A gene for carotene cleavage required for pheromone biosynthesis and carotene regulation in the fungus Phycomyces blakesleeanus.

Mating and sexual development in fungi are controlled by molecular mechanisms that are specific for each fungal group. Mating in Phycomyces blakesleeanus and other Mucorales requires pheromones derived from ß-carotene. Phycomyces mutants in gene carS accumulate large amounts of ß-carotene but do not enter the sexual process. We show that carS encodes a ß-carotene-cleaving oxygenase that catalyzes the first step in the biosynthesis of a variety of apocarotenoids, including those that act as pheromones. Therefore carS mutants cannot stimulate their sexual partners, although they respond to them. CarS catalyzes the biosynthesis of a ß-ring-containing apocarotenoid that inhibits the activity of the carotenogenic enzyme complex in vegetative cells and provides a feedback regulation for the ß-carotene pathway. The carS gene product is a keystone in carotenogenesis and in sexual reproduction.

New virulence groups in Fusarium oxysporum f. sp. phaseoli: the expression of the gene coding for the transcription factor ftf1 correlates with virulence.

Fusarium oxysporum f. sp. phaseoli strains isolated from runner bean plants showing Fusarium wilt symptoms were characterized. The analysis of the genetic diversity of these strains and the comparison with strains formerly isolated from diseased common bean plants grown in the same region of Spain indicated a close genetic similarity among them. Pathogenicity assays carried out on runner bean plants showed virulence differences that allowed the classification of these strains into three groups: super virulent, highly virulent, and weakly virulent. However, all the analyzed strains behaved as highly virulent when inoculated on common bean plants, indicating that virulence is specific of the host-pathogen interaction. We also analyzed the number of copies and expression of the gene encoding the transcription factor ftf1, which has been shown to be specific of virulent F. oxysporum strains and highly up-regulated during plant infection. In planta real-time quantitative polymerase chain reaction expression analysis showed that expression of ftf1 was correlated with the degree of virulence. The comparative analysis of the polymorphic copies of ftf1 detected in the strains here characterized and those detected in the genome sequence of F. oxysporum f. sp. lycopersici strain 4287 indicates that some of the copies are likely nonfunctional.