Chitosan Is Necessary for the Structure of the Cell Wall, and Full Virulence of .

Smut fungi comprise a large group of biotrophic phytopathogens infecting important crops, such as wheat and corn. is a plant pathogenic fungus responsible for common smut in maize and teocintle. Through our analysis of the transcriptome of the yeast-to-mycelium dimorphic transition at acid pH, we determined the number of genes encoding chitin deacetylases of the fungus, and observed that the gene encoding one of them (UMAG_11922; ) was the only one up-regulated.

Tec1, a member of the TEA transcription factors family, is involved in virulence and basidiocarp development in Ustilago maydis.

The life cycle of Ustilago maydis involves alternation of a haploid saprophytic yeast-like stage and a dikaryotic hyphal virulent form. Under in vitro conditions, basidiocarps are formed. Analysis of the transcriptional network of basidiocarp formation revealed the possible involvement of a Tec transcription factor (Tec1, UMAG_02835) in the process.

Acid pH Strategy Adaptation through in .

The role of the putative homolog of the transcriptional repressor , previously described in , and Cryptococcus neoformans, was analyzed by means of its mutation. In this gene regulates a set of stress-responsive genes, and in it is involved in pathogenesis. It was observed that the gene regulates several aspects of the cell response to acid pH, such as the production of mannosyl-erythritol lipids, inhibition of the expression of the siderophore cluster genes, filamentous growth, virulence and oxidative stress.

Analysis of the photoreceptors involved in the light-depending basidiocarp formation in Ustilago maydis.

We have described that formation of basidiocarps by Ustilago maydis requires illumination. In the current research, we have proceeded to analyze what kind of light receptors are involved in this phenomenon. Accordingly, we investigated whether the homologues of the White Collar (WC), and the phytochrome (PHY) genes played a role in this process.

Somatic Embryogenesis in Common BeanPhaseolus vulgaris L.

Common bean Phaseolus vulgaris L. has been shown to be a recalcitrant plant to induce somatic embryogenesis (SE) under in vitro conditions. An alternative strategy to yield SE is based upon the use of a cytokinin (benzyladenine) coupled with osmotic stress adaptation instead of the auxin-inducing SE in common bean.

Transcriptional analysis of the adaptation of Ustilago maydis during growth under nitrogen fixation conditions.

Regulation of genes involved in nitrogen metabolism likely plays a role in the ability of fungi to exploit and survive under different environmental situations. To learn about the mechanism of adaptation of the biotrophic fungus Ustilago maydis from a medium containing a source of fixed nitrogen, to a medium depending on the ability to fix N by its bacterial endosymbiont, we explored gene expression profiles using RNA-Seq analyses under these two conditions. The differentially expressed (DE) fungal genes were analyzed, identifying 90 genes that were regulated 24 h after shifting the fungus to media lacking ammonium nitrate as a nitrogen source.

Trichoderma: sensing the environment for survival and dispersal.

Species belonging to the genus Trichoderma are free-living fungi common in soil and root ecosystems, and have a broad range of uses in industry and agricultural biotechnology. Some species of the genus are widely used biocontrol agents, and their success is in part due to mycoparasitism, a lifestyle in which one fungus is parasitic on another. In addition Trichoderma species have been found to elicit plant defence responses and to stimulate plant growth.