Loss-of-function Aspergillus nidulans CclA, a Bre2 ortholog involved in histone 3 lysine 4 methylation, activated the expression of cryptic secondary metabolite (SM) clusters in A. nidulans. One novel cluster generated monodictyphenone, emodin and emodin derivatives while a second encoded two anti-osteoporosis polyketides, F9775A and F9775B. Modification of the chromatin landscape in fungal SM clusters allows for a simple technological means to express silent fungal secondary metabolite gene clusters.Aspergilli are ubiquitous filamentous fungi whose members include human and plant pathogens and industrial fungi with tremendous medical, agricultural and biotechnological importance. Although demonstrating synteny along large tracks of their sequenced genomes, * Corresponding authors: phone: (323) 442-1670; fax: (323) 442-1390, clayw@usc.edu, phone: (608) 262-9795; fax: (608) (2) clusters 3 . Yet the expression of most SM clusters and their concomitant products remain veiled. Two approaches for activating otherwise silent clusters were recently described. One strategy, utilizing the knowledge that many SM clusters contain a pathway specific transcription factor, fused an inducible promoter to a cluster transcription factor leading to the production of hybrid polyketide-nonribosomal peptide metabolites, the cytotoxic aspyridones A (3) and B (4) 4 . A second approach, based on genomic mining of microarrays generated from mutants of the global regulator of secondary metabolism LaeA 5, 6, 7 , led to the identification of the anti-tumor compound terrequinone A (5) 8 . Efforts to uncover the regulatory role of LaeA revealed that some subtelomeric SM clusters were located in heterochromatic regions of the genome where suppression was relieved by deletion of a key histone deacetylase 9 . The importance of histone modifications in SM clusters was further reflected in the initiation and spread of histone H4 acetylation concurrent with transcriptional activation of the subtelomeric A. parasiticus aflatoxin (6) gene cluster 10 .A consideration of the accruing evidence linking chromatin modifications with SM cluster regulation led us to examine the hypothesis that additional chromatin modifying proteins were important in SM cluster regulation. In particular, we examined a member of the COMPASS (complex associated with Set1) complex for possible regulatory roles in SM silencing. The COMPASS complex is a conserved eukaryotic transcriptional effector both facilitating and repressing chromatin-mediated processes through methylation of lysine 4 of histone 3 (H3K4) 11,12 . While H3K4me2 and H3K4me3 are found predominantly on active loci 12 , the COMPASS complex also regulates homothallic mating silencing, ribosomal DNA silencing, telomere length, and subtelomeric gene expression in yeast [13][14][15] .A critical member of the COMPASS complex is the SPRY domain protein designated Bre2 in Saccharomyces cerevisiae 11 . Analysis of the A. nidulans genome revealed a putative ortholog, here named CclA. Extracts of cclA delet...
Oxidative cyclizations are important transformations that occur widely during natural product biosynthesis. The transformations from acyclic precursors to cyclized products can afford morphed scaffolds, structural rigidity and biological activities. Some of the most dramatic structural alterations in natural product biosynthesis occur through oxidative cyclization. In this review, we examine the different strategies used by Nature to create new intra-(inter-)-molecular bonds via redox chemistry. The review will cover both oxidation- and reduction-enabled cyclization mechanisms, with an emphasis on the former. Radical cyclizations catalyzed by P450, nonheme iron, α-KG dependent oxygenases and radical SAM enzymes are discussed to illustrate the use of molecular oxygen and S-adenosylmethionine to forge new bonds at unactivated sites via one-electron manifolds. Nonradical cyclizations catalyzed by flavin-dependent monooxygenases and NAD(P)H-dependent reductases are covered to show the use of two-electron manifolds in initiating cyclization reactions. The oxidative installation of epoxides and halogens into acyclic scaffolds to drive subsequent cyclizations are separately discussed as examples of “disappearing” reactive handles. Lastly, oxidative rearrangement of rings systems, including contractions and expansions will be covered.
Nonribosomal peptides (NRPs) are a class of microbial secondary metabolites that have a wide variety of medicinally important biological activities, such as antibiotic (vancomycin), immunosuppressive (cyclosporin A), antiviral (luzopeptin A) and antitumor (echinomycin and triostin A) activities. However, many microbes are not amenable to cultivation and require time-consuming empirical optimization of incubation conditions for mass production of desired secondary metabolites for clinical and commercial use. Therefore, a fast, simple system for heterologous production of natural products is much desired. Here we show the first example of the de novo total biosynthesis of biologically active forms of heterologous NRPs in Escherichia coli. Our system can serve not only as an effective and flexible platform for large-scale preparation of natural products from simple carbon and nitrogen sources, but also as a general tool for detailed characterizations and rapid engineering of biosynthetic pathways for microbial syntheses of novel compounds and their analogs.
