These results agree with the differences found by Hernández et al

These results agree with the differences found by Hernández et al. [34], who

analyzed the extracellular activity of pectin lyase in both races of C. lindemuthianum under the same conditions employed in this study. When both races were grown BMS202 with glucose, extracellular PNL activity was barely detected after 8 (race 1472) and 10 (race 0) days of incubation, as observed in this study. Plant cell walls from P. vulgaris induced a similarly low PNL activity in the two isolates after 7-8 days of incubation. When pectin esterified to 92% was used as the carbon source, the activity in the pathogenic race nearly doubled compared with the activity in the non-pathogenic race. Early transcription Protein Tyrosine Kinase inhibitor of genes encoding lytic enzymes and late detection of the corresponding activities is a well documented phenomenon in different fungi [8, 30, 65, 68]. Apart from the presence of a regulatory system controlling gene expression, the production of active pectinase and probably other lyticases can be modulated by other mechanisms such as postranslational modification and protein transport [69]. These alternatives may help to explain the differences observed in this study. The pectin lyase of the pathogenic race of C. lindemuthianum is able to degrade highly esterified pectin (92%), AG-881 chemical structure unlike

that of the non-pathogenic race. Apparently, the differences between the pathogenic and non-pathogenic PTK6 races of C. lindemuthianum occur as much at the expression level as at the level of enzymatic activity, and it is clear that the non-pathogenic and pathogenic races of C. lindemuthianum respond of different form to the carbon sources (except for glucose, where the mRNA of Clpnl2 and the active enzyme is synthesized at basal levels). It has been proposed that the basal level of enzymatic activity breaks down the substrate, generating degradation products that further induce enzymatic activity [64]. A similar behavior has been

observed in our laboratory for other enzymes that degrade cell walls, such as cellulases and the xylanase and β-xylosidase of C. lindemuthianum (unpublished data). Several studies have reported that the pectinolytic enzymes play an important role in pathogenesis [70, 71]. These are the first enzymes that act during the infection of the plant, causing extensive degradation of the cell wall and the main symptoms of the disease [72]. However, in addition to enzyme production, the sequence in which the enzymes are produced, the speed of synthesis, concentration and diffusion of enzyme are also fundamental aspects of the pathogenesis process [72]. The non-pathogenic race of C. lindemuthianum used in this work is unable to infect P. vulgaris, and thus its lifestyle is closer to that of a saprophytic fungus.

Comments are closed.