Project description:Polarity defects are a hallmark of most carcinomas. Cells from invasive micropapillary carcinomas (IMPCs) of the breast are characterized by a striking cell polarity inversion and represent a good model for the analysis of polarity abnormalities. We have performed an in-depth investigation of polarity alterations in 24 IMPCs, compared with invasive carcinomas of no special type (ICNST). We used microarrays to compared gene expression profilings of IMPC with ICNST in a training set and in validation one. 124 breast cancer samples: 73 IMPC and 51 ICNST (training set: 63 samples and validation set: 61 samples)

Project description:In the study we show that a specific peripheral glial population, derived from boundary cap (BC) cells, constitutes a major source of mural cells for the developing vasculature. Using Cre-based reporter cell tracing and single cell transcriptomics, we show that BC cell derivatives migrate along the nerves and differentiate into pericytes and vascular smooth muscle cells in the skin. The switch from glial to mural molecular identity is initiated while the cells are still associated with nerves To further characterize this transition glial to vascular identity, we performed single cell transcriptomic analyses (scRNA-seq) on FACS-purified traced cells from dissociated E12.5 skin. Tomato-positive cells were isolated by FACS from embryonic skin at E12.5. Around 10,000 cells were loaded into one channel of the Chromium system using the V3 single cell reagent kit (10X Genomics) We analyzed 2527 single cell transcriptomes with a mean number of expressed genes per cell of 4,696. This study highlights the plasticity of BC derivatives and uncovers a novel, nerve-derived origin for skin mural cells.

Project description:Robust differentiation of human pluripotent stem cells into mural progenitor cells via transient activation of NKX3.1

Project description:Purpose: Pericytes, the mural cells of blood microvessels, have come into focus as regulators of microvascular development and function, but due to paucity of defining markers, the identification and functional characterization of PC remain problematic, and reported data are often controversial. Here, we used a new approach for the isolation of mural cell from mouse brain in combination with RNA-sequencing (RNA-seq) and previously published vascular transcriptome data to assemble a state-of-the-art catalogue of brain mural cell-enriched gene transcripts. Methods: We isolated double positive cells from the brain of Pdgfrb-eGFP/NG2-DsRed transgenic mice using FACS. Cells were lysed, RNA extracted and sequenced with next-generation sequencing (NGS). For comparison, we also determined the transcriptome of brain microvascular fragments (containing both endothelial cells and mural cells) isolated by mechanical tissue disintegration, collagenase digestion and immune-panning using anti-CD31 antibodies coupled to magnetic beads. The reads were aligned to the Ensembl mouse gene assembly (NCBIM37) using Tophat2 software (version 2.0.4). The duplicated reads were removed using the picard tool (version 1.92). To identify the genes significantly enriched in the pericyte samples as compared with microvascular samples, statistical tests were performed using the Cufflinks tool (version 2.2.1) Results: The result showed that mRNA transcripts representing 856 different genes were enriched more than two-fold in FACS isolated Pdgfrb-eGFP/NG2-DsRed double positive cells compared with whole microvascular fragments (False Discovery Rate < 0.05) The RNA from three FACS sorted brain mural cell samples and three whole brain microvascular samples isolated from three animals were processed and sequenced on the Illumina HiSeq 2500 platform in the sequencing facility in Uppsala University.

Project description:The NKX3.1 homeobox gene functions in mitochondria to regulate oxidative stress To investigate the role of NKX3.1 in regulation of oxidative stress, we employed transcriptome analysis of mouse prostate ( from 4 month old Nkx3.1+/+ and Nkx3.1-/- mice treated with paraquat), and human prostate cells ( RWPE1 cells engineered with empty vector (altered pTRIPZ), NKX3.1 wild type over-expression, and NKX3.1 (R52C) over-expression treated with paraquat). Mouse tissue or human cells were snap frozen for subsequent molecular analysis.

Project description:Mural painting Metagenome

Project description:Mural Painting Metagenome

Project description:The NKX3.1 homeobox gene functions in mitochondria to regulate oxidative stress To investigate the role of NKX3.1 in regulation of oxidative stress, we employed transcriptome analysis of mouse prostate ( from 4 month old Nkx3.1+/+ and Nkx3.1-/- mice treated with paraquat), and human prostate cells ( RWPE1 cells engineered with empty vector (altered pTRIPZ), NKX3.1 wild type over-expression, and NKX3.1 (R52C) over-expression treated with paraquat). Mouse tissue or human cells were snap frozen for subsequent molecular analysis.

