Your search keyword '"Eric Stas"' showing total 8 results

1. Robust differentiation of human enteroendocrine cells from intestinal stem cells

Author

Daniel Zeve, Eric Stas, Joshua de Sousa Casal, Prabhath Mannam, Wanshu Qi, Xiaolei Yin, Sarah Dubois, Manasvi S. Shah, Erin P. Syverson, Sophie Hafner, Jeffrey M. Karp, Diana L. Carlone, Jose Ordovas-Montanes, and David T. Breault

Subjects

Science

Abstract

Hormone-producing enteroendocrine cells (EEC) regulate of energy homeostasis and gastrointestinal function. Here the authors report protocols to induce human intestinal stem cells into EECs producing multiple gut hormones, including SST, 5-HT, CCK and GIP, using directed differentiation with small molecules targeting FOXO1, JNK and CB1 signalling.

Published

2022

2. Human Colon-on-a-Chip Enables Continuous In Vitro Analysis of Colon Mucus Layer Accumulation and PhysiologySummary

Author

Alexandra Sontheimer-Phelps, David B. Chou, Alessio Tovaglieri, Thomas C. Ferrante, Taylor Duckworth, Cicely Fadel, Viktoras Frismantas, Arlene D. Sutherland, Sasan Jalili-Firoozinezhad, Magdalena Kasendra, Eric Stas, James C. Weaver, Camilla A. Richmond, Oren Levy, Rachelle Prantil-Baun, David T. Breault, and Donald E. Ingber

Subjects

Diseases of the digestive system. Gastroenterology, RC799-869

Abstract

Background & Aims: The mucus layer in the human colon protects against commensal bacteria and pathogens, and defects in its unique bilayered structure contribute to intestinal disorders, such as ulcerative colitis. However, our understanding of colon physiology is limited by the lack of in vitro models that replicate human colonic mucus layer structure and function. Here, we investigated if combining organ-on-a-chip and organoid technologies can be leveraged to develop a human-relevant in vitro model of colon mucus physiology. Methods: A human colon-on-a-chip (Colon Chip) microfluidic device lined by primary patient-derived colonic epithelial cells was used to recapitulate mucus bilayer formation, and to visualize mucus accumulation in living cultures noninvasively. Results: The Colon Chip supports spontaneous goblet cell differentiation and accumulation of a mucus bilayer with impenetrable and penetrable layers, and a thickness similar to that observed in the human colon, while maintaining a subpopulation of proliferative epithelial cells. Live imaging of the mucus layer formation on-chip showed that stimulation of the colonic epithelium with prostaglandin E2, which is increased during inflammation, causes rapid mucus volume expansion via an Na-K-Cl cotransporter 1 ion channel–dependent increase in its hydration state, but no increase in de novo mucus secretion. Conclusions: This study shows the production of colonic mucus with a physiologically relevant bilayer structure in vitro, which can be analyzed in real time noninvasively. The Colon Chip may offer a new preclinical tool to analyze the role of mucus in human intestinal homeostasis as well as diseases, such as ulcerative colitis and cancer. Keywords: Organ Chip, Intestine, Organoid, Microfluidic, Goblet Cell, Inflammatory Bowel Disease

Published

2020

3. Robust differentiation of human enteroendocrine cells from intestinal stem cells

Author

David T. Breault, Wanshu Qi, Jose Ordovas-Montanes, Sarah Dubois, Diana L. Carlone, Manasvi S. Shah, Daniel Zeve, Joshua de Sousa Casal, Sophie Hafner, Eric Stas, Jeffrey M. Karp, Xiaolei Yin, Erin Syverson, and Prabhath Mannam

Subjects

endocrine system, Enteroendocrine Cells, Cellular differentiation, Science, Cell, Stem-cell differentiation, General Physics and Astronomy, Enteroendocrine cell, Quinolones, Biology, digestive system, Article, Energy homeostasis, General Biochemistry, Genetics and Molecular Biology, Directed differentiation, Glucagon-Like Peptide 1, medicine, Humans, Peptide YY, Secretion, Intestinal Mucosa, Anthracenes, Multidisciplinary, Stem Cells, Intestinal stem cells, Cell Differentiation, General Chemistry, Cell biology, stomatognathic diseases, medicine.anatomical_structure, Differentiation, Chromogranin A, Rimonabant, Stem cell, Somatostatin, Gastrointestinal function, hormones, hormone substitutes, and hormone antagonists, Endocannabinoids, Signal Transduction, Transcription Factors

