and Trichophyton spp., Eurotiomycetes; Chaetomium spp. and Metarhizium spp., Sordariomycetes) and use phylogenetic analyses of the most highly conserved domains from NRPSs (adenylation (A) domain) and PKSs (ketoacyl synthase (KS) domain) to examine the hypothesis that the hybrid NPS7/PKS24 was acquired by fungi from bacteria via HGT relatively early in the evolution of the Pezizomycotina. Our results reveal a unique ancestry of the A domain and KS domain in the hybrid gene relative to known fungal NRPSs and PKSs, provide strong evidence for HGT of the hybrid gene from a putative bacterial donor in the Burkholderiales, and suggest the HGT event occurred early in the evolution of the filamentous Ascomycota.     

Pentaketide resorcylic acid synthesis by type III polyketide synthase from Neurospora crassa

Type III polyketide synthases (PKSs) are responsible for aromatic polyketide synthesis in plants and bacteria. Genome analysis of filamentous fungi has predicted the presence of fungal type III PKSs, although none have thus far been functionally characterized. In the genome of Neurospora crassa, a single open reading frame, NCU04801.1, annotated as a type III PKS was found. In this report, we demonstrate that NCU04801.1 is a novel type III PKS catalyzing the synthesis of pentaketide alkylresorcylic acids. NCU04801.1, hence named 2'-oxoalkylresorcylic acid synthase (ORAS), preferred stearoyl-CoA as a starter substrate and condensed four molecules of malonyl-CoA to give a pentaketide intermediate. For ORAS to yield pentaketide alkylresorcylic acids, aldol condensation and aromatization of the intermediate, which is still attached to the enzyme, are presumably followed by hydrolysis for release of the product as a resorcylic acid. ORAS is the first type III PKS that synthesizes pentaketide resorcylic acids.     

Type III polyketide synthases in natural product biosynthesis

Polyketides represent an important class of biologically active and structurally diverse compounds in nature. They are synthesized from acyl-coenzyme A substrates by polyketide synthases (PKSs). PKSs are classified into three groups: types I, II, and III. This article introduces recent studies on type III PKSs identified from plants, bacteria, and fungi, and describes the catalytic functions of these enzymes in detail. Plant type III PKSs have been widely studied, as exemplified by chalcone synthase, which plays an important role in the synthesis of plant metabolites. Bacterial type III PKSs fall into five groups, many of which were identified from Streptomyces, a genus that has been well known for its production of bioactive molecules and genetic alterability. Although it was believed that type III PKSs exist exclusively in plants and bacteria, recent fungal genome sequencing projects and biochemical studies revealed the presence of type III PKSs in filamentous fungi, which provides a new chance to study fungal secondary metabolism and synthesize "unnatural" natural products. Type III PKSs have been used for the biosynthesis of novel molecules through precursor-directed and structure-based mutagenesis approaches.     

Insect-Specific Polyketide Synthases (PKSs), Potential PKS-Nonribosomal Peptide Synthetase Hybrids,and Novel PKS Clades in Tropical Fungi

