Elucidation of novel drought-responsive genes from tuber transcriptome of cassava under water deficit stress

Cassava (Manihot esculenta Carntz) is the major starchy root crop grown in the tropical parts of the world. Two cassava clones contrasting for their drought tolerance capacity (8S501- drought tolerant and H97-drought sensitive) were selected and grown in the field for studying the agronomical and molecular changes in both the clones under drought stress conditions. A reduction in the number of tuberous roots per plant, tuberous root length, average single tuber weight and tuber yield per plant was observed under drought stress when compared with the control conditions and also significantly lower mean values were observed for the sensitive clone H97 than that of the tolerant clone 8S501 when measured at 60 days of stress. Transcriptome sequencing of the tuber tissues of the two clones was done at 60 days of imposing drought stress. Different genes belonging to various groups like aquaporins, transporter genes, growth regulator related genes, calcium binding and mineral transfer-related genes, transferase genes and transcription factors were differentially expressed in the tubers under drought stress. Comparative transcriptomics revealed that acyl-CoA oxidase, primary-amine oxidase, glutathione peroxidase, vesicle transport, late embryogenesis abundant protein related, histone demethylase, BR-signaling kinase, palmitoyltransferase, DNA mismatch repair protein, heat shock protein related, starch/sucrose metabolic pathway related and MFS transporter genes were differentially expressed in the tubers of the tolerant clone 8S501 relative to the susceptible clone H97.