Project description:We futher characterized genome-wide chromatin accessibility of WT and SRC-2-/- mouse liver at CT10 through DNase-Seq. In addition,chromatin accessibility was significantly reduced in SRC-2-/- mouse liver compared to WT mice at CT10. DNase-Seq was carried out in WT and SRC-2-/- mice in liver at CT10 using two doses of DNaseI.

Project description:The 10x multiome (RNA+ATAC) kit was applied to CRL-1459 cells in culture at passage 10 and 15

Project description:B cells from tonsils of human donors were extracted for combined RNAseq+ATACseq from the same cell. One sample was prepared separately ("old") and is of lower quality, but still included. It primarily holds ATACseq information.

Project description:We generated genome-wide cistromes of BAF180 subunit of the SWI-SNF chromatin remodeling complex in mouse liver at CT10 and CT22. In addition, we performed ChIP-Seq analysis on REV-ERBα in WT and SRC-2-/- mouse liver at CT10. We found circadian oscilation of BAF180 chromatin recruitment in mouse liver with peak recruitment at CT22 and nadir at CT10. Further,REV-ERBα chromatin recruitment was significantly reduced in SRC-2-/- mouse liver compared to WT mice at CT10. ChIP-Seq for BAF180 was performed in WT mice liver at CT10 and CT22 using two different antibodies. ChIP-Seq for REV-ERBα was performed in WT and SRC-2-/- mice in liver at CT10 with biological replicates.

Project description:We generated Multiome RNA+ATAC data from the same cell from human PBMC. This served as a gold benchmark for a novel integration method for multi-omics data that we developed.

Project description:In competitive matches, strategic decisions and emotional control are important. Relevant cognitive functions and corresponding neural activities in simple and short-term laboratory tasks have been reported. Brain resources are intensively allocated in the frontal cortex during strategic decision-making. The suppression of the frontal cortex with alpha-synchronization optimizes emotional control. However, no studies have reported the contribution of neural activity to the outcome of a more complex and prolonged task. To clarify this issue, we focused on a fighting video game following a two-round first-pass system. Frontal high-gamma and alpha power in the first and third pre-round periods, respectively, were found to be increased in a winning match. Furthermore, inter-participant variations in the importance of strategic decisions and emotional control in the first and third pre-round periods were correlated with frontal high-gamma and alpha power, respectively. Therefore, the psychological and mental state, involving frontal neural fluctuations, is predictive of match outcome.

Project description:Large amplitude autonomous chemomechanical oscillations were observed in a coupled system consisting of a porous pH-responsive hydrogel and a bromate-sulfite-manganese (II) pH oscillatory reaction. The porous structure effectively improves the chemomechanical response speed, and the negative feedback species of the bulk oscillation Mn2+ takes part in the coupling by forming complex and physical crosslinks with the responsive group in the gel. It strengthens the porous gel by forming additional networks, which may contribute to sustaining the long-lasting chemomechanical oscillation. Additionally, the interaction between Mn2+ and the hydrogel alters the period of the oscillatory reaction due to its binding competition with H⁺, the positive feedback species.

Project description:We generated Multiome RNA+ATAC data from the same cell from human PBMC. This served as a gold benchmark for a novel integration method for multi-omics data that we developed.

Project description:This study looks at the ATAC+RNA profiles of human CD4 T cells under bioreactor-like conditions as ACT. Cells were stimulated toward Th1,Th2,Treg and Th17 under anti-CD3/28 activation, and profiled on day 5.

Project description:Anti-sense transcription originating upstream of mammalian protein-coding genes is a well-documented phenomenon, but remarkably little is known about the function or regulation of these anti-sense promoters or the non-coding RNAs they generate. Here we define at nucleotide resolution the divergent transcription start sites (TSSs) near mouse mRNAs. We find that coupled sense and anti-sense TSSs form the boundaries of an evolutionarily conserved and nucleosome-depleted regulatory region with dramatically enriched transcription factor (TF) occupancy. Notably, as the distance between sense and anti-sense TSSs increases, so does the level of TF binding and signal-dependent gene activation. We further discover a cluster of anti-sense TSSs in macrophages with an enhancer-like chromatin signature. Remarkably, this signature identifies promoters that are selectively and rapidly activated during immune challenge. We conclude that anti-sense TSSs can serve as potent, local enhancers of sense-strand gene expression by facilitating TF binding and deposition of activating histone modifications. ChIP-seq, Start-RNA-seq, and MNase-seq from mouse bone marrow-derived macrophages (BMDMs), and Start-RNA-seq from mouse embryonic fibroblasts (MEFs) are included. For ChIP-seq, two biological replicates are included for each of three treatment conditions; untreated, 30 minutes lipopolysaccharide (LPS), and 2 hours LPS. Each biological replicate for all ChIP conditions was sequenced in two lanes for depth, creating two technical replicates for each biological replicate. Raw files for paired technical replicates are labeled as repX.1 and repX.2, where repX.1 is technical replicate 1 and repX.2 is technical replicate 2. For Start-RNA-seq in BMDMs, two biological replicates are included for each of three treatment conditions; untreated, 30 min LPS, and 2 hr LPS. For MNase-seq, data from three biological replicates of untreated BMDMs are included. Four technical replicates of biological replicate 1, two technical replicates of biological replicate 2, and four technical replicates of biological replicate 3 are included. Raw files for paired technical replicates are labeled as repX.1, repX.2, repX.3, etc. For Start-RNA-seq in untreated MEFs, two biological replicates are included. Two technical replicates for each of the MEF Start-RNA-seq biological replicates are included. Paired technical replicates are labeled as repX.1 and repX.2.