Novel polyketide synthase from Nectria haematococca

We identified a polyketide synthase (PKS) gene, pksN, from a strain of Nectria haematococca by complementing a mutant unable to synthesize a red perithecial pigment. pksN encodes a 2,106-amino-acid polypeptide with conserved motifs characteristic of type I PKS enzymatic domains: beta-ketoacyl synthase, acyltransferase, duplicated acyl carrier proteins, and thioesterase. The pksN product groups with the Aspergillus nidulans WA-type PKSs involved in conidial pigmentation and melanin, bikaverin, and aflatoxin biosynthetic pathways. Inactivation of pksN did not cause any visible change in fungal growth, asexual sporulation, or ascospore formation, suggesting that it is involved in a specific developmental function. We propose that pksN encodes a novel PKS required for the perithecial red pigment biosynthesis.     

Exploring the diversity of marine-derived fungal polyketide synthases

Using an approach based on polymerase chain reaction (PCR), we examined the diversity of polyketide synthase (PKS) genes present in 160 marine fungal isolates, representing 142 species. We obtained ketosynthase (KS) domain PCR products from 99 fungal isolates, representing Dothideomycetes, Sordariomycetes, Eurotiomycetes, and incertae sedis. Sequence similarity searches and phylogenetic analysis of 29 marine partial-KS-encoding sequences revealed domains predicted to encode reducing, nonreducing, and 6-methylsalicylic acid PKSs. Bioinformatic analysis of an alignment of the KS sequences from marine-derived fungi revealed no unique motifs in this region. However, several specificity-determining positions were apparent between fungal 6-methylsalicylic acid PKSs as compared with either reducing or nonreducing PKSs. Evaluation of these positions in the context of a modelled three-dimensional protein structure highlighted their potential use as PKS classification markers. Evaluating primer-binding sites was necessary to obtain KS domain fragments from putative PKSs while maintaining a level of sequence information adequate to properly classify and characterize them.     

Production of the polyketide 6-MSA in yeast engineered for increased malonyl-CoA supply

The heterologous production of fungal polyketides was investigated using 6-methylsalicylic acid synthase (6-MSAS) as a model polyketide synthase and Saccharomyces cerevisiae as a host. In order to improve the production of 6-MSA by enhancing the supply of precursors, the promoter of the gene (ACC1) encoding acetyl-CoA carboxylase, which catalyzes the conversion of acetyl-CoA to malonyl-CoA, was replaced with a strong, constitutive promoter (TEF1p) in a strain harboring two plasmids carrying the genes encoding 6-MSAS from Penicillium patulum and PPTase from Aspergillus nidulans, respectively. The strain was characterized in batch cultivations with a glucose minimal media (20 g/L), and a 60% increase in 6-MSA titer was observed compared to a strain having the native promoter in front of ACC1. The production of 6-MSA was scaled up by the cultivation in minimal media containing 50 g/L of glucose, and hereby a final titer of 554+/-26 mg/L of 6-MSA was obtained.     

Phosphopantetheinyl transferase CfwA/NpgA is required for Aspergillus nidulans secondary metabolism and asexual development

Polyketide synthases (PKSs) and/or nonribosomal peptide synthetases (NRPSs) are central components of secondary metabolism in bacteria, plants, and fungi. In filamentous fungi, diverse PKSs and NRPSs participate in the biosynthesis of secondary metabolites such as pigments, antibiotics, siderophores, and mycotoxins. However, many secondary metabolites as well as the enzymes involved in their production are yet to be discovered. Both PKSs and NRPSs require activation by enzyme members of the 4'-phosphopantetheinyl transferase (PPTase) family. Here, we report the isolation and characterization of Aspergillus nidulans strains carrying conditional (cfwA2) and null (DeltacfwA) mutant alleles of the cfwA gene, encoding an essential PPTase. We identify the polyketides shamixanthone, emericellin, and dehydroaustinol as well as the sterols ergosterol, peroxiergosterol, and cerevisterol in extracts from A. nidulans large-scale cultures. The PPTase CfwA/NpgA was required for the production of these polyketide compounds but dispensable for ergosterol and cerevisterol and for fatty acid biosynthesis. The asexual sporulation defects of cfwA, DeltafluG, and DeltatmpA mutants were not rescued by the cfwA-dependent compounds identified here. However, a cfwA2 mutation enhanced the sporulation defects of both DeltatmpA and DeltafluG single mutants, suggesting that unidentified CfwA-dependent PKSs and/or NRPSs are involved in the production of hitherto-unknown compounds required for sporulation. Our results expand the number of known and predicted secondary metabolites requiring CfwA/NpgA for their biosynthesis and, together with the phylogenetic analysis of fungal PPTases, suggest that a single PPTase is responsible for the activation of all PKSs and NRPSs in A. nidulans.     

