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DEFENCE GENE EXPRESSION IN THE TOMATO-VERTICILLIUM PATHOSYSTEMCastroverde, Christian Danve 22 April 2010 (has links)
In tomato (Solanum lycopersicum), race-specific resistance against the fungal wilt pathogen Verticillium dahliae race 1 (Vd1) is established in the stem. However, the molecular factors and mechanisms leading to this resistance response are still unknown. In this study, Craigella resistant (CR) and susceptible (CS) tomato plants were successfully infected with Vd1 and this was verified by fungal quantification and symptom score assays. Previous microarray results showed interesting patterns of defence gene expression that correlated with biological phenomena. Plant defence genes code for proteins that are responsible for or associated with the plant resistance response. Through RT-PCR, this thesis set out to confirm these microarray observations and also to generate expression data for genes in which sensitivity was an issue in the microarray. The standard RT-PCR data confirmed a number of the microarray results, but some conflicts remained. From the defence genes investigated, there was agreement between the microarray data and the RT-PCR data for pre-mRNA processing factor 8, class IV chitinase, cyclin-dependent kinase inhibitor and IMP dehydrogenase/GMP reductase. Partial agreement was observed for genes coding for ethylene response factor 2, phenylalanine ammonia lyase and P6 protein. However, there
was total disagreement for 14-3-3, beta-glucanase, P1a, RNA-binding protein, calcium-binding protein and S-Adenosyl-L-methionine: hydroxide adenosyltransferase. Real-time
RT-PCR was attempted to clarify the remaining issues but further discrepancies arose, particularly in the Ve resistance genes. To resolve these discrepancies, two approaches were designed: (1) one based on the use of a universal internal control and (2) another based on restriction enzyme digestion. In general, the results were more consistent with standard RT-PCR. Overall, this study showed that standardization of a system involving vascular pathogens, leading to reproducible analysis, was possible but only with proper controls and additional validation. Standard RT-PCR appeared to offer a more accurate picture of the expression of defence genes in the tomato-Verticillium pathosystem. The defence gene expression results confirmed in this study remain as potential insights into the molecular mechanisms for Verticillium resistance in tomato plants.
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