Project description:DAP-seq was used to generate genome-wide DNA:TF interaction maps for fourteen maize ARFs from the evolutionarily conserved class A ‘activator’ and class B ‘repressor’ clades. Among the distinct binding sites that were identified, we observed a high degree of overlap for ARFs of the same class, but found substantial differences in motif sequence, spacing, site preference, and association with auxin induced genes among clade A and clade B ARFs.
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: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:We have developed a high throughput, next-generation DNA sequencing assay for rapid transcription factor binding site (TFBS) discovery in a genomic context. DNA affinity purification sequencing (DAP-seq), which uses affinity-purified transcription factors (TFs) to capture genomic DNA fragments, was applied to all 1,725 Arabidopsis thaliana TFs. High confidence TFBS motifs for 529 TFs and genome-wide enrichment maps for 349 factors were identified. In total,~ 2.7 million TFBS were identified which predict thousands of TF target genes enriched for known and novel functions.. Comparison of TF-binding using cytosine-methylated and -unmethylated genomic DNA revealed a 2-50 fold inhibition at methylated motifs for ~82% (264) of factors tested while 4.6% (15) showed stronger binding to methylated motifs. Finally, we describe how binding of Arabidopsis and maize Auxin Response Factors (ARFs) at phased motif repeats is highly enriched at ARF target gene promoters and how this architecture may allow for stabilization of dimers/multimers.
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:DAP-seq was used to generate genome-wide DNA:TF interaction maps for fourteen maize ARFs from the evolutionarily conserved class A ‘activator’ and class B ‘repressor’ clades. Among the distinct binding sites that were identified, we observed a high degree of overlap for ARFs of the same class, but found substantial differences in motif sequence, spacing, site preference, and association with auxin induced genes among clade A and clade B ARFs.