Project description:Regulation of homeotic gene expression is critical for proper developmental patterns in plants. The Arabidopsis thaliana floral homeotic gene AGAMOUS is regulated by LEUNIG (LUG). Mutations in LUG result in homeotic transformations of floral organ identity. LUG mutants also exhibit other defects that are independent of AG, including abnormal carpel and ovule development, reduced female and male fertility, and narrower leaves and floral organs, suggesting that LUG has a wider role in development. LUG is structurally similar to the transcription co-repressors Tup1 (S. cerevisiae) and Groucho (Drosophila), suggesting developmental pathways regulated by LUG may be controlled by a conserved eukaryotic repression mechanism. We aim to determine novel target genes regulated by LUG using transcriptome analysis. A mutant lug-3 line has been obtained from Dr. Zhongchi Liu. This line was used in the initial studies of LUG in the Meyerowitz lab. Lug-3 is a strong allele in the Lansberg erecta background, caused by a nonsense mutation that results in early termination of the protein and is likely null. The Lug-3 mutant exhibits narrow floral organs with staminoid petals and carpelloid sepals, abnormal carpel and ovule development, reduced plant height, increased lateral branching and narrow and smaller leaves. We proposed to use the lug-3 line in elucidating the role of LUG as a potential general regulator of transcription in Arabidopsis. mRNA populations will be isolated from wild type (Ler) and lug-3 plants that have produced inflorescence. This stage of development has been selected for several reasons. Firstly, mRNA populations from the widest range of tissue types from a single plant can be collected. Secondly, as AGAMOUS, which is involved in the regulation of floral development, is present in the Affymetrix gene chip, it will provided an excellent internal control to monitor between chips. Results will demonstrate whether LUG is likely to have a more global role in regulating transcription, and will identify pathways under the regulation of this co-repressor-like protein. 12 samples were used in this experiment.

Project description:Floral organs, whose identity is determined by specific combinations of homeotic genes, originate from a group of undifferentiated cells called the floral meristem. In Arabidopsis, the homeotic gene AGAMOUS (AG) terminates meristem activity and promotes development of stamens and carpels. To understand the program of gene expression activated by AG, we followed genome-wide expression during early stamen and carpel development. Keywords: Developmental time course

Project description:Floral organs, whose identity is determined by specific combinations of homeotic genes, originate from a group of undifferentiated cells called the floral meristem. In Arabidopsis, the homeotic gene AGAMOUS (AG) terminates meristem activity and promotes development of stamens and carpels. To understand the program of gene expression activated by AG, we followed genome-wide expression during early stamen and carpel development. Experiment Overall Design: Described in Gomez-Mena et al, 2005, Development 132: 429-438. Briefly, synchronous development of stamens and carpels was initiated by steroid treatment of plants homozygous for the ap1-1 and cal-1 mutations and expressing a fusion between AGAMOUS and the rat glucocorticoid receptor (35S:AGGR). RNA was extracted one, three and seven days after steroid treatment; two independent steroid-treated samples and two independent untreated controls were used for each time point.

Project description:Analyis gene expression in crc-1 knu-1 compared with knu-1 Initiation of the carpel primordia is marked by the termination of floral stem cells. Although genetic evidences have suggested that the YABBY gene CRABS CLAW (CRC) regulates the development of carpel, as well as the floral meristem determinacy as a target of the homeotic protein AGAMOUS, the underlying mechanism remains unclear. Here we show that the tetraspanin-encoding gene TONADO2 (TRN2) and the auxin biosynthesis gene YUCCA4 (YUC4) act as downstream targets of CRC.

Project description:The molecular mechanisms by which floral homeotic genes act as major developmental switches to specify the identity of floral organs, are still largely unknown. Floral homeotic genes encode transcription factors of the MADS-box family, which are supposed to assemble in a combinatorial fashion into organ-specific multimeric protein complexes. Major mediators of protein interactions are MADS-domain proteins of the SEPALLATA subfamily, which play a crucial role in the development of all types of floral organs. In order to characterize the roles of the SEPALLATA3 transcription factor complexes at the molecular level, we analyzed genome-wide the direct targets of SEPALLATA3. We used chromatin immunoprecipitation followed by ultrahigh-throughput sequencing or hybridization to whole-genome tiling arrays to obtain genome-wide DNA-binding patterns of SEPALLATA3. The results demonstrate that SEPALLATA3 binds to thousands of sites in the genome. Most potential target sites that were strongly bound in wild-type inflorescences, are also bound in the floral homeotic agamous mutant, which displays only the perianth organs, sepals and petals. Characterization of the target genes shows that SEPALLATA3 integrates and modulates different growth-related and hormonal pathways in a combinatorial fashion with other MADS-box proteins and possibly with non-MADS transcription factors. In particular, the results suggest multiple links between SEPALLATA3 and auxin signaling pathways. Our gene expression analyses link the genomic binding site data with the phenotype of plants expressing a dominant repressor version of SEPALLATA3, suggesting that it modulates auxin response to facilitate floral organ outgrowth and morphogenesis. Furthermore, the binding of the SEPALLATA3 protein to cis-regulatory elements of other MADS-box genes and expression analyses reveal that this protein is a key component in the regulatory transcriptional network underlying the formation of floral organs. ChIP experiments were performed on Arabidopsis wildtype and agamous mutant inflorescences using an antibody raised against a C-terminal peptide of SEP3. As control, ChIP experiments were performed on the sep3 mutant.

