Esophageal development and epithelial homeostasis.

The esophagus is a relatively simple organ that evolved to transport food and liquids through the thoracic cavity. It is the only part of the gastrointestinal tract that lacks any metabolic, digestive, or absorptive function. The mucosa of the adult esophagus is covered by a multilayered squamous epithelium with a remarkable similarity to the epithelium of the skin despite the fact that these tissues originate from two different germ layers. Here we review the developmental pathways involved in the establishment of the esophagus and the way these pathways regulate gut-airway separation. We summarize current knowledge of the mechanisms that maintain homeostasis in esophageal epithelial renewal in the adult and the molecular mechanism of the development of Barrett's metaplasia, the precursor lesion to esophageal adenocarcinoma. Finally, we examine the ongoing debate on the hierarchy of esophageal epithelial precursor cells and on the presence or absence of a specific esophageal stem cell population. Together the recent insights into esophageal development and homeostasis suggest that the pathways that establish the esophagus during development also play a role in the maintenance of the adult epithelium. We are beginning to understand how reflux of gastric content and the resulting chronic inflammation can transform the squamous esophageal epithelium to columnar intestinal type metaplasia in Barrett's esophagus.

[1]  Hayley E. Francies,et al.  Prospective Derivation of a Living Organoid Biobank of Colorectal Cancer Patients , 2015, Cell.

[2]  M. Diehn,et al.  Identification and genetic manipulation of human and mouse oesophageal stem cells , 2015, Gut.

[3]  J. Peters,et al.  BMP-driven NRF2 activation in esophageal basal cell differentiation and eosinophilic esophagitis. , 2015, The Journal of clinical investigation.

[4]  Toshiro Sato,et al.  Modeling colorectal cancer using CRISPR-Cas9–mediated engineering of human intestinal organoids , 2015, Nature Medicine.

[5]  A. Deal,et al.  FOXP1 potentiates Wnt/β-catenin signaling in diffuse large B cell lymphoma , 2015, Science Signaling.

[6]  C. Wijmenga,et al.  Polymorphisms Near TBX5 and GDF7 Are Associated With Increased Risk for Barrett’s Esophagus , 2015, Gastroenterology.

[7]  E. Lagasse,et al.  Cellular heterogeneity in the mouse esophagus implicates the presence of a nonquiescent epithelial stem cell population. , 2014, Cell reports.

[8]  Jian Sun,et al.  Genetic landscape of esophageal squamous cell carcinoma , 2014, Nature Genetics.

[9]  D. Tibboel,et al.  Clinical and etiological heterogeneity in patients with tracheo-esophageal malformations and associated anomalies. , 2014, European journal of medical genetics.

[10]  P. Fockens,et al.  A pSMAD/CDX2 complex is essential for the intestinalization of epithelial metaplasia. , 2014, Cell reports.

[11]  G. R. van den Brink,et al.  ER stress induces epithelial differentiation in the mouse oesophagus , 2014, Gut.

[12]  R. Fitzgerald,et al.  The human squamous oesophagus has widespread capacity for clonal expansion from cells at diverse stages of differentiation , 2014, Gut.

[13]  R. Śmigiel,et al.  Chromosome aberrations and gene mutations in patients with esophageal atresia. , 2013, Journal of pediatric gastroenterology and nutrition.

[14]  S. Chanock,et al.  A Genome-Wide Association Study Identifies New Susceptibility Loci for Esophageal Adenocarcinoma and Barrett’s Esophagus , 2013, Nature Genetics.

[15]  E. Kuipers,et al.  Barrett's oesophagus: epidemiology, cancer risk and implications for management , 2013, Gut.

[16]  H. Barr,et al.  Identification of lineage-uncommitted, long-lived, label-retaining cells in healthy human esophagus and stomach, and in metaplastic esophagus. , 2013, Gastroenterology.

[17]  Yun Lu,et al.  Sox2 cooperates with inflammation-mediated Stat3 activation in the malignant transformation of foregut basal progenitor cells. , 2013, Cell stem cell.

[18]  N. Barker Epithelial stem cells in the esophagus: who needs them? , 2012, Cell stem cell.

[19]  Simon C. Potter,et al.  Common variants at the MHC locus and at chromosome 16q24.1 predispose to Barrett’s esophagus , 2012, Nature Genetics.

