Project description:The FUSCA3 (FUS3) transcription factor is considered to be a master regulator of seed maturation because a wide range of seed maturation events are impaired in its defective mutant. To comprehensively identify genes under the control of FUS3, two types of microarray experiments were performed. First, transgenic plants in which FUS3 expression could be induced by the application of estrogen (ESTR) were used to identify the genes up-regulated in young seedlings of Arabidopsis in response to ectopic expression of FUS3. Second, transcriptomes were compared between fus3 mutant and wild type developing seeds. Combining the results of these experiments identified genes under relatively immediate and robust control of FUS3 during seed development. The analyses expanded the range of types of genes under the control of FUS3. The genes positively controlled by FUS3 are not confined to previously known seed maturation-related genes and include those for production of secondary metabolites such as glucosinolates, phenylpropanoids and falvonoids, and primary metabolism such as photosynthesis and fatty acid biosynthesis. Furthermore, several different patterns were identified in the manner of ectopic activation by FUS3 including the kinetics and abscisic acid (ABA) requirement of downstream genes depending on their natures of developmental regulation, suggesting mechanistic diversity of gene regulation by FUS3. This Series contains two different types of microarray experiments. First, seven-day-old seedlings of the ESTR-inducible FUS3 transgenic plants (ER-FUS3) were cultured for 3, 6, 12, 24, 36 or 48 h in a standard liquid medium or in that containing ESTR, ABA or both. RNA was prepared from each time point sample of each treatment and used to prepare Cy5-labeled cRNA, which was subsequently probed by DNA array with the reference Cy3-labeled cRNA prepared from the time zero untreated seedlings. Two biological replicates per treatment. Second, transcriptomes were compared between developing seeds of the wild-type (Col-0) and the fus3-3 mutant. This experiment contains two seed developmental stages, 8 days after flowering (DAF; bent cotyledon stage) and at 12 DAF (green cotyledon stage). Sample pairs in three biological replicates were analyzed by the two-color method. Dye-swapped hybridizations were performed in every replicate.

Project description:Triacylglycerol (TAG) is the main storage lipid in plant seeds and the major form of plant oil used for food and, increasingly, for industrial and biofuel applications. Several transcription factors, including FUSCA3 (At3g26790, FUS3), are associated with regulation of embryo 3maturation and oil biosynthesis in seeds. However, the ability of FUS3 to increase TAG biosynthesis in other tissues has not been quantitatively examined. Here, we evaluated the ability of FUS3 to activate TAG accumulation in non-seed tissues. Overexpression of FUS3 driven by an estradiol-inducible promoter increased oil contents in Arabidopsis seedlings up to 6% of dry weight; more than 50 fold over controls. Eicosenoic acid, a characteristic fatty acid of Arabidopsis seed oil, accumulated to over 20% of fatty acids in cotyledons and leaves. These large increases depended on added sucrose, although without sucrose TAG increased 3-4 fold. Inducing the expression of FUS3 in tobacco BY2 cells also increased TAG accumulation, and co-expression of FUS3 and diacylglycerol acyltransferase 1 (DGAT1) further increased TAG levels to 4% of dry weight. BY2 cell growth was not altered by FUS3 expression, although Arabidopsis seedling development was impaired, consistent with the ability of FUS3 to induce embryo characteristics in non-seed tissues. Microarrays of Arabidopsis seedlings revealed that FUS3 overexpression increased expression of a higher proportion of genes involved in TAG biosynthesis than genes involved in fatty acid biosynthesis or other lipid pathways. Together these results provide additional insights into FUS3 functions in TAG metabolism and suggest complementary strategies for engineering vegetative oil accumulation.

Project description:During seed maturation, the embryo accumulates nutrition storage compounds such as oil and reservve proteins, and acquires dormancy and desiccation tolerance. Arabidopsis transcription factors LEC1, LEC2, FUS3 and ABI3 are known as the master regulators of seed maturation because all these events during the seed maturation are severely affected by the respective mutants. In addition, the lec1, lec2 and fus3 mutants exhibit some heterochronic characteristics, as exemplified by the development of true leaf-like cotyledons during embryogenesis. To characterize these mutants at the whole genome expression level, microarray experiments were performed.

Project description:During seed maturation, the embryo accumulates nutrition storage compounds such as oil and reservve proteins, and acquires dormancy and desiccation tolerance. Arabidopsis transcription factors LEC1, LEC2, FUS3 and ABI3 are known as the master regulators of seed maturation because all these events during the seed maturation are severely affected by the respective mutants. In addition, the lec1, lec2 and fus3 mutants exhibit some heterochronic characteristics, as exemplified by the development of true leaf-like cotyledons during embryogenesis. To characterize these mutants at the whole genome expression level, microarray experiments were performed.