Polyketides draw much attention because of their potential use in pharmaceutical and biotechnological applications. This study identifies an abundant pool of polyketide synthase (PKS) genes from local isolates of tropical fungi found in Thailand in three different ecological niches: insect pathogens, marine inhabitants, and lichen mutualists. We detected 149 PKS genes from 48 fungi using PCR with PKS-specific degenerate primers. We identified and classified 283 additional PKS genes from 13 fungal genomes. Phylogenetic analysis of all these PKS sequences the comprising ketosynthase (KS) conserved region and the KS-acyltransferase interdomain region yielded results very similar to those for phylogenies of the KS domain and suggested a number of remarkable points. (i) Twelve PKS genes amplified from 12 different insect-pathogenic fungi form a tight cluster, although along with two PKS genes extracted from genomes of Aspergillus niger and Aspergillus terreus, in reducing clade III. Some of these insect-specific fungal PKSs are nearly identical. (ii) We identified 38 new PKS-nonribosomal peptide synthetase hybrid genes in reducing clade II. (iii) Four distinct clades were discovered with more than 75% bootstrap support. We propose to designate the novel clade D1 with 100% bootstrap support “reducing clade V.” The newly cloned PKS genes from these tropical fungi should provide useful and diverse genetic resources for future research on the characterization of polyketide compounds synthesized by these enzymes.One hallmark of tropical countries is the tremendous availability and diversity of natural resources. Tropical forests, freshwater reservoirs, and seas are home to an uncountable number of species, ranging from microorganisms (e.g., bacteria, fungi, and protozoa) to invertebrates to vertebrates to plants. Thailand is no exception. The country has a large collection of fungi found in different niches and habitats in its ecosystems. Interesting groups include fungi that are associated with insects, those that inhabit the sea, and those that are in lichen complexes; these are referred to here as insect fungi, marine fungi, and lichenized fungi, respectively. The first group is of particular interest because it represents a remarkable relationship (in this case, pathogenesis) between the fungi and their insect hosts. These entomopathogenic fungi were isolated from the dead insect bodies in different stages (e.g., larvae, pupae, nymphs, or adults). The marine fungi used in this study were mostly isolated from the living or dead plant parts floating at the seashore, whereas the lichen mutualistic fungi were isolated from lichen complexes on the bark of trees in tropical forests in Thailand. All these fungal isolates were deposited in National Center for Genetic Engineering and Biotechnology (BIOTEC) Culture Collection (BCC). The BCC has one of the richest collections (approximately 400 species and 5,000 isolates) of insect fungi in the world (19).Secondary metabolites may play an important role in organisms that synthesize them, for example, in spore development (7), protection, or host virulence (5). Polyketides (PKs) are natural secondary metabolite compounds derived from the condensation of acyl coenzyme A subunits in a head-to-tail manner, and they have a tremendous diversity in structure (33). Structural diversification of the PKs includes a variation in the number of subunits, types of subunits, degree of chemical reduction of the β-keto thioester, extent of stereochemistry of the α-keto group at each condensation, and subsequent processing (e.g., cyclicization) (25, 28, 33). The high therapeutic and economic value of PK compounds has attracted the interest of drug companies and government research agencies. Some PKs are commercially available for medical treatments, such as grahamimycin and patulin (antibiotics), lovastatin and compactin (cholesterol-lowering agents), griseofulvin (an antibiotic/antifungal agent), and monocerin (an antifungal agent).Enzymes that synthesize the PKs are called PK synthases (PKSs). PKSs are multifunctional enzymes that are composed of three principal domains: ketoacyl synthase (KS), acyltransferase (AT), and acyl carrier protein (ACP). Fungal PKSs are type I, multifunctional large enzymes and use an iterative strategy to synthesize PKs. They can be divided into two groups, nonreducing (NR) and reducing (4), and further subdivided into NR subclades I, II, and III and reducing subclades I, II, III, and IV (26). NR PKSs include those synthesizing pigments or aflatoxin. Reducing PKSs are involved in the synthesis of PK compounds with various chemical reductions in structure. Apart from the three major domains (KS, AT, and ACP) present in all PKSs, reducing PKSs contain three additional domains, i.e., dehydratase, enoyl reductase, and ketoreductase, which are involved in the reduction of the keto group to various stages (i.e., alcohol, unsaturated thiolester, and full saturation, respectively), therefore enhancing diversity of the PK structure.Kroken et al. (26) studied putative amino acid sequences of the PKS genes previously characterized in fungi and the PKS genes discovered from the genome sequencing projects for eight fungal species in the Ascomycota. PKS genes were found only in the genomes of the Pezizomycotina and not in the sequenced genomes of either Ascomycota in the Taphrinomycota or Saccharomycotina or Basidiomycota in the Hymenomycetes. Thus, we focused our search on the fungi in this subphylum. We aimed to mine valuable PKS genes from this fungal resource. One of the main objectives is to find novel secondary metabolites useful for medical or agricultural applications. One highly regarded example is the “vegetable caterpillar,” where the fungus Cordyceps sinensis grows on Hepialidae caterpillars. The fungus has long been used in traditional Chinese medicine. Extracts of Cordyceps sinensis were reported to have a variety of therapeutic effects, for example, antitumor (6), antioxidant (42), and antiaging (24) activities. The C. sinensis-Hepialidae pair is also called the “body snatcher”. This name comes from the fact that the fungus infects and consumes the insect tissue and fills up the insect cavity with its mycelia. Thus, another objective is to find metabolites involved in interaction between fungal pathogens and their insect hosts. Insect pests pose tremendous losses to humans in regard to health issues (vectors of diseases) and economic issues (crop plant losses by insect pathogens and building structure damage by termites). Little was known regarding the roles of PKs in producing fungi on their interaction with insect host. Better understanding of this relationship might have implications for insect control.We conducted our PKS screening using PCR with the degenerate KA series primers (2). In addition to our preliminary PKS screening with these primers in a few fungi (2), the KA series primers were used to clone the reducing PKS gene for radicicol biosynthesis from the fungus Pochonia chlamydosporia, and later its whole biosynthetic cluster was revealed (37). Here, the method and the primers were also proven to be successful in finding rich resources of hidden metabolic pathways for PK biosynthesis from 48 fungi that were isolated in Thailand and, particularly, have no genome sequences determined. In addition, more than 200 PKS genes were identified from our genome analysis of 13 filamentous fungi.     