A new reducing polyketide synthase gene from the lichen-forming fungus Cladonia metacorallifera

Lichens produce unique polyketide secondary metabolites including depsides, depsidones, dibenzofurans and depsones. The biosynthesis of these compounds is governed by polyketide synthase (PKS), but the mechanism via which they are produced has remained unclear until now. We reported the 6-methylsalicylic acid synthase (6-MSAS) type of PKS gene, which is a member of the fungal-reducing PKSs. A cultured mycobiont of Cladonia metacorallifera was employed in the isolation and characterization of a polyketide synthase gene (CmPKS1). The complete sequence information for CmPKS1 was acquired via the screening of a Fosmid genomic library with a 456 bp fragment corresponding to part of the acyl transferase (AT) domain as a probe. CmPKS1 contains β-ketoacyl synthase (KS), AT, dehydratase (DH), ketoreductase (KR) and phosphopantetheine attachment site (PP) domains.: The domain organization of CmPKS1 (KS-AT-DH-KR-PP) is a typical 6-MSAS-type PKS, and the results of phylogenetic analysis showed that CmPKS1 grouped with other fungal-reducing PKSs. Quantitative real time PCR analyses showed that CmPKS1 was expressed preferentially in the early growth stage of the axenically cultured mycobiont. Furthermore CmPKS1 expression was found to be dependent on the carbon sources and concentrations in the medium.     

Suppression of the acuH13 and acuH31 nonsense mutations in the carnitine/acylcarnitine translocase (acuH) gene of Aspergillus nidulans by the G265S substitution in the domain 2 of the release factor eRF1

A search for suppressors of the carnitine/acylcarnitine translocase (CACT) deficiency in Aspergillus nidulans permitted the identification of the suaE7 mutation, mapping at a new translational suppressor (suaE) gene. The suaE gene is essential in A. nidulans and encodes the eukaryotic release factor 1 (eRF1). The suaE7 mutation suppresses two acuH alleles (acuH13 and acuH31), both carrying nonsense mutations in the CACT encoding gene that involve the replacement of a CAG (Gln) codon with a premature TAG stop codon. In contrast, the suaE7 gene does not suppress the acuH20 amber nonsense mutation involving a TGG-->TAG change. The phenotype associated to the suaE7 mutation strictly resembles that of mutants at the suaA and suaC genes, two translational suppressor genes previously identified, suggesting that their gene products might functionally interact in translation termination. Sequencing of the suaE7 gene allowed the identification of a mutation in the domain 2 of the omnipotent class-1 eukaryotic release factor involving the Gly265Ser substitution in the A. nidulans eRF1. This mutation creates a structural context unfavourable for normal eRF binding that allows the misreading of stop codons by natural suppressor tRNAs, such as the tRNAs(Gln). Structural analysis using molecular modelling of A. nidulans eRF1 domain 2 bearing the G265S substitution and computer simulation results suggest that this mutation might impair the necessary conformational changes in the eRF1 to optimally recognize the stop codon and simultaneously interact with the peptidyl transferase centre of the 60S ribosomal subunit.     

Novel Polyketide Synthase from Nectria haematococca

We identified a polyketide synthase (PKS) gene, pksN, from a strain of Nectria haematococca by complementing a mutant unable to synthesize a red perithecial pigment. pksN encodes a 2,106-amino-acid polypeptide with conserved motifs characteristic of type I PKS enzymatic domains: β-ketoacyl synthase, acyltransferase, duplicated acyl carrier proteins, and thioesterase. The pksN product groups with the Aspergillus nidulans WA-type PKSs involved in conidial pigmentation and melanin, bikaverin, and aflatoxin biosynthetic pathways. Inactivation of pksN did not cause any visible change in fungal growth, asexual sporulation, or ascospore formation, suggesting that it is involved in a specific developmental function. We propose that pksN encodes a novel PKS required for the perithecial red pigment biosynthesis.     