[20]  Allon M. Klein,et al.  A Single Progenitor Population Switches Behavior to Maintain and Repair Esophageal Epithelium , 2012, Science.

[21]  G. R. van den Brink,et al.  Hedgehog signaling and maintenance of homeostasis in the intestinal epithelium. , 2012, Physiology.

[22]  M. Kasper,et al.  Hedgehog signalling stimulates precursor cell accumulation and impairs epithelial maturation in the murine oesophagus , 2012, Gut.

[23]  J. Klingensmith,et al.  Compartmentalization of the foregut tube: developmental origins of the trachea and esophagus , 2012, Wiley interdisciplinary reviews. Developmental biology.

[24]  C. Lightdale,et al.  Bile acid and inflammation activate gastric cardia stem cells in a mouse model of Barrett-like metaplasia. , 2012, Cancer cell.

[25]  K. Hochedlinger,et al.  Sox2(+) adult stem and progenitor cells are important for tissue regeneration and survival of mice. , 2011, Cell stem cell.

[26]  R. Shivdasani,et al.  Barx1-Mediated Inhibition of Wnt Signaling in the Mouse Thoracic Foregut Controls Tracheo-Esophageal Septation and Epithelial Differentiation , 2011, PloS one.

[27]  Khek Yu Ho,et al.  Residual Embryonic Cells as Precursors of a Barrett's-like Metaplasia , 2011, Cell.

[28]  J. Lynch,et al.  Ectopic Cdx2 Expression in Murine Esophagus Models an Intermediate Stage in the Emergence of Barrett's Esophagus , 2011, PloS one.

[29]  Eric T. Domyan,et al.  Signaling through BMP receptors promotes respiratory identity in the foregut via repression of Sox2 , 2011, Development.

[30]  V. Karantza,et al.  Keratins in health and cancer: more than mere epithelial cell markers , 2011, Oncogene.

[31]  B. Hogan,et al.  BMP signaling in the development of the mouse esophagus and forestomach , 2010, Development.

[32]  A. Klein-Szanto,et al.  NOTCH1 and NOTCH3 coordinate esophageal squamous differentiation through a CSL-dependent transcriptional network. , 2010, Gastroenterology.

[33]  T. Wang,et al.  TFF2 mRNA transcript expression marks a gland progenitor cell of the gastric oxyntic mucosa. , 2010, Gastroenterology.

[34]  P. Hainaut,et al.  Intraepithelial p63‐dependent expression of distinct components of cell adhesion complexes in normal esophageal mucosa and squamous cell carcinoma , 2010, International journal of cancer.

[35]  A. Klein-Szanto,et al.  Esophageal squamous cell dysplasia and delayed differentiation with deletion of krüppel-like factor 4 in murine esophagus. , 2010, Gastroenterology.

[36]  D. L. Wilburn,et al.  Aberrant epithelial-mesenchymal Hedgehog signaling characterizes Barrett's metaplasia. , 2010, Gastroenterology.

[37]  Kenneth K Wang,et al.  History, molecular mechanisms, and endoscopic treatment of Barrett's esophagus. , 2010, Gastroenterology.

[38]  Hans Clevers,et al.  Coexistence of Quiescent and Active Adult Stem Cells in Mammals , 2010, Science.

[39]  B. Hogan,et al.  Preparing for the first breath: genetic and cellular mechanisms in lung development. , 2010, Developmental cell.

[40]  Christopher P Crum,et al.  p63 in epithelial survival, germ cell surveillance, and neoplasia. , 2010, Annual review of pathology.

[41]  H. Clevers,et al.  Lgr5(+ve) stem cells drive self-renewal in the stomach and build long-lived gastric units in vitro. , 2010, Cell stem cell.

[42]  K. Ogawa,et al.  Hedgehog and epithelial‐mesenchymal transition signaling in normal and malignant epithelial cells of the esophagus , 2009, International journal of cancer.

[43]  M. Lu,et al.  Wnt2/2b and beta-catenin signaling are necessary and sufficient to specify lung progenitors in the foregut. , 2009, Developmental cell.

[44]  M. Herlyn,et al.  A subpopulation of mouse esophageal basal cells has properties of stem cells with the capacity for self-renewal and lineage specification. , 2008, The Journal of clinical investigation.