Characterization of two novel non-reducing polyketide synthase genes from the lichen-forming fungus Hypogymnia physodes

Lichens are known to produce a variety of secondary metabolites including polyketides, which have valuable biological activities. Some polyketides are produced solely by lichens. The biosynthesis of these compounds is primarily governed by iterative type I polyketide synthases. Hypogymnia physodes synthesize polyketides such as physodic, physodalic and hydroxyphysodic acid and atranorin, which are non-reducing polyketides. Two novel non-reducing polyketide synthase (PKS) genes were isolated from a fosmid genomic library of a mycobiont of H. physodes using a 409bp fragment corresponding to part of the reductase (R) domain as a probe. H. physodes PKS1 (Hyopks1) and PKS2 (Hypopks2) contain keto synthase (KS), acyl transferase (AT), acyl carrier protein (ACP), methyl transferase (ME) and R domains. Classification based on phylogeny analysis using the translated KS and AT domains demonstrated that Hypopks1 and Hypopks2 are members of the fungal non-reducing PKSs clade III. This is the first report of non-reducing PKSs containing the R domain-mediated release mechanisms in lichens, which are also rare fungal type I PKS in non-lichenized filamentous fungi.     

Biosynthesis of Aliphatic Polyketides by Type III Polyketide Synthase and Methyltransferase in Bacillus subtilis

