Abstract
Seed dormancy is a mechanism underlying the inability of viable seeds to germinate under optimal environmental conditions. To achieve rapid and uniform germination, wheat and other cereal crops have been selected against dormancy. As a result, most of the modern commercial cultivars have low level of seed dormancy and are susceptible to preharvest sprouting when wet and moist conditions occur prior to harvest. As it causes substantial loss in grain yield and quality, preharvest sprouting is an ever-present major constraint to the production of wheat. The significance of the problem emphasizes the need to incorporate an intermediate level of dormancy into elite wheat cultivars, and this requires detailed dissection of the mechanisms underlying the regulation of seed dormancy and preharvest sprouting. Seed dormancy research in wheat often involves after-ripening, a period of dry storage during which seeds lose dormancy, or comparative analysis of seeds derived from dormant and non-dormant cultivars. The increasing development in wheat genomic resources along with the application of transcriptomics, proteomics, and metabolomics approaches in studying wheat seed dormancy have extended our knowledge of the mechanisms acting at transcriptional and post-transcriptional levels. Recent progresses indicate that some of the molecular mechanisms are associated with hormonal pathways, epigenetic regulations, targeted oxidative modifications of seed mRNAs and proteins, redox regulation of seed protein thiols, and modulation of translational activities. Given that preharvest sprouting is closely associated with seed dormancy, these findings will significantly contribute to the designing of efficient strategies for breeding preharvest sprouting tolerant wheat.
Highlights
Seed is an important part of crop’s life cycle as it establishes the generation
WHEAT SEED DORMANCY AND CHANGES IN SEED PROTEOME In addition to induction of changes in protein redox status, dry after-ripening triggers differential abundance of specific seed stored proteins in the whole seed of wheat, including repression of those identified as storage protein triticin, antioxidative superoxide dismutase (SOD), α-amylase/trypsin inhibitor designated as CM16, a protease inhibitor cystatin, and 14-3-3 proteins (14-3-3s) that controls abscisic acid (ABA) action in seeds positively (Gao et al, 2013)
PROSPECTS Previous studies have shown that the role of after-ripening in enhancing dormancy breakage in wheat seeds is associated with changes in gene expression and seed proteome, and targeted oxidation of seed stored transcripts and proteins
Summary
Seed is an important part of crop’s life cycle as it establishes the generation. Some environmental factors appear to have similar effects on the dormancy of seeds in different genotypes; for example, high temperatures, short days, drought, and nutrient availability during seed development are generally associated with low level of seed dormancy at maturity (Rodriguez et al, 2011). Proteomic studies have shown that storage and non-storage proteins that will serve as a primary source of reduced nitrogen and participate in several cellular processes during germination, respectively, are stored in mature dormant seeds (Bykova et al, 2011b; Gao et al, 2013). Dry after-ripening induces accumulation of reactive oxygen species (ROS), and thereby oxidative modifications of seed stored mRNAs and proteins, which upon imbibition affect their translatability and functionality, respectively (Oracz et al, 2007; El-Maarouf-Bouteau et al, 2013; Gao et al, 2013). Comparison of embryos derived from dry dormant and dry after-ripened sunflower seeds revealed that active www.frontiersin.org
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