[45]  N. Manley,et al.  Bmp4 is required for tracheal formation: a novel mouse model for tracheal agenesis. , 2008, Developmental biology.

[46]  H. Clevers,et al.  Identification of stem cells in small intestine and colon by marker gene Lgr5 , 2007, Nature.

[47]  G. R. Brink,et al.  Hedgehog Signaling in Development and Homeostasis of the Gastrointestinal Tract , 2007 .

[48]  B. Hogan,et al.  Multiple dose-dependent roles for Sox2 in the patterning and differentiation of anterior foregut endoderm , 2007, Development.

[49]  Kenneth K Wang,et al.  Bone morphogenetic protein 4 expressed in esophagitis induces a columnar phenotype in esophageal squamous cells. , 2007, Gastroenterology.

[50]  J. Tobias,et al.  Overexpression of Kruppel-like factor 5 in esophageal epithelia in vivo leads to increased proliferation in basal but not suprabasal cells. , 2007, American journal of physiology. Gastrointestinal and liver physiology.

[51]  M. Lu,et al.  Foxp2 and Foxp1 cooperatively regulate lung and esophagus development , 2007, Development.

[52]  P. ten Dijke,et al.  Aberrant Bmp signaling and notochord delamination in the pathogenesis of esophageal atresia , 2007, Developmental dynamics : an official publication of the American Association of Anatomists.

[53]  G. R. van den Brink,et al.  The morphogenetic code and colon cancer development. , 2007, Cancer cell.

[54]  J. Klingensmith,et al.  Morphogenesis of the trachea and esophagus: current players and new roles for noggin and Bmps. , 2006, Differentiation; research in biological diversity.

[55]  J. Lü,et al.  Regulation of early lung morphogenesis: questions, facts and controversies , 2006, Development.

[56]  D. Fitzpatrick,et al.  Mutations in SOX2 cause anophthalmia-esophageal-genital (AEG) syndrome. , 2006, Human molecular genetics.

[57]  M. Brent,et al.  Molecular Properties of Adult Mouse Gastric and Intestinal Epithelial Progenitors in Their Niches* , 2006, Journal of Biological Chemistry.

[58]  J. Slack,et al.  Conversion of columnar to stratified squamous epithelium in the developing mouse oesophagus. , 2005, Developmental biology.

[59]  D. Bonneau,et al.  Absence of deletion at the SOX2 locus in a case of microphthalmia and esophageal atresia , 2004, American journal of medical genetics. Part A.

[60]  M. Oren,et al.  Critical role of p63 in the development of a normal esophageal and tracheobronchial epithelium. , 2004, American journal of physiology. Cell physiology.

[61]  M. Imamura,et al.  Neurotrophin receptor p75NTR characterizes human esophageal keratinocyte stem cells in vitro , 2003, Oncogene.

[62]  T. Ogura,et al.  Tbx5 and Tbx4 trigger limb initiation through activation of the Wnt/Fgf signaling cascade , 2003, Development.

[63]  N. Huh,et al.  Expression of Hornerin in Stratified Squamous Epithelium in the Mouse: A Comparative Analysis with Profilaggrin , 2003, The journal of histochemistry and cytochemistry : official journal of the Histochemistry Society.

[64]  M. Lu,et al.  Wnt7b regulates mesenchymal proliferation and vascular development in the lung. , 2002, Development.

[65]  K. Kaestner,et al.  Cdx2 ectopic expression induces gastric intestinal metaplasia in transgenic mice. , 2002, Gastroenterology.

[66]  P. Carlsson,et al.  Haploinsufficiency of the forkhead gene Foxf1, a target for sonic hedgehog signaling, causes lung and foregut malformations. , 2001, Development.

[67]  Nobuyuki Itoh,et al.  Fibroblast growth factors , 2001, Genome Biology.

[68]  F. Watt,et al.  Asymmetric stem-cell divisions define the architecture of human oesophageal epithelium , 2000, Current Biology.

[69]  D. Melton,et al.  Hedgehog signals regulate multiple aspects of gastrointestinal development. , 2000, Development.

[70]  B. Spencer‐Dene,et al.  An important role for the IIIb isoform of fibroblast growth factor receptor 2 (FGFR2) in mesenchymal-epithelial signalling during mouse organogenesis. , 2000, Development.