Abstract

Enteroendocrine (EE) cells are the most abundant hormone-producing cells in humans and are critical regulators of energy homeostasis and gastrointestinal function. Challenges in converting human intestinal stem cells (ISCs) into functional EE cells, ex vivo, have limited progress in elucidating their role in disease pathogenesis and in harnessing their therapeutic potential. To address this, we employed small molecule targeting of the endocannabinoid receptor signaling pathway, JNK, and FOXO1, known to mediate endodermal development and/or hormone production, together with directed differentiation of human ISCs from the duodenum and rectum. We observed marked induction of EE cell differentiation and gut-derived expression and secretion of SST, 5HT, GIP, CCK, GLP-1 and PYY upon treatment with various combinations of three small molecules: rimonabant, SP600125 and AS1842856. Robust differentiation strategies capable of driving human EE cell differentiation is a critical step towards understanding these essential cells and the development of cell-based therapeutics., Hormone-producing enteroendocrine cells (EEC) regulate of energy homeostasis and gastrointestinal function. Here the authors report protocols to induce human intestinal stem cells into EECs producing multiple gut hormones, including SST, 5-HT, CCK and GIP, using directed differentiation with small molecules targeting FOXO1, JNK and CB1 signalling.

Published

2022

4. Cholinergic Activation of Primary Human Derived Intestinal Epithelium Does Not Ameliorate TNF-α Induced Injury

Author

Ryan A. Koppes, Will Lake, Abigail N. Koppes, Shashi K. Murthy, David T. Breault, Eric Stas, and Sanjin Hosic

Subjects

0301 basic medicine, Chemistry, Enteroendocrine cell, 02 engineering and technology, Bethanechol, 021001 nanoscience & nanotechnology, Cell morphology, Intestinal epithelium, General Biochemistry, Genetics and Molecular Biology, Epithelium, Cell biology, 03 medical and health sciences, 030104 developmental biology, Nicotinic agonist, medicine.anatomical_structure, Modeling and Simulation, Paracellular transport, medicine, Tumor necrosis factor alpha, 2020 CMBE Young Innovators issue, 0210 nano-technology, medicine.drug

Abstract

INTRODUCTION: The intestinal epithelium contains specialized cells including enterocytes, goblet, Paneth, enteroendocrine, and stem cells. Impaired barrier integrity in Inflammatory Bowel Disease is characterized by elevated levels of pro-inflammatory cytokines, including tumor necrosis factor-alpha (TNF-α). Prior studies in immortalized lines such as Caco-2, without native epithelial heterogeneity, demonstrate the amelioration of TNF-α compromised barrier integrity via nicotinic (nAChR) or muscarinic (mAChR) acetylcholine receptor activation. METHODS: A tissue-engineered model of primary human small intestinal epithelium was derived from dissociated organoids cultured on collagen-coated Transwells. Differentiation was accomplished with serum-containing media and compared to Caco-2 and HT-29 regarding alkaline phosphatase expression, transepithelial electrical resistance (TEER), and IL-8 secretion. Inflammation was modeled via basal stimulation with TNF-α (25 ng/mL) with or without nicotine (nAChR agonist) or bethanechol (mAChR agonist). Apoptosis, density (cells/cm(2)), TEER, lucifer yellow permeability, 70 kDa dextran transport, cell morphology, and IL-8 secretion were characterized. RESULTS: Primary intestinal epithelium demonstrates significant functional differences compared to immortalized cells, including increased barrier integrity, IL-8 expression, mucus production, and the presence of absorptive and secretory cells. Exposure to TNF-α impaired barrier integrity, increased apoptosis, altered morphology, and increased secretion of IL-8. Stimulation of nAChR with nicotine did not ameliorate TNF-α induced permeability nor alter 70 kDa dextran transport. However, stimulation of mAChR with bethanechol decreased transport of 70 kDa dextran but did not ameliorate TNF-α induced paracellular permeability. CONCLUSIONS: A primary model of intestinal inflammation was evaluated, demonstrating nAChR or mAChR activation does not have the same protective effects compared to immortalized epithelium. Inclusion of other native stromal support cells are underway. ELECTRONIC SUPPLEMENTARY MATERIAL: The online version of this article (10.1007/s12195-020-00633-0) contains supplementary material, which is available to authorized users.

