126-4 Translation of Halophyte Transcriptome Resources to Improve Salt and Drought Stress Tolerance in Rice.
See more from this Division: C07 Genomics, Molecular Genetics & BiotechnologySee more from this Session: Genomics, Molecular Genetics and Biotechnology: I
Monday, November 3, 2014: 9:50 AM
Hyatt Regency Long Beach, Beacon Ballroom A
Salt and drought stresses negatively affect rice yield. The magnitude of yield reduction depends on the genotype and developmental stage of the plant, and the severity of the stress. While natural variations for stress tolerance exist in the primary and secondary gene pool of rice, conventional breeding to develop salt and drought tolerant varieties has been slow and less successful due to the complexity and low heritability of stress tolerance traits. Extremophiles, such as halophytes, adapt to abiotic stresses by physiological and biochemical adjustments through coordinate regulation and expression of a cascade of genes. Halophytes are of interest to translate their stress adaptation machinery into crop plants. Based on the concept that monocot halophytes are ideal for translational studies for cereals, we profiled the root and leaf transcriptome of Spartina alterniflora (smooth cordgrass), a Louisiana native monocot halophyte, which can withstand salinity up to double the strength of sea water. Digital and quantitative real-time expression profiles revealed significant enrichment (P<0.01) of transcription factors, vacuolar proton pump members and transporters under stress, and indicated novel transcriptional regulation networks in stress adaptation of this grass. Phenotype of rice overexpressors and knock-down mutants for a few selected candidate genes validated their role in stress tolerance in rice. Stress tolerance in overexpresser rice lines was attributed to their anticipatory preparedness by the (over)expression of superior halophyte genes. This was established by maintaining higher relative water content, regulation of stomatal movement, retention of photosynthetic activity, increased accumulation of osmolytes, antioxidants, and ion homeostasis. This study demonstrated that S. alterniflora is a rich reservoir of stress tolerance genes that can be used to develop stress-resilient rice and other cereals. Further, cross-transferability of its genic microsatellite markers indicated that S. alterniflora transcriptome resources will be a valuable platform for comparative transcriptomics studies with other stress tolerant/sensitive grasses.
See more from this Division: C07 Genomics, Molecular Genetics & BiotechnologySee more from this Session: Genomics, Molecular Genetics and Biotechnology: I