Project description:Investigation of differentially expressed gene in floral tissues of of Brassica rapa in comparison with leaves as control To unravel the transcriptomic changes associated with small early floral buds (<2 mm; FB2), large early floral buds (2-4 mm; FB4), stamen (ST) and carpel (CP) tissues, transcriptome profiling was carried out with Br300K oligo microarray.

Project description:The gene expression profiles of inflorescences of the floral homeotic mutants apetala1, apetala2, apetala3, pistillata, and agamous were compared to wild-type inflorescences using a flower-specific cDNA array (GSM21001-21015) and a "whole-genome" oligonucleotide array (Operon) (GSM21016-21035). All experiments were performed at least in triplicate. This SuperSeries is composed of the SubSeries listed below.

Project description:Floral organ identities in plants are specified by the combinatorial action of homeotic master regulatory transcription factors (TFs). How these factors achieve their regulatory specificities is however still largely unclear. Genome-wide in vivo DNA binding data show that homeotic MADS-domain proteins recognize partly distinct genomic regions, suggesting that DNA binding specificity contributes to functional differences of homeotic protein complexes. We used in vitro systematic evolution of ligands by exponential enrichment followed by high throughput DNA sequencing (SELEX-seq) on several floral MADS-domain protein homo- and heterodimers to measure their DNA-binding specificities. We show that specification of reproductive organs is associated with distinct binding preferences of a complex formed by SEPALLATA3 (SEP3) and AGAMOUS (AG). Binding specificity is further modulated by different binding site (BS) spacing preferences. Combination of SELEX-seq and genome-wide DNA binding data allows to differentiate between targets in specification of reproductive versus perianth organs in the flower. We validate the importance of DNA-binding specificity for organ-specific gene regulation by modulating promoter activity through targeted mutagenesis. Our study shows that intrafamily protein interactions affect DNA-binding specificity of floral MADS-domain proteins. DNA-binding specificity of individual dimers, as well as DNA-binding preferences of higher-order complexes differ between floral homeotic protein complexes. Differential DNA-binding of MADS-domain protein complexes plays a role in the specificity of target gene regulation.

Project description:The molecular mechanisms by which floral homeotic genes act as major developmental switches to specify the identity of floral organs, are still largely unknown. Floral homeotic genes encode transcription factors of the MADS-box family, which are supposed to assemble in a combinatorial fashion into organ-specific multimeric protein complexes. Major mediators of protein interactions are MADS-domain proteins of the SEPALLATA subfamily, which play a crucial role in the development of all types of floral organs. In order to characterize the roles of the SEPALLATA3 transcription factor complexes at the molecular level, we analyzed genome-wide the direct targets of SEPALLATA3. We used chromatin immunoprecipitation followed by ultrahigh-throughput sequencing or hybridization to whole-genome tiling arrays to obtain genome-wide DNA-binding patterns of SEPALLATA3. The results demonstrate that SEPALLATA3 binds to thousands of sites in the genome. Most potential target sites that were strongly bound in wild-type inflorescences, are also bound in the floral homeotic agamous mutant, which displays only the perianth organs, sepals and petals. Characterization of the target genes shows that SEPALLATA3 integrates and modulates different growth-related and hormonal pathways in a combinatorial fashion with other MADS-box proteins and possibly with non-MADS transcription factors. In particular, the results suggest multiple links between SEPALLATA3 and auxin signaling pathways. Our gene expression analyses link the genomic binding site data with the phenotype of plants expressing a dominant repressor version of SEPALLATA3, suggesting that it modulates auxin response to facilitate floral organ outgrowth and morphogenesis. Furthermore, the binding of the SEPALLATA3 protein to cis-regulatory elements of other MADS-box genes and expression analyses reveal that this protein is a key component in the regulatory transcriptional network underlying the formation of floral organs.

Project description:The molecular mechanisms by which floral homeotic genes act as major developmental switches to specify the identity of floral organs, are still largely unknown. Floral homeotic genes encode transcription factors of the MADS-box family, which are supposed to assemble in a combinatorial fashion into organ-specific multimeric protein complexes. Major mediators of protein interactions are MADS-domain proteins of the SEPALLATA subfamily, which play a crucial role in the development of all types of floral organs. In order to characterize the roles of the SEPALLATA3 transcription factor complexes at the molecular level, we analyzed genome-wide the direct targets of SEPALLATA3. We used chromatin immunoprecipitation followed by ultrahigh-throughput sequencing or hybridization to whole-genome tiling arrays to obtain genome-wide DNA-binding patterns of SEPALLATA3. The results demonstrate that SEPALLATA3 binds to thousands of sites in the genome. Most potential target sites that were strongly bound in wild-type inflorescences, are also bound in the floral homeotic agamous mutant, which displays only the perianth organs, sepals and petals. Characterization of the target genes shows that SEPALLATA3 integrates and modulates different growth-related and hormonal pathways in a combinatorial fashion with other MADS-box proteins and possibly with non-MADS transcription factors. In particular, the results suggest multiple links between SEPALLATA3 and auxin signaling pathways. Our gene expression analyses link the genomic binding site data with the phenotype of plants expressing a dominant repressor version of SEPALLATA3, suggesting that it modulates auxin response to facilitate floral organ outgrowth and morphogenesis. Furthermore, the binding of the SEPALLATA3 protein to cis-regulatory elements of other MADS-box genes and expression analyses reveal that this protein is a key component in the regulatory transcriptional network underlying the formation of floral organs. Keywords: ChIP-chip