Plants of sugarcane (Saccharum spp.) genetically transformed with the gene AtBI- 1 subjected to water deficit in green-house

Sugarcane is one of the main agricultural crops in the Brazilian social and economic scenario. Water stress in the culture of sugarcane is the main limiting factor for increasing productivity accounting for physiological, biochemical and molecular plants that can trigger metabolic disturbances activating programmed cell death (MCP). Knowing that the BI-1 gene has the potential to reduce the effects of MCP triggered by biotic and abiotic stresses in plants, this study aimed to analyze transgenic sugarcane that express the BI-1 gene of Arabidopsis thaliana (AtBI-1) under water stress. Also, transgenic and control plants were inoculated with Puccinia melanocephala fungus demonstrating that the genetic transformation process with the AtBI-1 gene altered the pre-existing characteristics of brown rust resistance in transgenic plants. Studies of tolerance to water deficit were performed in two experiments, the experiment 1 was prepared with transgenic and control plants with 90 days and the experiment 2 used plants with 60 days. Plants from experiment 1 were analyzed as for morphological characteristics such as number of stomata and trichomes, height and diameter of stem after plants being under water for 24 days as were analyzed photosynthetic rate, stomatal behavior, relative water content in leaves while in the experiment 2, plants were analyzed for the levels of proline, enzyme activities of guaiacol peroxidase (GPOX), ascorbate peroxidase (APX) and catalase (CAT) under water deficit for 17 days. These enzymes are involved in deactivation of active elements oxygen. The results demonstrated that the transgenic plants expressing the AtBI-1 gene presented the phenotype of lower height, higher index of leaf area, higher photosynthetic rate, higher stomatal behavior and higher relative water content in leaves than control plants increasing tolerance to drought stress. However, there were low levels of proline, low activity of GPOX activity, APX and CAT in transgenic plants during drought stress compared to control plants of the same treatment, but the observed high constitutive activity of catalase in transgenic plants. Catalase activity in these transgenic plants suggests the possibility of interaction between AtBI-1 and calmudolinas. Future studies may contribute to understand whether the BI-1protein is essential for the activation of catalase by calmudolinas. (AU)