Published

2020

5. Stiffness Restricts the Stemness of the Intestinal Stem Cells and Skews Their Differentiation Toward Goblet Cells

Author

Shijie He, Peng Lei, Wenying Kang, Priscilla Cheung, Tao Xu, Miyeko Mana, Chan Young Park, Hongyan Wang, Shinya Imada, Jacquelyn O. Russell, Jianxun Wang, Ruizhi Wang, Ziheng Zhou, Kashish Chetal, Eric Stas, Vidisha Mohad, Peter Bruun-Rasmussen, Ruslan I. Sadreyev, Richard A. Hodin, Yanhang Zhang, David T. Breault, Fernando D. Camargo, Ömer H. Yilmaz, Jeffrey J. Fredberg, and Nima Saeidi

Subjects

Hepatology, Gastroenterology

Published

2023

6. Human Colon-on-a-Chip Enables Continuous In Vitro Analysis of Colon Mucus Layer Accumulation and PhysiologySummary

Author

Thomas C. Ferrante, Viktoras Frismantas, Donald E. Ingber, David T. Breault, Sasan Jalili-Firoozinezhad, David B. Chou, Cicely Fadel, Magdalena Kasendra, James C. Weaver, Eric Stas, Rachelle Prantil-Baun, Oren Levy, Camilla A. Richmond, Alexandra Sontheimer-Phelps, Arlene D. Sutherland, Taylor Duckworth, and Alessio Tovaglieri

Subjects

0301 basic medicine, Goblet cell, Hepatology, Chemistry, Gastroenterology, Physiology, Inflammation, respiratory system, medicine.disease, Inflammatory bowel disease, Ulcerative colitis, Mucus, digestive system diseases, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Live cell imaging, medicine, Organoid, 030211 gastroenterology & hepatology, Secretion, lcsh:Diseases of the digestive system. Gastroenterology, medicine.symptom, lcsh:RC799-869

Abstract

Background & Aims: The mucus layer in the human colon protects against commensal bacteria and pathogens, and defects in its unique bilayered structure contribute to intestinal disorders, such as ulcerative colitis. However, our understanding of colon physiology is limited by the lack of in vitro models that replicate human colonic mucus layer structure and function. Here, we investigated if combining organ-on-a-chip and organoid technologies can be leveraged to develop a human-relevant in vitro model of colon mucus physiology. Methods: A human colon-on-a-chip (Colon Chip) microfluidic device lined by primary patient-derived colonic epithelial cells was used to recapitulate mucus bilayer formation, and to visualize mucus accumulation in living cultures noninvasively. Results: The Colon Chip supports spontaneous goblet cell differentiation and accumulation of a mucus bilayer with impenetrable and penetrable layers, and a thickness similar to that observed in the human colon, while maintaining a subpopulation of proliferative epithelial cells. Live imaging of the mucus layer formation on-chip showed that stimulation of the colonic epithelium with prostaglandin E2, which is increased during inflammation, causes rapid mucus volume expansion via an Na-K-Cl cotransporter 1 ion channel–dependent increase in its hydration state, but no increase in de novo mucus secretion. Conclusions: This study shows the production of colonic mucus with a physiologically relevant bilayer structure in vitro, which can be analyzed in real time noninvasively. The Colon Chip may offer a new preclinical tool to analyze the role of mucus in human intestinal homeostasis as well as diseases, such as ulcerative colitis and cancer. Keywords: Organ Chip, Intestine, Organoid, Microfluidic, Goblet Cell, Inflammatory Bowel Disease

