Genetic and biochemical insights into the itaconate pathway of Ustilago maydis enable enhanced production.

The Ustilaginaceae family of smut fungi, especially Ustilago maydis, gained biotechnological interest over the last years, amongst others due to its ability to naturally produce the versatile bio-based building block itaconate. Along with itaconate, U. maydis also produces 2-hydroxyparaconate. The latter was proposed to be derived from itaconate, but the underlying biochemistry and associated genes were thus far unknown. Here, we confirm that 2-hydroxyparaconate is a secondary metabolite of U. maydis and propose an extension of U. maydis' itaconate pathway from itaconate to 2-hydroxyparaconate. This conversion is catalyzed by the P450 monooxygenase Cyp3, encoded by cyp3, a gene, which is adjacent to the itaconate gene cluster of U. maydis. By deletion of cyp3 and simultaneous overexpression of the gene cluster regulator ria1, it was possible to generate an itaconate hyper producer strain, which produced up to 4.5-fold more itaconate in comparison to the wildtype without the by-product 2-hydroxyparaconate. By adjusting culture conditions in controlled pulsed fed-batch fermentations, a product to substrate yield of 67% of the theoretical maximum was achieved. In all, the titer, rate and yield of itaconate produced by U. maydis was considerably increased, thus contributing to the industrial application of this unicellular fungus for the biotechnological production of this valuable biomass derived chemical.

Biologically active Phytophthora mating hormone prepared by catalytic asymmetric total synthesis.

A Phytophthora mating hormone with an array of 1,5-stereogenic centers has been synthesized by using our recently developed methodology of catalytic enantioselective conjugate addition of Grignard reagents. We applied this methodology in a diastereo- and enantioselective iterative route and obtained two of the 16 possible stereoisomers of Phytophthora hormone alpha1. These synthetic stereoisomers induced the formation of sexual spores (oospores) in A2 mating type strains of three heterothallic Phytophthora species, P. infestans, P. capsici, and P. nicotianae but not in A1 mating type strains. The response was concentration-dependent, and the oospores were viable. These results demonstrate that the biological activity of the synthetic hormone resembles that of the natural hormone alpha1. Mating hormones are essential components in the sexual life cycle of a variety of organisms. For plant pathogens like Phytophthora, sexual reproduction is important as a source of genetic variation. Moreover, the thick-walled oospores are the most durable propagules that can survive harsh environmental conditions. Sexual reproduction can thus greatly affect disease epidemics. The availability of synthetic compounds mimicking the activity of Phytophthora mating hormone will be instrumental for further unravelling sexual reproduction in this important group of plant pathogens.