Project description:In this study, we applied sequential DNA affinity purification sequencing (seq-DAP-seq) to identiy genome-wide binding of a heterocomplex formed by two transcription factors of the MADS familly SEP3 and AG(AP1-I) (AG with its I domain switched with that of AP1). We compared the genome wide binding of SEP3-AG(AP1-I) to that of our previously published SEP3-AG data

Project description:In this study, we use DNA affinity purification sequencing to identiy genome-wide binding of LFY transcription factor, a master regulator of flower development in Arabidopsis. We generated two sets of data, one using genomic DNA from plant tissue, thus retain DNA methylation, as probe for DNA affinity purification (DAP-seq dataset), and the other using PCR amplified genomic DNA (without DNA methylation; AmpDAP-seq dataset).

Project description:As 5-15% of higher eukaryotes genes are transcription factors (TFs), the lack of transcription factor binding site (TFBS) information for most factors in most organisms limits the study of gene regulation. Here we describe a next-generation sequencing method, DNA affinity purification (DAP-Seq), an in vitro gDNA/TF interaction assay that produces whole-genome TFBS annotation for any factor from any organism. Like ChIP-Seq, DAP-Seq resolves TFBS as discrete peaks at genomic locations which allows for accurate motif prediction direct assignment of functionally relevant target genes, and shows better overlap with ChIP-Seq peaks than indirect motif assignment approaches. We applied DAP-Seq to a set of 50 transcription factors in eight Arabidopsis thaliana and one Zea Mays families to gain novel biological insight into TFBS architectures, functions, evolution and methylation-sensitivity. Overall, DAP-Seq offers a low-cost high-throughput approach to identify TFBS in native sequence context for any organism complete with all DNA chemical modifications.

Project description:DNA affinity purification sequencing (DAP-seq) data of LEAFY (LFY)

Project description:In this study, we compare the DNA binding specifify and affinity of SEPALLATA3 and AGAMOUS complexes The MADS transcription factors, SEPALLATA3 (SEP3) and AGAMOUS (AG), are required for floral organ identity and determinacy of the floral meristem in Arabidopsis. Dimerization is obligatory for their DNA binding, however SEP3 and SEP3-AG also form tetrameric complexes. The goal of this study is to understand how homo and hetero-dimerization and tetramerization of MADS TFs affect genome-wide DNA-binding patterns. Using a modified sequential DNA affinity purification sequencing protocol (seq-DAP-seq), we selectively purified SEP3 homomeric and SEP3-AG heteromeric complexes, including the dimeric SEP3 tet-AG complex and the tetrameric SEP3-AG complex, and determined their genome-wide binding.

Project description:To identify binding sites and nodule SAGs that are directly targeted by NAC094, we used DAP-seq, which allows the capture of the NAC094 regulatory targets at the whole-genome scale. A total of 2,819 binding peaks corresponding to 2,721 genes were identified from two repeats of the DAP-seq experiment.

Project description:To better understand FvRIF-mediated transcriptional regulation of fruit ripening, we performed DNA affinity purification sequencing (DAP-seq) to unravel FvRIF binding sites at the genome level. For DAP-seq analysis, the recombinant FvRIF fusion protein was used to purify the sheared genomic DNA of strawberry fruits. Two independent biological replicates of DAP-seq and DNA ‘input’ negative control libraries were prepared and submitted for deep sequencing.

Project description:SWIZ DAP-Seq

Project description:Genome-wide binding of SEPALLATA3 (SEP3) and AGAMOUS (AG) complexes determined by sequential DNA-affinity purification sequencing

Project description:Raw reads from DNA affinity purification sequencing of SWIZ (Bradi1g17700) against Bd21 genomic DNA.