A novel group of type I polyketide synthases (PKS) in animals and the complex phylogenomics of PKSs

Type I polyketide synthases (PKSs), and related fatty acid synthases (FASs), represent a large group of proteins encoded by a diverse gene family that occurs in eubacteria and eukaryotes (mainly in fungi). Collectively, enzymes encoded by this gene family produce a wide array of polyketide compounds that encompass a broad spectrum of biological activity including antibiotic, antitumor, antifungal, immunosuppressive, and predator defense functional roles. We employed a phylogenomics approach to estimate relationships among members of this gene family from eubacterial and eukaryotic genomes. Our results suggest that some animal genomes (sea urchins, birds, and fish) possess a previously unidentified group of pks genes, in addition to possessing fas genes used in fatty acid metabolism. These pks genes in the chicken, fish, and sea urchin genomes do not appear to be closely related to any other animal or fungal genes, and instead are closely related to pks genes from the slime mold Dictyostelium and eubacteria. Continued accumulation of genome sequence data from diverse animal lineages is required to clarify whether the presence of these (non-fas) pks genes in animal genomes owes their origins to horizontal gene transfer (from eubacterial or Dictostelium genomes) or to more conventional patterns of vertical inheritance coupled with massive gene loss in several animal lineages. Additionally, results of our broad-scale phylogenetic analyses bolster the support for previous hypotheses of horizontal gene transfer of pks genes from bacterial to fungal and protozoan lineages.     

Cloning and characterization of the aldA gene of Aspergillus nidulans

We have cloned and sequenced the aldA (encoding aldehyde dehydrogenase) gene of Aspergillus nidulans. The gene contains two introns which are similar in size and structure to other fungal introns. The amino acid sequence of aldehyde dehydrogenase (497 residues) shows a significant level of homology with analogous sequences in other organisms. Comparison of the primary structure of the active sites of the mammalian cytosolic and mitochondrial enzymes shows that the Aspergillus enzyme closely resembles the mammalian mitochondrial enzyme. Analysis of the 5' non-coding region of the aldA gene shows a TATA-like sequence located 90 bp upstream from the initiation codon. Two messenger-RNA start points are located 36 and 42 bp upstream from the start codon.     

Development of a highly efficient gene targeting system for Fusarium graminearum using the disruption of a polyketide synthase gene as a visible marker

We cloned a polyketide synthase gene (pks12) from Fusarium graminearum, a devastating fungal pathogen of cereals. Transformation-mediated gene disruption led to an easily detectable albino phenotype of the disruptants. We used the disruption of the pks12 gene as a visible marker for transformation-mediated homologous recombination and optimized the transformation procedure to achieve a high rate of homologous recombination. In combination with the published genomic sequence data and the generation of expressed sequence tags (ESTs) for F. graminearum, this is a useful tool to investigate this important plant pathogen on a molecular level. Optimized transformation of F. graminearum resulted in at least 93% homologous recombination events when the homologous genomic DNA fragment in the vector had a size of approximately 800bp and was linearized in the middle. Using a genomic sequence of approximately 500bp in the transformation vector, 70% of the transformants still exhibited homologous recombination. On the contrary, no more than 10% homologous recombination events were observed when less than 400bp DNA fragments were used. We co-transformed F. graminearum with two different vectors. One vector harboured a DNA insert homologous to the pks12 gene, while the other vector consisted of the same vector backbone carrying the selection marker specific for F. graminearum. About 70% of the transformants had a disrupted pks12 gene, and all of these showed an integration of the second vector into the pks disruption vector. Therefore, the time-consuming construction of a single transformation vector can be avoided; furthermore, it is now easily feasible to express a gene construct at a defined and mutated genomic site.     

Ketosynthase Domain Probes Identify Two Subclasses of Fungal Polyketide Synthase Genes

Analysis of fungal polyketide synthase gene sequences suggested that these might be divided into two subclasses, designated WA-type and MSAS-type. Two pairs of degenerate PCR primers (LC1 and LC2c, LC3 and LC5c) were designed for the amplification of ketosynthase domain fragments from fungal PKS genes in each of these subclasses. Both primer pairs were shown to amplify one or more PCR products from the genomes of a range of ascomycetous Deuteromycetes and Southern blot analysis confirmed that the products obtained with each pair of primers emanated from distinct genomic loci. PCR products obtained from Penicillium patulum and Aspergillus parasiticus with the LC1/2c primer pair and from Phoma sp. C2932 with both primer pairs were cloned and sequenced; the deduced protein sequences were highly homologous to the ketosynthase domains of other fungal PKS genes. Genes from which LC1/2c fragments were amplified (WA-type) were shown by a phylogenetic analysis to be closely related to fungal PKS genes involved in pigment and aflatoxin biosynthetic pathways, whereas the gene from which the LC3/5c fragment was amplified (MSAS-type) was shown to be closely related to genes encoding 6-methylsalicylic acid synthase (MSAS). The phylogenetic tree strongly supported the division of fungal PKS genes into two subclasses. The LC-series primers may be useful molecular tools to facilitate the cloning of novel fungal polyketide synthase genes.