Project description:Understanding how lung progenitor cells balance; proliferation against differentiation is relevant to clinical; disorders such as bronchopulmonary dysplasia of; premature babies and lung cancer. Previous studies have; established that lung development is severely disrupted in; mouse mutants with reduced levels of the proto-oncogene; Nmyc, but the precise mechanisms involved have not been; explored. We show here that Nmyc expression in the; embryonic lung is normally restricted to a distal population; of undifferentiated epithelial cells, a high proportion of; which are in the S phase of the cell cycle. Overexpression; of NmycEGFP in the epithelium under the control of; surfactant protein C (Sftpc) regulatory elements expands; the domain of S phase cells and upregulates numerous; genes associated with growth and metabolism, as shown by; transcriptional microarray. In addition, there is marked; inhibition of differentiation, coupled with an expanded; domain of expression of Sox9 protein, which is also; normally restricted to the distal epithelial compartment. By; contrast, conditional deletion of Nmyc leads to reduced; proliferation, epithelial differentiation and high levels; of apoptosis in both epithelium and mesenchyme. Unexpectedly, about 50% of embryos in which only one; copy of Nmyc is deleted die perinatally, with similarly; abnormal lungs. We propose a model in which Nmyc is; essential in the developing lung for maintaining a distal; population of undifferentiated, proliferating progenitor; cells. Experiment Overall Design: To generate Nmyc1EGF fusion protein, mouse Nmyc1 cDNA was Experiment Overall Design: inserted into the SmaI site of pEGFP (BectonDickinson), excised by Experiment Overall Design: SalI and EcoRI, and inserted into a vector containing a 3.7 kb Experiment Overall Design: promoter/enhancer of the human SFTPC gene (Wert et al., 1993). Experiment Overall Design: Transfection of 293 cells shows that the fusion protein localizes to Experiment Overall Design: the nucleus (see Fig. S1 in supplementary material). Four transgenic Experiment Overall Design: embryos were generated by pronuclear injection into Experiment Overall Design: (C57BL/6J and DBA/2J) F2 fertilized eggs. They were collected at Experiment Overall Design: E18.5, so it is not known if they would have survived postnatally. Experiment Overall Design: Duplicate samples are biological replicates.

Project description:comparison of expression of wildtype lungs and lungs with hypomorphic expression of nmyc. the lungs were pooled from several biological samples. The hypomorphoic mutant was orignally published in Moens CB et al [PMID: 1577267]. this is part of a larger collection of data comparing nmyc misexpression in the lung (gain of fucntion) and protein expression in the hypomorphic lungs. Keywords: expression comparison

Project description:JMJD6 (also known as PTDSR) is an important oncogene that is upregulated in 17q21-ter gained neuroblastoma.It plays a role in E2F and N-Myc-regulated gene pathways and neuroblastoma tumorigenesis Using ChIP-Seq, we profiled JMJD6 and NMYC binding in the NMYC overexpressing neuroblastoma cell line. We identified the genomic location of JMJD6 and NMYC binding peaks across the human genome.

Project description:comparison of expression of wildtype lungs and lungs with hypomorphic expression of nmyc. the lungs were pooled from several biological samples. The hypomorphoic mutant was orignally published in Moens CB et al [PMID: 1577267]. this is part of a larger collection of data comparing nmyc misexpression in the lung (gain of fucntion) and protein expression in the hypomorphic lungs. Experiment Overall Design: samples from pooled lungs were analyzed.

Project description:protein profiling of mouse lung organogenesis from embryonic day E13.5 until adulthood by gel-free two-dimensional liquid chromatography coupled to large-scale tandem mass spectrometry (MudPIT). protein expression in Nmyc loss of function mutant with a comparison to wildtype at E18 Keywords: protein, proteomics, Mudpit, lung, development, nuclear, cytosol, mitochondria, mouse

