Project description:Laminopathies are caused by mutations in components of the nuclear envelope (NE). While most NE components are widely expressed, laminopathies affect only a subset of tissues. However, the understanding of the molecular mechanisms that explain this phenomenon is still elusive. Here we have performed a genome wide DamID analysis in adult C. elegans nematodes comparing the DNA association profile of two components of the NE, Lamin/LMN-1 and Emerin/EMR-1. Although both proteins were associated to silent DNA, EMR-1 showed a predominant role in the anchoring of muscle and neuronal promoters to the nuclear periphery. Deletion of either EMR-1 or LEM-2, another integral NE protein, caused local changes in nuclear architecture with both increased and decreased LMN-1 association. Comparison of Dam::LMN-1 and Dam::EMR-1 DNA assotiation in wild type strains and Dam::LMN-1 DNA association in wild type, lem-2(tm1582) and emr-1(gk119) mutant backgrounds.

Project description:ChIP-seq using anti-GFP antibody to map genomic binding of Prdm4-EGFP in stably transfected mouse embryonic stem cells Two independent ChIP-seq replicates for each of two independent Prdm4-EGFP expressing ES cell clones resulting in four anti-GFP ChIP-seq experiments. These samples have paired mouse IgG control.

Project description:Nucleosome positions were determined in wild type cells, cells lacking Isw2 or Ume6, and cells containing a hybrid Chd1-Ume6 chimeric remodeler Matched MNase digests from W303 strain variants during log growth (OD600=0.4-0.6) were subject to paired-end sequencing for nucleosome mapping. For effects of the engineered fusion remodeling protein, a catalytically inactive (ATPase dead D513N) variant was included as a control.

Project description:We used high density oligonucleotide arrays to measure the relative expression levels of ~27,000 probe sets in the left ventricles of inbred rat strains; DA (high performing), Copenhagen (COP, low performing), as well as F1(COPxDA) rats bred from these tw

Project description:Multiple cancers may arise from within a clonal region of preneoplastic epithelium, a phenomenon termed M-^Qfield changeM-^R. However, it is not known how field change develops. We investigate this question and analyse the behavior of scattered single esophageal epithelial progenitor cells expressing a mutation that inhibits the Notch signaling pathway (Dominant negative Maml).

Project description:Cell type diversity is controlled by transcription factors (TFs), which regulate specific yet flexible gene expression programs depending on the cellular environment. However, how sets of TFs work together to promote such diversity with high precision is still unknown. We used the Hox TF Ultrabithorax (Ubx) as a model because of its essential functions in multiple cell types. Assuming that functional diversity emerges from specifc protein interactions in different cell types, we explored Ubx protein interactomes in three different tissue lineages in vivo. Using proximity dependent Biotin IDentification (BioID) in Drosophila embryos, we find that Ubx interacts with largely non-overlapping sets of proteins in each tissue lineage. Intriguingly, this specificity does not primarily result from Ubx binding to proteins with lineage-restricted functions. Instead, Ubx interacts in a lineage-specific manner with ubiquitously expressed subunits of proteins complexes controlling general aspects of gene expression, like chromatin remodelling or RNA processing. Thus, our work reveals that cell type-specific protein interaction networks not necessarily involve cell type-specific partners and that the function of key TFs may extend to the control over the entire realm of gene expression, including splicing and translation. These findings challenge two central dogmas in cell lineage specification, namely the strong reliance on differential RNA expression as a measure for specificity determinants and the enhancer-centric approach to understand gene regulation.

Project description:Progesterone Receptor Membrane Component 1 (PGRMC1) is expressed in many cancer cells, where it is associated with detrimental patient outcomes. Multiple different functions and cellular locations have been attributed to PGRMC1 in a variety of contexts, however the mechanisms underlying PGRMC1 biology remain obscure. The protein contains several phosphorylated residues including tyrosines which were acquired early in animal evolution and could be involved with animal cell differentiation mechanisms. Here we demonstrate that mutagenic manipulation of PGRMC1phosphorylation status in MIA PaCa-2 (MP) pancreatic cells exerts broad pleiotropic effects, influencing cell plasticity and tumorigenicity, as assayed by cell biological and proteomics measurements. Relative to MP cells over-expressing hemagglutinin (HA)-tagged wild-type PGRMC1- HA (WT), cells expressing a PGRMC1-HA-S57A/S181A double mutant (DM) exhibited reduced levels of proteins involved in energy metabolism and mitochondrial function. This was associated with Rho-kinase inhibitor (ROCKI)-sensitive changes including altered cell shape, motility, increased PI3K/Akt and JNK activity, and fragmented mitochondrial morphology. An S57A/Y180F/S181A triple mutant (TM) reduced PI3K/Akt and JNK activation, indicating involvement of Y180. Both TM cells and Y180F single mutant cells exhibited attenuated mouse xenograft tumor growth. Tyrosine 180 phosphorylation status of PGRMC1 exerts dramatic influence over cancer cell biology.

Project description:We introduce the Multiplexed Editing Regulatory Assay (MERA), a high-throughput CRISPR/Cas9-based approach that analyzes the regulatory genome for function in its native context. By tiling thousands of mutations across ~40 kb of cis-regulatory genomic space and using knock-in GFP reporters to read out gene activity, we obtain quantitative information on the contribution of cis-regulatory regions to gene expression. In addition, we performed a deep-sequencing strategy to find basepair-resolution functional motifs involved in regulation of the gene by sequencing thousands of functional and non-functional genotypes at genomic locations perturbed by specific guide RNAs. Design of 3908 gRNAs to perturb regulatory regions associated with the genes Tdgf1,Nanog,Zfp42 and Rpp25 as well as 10 GFP-targetting positive controls. Also, deep-sequencing of genomic regions mutated by 6 selected gRNAs after sorting the electroporated cells into GFP-positive and GFP-negative populations.

Project description:Analysis of the transcriptome of the wild-type strain BY4741 and its isogenic derivative ixr1 null, grown in aerobic, hypoxic conditions and after a hypoxic shift Two biological replicates in two technical replicates for each growth condition

Project description:The Dicer ribonuclease III (RNase III) enzymes process long double-stranded RNA (dsRNA) into the small interfering RNAs (siRNAs) that direct RNA interference. Here, we describe the structure and activity of a catalytically active fragment of Kluyveromyces polysporus Dcr1, which represents the noncanonical Dicers found in budding yeast. The crystal structure reveals a homodimer that resembles bacterial RNase III but includes a novel N-terminal domain and newly identified catalytic residues conserved throughout eukaryotic RNase III enzymes. Biochemical analyses show that Dcr1 dimers bind cooperatively along the dsRNA substrate and cleave at precise intervals based on the distance between consecutive active sites. Thus, unlike canonical Dicers, which successively remove siRNA duplexes from the dsRNA termini, Dcr1 initiates processing in the interior and works outward. The distinct mechanism of budding-yeast Dicers establishes a novel paradigm for natural protein-based molecular rulers and imparts substrate preferences with ramifications for biological function. High-throughput sequencing of small RNAs generated by in vitro processing of long dsRNA using Kluyveromyces polysporus Dicer