Browsing by Author "Mbewana, Sandiswa"
Now showing 1 - 1 of 1
Results Per Page
Sort Options
- ItemFunctional analysis of a lignin biosynthetic gene in transgenic tobacco(Stellenbosch : University of Stellenbosch, 2010-03) Mbewana, Sandiswa; Vivier, Melane A.; Joubert, Albert; University of Stellenbosch. Faculty of Agrisciences. Dept. of Viticulture and Oenology. Institute for Wine Biotechnology.ENGLISH ABSTRACT: Necrotrophic fungi infect many economically important crop plants. This results in great losses in the agricultural sector world-wide. Understanding the nature by which plants respond to pathogens is imperative for genetically enhancing disease resistance in plants. Research tools have significantly contributed to our understanding of how the plant responds to pathogen attack, identifying an array of defence mechanisms used by plants upon attack. Many fungal pathogens secrete endopolygalacturonases (endoPGs) when infecting plants. These hydrolytic enzymes are inhibited by polygalacturonase-inhibiting proteins (PGIPs) associated with plant cell walls. PGIPs are well characterised and their current known functions are all linked to endoPG inhibition and the subsequent upregulation of plant defence pathways. Work on grapevine PGIPs have shown that apart from being efficient antifungal proteins, leading to protection of the plant against Botrytis cinerea when overexpressed, PGIPs might also have additional functions linked to cell wall strengthening. This working hypothesis formed the motivation of this study where a cinnamyl alcohol dehydrogenase (CAD) (1.1.1.195) gene was targeted for functional analysis in tobacco (Nicotiana tabacum). Some previous work and genetic resources obtained is relevant to this study, specifically previously characterized transgenic tobacco lines overexpressing the Vitis vinifera pgip1 (Vvpgip1) gene. These lines have confirmed PGIP-specific resistance phenotypes against B. cinerea, as well as increased levels of CAD transcripts in healthy plants. Moreover, preliminary evaluations indicated increased lignin levels as well as differential expression of several other cell wall genes in these overexpressing lines (in the absence of infections). In this study we generated a transgenic tobacco population, overexpressing the native CAD14 gene, via Agrobacterium transformations. The transgene was overexpressed with the Cauliflower Mosaic Virus promoter (CaMV 35Sp). The CAD transgenic population was analyzed for transgene integration and expression and showed active transcription, even from leaves that normally don’t express CAD to high levels. These lines, together with the untransformed control, and a representative transgenic VvPGIP1 tobacco line previously characterized with elevated expression of CAD were used for all further analyses, specifically CAD activity assays of stems and leaves, as well as whole plant infections with B. cinerea. CAD enzyme activity assays were performed on healthy uninfected plant lines, without inducing native CAD expression or resistance phenotypes (i.e. without Botrytis infection). CAD activity was detected in leaves and stems, but a statistically sound separation between the CAD population and the untransformed control was only observed in the stems. The CAD assays also confirmed previous results that indicated that CAD transcription was upregulated in the PGIP line in the absence of infection. Overall, in all plant lines the stems exhibited 10-fold higher levels of CAD activity than the leaves, but the transgenic VvPGIP1 line showed a further 2-3-fold increase in CAD activity in the stems, when compared to the untransformed control and the majority of the CAD overexpressing lines. Disease assessment by whole plant infections with B. cinerea of the CAD transgenic plants revealed reduced disease susceptibility towards this pathogen. A reduction in disease susceptibility of 20 – 40% (based on lesion sizes) was observed for a homologous group of transgenic lines that was statistically clearly separated from the untransformed control plants following infection with Botrytis over an 11-day-period. The VvPGIP1 transgenic line displayed the strongest resistance phenotype, with reduction in susceptibility of 47%. The reduction in plant tissue maceration and lesion expansion was most pronounced in the VvPGIP1 line compared to the CAD transgenic plants, while the CAD transgenic plants showed more reduction than the untransformed control. In combination, the data confirms that CAD upregulation could lead to resistance phenotypes. Relating this data back to the previously observed upregulation of CAD in the VvPGIP1-overexpressing lines, the findings from this study corroborates that increased CAD activity contributes to the observed resistance phenotypes, possibility by strengthening the cell wall. In conclusion, this study yielded a characterized transgenic population overexpressing the CAD14 gene; this overexpression contributed to increased RNA transcription compared to the untransformed control plant, increased CAD activity (most notably in the stems) and a disease resistance phenotype against Botrytis. These findings corroborates the current working hypothesis in our group that PGIPs might have a role in preparing the plant cell for attack by contributing to specific cell wall changes. The exact mechanisms are still currently unknown and under investigation. The transgenic lines generated in this study will be invaluable in the subsequent analyses where these various phenotypes will be subjected to profiling and accurate cell wall analyses.