Project description:Idiopathic Pulmonary Fibrosis (IPF) is a devastating and life-threatening lung disease characterized by epithelial reprogramming and increased extracellular matrix deposition leading to loss of lung function. A prominent histopathological structure in the IPF lung are aberrant bronchioles filled with mucus, referred to as honeycomb cysts. These heterogeneous bronchiolized areas feature clusters of simple epithelium with Keratin (KRT)5+ basal-like cells interspersed with pseudostratified epithelium containing differentiated, hyperplastic epithelial cells as well as aberrant ciliated cells. Recent single-cell RNA sequencing studies of the lung epithelium shed further light into cellular subtypes unique to IPF, including basaloid KRT5-/KRT17+ cells present in the distal lung. However, IPF distal bronchiole cell subtypes still remain poorly characterized and their disease contribution remains underinvestigated. Using single-cell RNA sequencing of enriched EpCAM+ lung cells of the distal IPF lung, we identified G-protein coupled receptor (GPR) 87, as a marker of distal bronchioles and KRT5+ IPF basal cells contributing to impaired airway differentiation and honeycombing.

Project description:Diseases involving the distal lung alveolar epithelium include chronic obstructive pulmonary disease (COPD), idiopathic pulmonary fibrosis (IPF) and lung adenocarcinoma. Accurate labeling of specific cell types is critical for determining the contribution of each to pathogenesis of these diseases. The distal lung alveolar epithelium is comprised of two cell types, alveolar epithelial type 1 (AT1) and type 2 (AT2) cells. While cell type-specific markers, most prominently surfactant protein C (SFTPC), have allowed detailed studies of AT2 cell differentiation and their roles in disease, studies of AT1 cells have been hampered by lack of genes with expression unique to AT1 cells. To address this, we performed genome-wide expression profiling of multiple rat organs alongside purified rat AT2, AT1 and in vitro differentiated AT1-like cells, resulting in identification of 54 candidate AT1 cell markers. Cross-referencing with genes upregulated in human in vitro differentiated AT1-like cells narrowed the potential list to 18 candidate genes. Testing the top four candidate genes at RNA and protein levels revealed GRAM domain 2 (GRAMD2), a protein of unknown function, as unique to AT1 cells, while SCNN1G within lung is restricted to AT1 cells. RNAseq confirmed that GRAMD2 is transcriptionally silent in human AT2 cells. Immunofluorescence of mouse alveoli verified that GRAMD2 expression is restricted to the plasma membrane of AT1 cells. These new AT1 cell-specific genes, with GRAMD2 as a leading candidate, will enhance AT1 cell isolation, investigation of alveolar epithelial cell differentiation potential, and contribution of AT1 cells to distal lung diseases.

Project description:To comprehensively study the heterogeneity within distal airway epithelium, we performed single cell transcriptomic analysis of the normal human donor lung samples. Our analysis reveals that secretory (club) and basal cells in the distal lung airway epithelial cells are highly heterogenous. Further interrogation of secretory cells identified a subpopulation with potential for alveolar differentiation in vitro, implicating distal lung airway secretory cells as new candidates in alveolar repair and regeneration.

Project description:JMJD6 and NMYC binding examined by ChIP-seq in NMYC overexpressing CHP134 human neuroblastoma cells

Project description:We used microfluidic single cell RNA-seq on 198 individual mouse lung epithelial cells at 4 different stages throughout development to measure the transcriptional states which define the developmental and cellular hierarchy of the distal mouse lung epithelium. We classified 80 cells comprising the distal lung epithelium at E18.5 into distinct populations using an unbiased genome-wide approach that did not require a priori knowledge of the underlying cell types or prior purification of cell types. This “reverse tissue engineering” approach confirmed the basic outlines of the conventional model of cell type diversity in the distal lung and led to the discovery of a large number of novel transcriptional regulators and cell type markers that discriminate between the different populations. Moreover, we reconstructed the steps during maturation of bipotential progenitors into both alveolar lineages based on the presence of undifferentiated, differentiated as well as differentiation intermediate cells at the single time point E18.5. Finally, we followed Sftpc-positive cells throughout their lifecycle (E14.5, E16.5, E18.5, adult) and identified 7 gene sets that differentiate between the multipotential, bipotential, mature, as well as intermediate states of the AT2 lineage.