Evaluation of the infection process by Lecanicillium fungicola in Agaricus bisporus by scanning electron microscopy / Evaluación del proceso de infección por Lecanicillium fungicola en Agaricus bisporus por microscopia electrónica de barrido

Background. Lecanicillium fungicola causes dry bubble disease in Agaricus bisporus mushrooms leading to significant economic losses in commercial production. Aims. To monitor the infection process of L. fungicola in Brazilian strains of A. bisporus. Methods. The interaction between the mycelium of L. fungicola (LF.1) and three strains of A. bisporus (ABI 7, ABI 11/14 and ABI 11/21) was studied. Electron microscopy and X-ray microanalyses of vegetative growth and basidiocarp infection were evaluated. Results. Micrographs show that the vegetative mycelium of the Brazilian strains of A. bisporus is not infected by the parasite. The images show that the pathogen can interlace the hyphae of A. bisporus without causing damage, which contributes to the presence of L. fungicola during the substrate colonization, allowing their presence during primordial formation of A. bisporus. In the basidiocarp, germ tubes form within 16h of infection with L. fungicola and the beginning of penetration takes place within 18h, both without the formation of specialized structures. Conclusions. Scanning electron microscopy enabled the process of colonization and reproduction to be observed within the formation of phialides, conidiophores and verticils of L. fungicola. The formation of calcium oxalate crystals by the pathogen was also visible using the X-ray microanalysis, both at the hyphae in the Petri plate and at basidiocarp infection site (AU)

Antecedentes. Lecanicillium fungicola es el agente causal de la enfermedad de la mole seca en Agaricus bisporus, responsable de importantes pérdidas económicas en la producción comercial de esta seta. Objetivos. Comprobar el proceso de infección de L. fungicola en cepas brasileñas de A. bisporus. Métodos. Se estudió la interacción entre el micelio de L. fungicola (LF.1) y tres cepas de A. bisporus (ABI 7, ABI 11/14 y ABI 11/21). Se evaluaron mediante microscopia electrónica y microanálisis de rayos X el crecimiento vegetativo y la infección de los basidiocarpos. Resultados. Las micrografías muestran que el micelio vegetativo de las cepas brasileñas de A. bisporus no resultó afectado por la infección del parásito. Las imágenes muestran también cómo el agente patógeno puede entrelazar las hifas de A. bisporus sin causar daños, lo que contribuye a la perpetuación de L. fungicola durante la colonización del sustrato y durante la formación de los primordios de A. bisporus. En el basidiocarpo, los tubos germinales se forman después de 16h de la infección con L. fungicola y el comienzo de la penetración tiene lugar tras 18h, sin formación de estructuras especializadas. Conclusiones. La microscopia electrónica permite observar el proceso de colonización y reproducción con la formación de fiálides, conidióforos y verticilos de L. fungicola. La formación de cristales de oxalato de calcio por parte del agente patógeno también fue visible mediante el microanálisis por rayos X, tanto en la infección de las hifas en placa de Petri como en la de los basidiocarpos (AU)

Applications in environmental bioinorganic: Nutritional and ultrastructural evaluation and calculus of thermodynamic and structural properties of metal-oxalate complexes.

Lead (Pb) is known by its toxicity both for animals and plants. In order to evaluate its toxicity, plants of Brachiaria brizantha were cultivated on nutritive solution of Hoagland during 90 days and submitted to different concentrations of Pb. The content of macro and micronutrients was evaluated and there was a reduction on root content of Ca, besides the lowest dosages of Pb had induced an increase of N, S, Mn, Cu, Zn and Fe. The cell ultrastructure of leaves and roots were analyzed by transmission electronic microscopy (TEM). Among the main alterations occurred there were invaginations on cell walls, the presence of crystals on the root cells, accumulation of material on the interior of cells and vacuolar compartmentalization. On the leaves the degradation of chloroplasts was observed, as well as the increase of vacuoles. Structures for the formation of oxalate crystals were proposed through molecular modeling and thermodynamic stability. Calculi suggest the formation of highly stable metal-oxalate complexes.