Project description:Internal organs heal injuries with new connective tissue. However the cellular and molecular events, and the sources of this tissue, remain obscure. Here we tagged extracellular matrix around the mesothelium lining various mouse tissues: peritoneum, liver, and cecum, and applied various injury models. We discovered that preexisting matrix is transferred across organs into wounds. Using proteomics, genetic lineage-tracing and by selectively injuring juxtaposed organs, we demonstrate that the matrix tissue of origin likely dictates the final healing outcome: whether scarring or regeneration.

Project description:Neutrophils direct preexisting matrix in to initiate repair of damaged organs

Project description:Mesothelia, which cover all coelomic organs and body cavities in vertebrates, perform diverse functions in embryonic and adult life. Yet, mesothelia are traditionally viewed as simple, uniform epithelia. We used microarrays to demonstrate distinct differences between visceral and parietal mesothelia, the most basic subdivision of this tissue type, in terms of gene expression. Visceral mesothelium was isolated from the omentum of adult Wt1-cre;Rosa26ReYFP mice. In parallel, parietal mesothelium was isolated by teasing the mesothelium from the underlying skeletal muscle of the body wall of these animals. RNA was then extracted from these native mesothelia samples and used for hybridization in a microarray experiment.

Project description:Mesothelium is a multipotent resident progenitor cell of the coelomic organs that functions in organogenesis, repair and possible regeneration. We used hESCs to generate mesothelium of the epithelial and mesenchymal forms. Mesenchymal derivatives of mesothelium have been previously reported to function in tissue repair by promoting and participating in angiogenesis and neovascularization. We uncovered that hESC-derived mesothelium of the mesenchymal form (MesoT) are multipotent and generate smooth muscle cells, endothelial cells and pericytes and self-assemble into vessel-like networks in vitro. MesoT cells contribute to nascent coronary vessels in the repair zone of mechanically damaged neonatal mouse hearts. MesoT cells seeded onto vascular scaffolds self-assemble into vasculature capable of supporting peripheral blood flow following transplantation. Our findings demostrate the potential utility of MesoT cells in tissue repair and vascular engineering applications.

Project description:The mesothelium forms epithelial membranes that line the bodies cavities and surround the internal organs. Mesothelia widely contribute to organ homeostasis and regeneration, and their dysregulation can result in congenital anomalies of the viscera, ventral wall defects, and mesothelioma tumors. Nonetheless, the embryonic ontogeny and developmental regulation of mesothelium formation has remained uncharted. Here, we combine genetic lineage tracing, in toto live imaging, and single-cell transcriptomics in zebrafish to track mesothelial progenitor origins from the lateral plate mesoderm (LPM). Our single-cell analysis uncovers a post-gastrulation gene expression signature centered on hand2 that delineates distinct progenitor populations within the forming LPM. Combining gene expression analysis and imaging of transgenic reporter zebrafish embryos, we chart the origin of mesothelial progenitors to the lateral-most, hand2-expressing LPM and confirm evolutionary conservation in mouse. Our time-lapse imaging of transgenic hand2 reporter embryos captures zebrafish mesothelium formation, documenting the coordinated cell movements that form pericardium and visceral and parietal peritoneum. We establish that the primordial germ cells migrate associated with the forming mesothelium as ventral migration boundary. Functionally, hand2 mutants fail to close the ventral mesothelium due to perturbed migration of mesothelium progenitors. Analyzing mouse and human mesothelioma tumors hypothesized to emerge from transformed mesothelium, we find de novo expression of LPM-associated transcription factors, and in particular of Hand2, indicating the re-initiation of a developmental transcriptional program in mesothelioma. Taken together, our work outlines a genetic and developmental signature of mesothelial origins centered around Hand2, contributing to our understanding of mesothelial pathologies and mesothelioma.

Project description:Fibroblasts are polymorphic cells with pleiotropic roles in organ morphogenesis, tissue homeostasis and immune responses. In fibrotic diseases, fibroblasts synthesize abundant amounts of extracellular matrix which lead to scaring and organ failure. In sharp contrast, the hallmark feature of fibroblasts in arthritis is matrix degradation by the release of metalloproteinases and degrading enzymes, and subsequent tissue destruction. The mechanisms driving these functionally opposing pro-fibrotic and pro-inflammatory phenotypes of fibroblasts are enigmatic. We have compared resting, fibrotic, and inflammatory fibroblasts; PU.1 was overexpressed in dermal fibroblasts and compared to scr-transfected controls. Fibrotic fibroblasts isolated from the skin of patients with systemic sclerosis were treated with PU.1 inhibitor and compared to untreated fibrotic fibroblasts and respective healthy controls. Through this, we identified the transcription factor PU.1 as an essential orchestrator of the pro-fibrotic gene expression program. The interplay between transcriptional and post-transcriptional mechanisms which normally control PU.1 expression is perturbed in fibrotic diseases such as pulmonary fibrosis, systemic sclerosis, liver cirrhosis, kidney fibrosis and chronic graft-versus-host disease, resulting in upregulation of PU.1, the induction of fibrosis-associated gene sets, and a phenotypic switch in matrix-producing pro-fibrotic fibroblasts. In contrast, inactivation of PU.1 disrupts the fibrotic network and enables re-programming of fibrotic fibroblasts into resting fibroblasts with regression of fibrosis in different organs. Targeting of PU.1 may thus represent a novel therapeutic approach for the treatment of a wide range of fibrotic diseases.

Project description:Genome wide DNA methylation profiling of hESC-derived mesothelium (MesoT), hESCs and hESC-derived splanchnic mesoderm (SplM) compared to primary human tissue samples. The Illumina Infinium HumanMethylation450 BeadChip kit was used to obtain DNA methylation profiles across approximately 450,000 methylation sites. Samples include 2 WA09 hESCs, 2 hESC-derived splanchnic mesoderm and 3 hESC-derived mesothelium replicates.

Project description:The Preexisting T Cell Landscape Determines Response to T Cell-Engagers Therapy

Project description:The Preexisting T Cell Landscape Determines Response to T Cell-Engagers Therapy

Project description:Intratracheal transfer of isolated lung fibroblasts in bleomycin-induced lung fibrosis recapitulates the activation process of lung fibroblasts after epithelial injury. In order to investigate gene expression signatures of transferred fibroblasts, we purified transferred fibroblasts 2, 4, and 7 days after the transfer and performed transcriptome analysis. We also isolated Acta2 high and low cells by using Acta2-mKO1 reporter mice 4 days after the transfer.