Abstract
Pearl millet is a cereal crop known for its high tolerance to drought, heat and salinity stresses as well as for its nutritional quality. The molecular mechanism of drought tolerance in pearl millet is unknown. Here we attempted to unravel the molecular basis of drought tolerance in two pearl millet inbred lines, ICMB 843 and ICMB 863 using RNA sequencing. Under greenhouse condition, ICMB 843 was found to be more tolerant to drought than ICMB 863. We sequenced the root transcriptome from both lines under control and drought conditions using an Illumina Hi-Seq platform, generating 139.1 million reads. Mapping of sequenced reads against the foxtail millet genome, which has been relatively well-annotated, led to the identification of several differentially expressed genes under drought stress. Total of 6799 and 1253 differentially expressed genes were found in ICMB 843 and ICMB 863, respectively. Pathway and gene function analysis by KEGG online tool revealed that the drought response in pearl millet is mainly regulated by pathways related to photosynthesis, plant hormone signal transduction and mitogen-activated protein kinase signaling. The changes in expression of drought-responsive genes determined by RNA sequencing were confirmed by reverse-transcription PCR for 7 genes. These results are a first step to understanding the molecular mechanisms of drought tolerance in pearl millet and lay a foundation for its genetic improvement.
Highlights
Drought is a major abiotic stress that adversely affects agricultural productivity worldwide
Effect of drought treatment on physiology of pearl millet lines Within 5–7 days of drought stress treatment, ICMB 863 started showing drought stress symptoms such as leaf tip drying and rolling, whereas ICMB 843 did not show any of these symptoms
Both lines showed lodging during drought stress, but lodging was more severe in ICMB 863 (Fig 1A)
Summary
Drought is a major abiotic stress that adversely affects agricultural productivity worldwide. Most of the cereal crops on which the world population depends for food are susceptible to drought. Water deficiency is a global concern that is expected to become worse in the decades [1]. Understanding the mechanisms of drought tolerance in cereal crops and development of drought-tolerant varieties are key strategies to maintain yield under drought conditions. Mechanisms that overcome drought stress in plants include drought avoidance, drought tolerance, drought escape and drought recovery [2,3]. Plants respond to drought by inducing both regulatory and functional genes [4].
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