Diketopiperazine Formation in Fungi Requires Dedicated Cyclization and Thiolation Domains.

Cyclization of linear dipeptidyl precursors derived from nonribosomal peptide synthetases (NRPSs) into 2,5-diketopiperazines (DKPs) is a crucial step in the biosynthesis of a large number of bioactive natural products. However, the mechanism of DKP formation in fungi has remained unclear, despite extensive studies of their biosyntheses. Here we show that DKP formation en route to the fungal virulence factor gliotoxin requires a seemingly extraneous couplet of condensation (C) and thiolation (T) domains in the NRPS GliP. In vivo truncation of GliP to remove the CT couplet or just the T domain abrogated production of gliotoxin and all other gli pathway metabolites. Point mutation of conserved active sites in the C and T domains diminished cyclization activity of GliP in vitro and abolished gliotoxin biosynthesis in vivo. Verified NRPSs of other fungal DKPs terminate with similar CT domain couplets, suggesting a conserved strategy for DKP biosynthesis by fungal NRPSs.

Development of Halogenase Enzymes for Use in Synthesis.

Nature has evolved halogenase enzymes to regioselectively halogenate a diverse range of biosynthetic precursors, with the halogens introduced often having a profound effect on the biological activity of the resulting natural products. Synthetic endeavors to create non-natural bioactive small molecules for pharmaceutical and agrochemical applications have also arrived at a similar conclusion: halogens can dramatically improve the properties of organic molecules for selective modulation of biological targets in vivo. Consequently, a high proportion of pharmaceuticals and agrochemicals on the market today possess halogens. Halogenated organic compounds are also common intermediates in synthesis and are particularly valuable in metal-catalyzed cross-coupling reactions. Despite the potential utility of organohalogens, traditional nonenzymatic halogenation chemistry utilizes deleterious reagents and often lacks regiocontrol. Reliable, facile, and cleaner methods for the regioselective halogenation of organic compounds are therefore essential in the development of economical and environmentally friendly industrial processes. A potential avenue toward such methods is the use of halogenase enzymes, responsible for the biosynthesis of halogenated natural products, as biocatalysts. This Review will discuss advances in developing halogenases for biocatalysis, potential untapped sources of such biocatalysts and how further optimization of these enzymes is required to achieve the goal of industrial scale biohalogenation.

Multi-genome analysis identifies functional and phylogenetic diversity of basidiomycete adenylate-forming reductases.

Among the invaluable benefits of basidiomycete genomics is the dramatically enhanced insight into the potential capacity to biosynthesize natural products. This study focuses on adenylate-forming reductases, which is a group of natural product biosynthesis enzymes that resembles non-ribosomal peptide synthetases, yet serves to modify one substrate, rather than to condense two or more building blocks. Phylogenetically, these reductases fall in four classes. The phylogeny of Heterobasidion annosum (Russulales) and Serpula lacrymans (Boletales) adenylate-forming reductases was investigated. We identified a previously unrecognized phylogenetic branch within class III adenylate-forming reductases. Three representatives were heterologously produced and their substrate preferences determined in vitro: NPS9 and NPS11 of S. lacrymans preferred l-threonine and benzoic acid, respectively, while NPS10 of H. annosum accepted phenylpyruvic acid best. We also investigated two class IV adenylate-forming reductases of Coprinopsis cinerea, which each were active with l-alanine, l-valine, and l-serine as substrates. Our results show that adenylate-forming reductases are functionally more diverse than previously recognized. As none of the natural products known from the species investigated in this study includes the identified substrates of their respective reductases, our findings may help further explore the diversity of these basidiomycete secondary metabolomes.

A Highly Conserved Basidiomycete Peptide Synthetase Produces a Trimeric Hydroxamate Siderophore.

