Project description:We generated and analyzed ChIP-seq data for H3k4me3, H3k4me1, and H3k27me3. We annotated active and poised promoters and enhancers, as well as regions associated with repressed gene expression and found that poised promoters were associated with neuronal development genes, while active promoters were largely associated with housekeeping genes. Active and poised enhancers were associated with placental development genes, though only active enhancers were associated with genes that have placenta-specific expression.
Project description:mRNA molecules are generally thought to be messengers of genetic information in the cell. Stretches of RNA that are complementary in sequence have a propensity to pair, forming elements of secondary structure within RNA molecules. Although these structures will exist in every mRNA molecule, the role they play in gene regulation is not well understood. Currently two techniques are available to profile the cell RNA structure, in-vivo, in an unbiased manner. We applied one of those techniques, DMS-seq, for probing the human mRNA structure in primary foreskin fibroblasts (HFFs) along human cytomegalovirus (HCMV) infection. As a proof of concept, using DMS-seq, we managed to predict the already solved human 28S rRNA structure with high accuracy. Using our data, we are able to show for the first time in-vivo, that human coding sequences (CDSs) are less structured relative to UTRs. Additionally, we provide systematic in-vivo evidences for unwinding of the mRNA by the ribosomes during translation. Intriguingly, we also found structural changes in human CDSs around the start and stop codon, and also in 3’UTRs. The combination of accurate measurements of translation regulation and mapping changes in mRNA structure along a dynamic process can be used as a platform for deciphering cis-regulatory elements that control gene expression in various cell types, organisms and biological processes.
Project description:The goal of this study is to improve the quality, efficiency, and sustainability of milk production by improving the understanding of the function of cis-regulatory elements in regulating the bovine mammary gland. To this end, we have characterized the non-lactating and lactating mammary gland transcriptomes by whole transcriptome shotgun sequencing (RNA-seq). We will identify cis-regulatory elements in the non-lactating and lactating bovine mammary gland genome-wide. Finally, we will annotate and characterize mammary gland cis-regulatory elements by computational analysis and identify high-resolution genome-wide in vivo footprints of diverse trans-acting-factors (TF), over-represented TF bindings sites and overlapping SNPs.
Project description:We investigated the transcriptional activation and cis-regulatory elements of effector ISGs in CD8+ murine dendritic cells (DCs) stimulated with IFN-beta. We analysed gene repression changes and characterized activated cis-regulatory regions. Binding of ISGF3 subunits (IRF9, Stat1, and Stat2) and other transcription factors, DNA motifs, and chromatin status were also determined.