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Start Over Author "Magness, Scott T." Publisher elsevier b.v.
12 results on '"Magness, Scott T."'

2. Dysplastic Stem Cell Plasticity Functions as a Driving Force for Neoplastic Transformation of Precancerous Gastric Mucosa.

Author

Min, Jimin, Zhang, Changqing, Bliton, R. Jarrett, Caldwell, Brianna, Caplan, Leah, Presentation, Kimberly S., Park, Do-Joong, Kong, Seong-Ho, Lee, Hye Seung, Washington, M. Kay, Kim, Woo-Ho, Lau, Ken S., Magness, Scott T., Lee, Hyuk-Joon, Yang, Han-Kwang, Goldenring, James R., and Choi, Eunyoung

Abstract

Dysplasia carries a high risk of cancer development; however, the cellular mechanisms for dysplasia evolution to cancer are obscure. We have previously identified 2 putative dysplastic stem cell (DSC) populations, CD44v6neg/CD133+/CD166+ (double positive [DP]) and CD44v6+/CD133+/CD166+ (triple positive [TP]), which may contribute to cellular heterogeneity of gastric dysplasia. Here, we investigated functional roles and cell plasticity of noncancerous Trop2+/CD133+/CD166+ DSCs initially developed in the transition from precancerous metaplasia to dysplasia in the stomach. Dysplastic organoids established from active Kras-induced mouse stomachs were used for transcriptome analysis, in vitro differentiation, and in vivo tumorigenicity assessments of DSCs. Cell heterogeneity and genetic alterations during clonal evolution of DSCs were examined by next-generation sequencing. Tissue microarrays were used to identify DSCs in human dysplasia. We additionally evaluated the effect of casein kinase 1 alpha (CK1α) regulation on the DSC activities using both mouse and human dysplastic organoids. We identified a high similarity of molecular profiles between DP- and TP-DSCs, but more dynamic activities of DP-DSCs in differentiation and survival for maintaining dysplastic cell lineages through Wnt ligand-independent CK1α/β-catenin signaling. Xenograft studies demonstrated that the DP-DSCs clonally evolve toward multiple types of gastric adenocarcinomas and promote cancer cell heterogeneity by acquiring additional genetic mutations and recruiting the tumor microenvironment. Last, growth and survival of both mouse and human dysplastic organoids were controlled by targeting CK1α. These findings indicate that the DSCs are de novo gastric cancer-initiating cells responsible for neoplastic transformation and a promising target for intervention in early induction of gastric cancer. [Display omitted] ysplastic stem cell activity regulated by CK1α/β-catenin signaling can drive dysplastic cell evolution to adenocarcinoma in gastric carcinogenesis by acquiring cellular and genetic heterogeneity and recruiting microenvironment. [ABSTRACT FROM AUTHOR]

Published
2022
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4. Reserve Stem Cells in Intestinal Homeostasis and Injury.

Author

Bankaitis, Eric D., Ha, Andrew, Kuo, Calvin J., and Magness, Scott T.

Abstract

Renewal of the intestinal epithelium occurs approximately every week and requires a careful balance between cell proliferation and differentiation to maintain proper lineage ratios and support absorptive, secretory, and barrier functions. We review models used to study the mechanisms by which intestinal stem cells (ISCs) fuel the rapid turnover of the epithelium during homeostasis and might support epithelial regeneration after injury. In anatomically defined zones of the crypt stem cell niche, phenotypically distinct active and reserve ISC populations are believed to support homeostatic epithelial renewal and injury-induced regeneration, respectively. However, other cell types previously thought to be committed to differentiated states might also have ISC activity and participate in regeneration. Efforts are underway to reconcile the proposed relatively strict hierarchical relationships between reserve and active ISC pools and their differentiated progeny; findings from models provide evidence for phenotypic plasticity that is common among many if not all crypt-resident intestinal epithelial cells. We discuss the challenges to consensus on ISC nomenclature, technical considerations, and limitations inherent to methodologies used to define reserve ISCs, and the need for standardized metrics to quantify and compare the relative contributions of different epithelial cell types to homeostatic turnover and post-injury regeneration. Increasing our understanding of the high-resolution genetic and epigenetic mechanisms that regulate reserve ISC function and cell plasticity will help refine these models and could affect approaches to promote tissue regeneration after intestinal injury. [ABSTRACT FROM AUTHOR]

Published
2018
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5. Sox4 Promotes Atoh1-Independent Intestinal Secretory Differentiation Toward Tuft and Enteroendocrine Fates.

