Project description:Esophageal adenocarcinoma (EA) is increasingly prevalent and is thought to arise from Barrett’s esophagus (BE), a metaplastic condition in which chronic acid and bile reflux transforms the esophageal squamous epithelium into a gastric-intestinal glandular mucosa. The molecular determinants driving this metaplasia are poorly understood. We developed a human BE organoid biobank that recapitulates BE’s molecular heterogeneity. Bulk and single-cell transcriptomics, supported by patient tissue analysis, revealed that BE differentiation reflects a balance between SOX2 (foregut/esophageal) and CDX2 (hindgut/intestinal) transcription factors. Using squamous-specific inducible Sox2 knockout (Krt5CreER/+; Sox2∆/∆; ROSA26tdTomato/+) mice, we observed increased basal proliferation, reduced squamous differentiation, and expanded metaplastic glands at the squamocolumnar junction, some tracing back to Krt5-expressing cells. CUT&RUN analysis showed SOX2 bound and promoted differentiation-associated (e.g., Krt13) and repressed proliferation-associated (e.g., Mki67) targets. Thus, SOX2 is critical for foregut squamous epithelial differentiation and its decreased expression is likely an initiating step in progression to BE and thence to EA.

Project description:Esophageal adenocarcinoma (EA) is increasingly common. EA is thought to arise from a precursor lesion, Barrett’s esophagus (BE), in which chronic bile and acid reflux from the stomach injures the esophagus and induces the esophageal squamous epithelium to transition to a mixed gastric and intestinal glandular mucosa. The molecular determinants driving this metaplasia are poorly understood. We established a biobank of human patient-derived BE organoids that recapitulated the molecular heterogeneity of BE. Bulk and single-cell transcriptomics, corroborated with analysis of patient tissues, pointed to BE differentiation depending on a balance between two transcription factors that govern foregut versus hindgut embryonic gastrointestinal development: SOX2 (driving esophageal and stomach differentiation) and CDX2 (driving intestinal differentiation). Using squamous-specific inducible Sox2 knockout (Krt5CreER/+; Sox2Δ/Δ;ROSA26LSLTdTomato/+) mice, we found increased basal proliferation and decreased differentiation in the foregut squamous epithelium. Remarkably, Sox2Δ/Δ mice also harbored expanded glands at the squamocolumnar junction, some of which lineage traced to Krt5-expressing cells, indicating metaplasia from squamous epithelium. CUT&RUN analysis showed SOX2 bound and promoted differentiation-associated (e.g.,Krt13) and repressed proliferation-associated (e.g., Mki67) targets. Thus, SOX2 is critical for foregut squamous epithelial differentiation and its decreased expression likely an initiating step in progression to BE and thence to EA.

Project description:Tracheoesophageal disorders and diseases are prevalent in humans such that an organoid model of human esophagus could be greatly beneficial. We therefore established a three-dimensional esophageal organoid culture system through the directed differentiation of human pluripotent stem cells (hPSCs). We identified that sequential manipulation of several signaling pathways resulted in patterning of definitive endoderm to dorsal anterior foregut spheroids (dAFGs). Outgrowth of dAFGs for 1-2 months resulted in human esophageal organoids (HEOs) with a stratified squamous epithelium comparable to a late gestation mouse embryonic esophagus. These 1 and 2 month old HEOs were harvested for RNA to transcriptionally profile and compare them to profiles of esophageal tissue biopsies and keratinocytes. We then used HEOs and mouse embryos to identify how SOX2 mediates separation of the esophageal and respiratory lineages and found that loss of endodermal Sox2 results in complete esophageal agenesis. Using a SOX2 CRISPR interference iPS line, we generated dorsal and ventral anterior foregut progenitors (by manipulating BMP signaling) with or without SOX2-knockdown. At the transcriptional level, SOX2 acts to promote esophageal specification in both mice and humans in part by inhibiting Wnt signaling in the dorsal AFG and promoting survival of esophageal epithelium. In addition to this use of hPSC-derived esophageal organoids to study development, HEOs can be used for future studies of esophageal pathologies, such as Barrett’s metaplasia and carcinoma. 

Project description:Barrett’s esophagus (BE) is a metaplastic precursor lesion of esophageal adenocarcinoma (EA), the most rapidly increasing cancer in western societies. While the prevalence of BE is increasing, the vast majority of EA occurs in patients with undiagnosed BE. Thus, we sought to identify genes that are altered in BE compared to the normal mucosa of the esophagus, and which may be potential biomarkers for the development or diagnosis of BE. We performed gene expression analysis using HG-U133A Affymetrix chips on fresh frozen tissue samples of Barrett’s metaplasia and matched normal mucosa from squamous esophagus (NE) and gastric cardia (NC) in 43 BE patients.