Published

2020

7. Stiffness Regulates Intestinal Stem Cell Fate

Author

Shijie He, Peng Lei, Wenying Kang, Priscilla Cheung, Tao Xu, Miyeko Mana, Chan Young Park, Hongyan Wang, Shinya Imada, Jacquelyn O. Russell, Jianxun Wang, Ruizhi Wang, Ziheng Zhou, Kashish Chetal, Eric Stas, Vidisha Mohad, Marianna Halasi, Peter Bruun-Rasmussen, Ruslan I. Sadreyev, Irit Adini, Richard A. Hodin, Yanhang Zhang, David T. Breault, Fernando D. Camargo, Ömer H. Yilmaz, Jeffrey J. Fredberg, and Nima Saeidi

Subjects

musculoskeletal system, digestive system

Abstract

SummaryDoes fibrotic gut stiffening caused by inflammatory bowel diseases (IBD) direct the fate of intestinal stem cells (ISCs)? To address this question we first developed a novel long-term culture of quasi-3D gut organoids plated on hydrogel matrix of varying stiffness. Stiffening from 0.6kPa to 9.6kPa significantly reduces Lgr5high ISCs and Ki67+ progenitor cells while promoting their differentiation towards goblet cells. These stiffness-driven events are attributable to YAP nuclear translocation. Matrix stiffening also extends the expression of the stemness marker Olfactomedin 4 (Olfm4) into villus-like regions, mediated by cytoplasmic YAP. We next used single-cell RNA sequencing to generate for the first time the stiffness-regulated transcriptional signatures of ISCs and their differentiated counterparts. These signatures confirm the impact of stiffening on ISC fate and additionally suggest a stiffening-induced switch in metabolic phenotype, from oxidative phosphorylation to glycolysis. Finally, we used colon samples from IBD patients as well as chronic colitis murine models to confirm the in vivo stiffening-induced epithelial deterioration similar to that observed in vitro. Together, these results demonstrate stiffness-dependent ISC reprograming wherein YAP nuclear translocation diminishes ISCs and Ki67+ progenitors and drives their differentiation towards goblet cells, suggesting stiffening as potential target to mitigate gut epithelial deterioration during IBD.

Published

2021

8. MON-726 Modifications of FOXO1 and GATA4-NKX2.5 Signaling Induce Human Enteroendocrine Differentiation

Author

David T. Breault, Eric Stas, Daniel Zeve, and Manasvi S. Shah

Subjects

GATA4, Genetics and Development and Non-Steroid Hormone Signaling II, Endocrinology, Diabetes and Metabolism, Enteroendocrine cell, FOXO1, Biology, AcademicSubjects/MED00250, Genetics and Development (including Gene Regulation), Cell biology

Abstract

Enteroendocrine (EE) cells are the most abundant hormone-producing cells in the human body and are vital for metabolism, as well as intestinal and pancreatic function. They have been implicated in the pathogenesis of multiple diseases including diabetes mellitus. Although recent studies have identified multiple signaling pathways (including Wnt, MAPK, BMP and Notch) that can induce low levels of EE cell differentiation, the production of functional human EE cells in vitro remains challenging, making their study and therapeutic utilization difficult. To improve this, we employed the human intestinal organoid culturing system, as it mimics intestinal epithelial homeostasis, allowing for differentiation of multiple epithelial cell types. Using a small scale, directed screen, we targeted multiple transcriptional regulators, using small molecules known to control pancreatic and intestinal development, and hormone production. We chose small molecules instead of gene editing tools to avoid the potential pitfall of off-target mutagenesis. We found that inhibition of FoxO1 in our organoid culture led to an increase in EE cell differentiation as assessed by EE-specific gene expression, with a 5-10 fold upregulation in expression of ChgA, NeuroD1, and Neurog3 compared to whole mucosal biopsies (P Taken together, our data have identified multiple factors, including inhibition of FoxO1 and activation of GATA4-Nkx2.5, that can drive ex vivo human EE cell differentiation, with unique hormone production profiles, when targeted via small molecules. This is a critical first step towards understanding the role of enteroendocrine cells in disease and the development of EE cell-based therapies.

Published

2020