Project description:Single-color gene expression profiles from IMR-32 neuroblastoma cell lines were generated using 44K oligonucleotide microarrays. To gain insights into the molecular processes occurring upon TFAP2B re-expression, we performed gene expression measurements in TFAP2B and GFP expressing transgenic IMR-32 neuroblastoma cell lines at d2 and d7 of transgene induction. Single-color gene expression profiles from IMR-32 neuroblastoma cell lines were generated using 44K oligonucleotide microarrays. Total RNA of TFAP2B- and GFP-expressing IMR-32 cells was isolated at day 2 and day 7 using Trizol.

Project description:<p>Non-coding elements in our genomes that play critical roles in complex disease are frequently marked by highly unstable RNA species. Sequencing nascent RNAs attached to an actively transcribing RNA polymerase complex can identify unstable RNAs, including those templated from gene-distal enhancers (eRNAs). However, nascent RNA sequencing techniques remain challenging to apply in some cell lines and especially to intact tissues, limiting broad applications in fields such as cancer genomics and personalized medicine. Here we report the development of chromatin run-on and sequencing (ChRO-seq), a novel run-on technology that maps the location of RNA polymerase using virtually any frozen tissue sample, including samples with degraded RNA that are intractable to conventional RNA-seq. We used ChRO-seq to develop the first maps of nascent transcription in 23 human glioblastoma (GBM) brain tumors and patient derived xenografts. Remarkably, &#62;90,000 distal enhancers discovered using the signature of eRNA biogenesis within primary GBMs closely resemble those found in the normal human brain, and diverge substantially from GBM cell models. Despite extensive overall similarity, 12% of enhancers in each GBM distinguish normal and malignant brain tissue. These enhancers drive regulatory programs similar to the developing nervous system and are enriched for transcription factor binding sites that specify a stem-like cell fate. These results demonstrate that GBMs largely retain the enhancer landscape associated with their tissue of origin, but selectively adopt regulatory programs that are responsible for driving stem-like cell properties. We also identified enhancers and their associated transcription factors that regulate genes characteristic of each known GBM subtype, and discovered a core group of transcription factors that control the expression of genes associated with clinical outcomes. This study uncovers new insights into the molecular etiology of GBM and introduces ChRO-seq which can now be used to map regulatory programs contributing to a variety of complex diseases.</p>

Project description:Determining how organs attain precise positioning within an organism is a crucial facet of developmental biology. The Fox family winged-helix transcription factors are known to play key roles in development of multiple organs. Drosophila FoxL1 (aka Fd64A) is dynamically expressed in embryos but its function is completely uncharacterized. FoxL1 is expressed in a single group of body wall - muscles in the 2nd and 3rd thoracic segments, in homologous abdominal muscles at earlier stages, and in the hindgut mesoderm from early through late embryogenesis. We show that FoxL1 expression in T2 and T3 is in VIS5, which is not a single muscle spanning the entire thorax, as previously published, but is, instead, three individual muscles, each spanning a single thoracic segment. We generate mutations in foxL1 and show that, surprisingly, none of the tissues that express FoxL1 are affected by its loss. Instead, loss of foxL1 results in defects in salivary gland positioning and morphology, as well as defects in the migration of hemocytes, germ cells and Malpighian tubules. We also show that FoxL1-dependent expression of secreted Sema2a in T3 VIS5 is required for normal salivary gland positioning. Altogether, these findings suggest that Drosophila FoxL1 functions like its mammalian counterpart in non-autonomously orchestrating the behaviors of surrounding tissues. We performed a microrarray analysis comparing gene expression changes between wild-type and foxL1 null embryos (foxL1del/foxL1cr). Total RNA was collected from embryos from stages 11-15, which correspondes with expression of foxL1 in the embryo.

Project description:Chromatin and gene-regulatory dynamics of mouse nephron progenitors at single-cell resolution

Project description:Background: Unraveling the dynamic accessibility of regulatory chromatin at single-cell resolution is key to understanding stem/progenitor cell fate choices in health and disease. Nephron progenitor cells (NPCs) are a multipotent population giving rise to all cell types of the nephron, from the glomerular epithelium to the distal tubule. At any given time, the NPC’s choice to self-renew or differentiate and gain a new identity is determined not only by its transcription factor repertoire but also by the genome accessibility of the cognate cis-regulatory elements. Methods: We performed singleome and multiome analysis of chromatin accessibility and gene expression in thousands of embryonic and neonatal NPCs toward defining the regulatory landscape driving fate choices during nephrogenesis. Results: We show that chromatin accessibility recovers the diverse states of NPCs and precursor states of proximal and distal nephron epithelial cells. We define the key cell type-specific transcriptional regulators across pseudotime and NPC age. We find that chromatin accessibility in the podocyte lineage is established early in the trajectory and identify a subset of Forkhead factors exhibiting high chromatin activity in podocyte precursors. We also determined that strong linkages between cis-regulatory elements and expression levels distinguish fate-determining TFs. Conclusions: Single-cell mapping of accessible and active chromatin defines the regulatory landscape of nephrogenesis and provides a foundation for future studies in disease states characterized by abnormal nephrogenesis.

