Project description:ChIP-seq has become the method of choice for studying functional DNA-protein interactions on a genome wide scale. The method is based on co-immunoprecipitation of DNA binding proteins with formaldehyde cross-linked DNA, followed by deep sequencing of immunoprecipitated chromatin fragments, allowing for the identification of binding sites with high accuracy [1-5]. Traditionally, genome-wide tiling path microarrays were used for the detection of specifically immunoprecipitated DNA fragments, but current next-generation sequencers now generate sufficient data to assay multiple samples in a single sequencing run, making this method more time and cost effective compared to microarray-based approaches [2]. However, due to limitations in read length of next generation sequencing technologies (50-76bp), it is not possible to sequence the complete length of immunoprecipitated DNA fragments which can be up to 2kb long reflecting biology in case of big protein complexes. As a consequence only the ends of the immunoprecipitated DNA fragments are sequenced. Deconvolution of sequencing reads mapping to the positive and negative strand is required to identify the real DNA binding site [4-9]. This limitation is most obvious in case of large complex regions where multiple binding sites of various regulatory elements are clustered close to each other. Deconvolution of such regions and the exact identification of individual binding positions is very challenging [4]. Similar problems can occur when studying histone positioning in cases where the length of ChIP fragments is bigger than the average distance of 2 neighboring nucleosomes. In addition frequently only narrow size range of immunoprecipitated fragments is selected for sequencing and thus possible bias towards binding regions within the selected range can be expected by loosing larger fragments possible originated from protein complexes interacting with DNA. To circumvent these complications, we modified the procedure for the preparation of ChIP-seq samples by introducing an additional extensive fragmentation round after isolation of immunoprecipitated chromatin to generate 70-110 bp long DNA fragments. For testing, we choose Tcf4 protein which is a well-studied downstream element of the Wnt-pathway for which the genome wide binding site profile is known was already known from ChIP-on-CHIP experiments [10]. Using the modified approach, we were able to identify Tcf4 binding sites at near nucleotide resolution without computational deconvolution. Furthermore, high-resolution information on genome-wide binding site regions allowed for the identification of potential novel Tcf4 co-factors as well as target genes. 5 samples + 3 input samples

Project description:Surprisingly few pathways signal between cells, raising questions about mechanisms for tissue-specific responses. In particular, Wnt ligands signal in many mammalian tissues, including the intestinal epithelium, where constitutive signaling causes cancer. Genome-wide analysis of DNA cis-regulatory regions bound by the intestine-restricted transcription factor CDX2 in colonic cells uncovered highly significant over-representation of sequences that bind TCF4, a transcriptional effector of intestinal Wnt signaling. Chromatin immunoprecipitation confirmed TCF4 occupancy at most such sites and co-occupancy of CDX2 and TCF4 across short distances. A region spanning the single nucleotide polymorphism rs6983267, which lies within a MYC enhancer and confers colorectal cancer risk in humans, represented one of many co-occupied sites. Co-occupancy correlated with intestine-specific gene expression and CDX2 loss reduced TCF4 binding.These results implicate CDX2 in directing TCF4 binding in intestinal cells. Co-occupancy of regulatory regions by signal-effector and tissue-restricted transcription factors may represent a general mechanism for ubiquitous signaling pathways to achieve tissue-specific outcomes. A series of ChIP-chip experiments identified the CDX2 cistrome and discovered and validated extensive co-binding with TCF4 in colon cancer cell lines Transcriptional profiling following shRNA-mediated CDX2 knockdown was employed to identify CDX2-dependent gene expression in the human colon cancer cell line Caco2

Project description:The transcription factor 4 (TCF4) locus is a robust association finding with schizophrenia (SZ), but little is known about the genes regulated by the encoded transcription factor. Therefore, we conducted chromatin immunoprecipitation sequencing (ChIP-seq) of TCF4 in neural-derived (SH-SY5Y) cells to identify genome-wide TCF4 binding sites, followed by data integration with SZ association findings. We identified 11,322 TCF4 binding sites overlapping in two ChIP-seq experiments. These sites are significantly enriched for the TCF4 Ebox binding motif (>85% having ≥1 Ebox) and implicate a gene set enriched for genes down-regulated in TCF4 siRNA knockdown experiments, indicating the validity of our findings. The TCF4 gene set was also enriched among 1) Gene Ontology categories such as axon/neuronal development, 2) genes preferentially expressed in brain, in particular pyramidal neurons of the somatosensory cortex, and 3) genes down-regulated in post-mortem brain tissue from SZ patients (OR=2.8, permutation p<4x10-5). Considering genomic alignments, TCF4 binding sites significantly overlapped those for neural DNA binding proteins such as FOXP2 and the SZ-associated EP300. TCF4 binding sites were modestly enriched among SZ risk loci from the Psychiatric Genomic Consortium (OR=1.56, p=0.03). In total, 130 TCF4 binding sites occurred in 39 of the 108 regions published in 2014. Thirteen genes within the 108 loci had both a TCF4 binding site ±10kb and were differentially expressed in siRNA knockdown experiments of TCF4, suggesting direct TCF4 regulation. These findings confirm TCF4 as an important regulator of neural genes and point towards functional interactions with potential relevance for SZ.

