Transcriptional profiles studies in response to biotic and abiotc stress in sugarcane

Sugarcane is a high biomass tropical C4 grass crop which accumulates large quantities of sucrose and is used for bioethanol production, a low-carbon emission fuel. Biotic and abiotic constraints significantly impact crop productivity, because they can severely impair plant growth and performance. Understanding the molecular basis for this loss in productivity will aid in identifying strategies for mitigation. To study these two types of stresses, young sugarcane plants were subject to herbivore and water privation. An investigation was undertaken to study the sugarcane transcriptional changes following Diatraea saccharalis damage, using macroarrays to monitor a selection of transcripts, containing sequences of sugarcane ESTs of serine proteases and serine proteinase inhibitors from the SUCEST (Sugarcane EST Project) database. Macroarray analyses revealed differently expressed sequences in response to herbivory. Real-Time PCR confirmed that 10 ESTs homologous to proteinase inhibitors (4 homologous to maize and rice Bowman-Birk inhibitors (BBI), 5 homologous to maize proteinase inhibitors (MPI) and 1 homologue to subtilisin inhibitor) and 3 ESTs homologous to serine proteases of the S1, S10 and S14 family were positively regulated by herbivory. While the protease inhibitor\'s function in defense is well established, the involvement of plant proteases in response to herbivory still remains to be elucidated. In this work we show that a sugarcane encoding S14 family protease member was upregulated in response to both D. saccharalis damage and wound treatment. Interestingly, homologous sequences from rice and Arabidopsis also responded to the same treatments, suggesting a conserved role of this S14 protease in defense against herbivores. One important application of these results is the identification of genes for use in biotechnological strategies to improve sugarcane insect resistance. Another investigation was undertaken to study the physiological parameters and transcriptional profiles of genes responsive to water stress in young sugarcane plants. Results of this work indicated that termination of irrigation resulted in measurable physiological effects in sugarcane plants and analysis of the expression of the chosen stress-response genes revealed significant differential expression between the control and treatment groups. RNA-Seq results revealed transcriptional activity of 24.142 transcripts from sugarcane leaf subjected to water stress. Gene expression analyses in response to water deprivation revealed 68 (early response) and 2,390 (later response) differentially expressed transcripts on day 3 and day 7, respectively. Sustained decreases in various physiological parameters were observed in water-stressed sugarcane plants after six days of water deprivation. Reductions in photosynthesis rate, stomatal conductance and leaf transpiration occurred before visible physical changes were observed, but this was preceded by significant changes in expression of genes with roles in photosynthesis. RNA-seq identified novel transcripts with roles in early and late response to drought stress and Real-Time qPCR validation confirmed the RNA-Seq results. This will inform further research on water use efficiency in sugarcane, leading to identification of varieties with improved tolerance to adverse environmental conditions. (AU)