Project description:Array data detailing the progression of DNA replication in the yeast Lachancea waltii. L. waltii cells were pregrown in heavy isotope medium and synchronized at early S phase. They were then released into normal medium, wherein DNA replication proceeds. Replicated DNA molecules are thus of heavy-light (HL) composition as compared to unreplicated molecules, which are heavy-heavy (HH). 4 time points were taken and the percent of heavy-light DNA was determined at each time point. The heavy-heavy and heavy-light DNA molecules were separated by ultracentrifugation, differentially labeled, and hybridized to a genomic array for L. waltii. The array thus shows the progression of DNA replication.

Project description:The innovation of combined chemical tools, such as small molecule inhibitors, activity-based probes (ABPs), and proteolysis targeting chimeras (PROTACs) for a specific target, not only advances clinical drug discovery but also provides a chemical toolbox to study the diverse biological perspective of targeted proteins. Here we report the development of such a chemical toolbox for the multifunctional human Parkinson disease protein 7 (PARK7/DJ-1) that has drawn attention as a candidate for drug discovery due to its involvement with Parkinson's disease and cancers. By combining structure-guided design, small library synthesis and high-throughput screening, we identified two compounds, JYQ-164 and JYQ-173, inhibiting PARK7 with high potency in vitro and in cell. These compounds covalently and selectively target its highly conserved and functionally essential residue, Cys106. Based on these compounds, we further developed two cell-permeable fluorescent probes, JYQ-192 and JYQ-196, with a SulfoCy5 dye to visualize PARK7 activity in living cells and a first-in-class PARK7 degrader JYQ-194 that selectively targets PARK7 to proteasomal degradation in human cells. Together, our study provides a valuable toolbox to advance the biology research of PARK7 in a cellular context and opens new opportunities for potential therapeutic application.

Project description:Neural stem cells (NSCs) generate new neurons throughout life in two distinct areas of the mammalian brain: the subventricular zone (SVZ) lining the lateral ventricles and the hippocampal dentate gyrus (DG). How gene expression signatures differ among NSCs and immature neurons within and between these adult neurogenic regions is unknown. We isolated NSCs and their progeny using transgenic mice expressing GFP under the control of the Sox2 promoter (labeling NSCs) and transgenic mice expressing DsRed under the control of the doublecortin (Dcx) promoter (labeling immature neurons). Comparison of the transcriptomes of SOX2+ cells derived from both neurogenic areas revealed that NSCs are highly similar but that functionally significant differences in gene expression exist: IGF2, which is expressed only in SOX2+ cells in the DG but not in the SVZ, is required for proliferation of DG-derived but not SVZ-derived NSCs. Gene expression profiles strongly diverged in immature neurons, and we provide evidence that ephrinB3, which was up-regulated only in the DG but not in the SVZ during neuronal differentiation, regulates the survival of newborn granule cells. Thus, the data provided here show that stem cell populations in the adult DG and SVZ are similar but have unique properties that manifest themselves later during neural differentiation, resulting in distinct neuronal populations Hippocampi and SVZ from 6 week old DCX-DsRed and Sox2-GFP Reporter mice were dissected and cell sorted using FACS. cDNA were generated and analysed using Agilent Platform.

Project description:In this experiment we would like to identify the binding sites of Dazl on the transcriptome of mESCs. To do that, we carried out an iCLIP experiment using mESCs grown in 2iL condition.

Project description:Beneficial effects of SIRT1 on healthspan are likely to be pleiotropic and may include effects on DNA methylation. We demonstrated recently that manipulating SIRT1 in human cells affected DNA methylation of a panel of test genes, and that genes with expression modified by dietary restriction corresponded with genes that underwent changes in DNA methylation during ageing. Here we tested the hypothesis that genes particularly susceptible to SIRT1-induced effects on DNA methylation across the genome map to genes for which DNA methylation changes during ageing. We increased or reduced SIRT1 expression in human intestinal (Caco-2) and vascular endothelial (HuVEC) cells by transient transfection with an expression construct or with siRNA, respectively. Effects on DNA methylation were measured by enriching for the methylated fraction then either sequencing (HuVEC) or hybridising to a human promoter microarray (Caco-2). Effects using these two different cell lines and techniques for analysis were remarkably consistent. Genes with a DNA methylation status affected by SIRT1 manipulation were enriched for those that undergo age-dependent changes in DNA methylation, thus supporting our hypothesis. Polycomb group protein target genes (PCGTs), which are suppressed by epigenetic mechanisms in stem cells and have been shown previously to correspond with loci particularly susceptible to age-related changes in DNA methylation, were over-represented within the set of genes showing altered DNA methylation in response to SIRT1 manipulation in both cell lines. We thus propose that effects of SIRT1 to extend healthspan include influences on the DNA methylation status of genes affected during ageing, in particular PCGTs. Analysis of methylation profiles of Caco-2 cells meeting the following conditions: SIRT1 overexpressed by transfection with pCMV6-ENTRY-SIRT1 (2 replicates), corresponding vector control (2 replicates), each of the siRNAs that target SIRT1 (1 & 2 replicates, respectively) and control siRNA (2 replicates).

Project description:To identify the accessible chromatin in wild-type mouse embryonic stem cells (mESCs), we performed ATAC-seq in mESCs.