Type III polyketide synthases (PKSs) synthesize a variety of aromatic polyketides in plants, fungi, and bacteria. The bacterial genome projects predicted that probable type III PKS genes are distributed in a wide variety of gram-positive and -negative bacteria. The gram-positive model microorganism Bacillus subtilis contained the bcsA-ypbQ operon, which appeared to encode a type III PKS and a methyltransferase, respectively. Here, we report the characterization of bcsA (renamed bpsA, for Bacillus pyrone synthase, on the basis of its function) and ypbQ, which are involved in the biosynthesis of aliphatic polyketides. In vivo analysis demonstrated that BpsA was a type III PKS catalyzing the synthesis of triketide pyrones from long-chain fatty acyl-coenzyme A (CoA) thioesters as starter substrates and malonyl-CoA as an extender substrate, and YpbQ was a methyltransferase acting on the triketide pyrones to yield alkylpyrone methyl ethers. YpbQ thus was named BpsB because of its functional relatedness to BpsA. In vitro analysis with histidine-tagged BpsA revealed that it used broad starter substrates and produced not only triketide pyrones but also tetraketide pyrones and alkylresorcinols. Although the aliphatic polyketides were expected to localize in the membrane and play some role in modulating the rigidity and properties of the membrane, no detectable phenotypic changes were observed for a B. subtilis mutant containing a whole deletion of the bpsA-bpsB operon.Type III polyketide synthases (PKSs), represented by a plant chalcone synthase (CHS), are the condensing enzymes that catalyze the synthesis of aromatic polyketides in plants, fungi, and bacteria (2). CHS catalyzes the decarboxylative condensation of p-coumaroyl-coenzyme A (p-coumaroyl-CoA), called a starter substrate, with three malonyl-CoAs, called extender substrates, and synthesizing a tetraketide intermediate. The synthesized tetraketide intermediate was cyclized and aromatized by CHS and resulted in naringenin chalcone. Like CHS, most of the type III PKSs catalyze the condensation of a starter substrate with several molecules of an extender substrate and cyclization. There are many type III PKSs that differ in these specificities.Until recently, type III PKSs were discovered only from plants. In 1999, the first bacterial type III PKS, RppA, was discovered. RppA catalyzes the condensation of five malonyl-CoAs to synthesize 1,3,6,8-tetrahydroxynaphthalene, which is a precursor of hexahydroxyperylenequinone melanin in the actinomycete Streptomyces griseus (4). Since then, the genome projects of various bacteria have revealed that type III PKSs are widely distributed in a variety of bacteria. For example, ArsB and ArsC, both of which are type III PKSs in Azotobacter vinelandii, catalyze the synthesis of alkylresorcinols and alkylpyrones, respectively, which are essential for encystment as the major lipids in the cyst membrane (5). In S. griseus, the srs operon consisting of srsA, srsB, and srsC is responsible for the synthesis of methylated phenolic lipids derived from alkylresorcinols and alkylpyrones (6). The function of each of the operon members is that SrsA is a type III PKS responsible for the synthesis of phenolic lipids alkylresorcinol and alkylpyrones, SrsB is a methyltransferase acting on the phenolic lipids to yield alkylresorcinol methyl ethers, and SrsC is a hydroxylase acting on the alkylresorcinol methyl ethers. The phenolic lipids synthesized by the Srs enzymes confer resistance to β-lactam antibiotics (6). Therefore, it is suggested that phenolic lipids play an important role as minor components in the biological membrane in various bacteria. In fact, srsAB- and srsABC-like operons are distributed widely in both gram-positive and -negative bacteria (see Fig. S1 in the supplemental material). However, most of these type III PKSs have not been characterized.Bacillus subtilis is one of the best-characterized gram-positive bacteria. BcsA, which stands for bacterial chalcone synthase, was annotated as a homologue of type III PKS in B. subtilis (3). As described in this paper, however, this annotation needs correction. We renamed the gene bpsA (for Bacillus pyrone synthase). Moreover, the functional unknown gene ypbQ is located next to bpsA. YpbQ, consisting of 168 amino acid residues, contained an isoprenylcysteine carboxyl methyltransferase (ICMT) domain of the ICMT family members, which are unique membrane proteins that are involved in the posttranslational modification of oncogenic proteins (23). Therefore, the bpsA and ypbQ genes were predicted to form an operon, just like srsA and srsB in the srs operon in S. griseus. We therefore named ypbQ, a thus-far functionally unknown gene, bpsB.In this study, we characterized the functions of BpsA and BpsB by in vivo and in vitro experiments. The in vivo experiments revealed that the overexpression of bpsA in B. subtilis led to the production of triketide pyrones, and the co-overexpression of bpsA and bpsB led to the production of triketide pyrone methyl ethers. The in vitro analysis showed that BpsA produced triketide pyrones and a small amount of tetraketide pyrones and tetraketide resorcinols from long-chain fatty acyl CoA thioesters as starter substrates and malonyl-CoA as an extender substrate. Therefore, BpsA is a type III PKS that is responsible for the synthesis of alkylpyrones, and BpsB is a methyltransferase that acts on the alkylpyrones to yield alkylpyrone methyl ethers. BpsB is the first enzyme found to methylate alkylpyrones. Furthermore, we attempted to analyze the biological function of the aliphatic polyketides by disrupting the bpsA and bpsB genes, but no distinct phenotypic changes were detected under laboratory conditions.     

Functional analysis of the polyketide synthase genes in the filamentous fungus Gibberella zeae (anamorph Fusarium graminearum)

Polyketides are a class of secondary metabolites that exhibit a vast diversity of form and function. In fungi, these compounds are produced by large, multidomain enzymes classified as type I polyketide synthases (PKSs). In this study we identified and functionally disrupted 15 PKS genes from the genome of the filamentous fungus Gibberella zeae. Five of these genes are responsible for producing the mycotoxins zearalenone, aurofusarin, and fusarin C and the black perithecial pigment. A comprehensive expression analysis of the 15 genes revealed diverse expression patterns during grain colonization, plant colonization, sexual development, and mycelial growth. Expression of one of the PKS genes was not detected under any of 18 conditions tested. This is the first study to genetically characterize a complete set of PKS genes from a single organism.     

Structure-guided programming of polyketide chain-length determination in chalcone synthase.