Project description:Direct lineage reprogramming provides a unique system to study cell fate transitions and unearth molecular mechanisms that safeguard cellular identity. We previously reported on direct conversion of mouse fibroblasts into induced myogenic progenitor cells (iMPCs) by means of transient MyoD overexpression in concert with small molecules treatment. Here we employed integrative multi-omic assays to delineate the molecular landscape of fibroblast reprogramming into iMPCs in comparison to transdifferentiation into myogenic cells solely by MyoD overexpression. Utilizing bulk RNA-sequencing and mass spectrometry we characterized molecular regulators and pathways that endow a myogenic stem cell identity on fibroblasts only in the presence of small molecule treatment. We further demonstrate that iMPC reprogramming is a stepwise process, commencing with the appearance of myofibers and committed myogenic progenitors prior to the formation of satellite cell-like myogenic progenitors that express a suite of stem cell markers including Pax7, Dek, Myf5, Sox8, and Dmrt2. To directly compare iMPCs to satellite cell-derived primary myoblasts, we employed a fluorescent Pax7-GFP reporter to purify Pax7+ cells from the heterogenous iMPC cultures and assess their equivalency to FACS-purified Pax7-GFP+ myoblasts. We demonstrate that Pax7+ iMPCs share molecular attributes with myoblasts, however also express genes and signaling pathways that are indicative of activated satellite cells including Carm1, Dlk1, Lgr5, Fos, Dek, Calcr and Pitx3. We further establish that iMPC formation and maintenance is dependent on the Notch pathway, as small molecule inhibition of Notch abrogates iMPC formation and derails stable iMPC cultures via depletion of Pax7 expressing cells. Lastly, using single cell RNA-sequencing we determine the cell populations that comprise iMPCs in addition to reconstructing the differentiation trajectory present in these heterogenous cultures. We demonstrate that a highly proliferative activated satellite cell-like population differentiates into committed myoblasts and myocytes that further give rise to myofibers that express mature muscle markers, thus capturing a dynamic differentiation program in vitro. Collectively, this study charts a molecular blueprint for reprogramming fibroblasts into myogenic stem and progenitor cells and further establishes the fidelity of stable iMPC cultures in capturing skeletal muscle regeneration in vitro for disease modeling and basic research applications.

Project description:Direct lineage reprogramming provides a unique system to study cell fate transitions and unearth molecular mechanisms that safeguard cellular identity. We previously reported on direct conversion of mouse fibroblasts into induced myogenic progenitor cells (iMPCs) by means of transient MyoD overexpression in concert with small molecules treatment. Here we employed integrative multi-omic assays to delineate the molecular landscape of fibroblast reprogramming into iMPCs in comparison to transdifferentiation into myogenic cells solely by MyoD overexpression. Utilizing bulk RNA-sequencing and mass spectrometry we characterized molecular regulators and pathways that endow a myogenic stem cell identity on fibroblasts only in the presence of small molecule treatment. We further demonstrate that iMPC reprogramming is a stepwise process, commencing with the appearance of myofibers and committed myogenic progenitors prior to the formation of satellite cell-like myogenic progenitors that express a suite of stem cell markers including Pax7, Dek, Myf5, Sox8, and Dmrt2. To directly compare iMPCs to satellite cell-derived primary myoblasts, we employed a fluorescent Pax7-GFP reporter to purify Pax7+ cells from the heterogenous iMPC cultures and assess their equivalency to FACS-purified Pax7-GFP+ myoblasts. We demonstrate that Pax7+ iMPCs share molecular attributes with myoblasts, however also express genes and signaling pathways that are indicative of activated satellite cells including Carm1, Dlk1, Lgr5, Fos, Dek, Calcr and Pitx3. We further establish that iMPC formation and maintenance is dependent on the Notch pathway, as small molecule inhibition of Notch abrogates iMPC formation and derails stable iMPC cultures via depletion of Pax7 expressing cells. Lastly, using single cell RNA-sequencing we determine the cell populations that comprise iMPCs in addition to reconstructing the differentiation trajectory present in these heterogenous cultures. We demonstrate that a highly proliferative activated satellite cell-like population differentiates into committed myoblasts and myocytes that further give rise to myofibers that express mature muscle markers, thus capturing a dynamic differentiation program in vitro. Collectively, this study charts a molecular blueprint for reprogramming fibroblasts into myogenic stem and progenitor cells and further establishes the fidelity of stable iMPC cultures in capturing skeletal muscle regeneration in vitro for disease modeling and basic research applications.