Project description:The biomarker CA125, a peptide epitope located in several tandem repeats of the mucin MUC16, is the gold-standard for monitoring regression and recurrence of high-grade serous ovarian cancer in response to therapy. However, the CA125 epitope along with several structural features of the MUC16 molecule are ill-defined. One central aspect still unresolved is the number of tandem repeats in MUC16 and how many of these contain the CA125 epitope. Studies from the early 2000s assembled short DNA reads to estimate that MUC16 contained 63 repeats. Here, we conduct Nanopore long-read sequencing of MUC16 transcripts from three primary ovarian tumors and established cell lines (OVCAR3, OVCAR5, and Kuramochi) for a more exhaustive and accurate estimation and sequencing of the MUC16 tandem repeats. The consensus sequence derived from these six sources was confirmed by proteomics validation and agrees with recent additions to the NCBI database. We propose a model of MUC16 containing 19—not 63—tandem repeats. Additionally, we predict the structure of the tandem repeat domain using the deep-learning algorithm, AlphaFold. The predicted structure displays an SEA domain and unstructured linker region rich in proline, serine, and threonine residues in all 19 tandem repeats. Our studies now pave the way for a detailed characterization of the CA125 epitope. Sequencing and modeling of the MUC16 tandem repeats along with their glycoproteomic characterization, currently underway in our laboratories, will help identify novel epitopes in the MUC16 molecule that improve on the sensitivity and clinical utility of the current CA125 assay.

Project description:To combat methicillin-resistant Staphylococcus aureus (MRSA) infections novel drugs addressing unprecedented and resistance-free targets are desperately needed. From a screen of human kinase inhibitors, we find that the anti-cancer drug sorafenib effectively kills MRSA strains. By dissection of the sorafenib scaffold and systematic synthesis of 72 analogs, we identify a potent compound – PK150 – exhibiting a minimal inhibitory concentration of 300 nM against several MRSA strains. The antibiotic induced rapid killing of S. aureus, including challenging persisters, and eradicated established biofilms. PK150 holds promising therapeutic potential as it did not induce in vitro resistance and exhibited good oral bioavailability and in vivo efficacy in a mouse infection model. Mode of action analysis by chemical proteomics revealed several targets including stimulation of protein secretion by signal peptidase IB (SpsB). Enhanced levels of extracellular proteins and resulting imbalances in secreted autolysin levels of PK150-treated bacteria support this target hypothesis. The associated antibiotic effects, especially the lack of resistance development, likely stem from the polypharmacology attribute of the compound. PK150 is therefore the founding member of a new class of highly active antibiotics.

Project description:The transcription factor (TF) Forkhead Box P3 (FOXP3) is constitutively expressed in high levels in natural occurring CD4+CD25+ regulatory T cells (nTreg) and is not only the most accepted marker for that cell population, but is considered lineage determinative. Chromatin immunoprecipitation (ChIP) of transcription factors in combination with genomic tiling microarray analysis (ChIP-on-Chip) has been shown to be an appropriate tool to identify FOXP3 transcription factor binding sites (TFBS) on a genome-wide scale. In combination with microarray expression analysis the ChIP-on-Chip technique allows to identify direct FOXP3 target genes. ChIP-on-Chip analysis of human FOXP3M-NM-^T2 isoform expressed in resting and PMA / ionomycin stimulated Jurkat T cells revealed several thousand putative FOXP3 binding sites and importance of intronic regions for FOXP3 binding. Knowledge of general distribution patterns of FOXP3 TFBS in the human genome under resting and activated conditions contributes to a better understanding of this TF and its influence on direct target genes with importance for Treg cell phenotype and function. ChIP-DNA from FOXP3(M-NM-^T2) expressing Jurkat T cells under resting and PMA / ionomycin stimulated conditions from duplicate experiments was analyzed. FOXP3-specific tiling array data were analyzed in reference to an individual isotype control dataset (J-FOXP3 ChIP'd with FOXP3 antibody vs. J-FOXP3 ChIP'd with isotype control antibody). In total 8 tiling array analyses were performed (2x resting J-FOXP3 with FOXP3-IP, 2x resting J-FOXP3 with isotype-IP, 2x PMA/iono J-FOXP3 with FOXP3-IP, 2x PMA/iono J-FOXP3 with isotype-IP)

Project description:Drug resistance is vital for the poor prognosis of acute myeloid leukemia (AML) patients, but the underlying mechanism remains poorly understood. Given the unique microenvironment of bone marrow, we reasoned that drug resistance of AML might rely on distinct microenvironment-associated metabolic processes. Here, we identified SDH deficiency and over-cumulative succinate as typical features in AML, with a marked function in causing the resistance of AML cells to a wide range of anti-cancer therapies. Mechanistically, succinate promoted the accumulation of oncogenic proteins in a manner that precedes transcriptional activation. This function was mediated by succinate-triggered upregulation of UBC12 phosphorylation, which impaired its E2 function in cullins neddylation. Notably, decreasing succinate levels by fludarabine could effectively restore the drug sensitivity of SDH-deficient AML PDX. Together, we uncover a novel function of succinate in driving drug resistance by regulating p-UBC12/cullin activity, and indicate reshaping succinate metabolism as a promising treatment for SDH-deficient AML.