Author

Gracz, Adam D., Samsa, Leigh Ann, Fordham, Matthew J., Trotier, Danny C., Zwarycz, Bailey, Lo, Yuan-Hung, Bao, Katherine, Starmer, Joshua, Raab, Jesse R., Shroyer, Noah F., Reinhardt, R. Lee, and Magness, Scott T.

Abstract

Background & Aims The intestinal epithelium is maintained by intestinal stem cells (ISCs), which produce postmitotic absorptive and secretory epithelial cells. Initial fate specification toward enteroendocrine, goblet, and Paneth cell lineages requires the transcription factor Atoh1 , which regulates differentiation of the secretory cell lineage. However, less is known about the origin of tuft cells, which participate in type II immune responses to parasite infections and appear to differentiate independently of Atoh1. We investigated the role of Sox4 in ISC differentiation. Methods We performed experiments in mice with intestinal epithelial-specific disruption of Sox4 (Sox4 fl/fl: vilCre ; SOX4 conditional knockout [cKO]) and mice without disruption of Sox4 (control mice). Crypt- and single-cell–derived organoids were used in assays to measure proliferation and ISC potency. Lineage allocation and gene expression changes were studied by immunofluorescence, real-time quantitative polymerase chain reaction, and RNA-seq analyses. Intestinal organoids were incubated with the type 2 cytokine interleukin 13 and gene expression was analyzed. Mice were infected with the helminth Nippostrongylus brasiliensis and intestinal tissues were collected 7 days later for analysis. Intestinal tissues collected from mice that express green fluorescent protein regulated by the Atoh1 promoter (Atoh1 GFP mice) and single-cell RNA-seq analysis were used to identify cells that coexpress Sox4 and Atoh1. We generated SOX4-inducible intestinal organoids derived from Atoh1 fl/fl: vilCre ER (ATOH1 inducible knockout) mice and assessed differentiation. Results Sox4cKO mice had impaired ISC function and secretory differentiation, resulting in decreased numbers of tuft and enteroendocrine cells. In control mice, numbers of SOX4+ cells increased significantly after helminth infection, coincident with tuft cell hyperplasia. Sox4 was activated by interleukin 13 in control organoids; SOX4cKO mice had impaired tuft cell hyperplasia and parasite clearance after infection with helminths. In single-cell RNA-seq analysis, Sox4 +/ Atoh1 cells were enriched for ISC, progenitor, and tuft cell genes; 12.5% of Sox4 -expressing cells coexpressed Atoh1 and were enriched for enteroendocrine genes. In organoids, overexpression of Sox4 was sufficient to induce differentiation of tuft and enteroendocrine cells—even in the absence of Atoh1. Conclusions We found Sox4 promoted tuft and enteroendocrine cell lineage allocation independently of Atoh1. These results challenge the longstanding model in which Atoh1 is the sole regulator of secretory differentiation in the intestine and are relevant for understanding epithelial responses to parasitic infection. Graphical abstract [ABSTRACT FROM AUTHOR]

Published
2018
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6. SOX9 Maintains Reserve Stem Cells and Preserves Radioresistance in Mouse Small Intestine.

Author

Roche, Kyle C., Gracz, Adam D., Liu, Xiao Fu, Newton, Victoria, Akiyama, Haruhiko, and Magness, Scott T.

Abstract

Background & Aims Reserve intestinal stem cells (rISCs) are quiescent/slowly cycling under homeostatic conditions, allowing for their identification with label-retention assays. rISCs mediate epithelial regeneration after tissue damage by converting to actively proliferating stem cells (aISCs) that self renew and demonstrate multipotency, which are defining properties of stem cells. Little is known about the genetic mechanisms that regulate the production and maintenance of rISCs. High expression levels of the transcription factor Sox9 (Sox9 high ) are associated with rISCs. This study investigates the role of SOX9 in regulating the rISC state. Methods We used fluorescence-activated cell sorting to isolate cells defined as aISCs ( Lgr5 high ) and rISCs ( Sox9 high ) from Lgr5 EGFP and Sox9 EGFP reporter mice. Expression of additional markers associated with active and reserve ISCs were assessed in Lgr5 high and Sox9 high populations by single-cell gene expression analyses. We used label-retention assays to identify whether Sox9 high cells were label-retatining cells (LRCs). Lineage-tracing experiments were performed in Sox9 -CreERT2 mice to measure the stem cell capacities and radioresistance of Sox9 -expressing cells. Conditional SOX9 knockout mice and inducible-conditional SOX9 knockout mice were used to determine whether SOX9 was required to maintain LRCs and rISC function. Results Lgr5 high and a subset of crypt-based Sox9 high cells co-express markers of aISC and rISC ( Lgr5 , Bmi1 , Lrig1 , and Hopx ). LRCs express high levels of Sox9 and are lost in SOX9-knockout mice. SOX9 is required for epithelial regeneration after high-dose irradiation. Crypts from SOX9-knockout mice have increased sensitivity to radiation, compared with control mice, which could not be attributed to impaired cell-cycle arrest or DNA repair. Conclusions SOX9 limits proliferation in LRCs and imparts radiation resistance to rISCs in mice. [ABSTRACT FROM AUTHOR]

Published
2015
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9. Isolation and Characterization of Intestinal Stem Cells Based on Surface Marker Combinations and Colony-Formation Assay.

