Project description:We respectively knocked down ZNF200 and DDX17 in the H520 and A549 cell lines. Since H3K4me3 is an epigenetic modification that marks the active state of gene promoter regions and is typically associated with the activation of gene expression, we subsequently performed ATAC-seq experiments using antibodies against histone H3K4me3.

Project description:To investigate the role of PBX2 in Head and neck squamous cell carcinoma. We performed profiling targeting the CUT＆Tag data of the IgG and HA-PBX2 groups

Project description:This study uses Cleavage Under Targets and Tagmentation (Cut&Tag) chromatin profiling to map genome-wide binding sites of TES (TEAD1 Epigenetic Silencer, an engineered epigenetic silencer factor consisting of KRAB-hTEAD1(1-166)-DNMT3A/3L with V5 tag) and overexpressed wild-type TEAD1 (HA-tagged) in SNB19 glioblastoma cells. Cut&Tag was performed using the CUTANA protocol (EpiCypher). Three biological replicates were prepared for TES (detected via anti-V5) and TEAD1 (detected via anti-HA), with mouse IgG and rabbit IgG as negative controls. Peak calling identified binding sites for both factors, showing that TES largely preserves the DNA-binding specificity of wild-type TEAD1 while converting it into a transcriptional repressor.

Project description:Genome-wide distribution of H3K9me3, RNA polymerase II, Rloop, DDX55 and HA-tagged DDX55 in WT and DDX55 knockout CD4 naive T cells were determined by cleavage under targets and tagmentation (CUT&Tag) assays followed by deep sequencing (CUT&Tag-seq) with corresponding antibodies.

Project description:CUT&Tag assays were performed in H1299 lung adenocarcinoma cells to profile genome-wide binding of hnRNPK. An IgG antibody was used as a negative control. Paired-end sequencing was conducted on an Illumina platform, and the data were used to identify hnRNPK binding sites and integrate with transcriptomic analyses.

Project description:We performed CUT&Tag experiments in MED23-HA and WT 293T cells to analyze the genomic occupation profiles for the Mediator MED23.

Project description:Cut&Tag using antibodies against H3K27me3, H3K4me1, H3K4me3, HeK27ac, IgG Cells: mouses embryonic stem cells (mESCs), RGd2 Culture conditions: 2i, 30hr N2B27/DMSO/siNegative, 30hr N2B27MEK(i)/siNanog

Project description:Cut & Run analysis was performed in an neuroblastoma cell line to analyze DNA bindings of ASCL1-tag-HA in GI-MEN ASCL1-tag-HA cells and GI-MEN ASCL1-tag-HA+4TFs cells; analyze DNA bindings of MYCN, PHOX2B and H3K27ac in, GI-MEN 4TFs cells, and GI-MEN ASCL1-tag-HA+4TFs cells.

Project description:Background: Genome-wide profiling of DNA-protein interactions in cells can provide important information about mechanisms of gene regulation. Most current methods for genome-wide profiling of DNA-bound proteins such as ChIP-seq and CUT&Tag use conventional IgG antibodies to bind the target protein(s). This limits their applicability to targets with available high affinity and specificity antibodies and prevents their use for other targets. Here we describe NanoTag, an IgG-free method derived from CUT&Tag to profile DNA-protein interactions. NanoTag is based on a fusion between an anti-GFP nanobody and Tn5 transposase that can map GFP-tagged proteins associated with chromatin in a fast, cost-effective and animal-free manner. Results: We used NanoTag to indirectly profile the histone mark H3K4me3 genome-wide via its binding partner TATA box-binding protein-associated factor 3 (TAF3) and the transcription factors Nanog and CTCF in mouse embryonic stem cells (mESCs). NanoTag results show high inter-replicate reproducibility, high signal-to-noise ratio and strong correlation with CUT&Tag datasets, validating its accuracy and reliability. Conclusions: NanoTag provides a novel, flexible and cost-effective IgG-free method to generate high resolution DNA-binding profiles in cells and tissues.

Project description:CUT&RUN for IgG, H3K4me3 and HA-SPDEF in human PDA HPAF-II cells and CUT&RUN HA-Spdef in murine KPC 2D FC1245 cells We performed CUT&RUN assay in human and murine PDA cells to profile the direct binding of SPDEF to target genes.