C-Methylation controls the biosynthetic programming of alternapyrone.

Alternapyrone is a highly methylated polyene α-pyrone biosynthesised by a highly reducing polyketide synthase. Mutations of the catalytic dyad residues, H1578A/Q and E1604A, of the C-methyltransferase domain resulted in either significantly reduced or no production of alternapyrone, indicating the importance of C-methylation for alternapyrone biosynthesis.

SAXS reveals highly flexible interdomain linkers of tandem acyl carrier protein-thioesterase domains from a fungal nonreducing polyketide synthase.

Menisporopsin A is a fungal bioactive macrocyclic polylactone, the biosynthesis of which requires only reducing (R) and nonreducing (NR) polyketide synthases (PKSs) to guide a series of esterification and cyclolactonization reactions. There is no structural information pertaining to these PKSs. Here, we report the solution characterization of singlet and doublet acyl carrier protein (ACP2 and ACP1 -ACP2 )-thioesterase (TE) domains from NR-PKS involved in menisporopsin A biosynthesis. Small-angle X-ray scattering (SAXS) studies in combination with homology modelling reveal that these polypeptides adopt a distinctive beads-on-a-string configuration, characterized by the presence of highly flexible interdomain linkers. These models provide a platform for studying domain organization and interdomain interactions in fungal NR-PKSs, which may be of value in directing the design of functionally optimized polyketide scaffolds.

Heterologous biosynthesis of a fungal macrocyclic polylactone requires only two iterative polyketide synthases.

Menisporopsin A is a bioactive macrocyclic polylactone produced by the fungus Menisporopsis theobromae BCC 4162. A scheme for the biosynthesis of this compound has been proposed, in which reducing (R) and non-reducing (NR) polyketide synthases (PKSs) would catalyze the formation of each menisporopsin A subunit, while an additional non-ribosomal peptide synthetase (NRPS)-like enzyme would be required to perform multiple esterification and cyclolactonization reactions. Transcriptome analysis of M. theobromae identified an R-PKS gene, men1, and an NR-PKS gene, men2, which both exhibited highest expression levels during the menisporopsin A production phase. These were cloned into separate vectors for heterologous expression in Aspergillus oryzae NSAR1. Unexpectedly, coexpression of the two PKSs alone was sufficient to catalyze the formation of the macrocyclic polylactone, ascotrichalactone A, a structural derivative of menisporopsin A. The unanticipated esterification and cyclolactonization activities could reside in the unusual thioesterase domain of the NR-PKS, which is similar to that of the NRPS catalyzing elongation and cyclization of trilactone in enterobactin biosynthesis and that of modular PKSs catalyzing macrodiolide formation in elaiophylin and conglobatin biosyntheses.