Project description:Background: Unraveling the dynamic accessibility of regulatory chromatin at single-cell resolution is key to understanding stem/progenitor cell fate choices in health and disease. Nephron progenitor cells (NPCs) are a multipotent population giving rise to all cell types of the nephron, from the glomerular epithelium to the distal tubule. At any given time, the NPC’s choice to self-renew or differentiate and gain a new identity is determined not only by its transcription factor repertoire but also by the genome accessibility of the cognate cis-regulatory elements. Methods: We performed singleome and multiome analysis of chromatin accessibility and gene expression in thousands of embryonic and neonatal NPCs toward defining the regulatory landscape driving fate choices during nephrogenesis. Results: We show that chromatin accessibility recovers the diverse states of NPCs and precursor states of proximal and distal nephron epithelial cells. We define the key cell type-specific transcriptional regulators across pseudotime and NPC age. We find that chromatin accessibility in the podocyte lineage is established early in the trajectory and identify a subset of Forkhead factors exhibiting high chromatin activity in podocyte precursors. We also determined that strong linkages between cis-regulatory elements and expression levels distinguish fate-determining TFs. Conclusions: Single-cell mapping of accessible and active chromatin defines the regulatory landscape of nephrogenesis and provides a foundation for future studies in disease states characterized by abnormal nephrogenesis.

Project description:<p>We generated primary cultures from mechanically isolated kidney glomeruli (filtration unit of the nephron) which are composed of podocytes and mesangial cells. In parallel, we generated primary kidney cortex tubule cell cultures, which are composed primarily of proximal tubule cells. Early passage cultures of these two cell types were subjected to chromatin accessibility profiling (DNase-Seq) and gene expression profiling (RNA-Seq). We found thousands of dynamically regulated enhancers in both cell types that potentially regulate nearby and distal target genes that are differentially expressed. These data will be useful for understanding the epigenomic regulation of gene transcription in key kidney cell types.</p>

Project description:50 lymphoblastoid cell lines of adult female Twins which are part of the MuTHER study, subjected to Chromatin Immunoprecipitation using an antibody for H3K4me1. H3K4me1 peaks mark distal regulatory elements.

Project description:The kidney is a complex organ composed of more than 30 terminally differentiated cell types that all are required to perform its numerous homeostatic functions. De-fects in kidney development are a significant cause of chronic kidney disease in children, which can lead to kidney failure that can only be treated by transplant or dialysis. A better understanding of molecular mechanisms that drive kidney development is important for designing strategies to enhance renal repair and regeneration. In this study, we profiled gene expression in the developing mouse kidney at embryonic day 14.5 at single cell resolution. Consistent with previous studies, clusters with distinct transcriptional signatures clearly identify major compartments and cell types of the developing kidney. Cell cycle activity distinguishes between the “primed” and “self-renewing” sub-populations of nephron progenitors, with increased expression of the cell cycle related genes Birc5, Cdca3, Smc2 and Smc4 in “primed” nephron progenitors. Augmented Birc5 expression was also detected in immature distal tubules and a sub-set of ureteric bud cells, suggesting that Birc5 might be a novel key molecule required for early events of nephron patterning and tubular fusion between the distal nephron and the collecting duct epithelia.

Project description:Active regulatory elements in eukaryotes are typically characterized by an open, nucleosome-depleted chromatin structure; mapping areas of open chromatin has accordingly emerged as a widely used tool in the arsenal of modern functional genomics. However, existing approaches for profiling chromatin accessibility are limited by their reliance on DNA fragmentation and short read sequencing, which leaves them unable to provide information about the state of chromatin on larger scales or reveal coordination between the chromatin state of individual distal regulatory elements. To address these limitations, we have developed a method for profiling accessibility of individual chromatin fibers at multi-kilobase length scale (SMAC-seq, or Single-Molecule long-read Acessible Chromatin mapping sequencing assay), enabling the simultaneous, high-resolution, single-molecule assessment of the chromatin state of distal genomic elements. Our strategy is based on combining the preferential methylation of open chromatin regions by DNA methyltransferases (CpG and GpC 5-methylcytosine (5mC) and N6-methyladenosine (m6A) enzymes) and the ability of long-read single-molecule nanopore sequencing to directly read out the methylation state of individual DNA bases. Applying SMAC-seq to the budding yeast Saccharomyces cerevisiae, we demonstrate that aggregate SMAC-seq signals match bulk-level accessibility measurements, observe single-molecule protection footprints of nucleosomes and transcription factors, and quantify the correlation between the chromatin states of distal genomic elements