[71]  R. Orlando,et al.  Esophageal submucosal glands: structure and function , 1999, American Journal of Gastroenterology.

[72]  P. Minoo,et al.  Defects in tracheoesophageal and lung morphogenesis in Nkx2.1(-/-) mouse embryos. , 1999, Developmental biology.

[73]  Christopher P. Crum,et al.  p63 is essential for regenerative proliferation in limb, craniofacial and epithelial development , 1999, Nature.

[74]  L. Whitbread,et al.  Expression of the intermediate filament keratin gene, K15, in the basal cell layers of epithelia and the hair follicle. , 1998, Experimental cell research.

[75]  D. Danilenko,et al.  Fgf-10 is required for both limb and lung development and exhibits striking functional similarity to Drosophila branchless. , 1998, Genes & development.

[76]  A. McMahon,et al.  Sonic hedgehog regulates branching morphogenesis in the mammalian lung , 1998, Current Biology.

[77]  M. Post,et al.  Essential function of Gli2 and Gli3 in the formation of lung, trachea and oesophagus , 1998, Nature Genetics.

[78]  H. Westphal,et al.  Sonic hedgehog is essential to foregut development , 1998, Nature Genetics.

[79]  A. Yang,et al.  p63, a p53 homolog at 3q27-29, encodes multiple products with transactivating, death-inducing, and dominant-negative activities. , 1998, Molecular cell.

[80]  P. Chambon,et al.  Function of the retinoic acid receptors (RARs) during development (II). Multiple abnormalities at various stages of organogenesis in RAR double mutants. , 1994, Development.

[81]  A. Joyner,et al.  Expression of three mouse homologs of the Drosophila segment polarity gene cubitus interruptus, Gli, Gli-2, and Gli-3, in ectoderm- and mesoderm-derived tissues suggests multiple roles during postimplantation development. , 1994, Developmental biology.

[82]  G. Hutchins,et al.  Septation of the respiratory and digestive tracts in human embryos: Crucial role of the tracheoesophageal sulcus , 1994, The Anatomical record.

[83]  E. Fuchs,et al.  The roles of K5 and K14 head, tail, and R/K L L E G E domains in keratin filament assembly in vitro , 1992, The Journal of cell biology.

[84]  R. Lauro,et al.  The transcription factor TTF-1 is expressed at the onset of thyroid and lung morphogenesis and in restricted regions of the foetal brain. , 1991, Development.

[85]  G. Millane,et al.  Development of esophageal epithelium in the fetal and neonatal mouse , 1991, The Anatomical record.

[86]  A. Steven,et al.  Identification of a major keratinocyte cell envelope protein, loricrin , 1990, Cell.

[87]  Jean Kanitakis,et al.  Filaggrin expression in normal and pathological skin , 1988, Virchows Archiv A.

[88]  P. Arsenault,et al.  Maturation of human fetal esophagus maintained in organ culture , 1987, The Anatomical record.

[89]  K. Resing,et al.  High-molecular-weight precursor of epidermal filaggrin and hypothesis for its tandem repeating structure. , 1984, Biochemistry.

[90]  H Green,et al.  Involucrin synthesis and tissue assembly by keratinocytes in natural and cultured human epithelia , 1981, The Journal of cell biology.

[91]  I. Bouchier,et al.  The electron microscopy of normal human oesophageal epithelium , 1978, Virchows Archiv. B, Cell pathology.

[92]  C. P. Leblond,et al.  MITOSIS AND DIFFERENTIATION IN THE STRATIFIED SQUAMOUS EPITHELIUM OF THE RAT ESOPHAGUS. , 1965, The American journal of anatomy.

[93]  R. Lovell-Badge,et al.  Multipotent cell lineages in early mouse development depend on SOX2 function. , 2003, Genes & development.

[94]  Nobuyuki Itoh,et al.  Fgf10 is essential for limb and lung formation , 1999, Nature Genetics.

[95]  D J Ruiter,et al.  Cell type heterogeneity of cytokeratin expression in complex epithelia and carcinomas as demonstrated by monoclonal antibodies specific for cytokeratins nos. 4 and 13. , 1986, Experimental cell research.

[96]  C. P. Leblond,et al.  The pattern of stem cell renewal in three epithelia. (esophagus, intestine and testis). , 1967, Proceedings. Canadian Cancer Conference.