The model white-rot basidiomycete, Ceriporiopsis (Gelatoporia) subvermispora B, encodes putative natural product biosynthesis genes. Among them is the gene for the seven-domain nonribosomal peptide synthetase CsNPS2. It is a member of the as-yet-uncharacterized fungal type VI siderophore synthetase family, which is highly conserved and widely distributed among the basidiomycetes. These enzymes include only one adenylation (A) domain, i.e., one complete peptide synthetase module, and two thiolation/condensation (T-C) didomain partial modules which together constitute an AT1C1T2C2T3C3 domain setup. The full-length CsNPS2 enzyme (274.5 kDa) was heterologously produced as a polyhistidine fusion in Aspergillus niger as a soluble and active protein. N 5-acetyl-N 5-hydroxy-l-ornithine (l-AHO) and N 5-cis-anhydromevalonyl-N 5 -hydroxy-l-ornithine (l-AMHO) were accepted as the substrates, based on results of an in vitro substrate-dependent [32P]ATP-pyrophosphate radioisotope exchange assay. Full-length holo-CsNPS2 catalyzed amide bond formation between three l-AHO molecules to release the linear l-AHO trimer, called basidioferrin, as the product in vitro, which was verified by liquid chromatography-high-resolution electrospray ionization-mass spectrometry analysis. Phylogenetic analyses suggested that type VI family siderophore synthetases are widespread in mushrooms and evolved in a common ancestor of basidiomycetes.IMPORTANCE The basidiomycete nonribosomal peptide synthetase CsNPS2 represents a member of a widely distributed but previously uninvestigated class (type VI) of fungal siderophore synthetases. Genes orthologous to CsNPS2 are highly conserved across various phylogenetic clades of the basidiomycetes. Hence, our work serves as a broadly applicable model for siderophore biosynthesis and iron metabolism in higher fungi. Also, our results on the amino acid substrate preference of CsNPS2 support a further understanding of the substrate selectivity of fungal adenylation domains. Methodologically, this report highlights the Aspergillus niger/SM-Xpress-based system as a suitable platform to heterologously express multimodular basidiomycete biosynthesis enzymes in the >250-kDa range in soluble and active form.

RadH: A Versatile Halogenase for Integration into Synthetic Pathways.

Flavin-dependent halogenases are useful enzymes for providing halogenated molecules with improved biological activity, or intermediates for synthetic derivatization. We demonstrate how the fungal halogenase RadH can be used to regioselectively halogenate a range of bioactive aromatic scaffolds. Site-directed mutagenesis of RadH was used to identify catalytic residues and provide insight into the mechanism of fungal halogenases. A high-throughput fluorescence screen was also developed, which enabled a RadH mutant to be evolved with improved properties. Finally we demonstrate how biosynthetic genes from fungi, bacteria, and plants can be combined to encode a new pathway to generate a novel chlorinated coumarin "non-natural" product in E. coli.

Structure and biocatalytic scope of thermophilic flavin-dependent halogenase and flavin reductase enzymes.

Flavin-dependent halogenase (Fl-Hal) enzymes have been shown to halogenate a range of synthetic as well as natural aromatic compounds. The exquisite regioselectively of Fl-Hal enzymes can provide halogenated building blocks which are inaccessible using standard halogenation chemistries. Consequently, Fl-Hal are potentially useful biocatalysts for the chemoenzymatic synthesis of pharmaceuticals and other valuable products, which are derived from haloaromatic precursors. However, the application of Fl-Hal enzymes, in vitro, has been hampered by their poor catalytic activity and lack of stability. To overcome these issues, we identified a thermophilic tryptophan halogenase (Th-Hal), which has significantly improved catalytic activity and stability, compared with other Fl-Hal characterised to date. When used in combination with a thermostable flavin reductase, Th-Hal can efficiently halogenate a number of aromatic substrates. X-ray crystal structures of Th-Hal, and the reductase partner (Th-Fre), provide insights into the factors that contribute to enzyme stability, which could guide the discovery and engineering of more robust and productive halogenase biocatalysts.

Plant-like biosynthesis of isoquinoline alkaloids in Aspergillus fumigatus.

Natural product discovery efforts have focused primarily on microbial biosynthetic gene clusters (BGCs) containing large multimodular polyketide synthases and nonribosomal peptide synthetases; however, sequencing of fungal genomes has revealed a vast number of BGCs containing smaller NRPS-like genes of unknown biosynthetic function. Using comparative metabolomics, we show that a BGC in the human pathogen Aspergillus fumigatus named fsq, which contains an NRPS-like gene lacking a condensation domain, produces several new isoquinoline alkaloids known as the fumisoquins. These compounds derive from carbon-carbon bond formation between two amino acid-derived moieties followed by a sequence that is directly analogous to isoquinoline alkaloid biosynthesis in plants. Fumisoquin biosynthesis requires the N-methyltransferase FsqC and the FAD-dependent oxidase FsqB, which represent functional analogs of coclaurine N-methyltransferase and berberine bridge enzyme in plants. Our results show that BGCs containing incomplete NRPS modules may reveal new biosynthetic paradigms and suggest that plant-like isoquinoline biosynthesis occurs in diverse fungi.