Author

Wang, Fengchao, Scoville, David, He, Xi C., Mahe, Maxime M., Box, Andrew, Perry, John M., Smith, Nicholas R., Lei, Nan Ye, Davies, Paige S., Fuller, Megan K., Haug, Jeffrey S., McClain, Melainia, Gracz, Adam D., Ding, Sheng, Stelzner, Matthias, Dunn, James C.Y., Magness, Scott T., Wong, Melissa H., Martin, Martin G., and Helmrath, Michael

Abstract

Background & Aims: Identification of intestinal stem cells (ISCs) has relied heavily on the use of transgenic reporters in mice, but this approach is limited by mosaic expression patterns and difficult to directly apply to human tissues. We sought to identify reliable surface markers of ISCs and establish a robust functional assay to characterize ISCs from mouse and human tissues. Methods: We used immunohistochemistry, real-time reverse-transcription polymerase chain reaction, and fluorescence-activated cell sorting (FACS) to analyze intestinal epithelial cells isolated from mouse and human intestinal tissues. We compared different combinations of surface markers among ISCs isolated based on expression of Lgr5–green fluorescent protein. We developed a culture protocol to facilitate the identification of functional ISCs from mice and then tested the assay with human intestinal crypts and putative ISCs. Results: CD44+CD24loCD166+ cells, isolated by FACS from mouse small intestine and colon, expressed high levels of stem cell–associated genes. Transit-amplifying cells and progenitor cells were then excluded based on expression of GRP78 or c-Kit. CD44+CD24loCD166+ GRP78lo/– putative stem cells from mouse small intestine included Lgr5-GFPhi and Lgr5-GFPmed/lo cells. Incubation of these cells with the GSK inhibitor CHIR99021 and the E-cadherin stabilizer Thiazovivin resulted in colony formation by 25% to 30% of single-sorted ISCs. Conclusions: We developed a culture protocol to identify putative ISCs from mouse and human tissues based on cell surface markers. CD44+CD24loCD166+, GRP78lo/–, and c-Kit facilitated identification of putative stem cells from the mouse small intestine and colon, respectively. CD44+CD24−/loCD166+ also identified putative human ISCs. These findings will facilitate functional studies of mouse and human ISCs. [Copyright &y& Elsevier]

Published
2013
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12. A microengineered collagen scaffold for generating a polarized crypt-villus architecture of human small intestinal epithelium.

Author

Wang, Yuli, Gunasekara, Dulan B., Reed, Mark I., Sims, Christopher E., Allbritton, Nancy L., DiSalvo, Matthew, Magness, Scott T., and Bultman, Scott J.

Subjects
*SMALL intestine physiology, *COLLAGEN, *EPITHELIUM, *PROGENITOR cells, *IMMUNOFLUORESCENCE, *MICROFABRICATION
Abstract

The human small intestinal epithelium possesses a distinct crypt-villus architecture and tissue polarity in which proliferative cells reside inside crypts while differentiated cells are localized to the villi. Indirect evidence has shown that the processes of differentiation and migration are driven in part by biochemical gradients of factors that specify the polarity of these cellular compartments; however, direct evidence for gradient-driven patterning of this in vivo architecture has been hampered by limitations of the in vitro systems available. Enteroid cultures are a powerful in vitro system; nevertheless, these spheroidal structures fail to replicate the architecture and lineage compartmentalization found in vivo , and are not easily subjected to gradients of growth factors. In the current work, we report the development of a micropatterned collagen scaffold with suitable extracellular matrix and stiffness to generate an in vitro self-renewing human small intestinal epithelium that replicates key features of the in vivo small intestine: a crypt-villus architecture with appropriate cell-lineage compartmentalization and an open and accessible luminal surface. Chemical gradients applied to the crypt-villus axis promoted the creation of a stem/progenitor-cell zone and supported cell migration along the crypt-villus axis. This new approach combining microengineered scaffolds, biophysical cues and chemical gradients to control the intestinal epithelium ex vivo can serve as a physiologically relevant mimic of the human small intestinal epithelium, and is broadly applicable to model other tissues that rely on gradients for physiological function. [ABSTRACT FROM AUTHOR]

Published
2017
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