Project description:Epigenetics helps define current cell states, yet also shapes how cells respond to external cues such as differentiation or stress. The epigenetic plasticity of a cell describes how flexible this regulation is. Bivalent chromatin is an exemplar of epigenetic plasticity. This co-occurrence of the active-associated H3K4me3 and inactive-associated H3K27me3 histone modifications on opposite tails of the same nucleosome was first described in mouse embryonic stem cells where it is found at promoters of key developmental genes. It has been postulated that bivalent chromatin poises these promoters, keeping them free from repressive DNAmethylation, enabling them to be transcriptionally upregulated upon differentiation. Bivalent chromatin has also been reported in other cell types including somatic cells and cancer cells, however we know little of the dynamics, resolution and regulation of this chromatin state. This is partly due to the technical challenges distinguishing bone-fide bivalent chromatin, where both marks are on the same nucleosome, from sample heterogeneity where some alleles have H3K4me3 and others H3K27me3. We developed a robust and sensitive reChIP method to accurately profile bivalent chromatin in as little as 2 million mouse embryonic stem cells. We validated the sensitivity of our method to detect changes in bivalent chromatin by profiling mouse ESCs lacking the epigenetic priming factors Dppa2 and Dppa4.

Project description:We present a high-sensitivity SCP workflow named Chip-Tip, identifying >5000 proteins in individual HeLa cells

Project description:ChIP seq of mESC treated with doxorubicin

Project description:The role of Arid4b in mESC lineage commitment (ChIP-Seq)

Project description:mESC were treated with doxorubicin and then histone modifications or p53 binding sites were analyzed

Project description:Transcriptomic Analysis of Naïve mESC, Primed mESC and EpiLC

Project description:WGA protocol optimization

Project description:control vs doxorubicin treated mESC WT, p53 KO mESC, and Dux KO mESC

Project description:RNAseq of setd2KO mESC

Project description:scRNAseq identifies extra-embryonic cell type preference for DUX-pulsed mESC differentiating into embryoid bodies.