Project description:During seed maturation, the embryo accumulates nutrition storage compounds such as oil and reserve proteins, and acquires dormancy and desiccation tolerance. Arabidopsis transcription factors LEC1, LEC2, FUS3 and ABI3 are known as the master regulators of seed maturation because all these events during the seed maturation are severely affected by the respective mutants. In addition, the lec1, lec2 and fus3 mutants exhibit some heterochronic characteristics, as exemplified by the development of true leaf-like cotyledons during embryogenesis. To characterize these mutants at the whole genome expression level, microarray experiments were performed. Developing seeds were dissected from the siliques of the lec1-1, lec2-1, or fus3-3 homozygous plants or the respective wild type plants (Col-0 for fus3-3, WS for lec1-1 and lec2-1) at 8 and 12 days after flowering. Seeds samples were obtained from triplicate batches of plants and used for RNA preparation.

Project description:During seed maturation, the embryo accumulates nutrition storage compounds such as oil and reserve proteins, and acquires dormancy and desiccation tolerance. Arabidopsis transcription factors LEC1, LEC2, FUS3 and ABI3 are known as the master regulators of seed maturation because all these events during the seed maturation are severely affected by the respective mutants. In addition, the lec1, lec2 and fus3 mutants exhibit some heterochronic characteristics, as exemplified by the development of true leaf-like cotyledons during embryogenesis. To characterize these mutants at the whole genome expression level, microarray experiments were performed. Developing seeds were dissected from the siliques of the abi3-6 homozygous plants or the respective wild type plants (Col-0) at 12 and 16 days after flowering. Seeds samples were obtained from triplicate batches of plants and used for RNA preparation.

Project description:FUSCA3 (FUS3) is a B3 domain transcription factor that is a member of the LEAFY COTYLEDON (LEC) group of genes. The LEC genes encode proteins that also include LEC2, a B3 domain factor related to FUS3, and LEC1, a CCAAT box binding factor. LEC1, LEC2 and FUS3 are essential for plant embryo development. We report ChIP-chip experiments using the Affymetrix tiling array to globally map binding sites for FUS3. Fangfang Wang and Sharyn E. Perry (2013) Plant Physiology preview FUSCA3 was expressed by the native promoter and included a C-terminal 10x-c-myc tag. This transgene was able to rescue the fus3-3 mutant. A second transgene (35S:AGL15) was present to allow establishment of stable somatic embryo cultures. ChIP was performed using anti-c-myc antibody (Myc-Tag (9B11) Mouse mAb; Cell Signaling 2276S) on tissue expressing FUS3-myc (three biological replicates) and on three controls of tissue expressing FUS3 (no epitope tag).

Project description:FUSCA3 (FUS3) is a B3 domain transcription factor that is a member of the LEAFY COTYLEDON (LEC) group of genes. The LEC genes encode proteins that also include LEC2, a B3 domain factor related to FUS3, and LEC1, a CCAAT box binding factor. LEC1, LEC2 and FUS3 are essential for plant embryo development. We report ChIP-chip experiments using the Affymetrix tiling array to globally map binding sites for FUS3. Fangfang Wang and Sharyn E. Perry (2013) Plant Physiology preview

Project description:Developing Arabidopsis seeds accumulate oils and seed storage proteins synthesized by the pathways of primary metabolism. Seed development and metabolism are positively regulated by transcription factors belonging to the LAFL regulatory network. The VAL gene family encodes repressors of the seed maturation program in germinating seeds, although they are also expressed during seed maturation. VAL1 functions as a repressor of seed metabolism, as val1 mutant seeds accumulated elevated levels of storage proteins compared to the wild type. Two VAL1 splice variants were identified through RNA sequencing analysis: a full-length and a truncated form lacking the plant-homeodomain-like domain associated with epigenetic repression. None of the transcripts encoding the core LAFL network transcription factors were affected in val1 embryos. Instead, activation of VAL1 by FUSCA3 appears to result in repression of a subset of seed maturation genes downstream of core LAFL regulators as 39% of transcripts in the FUSCA3 regulon were de-repressed in the val1 mutant. The LEC1 and LEC2 regulons also responded but to a lesser extent. Additional 832 transcripts that were not LAFL targets were de-repressed in val1 mutant embryos. These transcripts are candidate targets of VAL1, acting through epigenetic and/or transcriptional repression.

Project description:Developing Arabidopsis seeds accumulate oils and seed storage proteins synthesized by the pathways of primary metabolism. Seed development and metabolism are positively regulated by transcription factors belonging to the LAFL regulatory network. The VAL gene family encodes repressors of the seed maturation program in germinating seeds, although they are also expressed during seed maturation. VAL1 functions as a repressor of seed metabolism, as val1 mutant seeds accumulated elevated levels of storage proteins compared to the wild type. Two VAL1 splice variants were identified through RNA sequencing analysis: a full-length and a truncated form lacking the plant-homeodomain-like domain associated with epigenetic repression. None of the transcripts encoding the core LAFL network transcription factors were affected in val1 embryos. Instead, activation of VAL1 by FUSCA3 appears to result in repression of a subset of seed maturation genes downstream of core LAFL regulators as 39% of transcripts in the FUSCA3 regulon were de-repressed in the val1 mutant. The LEC1 and LEC2 regulons also responded but to a lesser extent. Additional 832 transcripts that were not LAFL targets were de-repressed in val1 mutant embryos. These transcripts are candidate targets of VAL1, acting through epigenetic and/or transcriptional repression. 2 genotypes, 7 time points, 3 biological and 4 technical replicates