The recently sequenced genomes of several Aspergillus species have revealed that these organisms have the potential to produce a surprisingly large range of natural products, many of which are currently unknown. We have found that A. nidulans produces emericellamide A, an antibiotic compound of mixed origins with polyketide and amino acid building blocks. Additionally, we describe the discovery of four previously unidentified, related compounds that we designate emericellamide C-F. Using recently developed gene targeting techniques, we have identified the genes involved in emericellamide biosynthesis. The emericellamide gene cluster contains one polyketide synthase and one nonribosomal peptide synthetase. From the sequences of the genes, we are able to deduce a biosynthetic pathway for the emericellamides. The identification of this biosynthetic pathway opens the door to engineering novel analogs of this structurally complex metabolite.
Pericyclic reactions are among the most powerful synthetic transformations to make multiple regioselective and stereoselective carbon-carbon bonds1. These reactions have been widely applied for the synthesis of biologically active complex natural products containing contiguous stereogenic carbon centers2–6. Despite the prominence of pericyclic reactions in total synthesis, only three naturally existing enzymatic examples, intramolecular Diels-Alder (IMDA) reaction7, Cope8 and Claisen rearrangements9, have been characterized. Here, we report the discovery of a S-adenosyl-L-methionine (SAM) dependent enzyme LepI that can catalyse stereoselective dehydration, bifurcating IMDA/hetero-DA (HDA) reactions via an ambimodal transition state, and a [3,3]-sigmatropic retro-Claisen rearrangement leading to the formation of dihydopyran core in the fungal natural product leporin10. Combined in vitro enzymatic characterization and computational studies provide evidence and mechanistic insight about how the O-methyltransferase-like protein LepI regulates the bifurcating biosynthetic reaction pathways (“direct” HDA and “byproduct recycle” IMDA/retro-Claisen reaction pathways) by utilizing SAM as the cofactor in order to converge to the desired biosynthetic end product. This work highlights that LepI is the first example of an enzyme catalysing a (SAM-dependent) retro-Claisen rearrangement. We suggest that more pericyclic biosynthetic enzymatic transformations are yet to be discovered in the intriguing enzyme toolboxes in Nature11, and propose an ever expanding role of the versatile cofactor SAM in enzyme catalysis.
The Diels-Alder reaction, which forms a six-membered ring from an alkene (dienophile) and a 1,3-diene, is synthetically very useful for construction of cyclic products with high regio- and stereoselectivity under mild conditions. It has been applied to the synthesis of complex pharmaceutical and biologically active compounds. Although evidence on natural Diels-Alderases has been accumulated in the biosynthesis of secondary metabolites, there has been no report on the structural details of the natural Diels-Alderases. The function and catalytic mechanism of the natural Diels-Alderase are of great interest owing to the diversity of molecular skeletons in natural Diels-Alder adducts. Here we present the 1.70 A resolution crystal structure of the natural Diels-Alderase, fungal macrophomate synthase (MPS), in complex with pyruvate. The active site of the enzyme is large and hydrophobic, contributing amino acid residues that can hydrogen-bond to the substrate 2-pyrone. These data provide information on the catalytic mechanism of MPS, and suggest that the reaction proceeds via a large-scale structural reorganization of the product.
Spirotryprostatins, an indole alkaloid class of nonribosomal peptides isolated from Aspergillus fumigatus, are known for their antimitotic activity in tumor cells. Because spirotryprostatins and many other chemically complex spiro-carbon-bearing natural products exhibit useful biological activities, identifying and understanding the mechanism of spiro-carbon biosynthesis is of great interest. Here we report a detailed study of spiro-ring formation in spirotryprostatins from tryprostatins derived from the fumitremorgin biosynthetic pathway, using reactants and products prepared with engineered yeast and fungal strains. Unexpectedly, FqzB, an FAD-dependent monooxygenase from the unrelated fumiquinazoline biosynthetic pathway, catalyzed spiro-carbon formation in spirotryprostatin A via an epoxidation route. Furthermore, FtmG, a cytochrome P450 from the fumitremorgin biosynthetic pathway, was determined to catalyze the spiro-ring formation in spirotryprostatin B. Our results highlight the versatile role of oxygenating enzymes in the biosynthesis of structurally complex natural products and indicate that cross-talk of different biosynthetic pathways allows product diversification in natural product biosynthesis.
The 6,6-quinolone scaffold of the viridicatin-type of fungal alkaloids are found in various quinolone alkaloids which often exhibit useful biological activities. Thus, it is of interest to identify viridicatin-forming enzymes and understand how such alkaloids are biosynthesized. Here an Aspergillal gene cluster responsible for the biosynthesis of 4'-methoxyviridicatin was identified. Detailed in vitro studies led to the discovery of the dioxygenase AsqJ which performs two distinct oxidations: first desaturation to form a double bond and then monooxygenation of the double bond to install an epoxide. Interestingly, the epoxidation promotes non-enzymatic rearrangement of the 6,7-bicyclic core of 4'-methoxycyclopenin into the 6,6-quinolone viridicatin scaffold to yield 4'-methoxyviridicatin. The finding provides new insight into the biosynthesis of the viridicatin scaffold and suggests dioxygenase as a potential tool for 6,6-quinolone synthesis by epoxidation of benzodiazepinediones.
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