Chalcone synthase (CHS) belongs to the family of type III polyketide synthases (PKS) that catalyze formation of structurally diverse polyketides. CHS synthesizes a tetraketide by sequential condensation of three acetyl anions derived from malonyl-CoA decarboxylation to a p-coumaroyl moiety attached to an active site cysteine. Gly256 resides on the surface of the CHS active site that is in direct contact with the polyketide chain derived from malonyl-CoA. Thus, position 256 serves as an ideal target to probe the link between cavity volume and polyketide chain-length determination in type III PKS. Functional examination of CHS G256A, G256V, G256L, and G256F mutants reveals altered product profiles from that of wild-type CHS. With p-coumaroyl-CoA as a starter molecule, the G256A and G256V mutants produce notably more tetraketide lactone. Further restrictions in cavity volume such as that seen in the G256L and G256F mutants yield increasing levels of the styrylpyrone bis-noryangonin from a triketide intermediate. X-ray crystallographic structures of the CHS G256A, G256V, G256L, and G256F mutants establish that these substitutions reduce the size of the active site cavity without significant alterations in the conformations of the polypeptide backbones. The side chain volume of position 256 influences both the number of condensation reactions during polyketide chain extension and the conformation of the triketide and tetraketide intermediates during the cyclization reaction. These results viewed in conjunction with the natural sequence variation of residue 256 suggest that rapid diversification of product specificity without concomitant loss of substantial catalytic activity in related CHS-like enzymes can occur by site-specific evolution of side chain volume at position 256.     

Insights from the first putative biosynthetic gene cluster for a lichen depside and depsidone

The genes for polyketide synthases (PKSs), enzymes that assemble the carbon backbones of many secondary metabolites, often cluster with other secondary pathway genes. We describe here the first lichen PKS cluster likely to be implicated in the biosynthesis of a depside and a depsidone, compounds in a class almost exclusively produced by lichen fungi (mycobionts). With degenerate PCR with primers biased toward presumed PKS genes for depsides and depsidones we identified among the many PKS genes in Cladonia grayi four (CgrPKS13-16) potentially responsible for grayanic acid (GRA), the orcinol depsidone characteristic of this lichen. To single out a likely GRA PKS we compared mRNA and GRA induction in mycobiont cultures using the four candidate PKS genes plus three controls; only CgrPKS16 expression closely matched GRA induction. CgrPKS16 protein domains were compatible with orcinol depside biosynthesis. Phylogenetically CgrPKS16 fell in a new subclade of fungal PKSs uniquely producing orcinol compounds. In the C. grayi genome CgrPKS16 clustered with a CytP450 and an o-methyltransferase gene, appropriately matching the three compounds in the GRA pathway. Induction, domain organization, phylogeny and cluster pathway correspondence independently indicated that the CgrPKS16 cluster is most likely responsible for GRA biosynthesis. Specifically we propose that (i) a single PKS synthesizes two aromatic rings and links them into a depside, (ii) the depside to depsidone transition requires only a cytochrome P450 and (iii) lichen compounds evolved early in the radiation of filamentous fungi.     

The first plant type III polyketide synthase that catalyzes formation of aromatic heptaketide

A cDNA encoding a novel plant type III polyketide synthase (PKS) was cloned from rhubarb (Rheum palmatum). A recombinant enzyme expressed in Escherichia coli accepted acetyl-CoA as a starter, carried out six successive condensations with malonyl-CoA and subsequent cyclization to yield an aromatic heptaketide, aloesone. The enzyme shares 60% amino acid sequence identity with chalcone synthases (CHSs), and maintains almost identical CoA binding site and catalytic residues conserved in the CHS superfamily enzymes. Further, homology modeling predicted that the 43-kDa protein has the same overall fold as CHS. This provides new insights into the catalytic functions of type III PKSs, and suggests further involvement in the biosynthesis of plant polyketides.     

植物类型III聚酮合酶超家族晶体结构与功能

植物类型Ⅲ聚酮化合物合酶(PKS)催化合成多种植物次生代谢产物的基本分子骨架,参与植物体许多重要生物学功能的行使,一直是研究蛋白结构与功能关系、基于结构进行分子改造的重要模式分子家族。目前在蛋白质数据库(PDB)中有超过80个不同种属来源的类型Ⅲ PKS的三维结构被报道,其中包括了研究最为透彻的查尔酮合酶在内的7种酶的晶体结构,这些结构的发表对于阐明该类酶复杂多变的底物专一性、链延伸和不同的环化反应机制奠定了结构基础。三维空间结构解析以及基于定点突变的结构功能分析是进行酶工程、基因工程的基础。以下系统综述了植物类型Ⅲ PKS超家族晶体结构和功能的研究进展。     

Non-modular polyketide synthases in myxobacteria

Myxobacteria are prolific producers of a wide variety of secondary metabolites. The vast majority of these compounds are complex polyketides which are biosynthesised by multimodular polyketide synthases (PKSs). In contrast, few myxobacterial metabolites isolated to date are derived from non-modular PKSs, in particular type III PKSs. This review reports our progress on the characterisation of type III PKSs in myxobacteria. We also summarize current knowledge on bacterial type III PKSs, with a special focus on the evolutionary relationship between plant and bacterial enzymes. The biosynthesis of a quinoline alkaloid in Stigmatella aurantiaca by a non-modular PKS is also discussed.     

