Project description:Whole-genome transcriptional profiles of rice cell types, isolated by laser-capture microdissection. The first comprehensive multi-organ cell type transcriptome atlas from a plant, with 40 distinct cell types from several developmental stages of seeds, shoots and roots, reveals cell-specific promoter motifs, interaction partner candidates, hormone response centers, and other previously unrecognized cellular properties and patterns. Keywords: Cell type comparison

Project description:Rice (Oryza sativa L.) is one of the most important staple foods in the world, feeding more than 50% of the human population. One of its most damaging pathogens, with major impact on rice yield, is the migratory root rot nematode Hirschmanniella oryzae. In comparison with the existing knowledge on the infection process of dicots by sedentary nematodes, far less is known about the interaction between monocot plants and nematodes or plant interactions with migratory nematode species. Therefore, to gain deeper insight into the systemic transcriptional changes in rice after migratory root rot nematode infection we have performed mRNA-Seq on the shoots of root rot nematode infected rice plants. The observations were independently validated using qRT-PCR and biochemical analyses. This research reveals significant modifications in the metabolism of the plant, with a general suppression of chlorophyll biosynthesis, and primary metabolic processes involved in plant growth . Differential expression analysis between controls rice shoots and shoots from root rot nematode (H. oryzae) infected rice at two time points.

Project description:Plant organ formation, or organogenesis is the process in which the primordium derived from shoot apical meristem develops into an organ with a given shape and proper function, through a series of cell division and differentiation. To decipher the genetic program underling plant organ formation, we targeted early rice stamen development that covers most important events in male organ formation and germ cell initiation in plants.

Project description:We performed the transcriptome-wide m6A profiling (MeRIP) with poly(A) RNA samples isolated from shoots and roots of wild type (Nipp), FTO homogeneous transgenic (FTO) and demethylation activity dead mutant variant of FTO transgenic (FTOmut) rice plants. The m6A motif and the distribution of the detected m6A sites along transcripts were consistent with reported results from previous m6A sequencing studies in plants. We then analyzed the differentially methylated m6A sites in poly(A) RNA species including those transcribed from gene loci and from repetitive elements (repeat RNAs). Compared to Nipp plants, both shoots and roots of FTO transgenic plants had showed more hypomethylated m6A peaks (hypo-m6A, 222 in shoots and 3313 in roots) than hypermethylated m6A peaks (hyper-m6A, 63 in shoots and 127 in roots) in mRNAs, while FTOmut rice had showed more hyper-m6A in shoots (349 for hyper vs 31 for hypo) but more hypo-m6A in roots (291 for hyper vs 380 for hypo) than the WT. The hypomethylated m6A peaks in FTO transgenic plants were highly enriched within 3'UTR. Gene Ontology (GO) analysis of these identified hypomethylated m6A-containing coding genes in both FTO transgenic rice shoots and roots revealed an enrichment for functional annotations related to “cellular homeostatic process”, “one-carbon and small molecule metabolic process”, and “gene expression”. We also found the extent of m6A hypomethylation was more pronounced for repeat RNAs than for mRNA species.The quantitative RNA-seq analysis that included ERCC spike-in controls confirmed that FTO plants do indeed accumulate higher overall levels of poly(A) RNA than do WT shoots and roots. Above all, FTO mediated m6A demethylation in plant mRNA and repeats RNA, leading to the activation of transcription.

Project description:Rice (Oryza sativa L.) is one of the most important staple foods in the world, feeding more than 50% of the human population. One of its most damaging pathogens, with major impact on rice yield, is the migratory root rot nematode Hirschmanniella oryzae. In comparison with the existing knowledge on the infection process of dicots by sedentary nematodes, far less is known about the interaction between monocot plants and nematodes or plant interactions with migratory nematode species. Therefore, to gain deeper insight into the systemic transcriptional changes in rice after migratory root rot nematode infection we have performed mRNA-Seq on the shoots of root rot nematode infected rice plants. The observations were independently validated using qRT-PCR and biochemical analyses. This research reveals significant modifications in the metabolism of the plant, with a general suppression of chlorophyll biosynthesis, and primary metabolic processes involved in plant growth .

