Characterization of CyrI, the hydroxylase involved in the last step of cylindrospermopsin biosynthesis: Binding studies, site-directed mutagenesis and stereoselectivity.

Cylindrospermopsin, a cytotoxin from cyanobacteria, is biosynthesized by a complex pathway, which involves CyrI, an iron and 2-oxoglutarate dependent hydroxylase that transforms 7-deoxy-cylindrospermopsin into cylindrospermopsin and its epimer, 7-epi-cylindrospermopsin, in the last step. The activity of CyrI from Oscillatoria sp. PCC 7926 depends on Fe(II) (Km = 2.1 µM), and 2-oxoglutarate (Km = 3.2 µM), and is strongly inhibited by 7-deoxy-cylindrospermopsin at concentration higher than 1 µM. Using tryptophan fluorescence, we measured the binding to CyrI of Fe(II) (KD = 0.02 µM) and 2-oxoglutarate (KD = 53 µM and KD = 1.1 µM in the absence or presence of 10 µM Fe(II), respectively). The Oscillatoria sp. PCC 6506 CyrI mutants H157A, D159A, H247A, and R257A were all inactive, and impaired in the binding of Fe(II) or 2-oxoglutarate, confirming the identity of the iron ligands and the role of R257 in the binding of 2-oxoglutarate. We constructed several chimeric enzymes using the Oscillatoria sp. PCC 7926 CyrI protein (stereoselective) and that from Oscillatoria sp. PCC 6506 (not stereoselective) to help understanding the structural factors that influence the stereoselectivity of the hydroxylation. Our data suggest that a predicted α-helix in CyrI (positions 87-108) seems to modulate the stereoselectivity of the reaction.

Mutations in Podospora anserina MCM1 and VelC Trigger Spontaneous Development of Barren Fruiting Bodies.

The ascomycete Podospora anserina is a heterothallic filamentous fungus found mainly on herbivore dung. It is commonly used in laboratories as a model system, and its complete life cycle lasting eight days is well mastered in vitro. The main objective of our team is to understand better the global process of fruiting body development, named perithecia, induced normally in this species by fertilization. Three allelic mutants, named pfd3, pfd9, and pfd23 (for "promoting fruiting body development") obtained by UV mutagenesis, were selected in view of their abilities to promote barren perithecium development without fertilization. By complete genome sequencing of pfd3 and pfd9, and mutant complementation, we identified point mutations in the mcm1 gene as responsible for spontaneous perithecium development. MCM1 proteins are MADS box transcription factors that control diverse developmental processes in plants, metazoans, and fungi. We also identified using the same methods a mutation in the VelC gene as responsible for spontaneous perithecium development in the vacua mutant. The VelC protein belongs to the velvet family of regulators involved in the control of development and secondary metabolite production. A key role of MCM1 and VelC in coordinating the development of P. anserina perithecia with gamete formation and fertilization is highlighted.