[摘要] ENGLISH ABSTRACT: This project involved the analysis of genes in Solanaceae species that have previously been shown to be involved in the phosphorylation of starch or its subsequent dephosphorylation. Both these processes are essential for normal starch mobilization. A tomato conditional mutant lacking the starch phosphorylating enzyme glucan water dikinase was analyzed. It is known that starch accumulates transiently in tomato fruit and is degraded throughout the ripening process. The study aimed to determine the effect of inhibited starch degradation on fruit development. Unfortunately no effect on starch mobilisation was found in the fruit of the mutant. Immunoblot analysis revealed expression of Glucan Water Dikinase (GWD) within the fruit of the tomato mutant indicating that the conditionality of the mutation was compromised.The second set of experiments analyzed the roles of Starch Excess4 (SEX4), Like Sex Four-1 and Like Sex Four-2 (LSF1 and LSF2) in starch degradation in potato and Nicotiana benthamiana. These enzymes have, thus far, only been studied in Arabidopsis, with the proposed role for SEX4 and LSF2 being that they are involved in dephosphorylation of the C-6 and C-3 positions of starch breakdown products. The role of LSF1 is unclear, although it is not thought to be a phosphatase.SEX4, LSF1 and LSF2 were repressed individually while the expression of SEX4 and LSF2 were also inhibited simultaneously. Using a transient repression system in N. benthamiana it was shown that all of the genes play a role in leaf starch degradation. The SEX4 and LSF2 enzymes were shown to influence the proportion of phosphate located on the starch which contained an altered ratio of C-3/C-6 phosphate.Stably transformed potato plants were produced where SEX4 and LSF2 were successfully repressed in potato leaves and tubers. Although AtLSF2 had been shown not to be essential for normal starch degradation on its own, in potato plants when LSF2 was repressed, the plants developed a starch-excess phenotype. Taken together with the N. benthamiana data this indicates that LSF2 plays a bigger role in leaf starch degradation in Solanaceae than in Arabidopsis.The ratio of C-3/C-6 phosphate was also altered in tuber starch from some of the silenced plants. Starch from SEX4 repressed potato plants contained increased amounts of glucose-6-phosphate and increased glucose-3-phosphate in the tuber when compared to the WT. An increase in the proportion of C-6 or C-3 phosphate is not surprising with SEX4 being characterized as a phosphatase specific for C-6 position and LSF2 for the C-3 position in Arabidopsis, however the combined increase in C-3 and C-6 amounts in StSEX4 silenced plants is interesting. The differences seen in the phosphate alteration in both N. benthamiana leaves and potato tubers indicates that in Solanaceae species these proteins may have a slightly altered specificity when compared with Arabidopsis, although they are undoubtedly involved in starch degradation.The effect of silencing SEX4 or LSF2 on cold-induced sweetening was also investigated, with no effect being found. This may be because of functional redundancy between the proteins and a better approach in terms of blocking cold sweetening would be to simultaneously repress SEX4 and LSF2.Overall, these enzymes seem to play similar roles in leaves of Solanum species as has been described in Arabidopsis. The starch from the engineered plants did have an altered phosphate ratio and further analysis is needed to determine if this leads to improved or additional functionality.