Project description:Nitrogen is major nutrient for plant growth. Two forms for inorganic nitrogen are available for plant, ammonium and nitrate. External status of them affects largely plant growth and production. Generally, root is a sole organ to uptake nitrogen. Hence, identifying regulatory genes depend on nitrogen status in roots is important to improve sustainable production or rice. To isolate the candidate gene, array experiments were performed. Consequently, we isolated genes which showed marked accumulation in deficient and sufficient concentrations of ammonium in roots.

Project description:Plant hormones and small secretory peptides often function as environmental stress mediators. Some recent reports indicate that small secretory peptides, such as CLAVATA3/EMBRYO SURROUNDING REGION-RELATED (CLE), also function as mediators of environmental stimuli. CLE３ is induced in roots by defense elicitor treatment. Plants without functional CLE3 showed compromized defense gene responses in shoots when plant roots were treated with NaSA. Here, we identified specific genes downstream of CLE3 in roots and shoots with transformed Arabidopsis plants.

Project description:Climate change is affecting crop production due to soil salinization and water scarcity, and is predicted to worsen in the coming years. Rice is a major staple food and the most salt-sensitive cereal. High salinity in the soil triggers several adaptive responses in rice to cope with osmotic and ionic stress at the physiological, cellular and molecular levels. A major QTL for salinity tolerance, named Saltol, is present on chromosome 1 of Indian rice landrace varieties such as Pokkali and Nona Bokra. In this study, we characterized the physiological and early proteomic responses to salinity in FL478, an inbred rice line harboring the Saltol region. For this, plantlets were cultured in hydroponic cultures with 100 mM NaCl and evaluated at 6, 24 and 48h. At the physiological level, salinity significantly reduced shoot length after 48 h, whereas root length significantly increased. Moreover, the Na+/K+ ratio was maintained at lower levels in the shoots compared to the roots FL478 plantlets. On the other hand, roots showed a faster and more coordinated proteomic response than shoots, which was evident from only 6h of treatment. These responses were markedly related with transcription- and translation-related proteins. Moreover, roots exhibited a higher accumulation of stress-related proteins in response to salinity treatment, like peroxidase and SalT, which are both present in the Saltol QTL. Both, physiological and proteomic response, showed that roots respond in a highly adaptive manner to salinity stress compared to shoots, which suggests that this tissue is critical to the tolerance observed in varieties harbouring the Saltol region.

Project description:Plant organ formation, or organogenesis is the process in which the primordium derived from shoot apical meristem develops into an organ with a given shape and proper function, through a series of cell division and differentiation. To decipher the genetic program underling plant organ formation, we targeted early rice stamen development that covers most important events in male organ formation and germ cell initiation in plants. Totally, seven samples were used in this experiment. Stamens of stages 2-6 was collected through microdissection under microscope. And to ensure the stamen primordia collected are at corresponding stages, rice panicles were cut in half longitudinally, one half for paraffin sectioning to confirm developmental stages and the other half for preparing GEP samples. Samples of primordial and just-expanded third leaves were used as controls because leaf and stamen are homolog organs. RNA was extracted and amplified with Two-Cycle Eukaryotic Target Labeling Assay kit, and then hybridized to microarrays. Three biological replicates were applied for each sample.

Project description:Although previous studies have addressed the possible benefits of arbuscular mycorrhizal (AM) symbiosis for rice plants under salinity, the underlying molecular mechanisms are still unclear. Here, we showed that rice colonized with AM fungi had better growth performance and higher K+/Na+ ratio under salt stress. Differentially expressed genes (DEGs) responding to AM symbiosis especially under salt stress were obtained from RNA sequencing. AM-regulated DEGs in cell wall modification and peroxidases categories were mainly upregulated in shoots, suggesting AM symbiosis might assist in relaxing the cell wall and scavenging reactive oxygen species (ROS). AM symbiosis indeed improved ROS scavenging capacity in rice shoots under salt stress. In addition, genes involved in Calvin cycle and terpenoid synthesis were enhanced by AM symbiosis in shoots and roots under salt stress, respectively. AM-upregulated cation transporters and aquaporin in both shoots and roots were highlighted. Strikingly, “protein tyrosine kinase activity” subcategory was the most significantly over-represented GO term among all AM-upregulated and downregulated DEGs in both shoots and roots, highlighting the importance of kinase on AM-enhanced salinity tolerance. Overall, our results from the transcriptomic analyses indicate that AM symbiosis uses a multipronged approach to help plants achieve salt stress tolerance.