Identification of csypyrone B2 and B3 as the minor products of Aspergillus oryzae type III polyketide synthase CsyB

Since our first report on the identification of the fungal type III polyketide synthase (PKS) genes csyA～D in Aspergillus oryzae RIB40, type III PKS homologues have also been found in other fungal species. We previously reported the isolation and structural determination of csypyrone B1 as the main product of CsyB when inductively expressed in Aspergillus oryzae. Herein we report the isolation and identification of the two minor products of the csyB transformant in addition to csypyrone B1 as 4-(3-acetyl-4-hydroxy-2-oxo-2H-pyran-6-yl)butyric acid and 5-(3-acetyl-4-hydroxy-2-oxo-2H-pyran-6-yl)pentanoic acid. These compounds were named csypyrone B2 and B3, respectively, and both are homologues of main product csypyrone B1 with different side chain lengths. This result suggests that the carbon skeleton of the csypyrone B precursor is constructed by the condensation of fatty acyl-CoA and acetylmalonyl-CoA followed by pyrone formation. The alkyl side chain of the precursor may be oxidatively cleaved by enzyme(s) in the host fungus to give variations of csypyrone B with propanoic acid, butyric acid, or pentanoic acid side chains.     

Towards Prediction of Metabolic Products of Polyketide Synthases: An In Silico Analysis

Sequence data arising from an increasing number of partial and complete genome projects is revealing the presence of the polyketide synthase (PKS) family of genes not only in microbes and fungi but also in plants and other eukaryotes. PKSs are huge multifunctional megasynthases that use a variety of biosynthetic paradigms to generate enormously diverse arrays of polyketide products that posses several pharmaceutically important properties. The remarkable conservation of these gene clusters across organisms offers abundant scope for obtaining novel insights into PKS biosynthetic code by computational analysis. We have carried out a comprehensive in silico analysis of modular and iterative gene clusters to test whether chemical structures of the secondary metabolites can be predicted from PKS protein sequences. Here, we report the success of our method and demonstrate the feasibility of deciphering the putative metabolic products of uncharacterized PKS clusters found in newly sequenced genomes. Profile Hidden Markov Model analysis has revealed distinct sequence features that can distinguish modular PKS proteins from their iterative counterparts. For iterative PKS proteins, structural models of iterative ketosynthase (KS) domains have revealed novel correlations between the size of the polyketide products and volume of the active site pocket. Furthermore, we have identified key residues in the substrate binding pocket that control the number of chain extensions in iterative PKSs. For modular PKS proteins, we describe for the first time an automated method based on crucial intermolecular contacts that can distinguish the correct biosynthetic order of substrate channeling from a large number of non-cognate combinatorial possibilities. Taken together, our in silico analysis provides valuable clues for formulating rules for predicting polyketide products of iterative as well as modular PKS clusters. These results have promising potential for discovery of novel natural products by genome mining and rational design of novel natural products.     

Evolution of metabolic diversity: Insights from microbial polyketide synthases

Polyketides are a family of complex natural products that are built from simple carboxylic acid building blocks. In microorganisms, the majority of these secondary metabolites are produced by exceptionally large, multifunctional proteins termed polyketide synthases (PKSs). Each unit of a type I PKS assembly line resembles a mammalian type fatty acid synthase (FAS), although certain domains are optionally missing. The evolutionary analysis of microbial PKS has revealed a long joint evolution process of PKSs and FASs. The phylogenomic analysis of modular type I PKSs as the most widespread PKS type in bacteria showed a large impact of gene duplications and gene losses on the evolution of type I PKS in different bacterial groups. The majority of type I PKSs in actinobacteria and cyanobacteria may have evolved from a common ancestor, whereas in proteobacteria most type I PKSs were acquired from other bacterial groups. The modularization of type I PKSs almost unexceptionally started with multiple duplications of a single ancestor module. The repeating modules represent ideal platforms for recombination events that can lead to corresponding changes in the actual chemistry of the products. The analysis of these “natural reprogramming” events of PKSs may assist in the development of concepts for the biocombinatorial design of bioactive compounds.