Project description:SAGE libraries made of squamous esophagus tissue, primary cell culture or esophageal squamous cell carcinoma Keywords: SAGE analysis of different tissues squamous esophagus biopsy was taken from 1 male metaplastic Barrett's esophagus patient. primary cell culture was from 1 male Barrett's esophagus patient. Esophageal squamous cell carcinoma was from a patient known to have ESCC

Project description:Barrett’s esophagus (BE) is a metaplastic precursor lesion of esophageal adenocarcinoma (EA), the most rapidly increasing cancer in western societies. While the prevalence of BE is increasing, the vast majority of EA occurs in patients with undiagnosed BE. Thus, we sought to identify genes that are altered in BE compared to the normal mucosa of the esophagus, and which may be potential biomarkers for the development or diagnosis of BE.

Project description:Lineage-survival oncogenes are targeted by gene amplification in cancers arising from the tissues where these genes play a role in normal development. Here we show that the transcription factor SOX2—previously known to be mutated in hereditary human esophageal malformations, to be necessary for normal esophageal squamous development, to promote proliferation of basal tracheal cells and to co-operate in induction of pluripotent stem cells -- acts as an amplified oncogene in squamous cell carcinomas (SCC) of the lung and esophagus. We identified SOX2 at a peak of genomic amplification on chromosome 3q26.33 in SCCs of both the lung and esophagus but did not find it to be significantly amplified in adenocarcinomas from these tissues. Tumors with SOX2 amplification showed higher SOX2 mRNA expression, and suppression of SOX2 by RNAi in lung and esophageal SCC cell lines revealed that SOX2 expression is required for proliferation and anchorage-independent growth. Furthermore, ectopic expression of SOX2 cooperated with FOXE1 or FGFR2 to transform immortalized tracheobronchial epithelial cells. SOX2-driven tumors showed expression of markers of both squamous differentiation and pluripotency. These observations identify SOX2 as a novel lineage survival oncogene in lung and esophageal SCC and suggest novel connections between development, pluripotency and carcinogenesis.

Project description:Barrett's esophagus is characterized by the replacement of squamous epithelium with specialized intestinal metaplastic mucosa. The exact mechanisms of initiation and development of Barrett's metaplasia remain unknown, but a hypothesis of successful adaptation against noxious reflux components has been proposed. To search for the repertoire of adaptation mechanisms of Barrett's metaplasia, we employed high-throughput functional genomic and proteomic methods that defined the molecular background of metaplastic mucosa resistance to reflux. Transcriptional profiling was established for 23 pairs of esophageal squamous epithelium and Barrett's metaplasia tissue samples using Affymetrix U133A 2.0 GeneChips and validated by quantitative real-time polymerase chain reaction. Differences in protein composition were assessed by electrophoretic and mass-spectrometry-based methods. Among 2,822 genes differentially expressed between Barrett's metaplasia and squamous epithelium, we observed significantly overexpressed metaplastic mucosa genes that encode cytokines and growth factors, constituents of extracellular matrix, basement membrane and tight junctions, and proteins involved in prostaglandin and phosphoinositol metabolism, nitric oxide production, and bioenergetics. Their expression likely reflects defense and repair responses of metaplastic mucosa, whereas overexpression of genes encoding heat shock proteins and several protein kinases in squamous epithelium may reflect lower resistance of normal esophageal epithelium than Barrett's metaplasia to reflux components. Despite the methodological and interpretative difficulties in data analyses discussed in this paper, our studies confirm that Barrett's metaplasia may be regarded as a specific microevolution allowing for accumulation of mucosal morphological and physiological changes that better protect against reflux injury. Department of Gastroenterology, Medical Center for Postgraduate Education and Maria SkM-EM-^Bodowska-Curie Memorial Cancer Center and Institute of Oncology, 02-781 Warsaw, Poland 2 types of tissue sample derived from the same patient: > Normal squamous epithelium (NE) from patients with longsegment of BarretM-bM-^@M-^Ys epithelium > Metaplastic epithelium from BarrettM-bM-^@M-^Ys esophagus (BE)

Project description:Barrett's esophagus is a metaplastic condition of the distal esophagus, characterized by the replacement of normal squamous epithelium by columnar epithelium. Patients with BE have an increased risk of developing esophageal adenocarcinoma. MicroRNAs have been implicated to be disease and tissue specific, however limited data of microRNA expression in the esophagus is available. Therefore we evaluated microRNA expression profiles of esophageal adenocarcinoma and compared these with Barrett's esophagus and normal squamous esophagus.

Project description:To test the hypothesis that there is a specific miRNA expression signature which characterizes Barrett's esophagus development and progression, we performed miRNA microarray analysis comparing normal esophageal squamous epithelium with the two different metaplastic lesions occuring within Barrett's mucosa (i.e. gastric metaplasia and intestinal metaplasia). Samples of H. pylori-related gastritis and gastric intestinal metaplasia were also considered in the definition of esophageal-specific miRNAs. miRNA microarray analysis was performed in a series of samples obtained from (a) 10 histologically-proven long-segment Barrett's esophagus patients; (b) 10 patients with H. pylori-related chronic atrophic gastritis. Overall, 10 normal esophageal squamous epithelium samples, 10 esophageal intestinal metaplasia samples, 10 esophageal gastric metaplasia samples, 10 H. pylori -related gastritis samples (no atrophic lesion detected; obtained from the antrum) and 10 gastric intestinal metaplasia samples (obtained from the antrum) were considered.