Drought is a major abiotic stress that affects plant growth, production, and survival. Plants have evolved sophisticated and highly complex reactions to drought stress, including large-scale transcriptome reconfiguration. Foxtail millet (Setaria italica) is a member of the Poaceae family. Because of its outstanding tolerance to drought stress foxtail millet has the potential to become a new model organism. To enrich our knowledge of the processes that contribute to drought resistance, we have used a deep sequencing approach to generate a genome-wide transcriptome of foxtail millet after exposure to simulated drought stress. A large number of differentially expressed genes were characterized; in particular, we examined the roles of small interfering RNAs (siRNAs) and long noncoding RNAs (lncRNAs) in response to a water-deficit condition. These RNAs have remained largely unexplored in previous studies of stress-induced transcriptomes. We found that the reduced levels of 24-nt siRNA flanking genes were associated, for the most part, with proximal up-regulated genes, indicating a potential effect of 24-nt siRNAs on drought-regulated gene expression. Several lncRNAs that responded to the simulated drought stress were also identified, and we found that one of them shared sequence conservation and colinearity with its counterpart in sorghum (Sorghum bicolor). Our findings provide new insights into drought-induced changes in the foxtail millet transcriptome.
The endosperm of cereal grains is one of the most valuable products of modern agriculture. Cereal endosperm development comprises different phases characterized by mitotic cell proliferation, endoreduplication, the accumulation of storage compounds, and programmed cell death. Although manipulation of these processes could maximize grain yield, how they are regulated and integrated is poorly understood. We show that the Retinoblastoma-related (RBR) pathway controls key aspects of endosperm development in maize. Down-regulation of RBR1 by RNAi resulted in up-regulation of RBR3-type genes, as well as the MINICHROMOSOME MAINTE-NANCE 2-7 gene family and PROLIFERATING CELL NUCLEAR ANTI-GEN, which encode essential DNA replication factors. Both the mitotic and endoreduplication cell cycles were stimulated. Developing transgenic endosperm contained 42-58% more cells and ∼70% more DNA than wild type, whereas there was a reduction in cell and nuclear sizes. In addition, cell death was enhanced. The DNA content of mature endosperm increased 43% upon RBR1 downregulation, whereas storage protein content and kernel weight were essentially not affected. Down-regulation of both RBR1 and CYCLIN DEPENDENT KINASE A (CDKA);1 indicated that CDKA;1 is epistatic to RBR1 and controls endoreduplication through an RBR1-dependent pathway. However, the repressive activity of RBR1 on downstream targets was independent from CDKA;1, suggesting diversification of RBR1 activities. Furthermore, RBR1 negatively regulated CDK activity, suggesting the presence of a feedback loop. These results indicate that the RBR1 pathway plays a major role in regulation of different processes during maize endosperm development and suggest the presence of tissue/organlevel regulation of endosperm/seed homeostasis. seed development | endocycle T he seed endosperm is a triploid tissue resulting from the fusion of one haploid sperm nucleus with the diploid central cell nucleus within the female gametophyte. Development of the endosperm in flowering plants is characterized by acytokinetic mitoses of the primary endosperm nucleus, resulting in a syncytium, cellularization of syncytial nuclear domains, and cell proliferation through mitotic activity that is coupled to cell division (1, 2). Additionally, in the Poaceae (grass) family, the endosperm undergoes a rapid growth phase that coincides with accumulation of storage compounds, such as starch and storage proteins, during a specialized type of cell cycle known as endoreduplication. Endoreduplication is characterized by one or more rounds of DNA synthesis in the absence of mitosis, resulting in polyploid cells (3-5). Endoreduplication is highly correlated with cell size in many plant and animal tissues, but its role in endosperm development has not been established. Upon completion of endoreduplication and storage metabolite synthesis, cereal endosperm cells undergo programmed cell death (PCD), resulting in extensive DNA degradation (5, 6). In maize (Zea mays L.), endosperm cells transition from a mitotic to an endore...
BackgroundLate embryogenesis abundant (LEA) proteins are involved in protecting higher plants from damage caused by environmental stresses. Foxtail millet (Setaria italica) is an important cereal crop for food and feed in semi-arid areas. However, the molecular mechanisms underlying tolerance to these conditions are not well defined.ResultsHere, we characterized a novel atypical LEA gene named SiLEA14 from foxtail millet. It contains two exons separated by one intron. SiLEA14 was expressed in roots, stems, leaves, inflorescences and seeds at different levels under normal growth conditions. In addition, SiLEA14 was dramatically induced by osmotic stress, NaCl and exogenous abscisic acid. The SiLEA14 protein was localized in the nucleus and the cytoplasm. Overexpression of SiLEA14 improved Escherichia coli growth performance compared with the control under salt stress. To further assess the function of SiLEA14 in plants, transgenic Arabidopsis and foxtail millet plants that overexpressed SiLEA14 were obtained. The transgenic Arabidopsis seedlings showed higher tolerance to salt and osmotic stress than the wild type (WT). Similarly, the transgenic foxtail millet showed improved growth under salt and drought stresses compared with the WT. Taken together, our results indicated that SiLEA14 is a novel atypical LEA protein and plays important roles in resistance to abiotic stresses in plants.ConclusionWe characterized a novel atypical LEA gene SiLEA14 from foxtail millet, which plays important roles in plant abiotic stress resistance. Modification of SiLEA14 expression may improve abiotic stress resistance in agricultural crops.Electronic supplementary materialThe online version of this article (doi:10.1186/s12870-014-0290-7) contains supplementary material, which is available to authorized users.
Highlight textSiARDP is a DREB-type transcription factor from foxtail millet. SiARDP is involved in ABA-dependent signal pathways under the control of SiARDP and plays a positive role in plant responses to drought stress.
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