Project description:We performed chloroplast ChIP-seq (cpChIP-seq) to identify the possible DNA-binding sites of mTERF5 in Arabidopsis thaliana. To this end, we generated transgenic Arabidopsis plants expressing mTERF5 carrying an HA tag under the control of the CaMV 35S promoter. Then, We used the polyclonal antibody (abcam, ab9110, lot GR304617-8 ) against HA tag which conjugated to ChIP-Grade protein A/G agarose (Thermo scientific, 26161, lot QJ223903) to perform cpChIP assay. The obtained chromatin immunoprecipitated DNA of chloroplasts were used to build DNA libaries for high-throughput sequencing. Finally, we showed that three potenssial DNA regions across the chloroplast genome compared to the control group were enriched by mTERF5.

Project description:We report the genome-wide analysis from chromatin immunoprecipitated DNA (ChIP-sequencing) at very high resolution of the DNA binding pattern of ParBF (SopB) either on the full length plasmid F or on E. coli chromosome carrying the parSF centromere sequence. We also varied the intracellular ParBF concentration to discriminate between the several proposed mechanism of partition complexes assembly.

Project description:A genomic overview of in vivo binding of a transcription factor Snail in the ascidian early gastrula embryo. Fertilized eggs were electroporated with a construct encoding GFP-tagged Snail. After fixation, chromatin was sonicated to obtain DNA fragments with an average of size of 1kb. The DNA fragments were enriched by immunoprecipitation with an polyclonal antibody specific for GFP (Invitrogen). The immunoprecipitated and WCE (Whole Cell Extract) DNA were amplified by LM-PCR for the Chip analysis. Two independent experiments were performed to reduce experimental errors.

Project description:A genomic overview of in vivo binding of a transcription factor Neurogenin in the ascidian 64-cell stage embryo. Fertilized eggs were electroporated with a construct encoding GFP-tagged Neurogenin. After fixation, chromatin was sonicated to obtain DNA fragments with an average of size of 1kb. The DNA fragments were enriched by immunoprecipitation with an polyclonal antibody specific for GFP (Invitrogen). The immunoprecipitated and WCE (Whole Cell Extract) DNA were amplified by LM-PCR for the Chip analysis. Two independent experiments were performed to reduce experimental errors.

Project description:A genomic overview of in vivo binding of a transcription factor Tbx6b in the ascidian early gastrula embryo. Fertilized eggs were electroporated with a construct encoding GFP-tagged Tbx6b. After fixation, chromatin was sonicated to obtain DNA fragments with an average of size of 1kb. The DNA fragments were enriched by immunoprecipitation with an polyclonal antibody specific for GFP (Invitrogen). The immunoprecipitated and WCE (Whole Cell Extract) DNA were amplified by LM-PCR for the Chip analysis. Two independent experiments were performed to reduce experimental errors.

Project description:A genomic overview of in vivo binding of a transcription factor Otx in the ascidian early gastrula embryo. Fertilized eggs were electroporated with a construct encoding GFP-tagged Otx. After fixation, chromatin was sonicated to obtain DNA fragments with an average of size of 1kb. The DNA fragments were enriched by immunoprecipitation with an polyclonal antibody specific for GFP (Invitrogen). The immunoprecipitated and WCE (Whole Cell Extract) DNA were amplified by LM-PCR for the Chip analysis. Two independent experiments were performed to reduce experimental errors.

Project description:A genomic overview of in vivo binding of a transcription factor SoxC in the ascidian early gastrula embryo. Fertilized eggs were electroporated with a construct encoding GFP-tagged SoxC. After fixation, chromatin was sonicated to obtain DNA fragments with an average of size of 1kb. The DNA fragments were enriched by immunoprecipitation with an polyclonal antibody specific for GFP (Invitrogen). The immunoprecipitated and WCE (Whole Cell Extract) DNA were amplified by LM-PCR for the Chip analysis. Two independent experiments were performed to reduce experimental errors.