Project description:Understanding the mechanisms of transcriptional regulation for genes involved with FA biosynthesis and TAG accumulation in seeds can represent an important step in the development of crops with increased oil content. Among well studied transcription factors (TFs), WRINKLED1 (WRI1), a member of the APETALA2 (AP2) family of TFs, has been characterized as a central regulator of FA biosynthesis in seeds of many plant species. Despite its importance for the process, the detailed mechanisms of WRI1 function in regulating FA biosynthesis in seeds is still not well understood. This study aimed to characterize the gene networks controled by WRI1 during soybean embryo development and its function as central regulator of FA biosynthesis and TAG accumulation in seeds. In this part of the study, we identified genes misregulated in the embryos of the Arabidopsis mutant wrinkled1-1, when compared to wild-type.

Project description:To dissect the gene regulatory networks operating during soybean embryo development, we identified the binding sites genome-wide for transcription factor GLYMA.06G314400 and GLYMA.13G317000 in early maturation embryos using ChIP-seq.

Project description:To dissect the gene regulatory networks operating during soybean embryo development, we identified the binding sites genome-wide for transcription factor GLYMA.04G093300 and GLYMA.06G314400 in cotyledon stage embryos using ChIP-seq.

Project description:BACKGROUND:The complexity of RNA regulation is one of the current frontiers in animal and plant molecular biology research. RNA-binding proteins (RBPs) are characteristically involved in post-transcriptional gene regulation through interaction with RNA. Recently, the mRNA-bound proteome of mammalian cell lines has been successfully cataloged using a new method called interactome capture. This method relies on UV crosslinking of proteins to RNA, purifying the mRNA using complementary oligo-dT beads and identifying the crosslinked proteins using mass spectrometry. We describe here an optimized system of mRNA interactome capture for Arabidopsis thaliana leaf mesophyll protoplasts, a cell type often used in functional cellular assays. RESULTS:We established the conditions for optimal protein yield, namely the amount of starting tissue, the duration of UV irradiation and the effect of UV intensity. We demonstrated high efficiency mRNA-protein pull-down by oligo-d(T)25 bead capture. Proteins annotated to have RNA-binding capacity were overrepresented in the obtained medium scale mRNA-bound proteome, indicating the specificity of the method and providing in vivo UV crosslinking experimental evidence for several candidate RBPs from leaf mesophyll protoplasts. CONCLUSIONS:The described method, applied to plant cells, allows identifying proteins as having the capacity to bind mRNA directly. The method can now be scaled and applied to other plant cell types and species to contribute to the comprehensive description of the RBP proteome of plants.

Project description:Gene expression profiles during seed development and fatty acid (FA) metabolism, as well as the relevant regulation, of Brassica napus were studied through multiple high-throughput genomic approaches. Serial Analysis of Gene Expression (SAGE) using seed materials obtained a total of 68,718 tags, of which 23,897 were unique and 503 tags were functionally identified, and revealed the transcriptome of approximately 35,000 transcripts in B. napus developing seeds. Further, ~22,000 independent ESTs were obtained by large-scale sequencing using immature embryos at different stages, and 8343 uni-ESTs and 3355 full-length cDNAs were identified respectively, resulting in the systemic identification of B. napus FA biosynthesis-related genes. Gene expression profiles were further studied employing cDNA chip hybridization to reveal the global regulatory network of FA metabolism in developing seeds. Together with the analysis on FA amounts and composition, it was shown that 17-21 days after pollination (DAP) was a crucial stage for transition of seed to sink tissue. High expressions of FA biosynthesis-related genes and transition of FA components are mainly at stages 21 DAP or 21-25 DAP respectively. In addition, compared to Arabidopsis, more critical roles of starch metabolism are detected for B. napus seed FA metabolism and storage components accumulation. Crucial effects of starch metabolism, carbon flux, oxidative pentose phosphate pathway (OPPP), photosynthesis, and other regulators in FA metabolism were discussed. Keywords: Brassica napus, immature seed, SAGE, EST, cDNA microarray

Project description:To dissect the gene regulatory networks operating during soybean embryo development, we identified the binding sites genome-wide for transcription factor GLYMA.13G317000 in mid-maturation embryos using ChIP-seq.

Project description:To dissect the gene regulatory networks operating during soybean embryo development, we identified the binding sites genome-wide for transcription factor GLYMA.08G357600 in early maturation embryos using ChIP-seq.

Project description:To dissect the gene regulatory networks operating during soybean embryo development, we identified the binding sites genome-wide for transcription factor GLYMA.08G357600 in mid-maturation embryos using ChIP-seq.

Project description:To dissect the gene regulatory networks operating during soybean embryo development, we identified the binding sites genome-wide for transcription factor GLYMA.04G093300 in early maturation embryos using ChIP-seq.

Project description:To dissect the gene regulatory networks operating during soybean embryo development, we identified the binding sites genome-wide for transcription factor GLYMA.07G038400 in early maturation embryos using ChIP-seq.