Your search keyword '"Magness, Scott T."' showing total 6 results

1. A Monolayer of Primary Colonic Epithelium Generated on a Scaffold with a Gradient of Stiffness for Drug Transport Studies.

Author

Gunasekara DB, Speer J, Wang Y, Nguyen DL, Reed MI, Smiddy NM, Parker JS, Fallon JK, Smith PC, Sims CE, Magness ST, and Allbritton NL

Subjects

Animals, Atenolol metabolism, Caco-2 Cells, Chickens, Collagen chemistry, Humans, Mice, Propranolol metabolism, Rhodamine 123 metabolism, Riboflavin metabolism, Biological Transport physiology, Colon physiology, Epithelium physiology, Tissue Engineering methods

Abstract

Animal models are frequently used for in vitro physiologic and drug transport studies of the colon, but there exists significant pressure to improve assay throughput as well as to achieve tighter control of experimental variables than can be achieved with animals. Thus, development of a primary in vitro colonic epithelium cultured as high resistance with transport protein expression and functional behavior similar to that of a native colonic would be of enormous value for pharmaceutical research. A collagen scaffold, in which the degree of collagen cross-linking was present as a gradient, was developed to support the proliferation of primary colonic cells. The gradient of cross-linking created a gradient in stiffness across the scaffold, enabling the scaffold to resist deformation by cells. mRNA expression and quantitative proteomic mass spectrometry of cells growing on these surfaces as a monolayer suggested that the transporters present were similar to those in vivo. Confluent monolayers acted as a barrier to small molecules so that drug transport studies were readily performed. Transport function was evaluated using atenolol (a substrate for passive paracellular transport), propranolol (a substrate for passive transcellular transport), rhodamine 123 (Rh123, a substrate for P-glycoprotein), and riboflavin (a substrate for solute carrier transporters). Atenolol was poorly transported with an apparent permeability ( P app ) of <5 × 10 -7 cm s -1 , while propranolol demonstrated a P app of 9.69 × 10 -6 cm s -1 . Rh123 was transported in a luminal direction ( P app,efflux / P app,influx = 7) and was blocked by verapamil, a known inhibitor of P-glycoprotein. Riboflavin was transported in a basal direction, and saturation of the transporter was observed at high riboflavin concentrations as occurs in vivo. It is anticipated that this platform of primary colonic epithelium will find utility in drug development and physiological studies, since the tissue possesses high integrity and active transporters and metabolism similar to that in vivo.

Published

2018

2. IGF1 stimulates crypt expansion via differential activation of 2 intestinal stem cell populations.

Author

Van Landeghem, Laurianne, Santoro, M. Agostina, Mah, Amanda T., Krebs, Adrienne E., Dehmer, Jeffrey J., McNaughton, Kirk K., Helmrath, Michael A., Magness, Scott T., and Lund, P. Kay

Subjects

INTESTINAL injuries, GREEN fluorescent protein, SOMATOMEDIN C, STEM cells, EPITHELIUM, TISSUE physiology

Abstract

Insulin-like growth factor 1 (IGF1) has potent trophic effects on normal or injured intestinal epithelium, but specific effects on intestinal stem cells (ISCs) are undefined. We used Sox9-enhanced green fluorescent protein (EGFP) reporter mice that permit analyses of both actively cycling ISCs (Sox9-EGFPLow) and reserve/facultative ISCs (Sox9-EGFPHigh) to study IGF1 action on ISCs in normal intestine or during crypt regeneration after high-dose radiation-induced injury. We hypothesized that IGF1 differentially regulates proliferation and gene expression in actively cycling and reserve/facultative ISCs. IGF1 was delivered for 5 days using subcutaneously implanted mini-pumps in uninjured mice or after 14 Gy abdominal radiation. ISC numbers, proliferation, and transcriptome were assessed. IGF1 increased epithelial growth in nonirradiated mice and enhanced crypt regeneration after radiation. In uninjured and regenerating intestines, IGF1 increased total numbers of Sox9-EGFPLow ISCs and percentage of these cells in M-phase. IGF1 increased percentages of Sox9-EGFPHigh ISCs in S-phase but did not expand this population. Microarray revealed that IGF1 activated distinct gene expression signatures in the 2 Sox9-EGFP ISC populations. In vitro IGF1 enhanced enteroid formation by Sox9-EGFPHigh facultative ISCs but not Sox9-EGFPLow actively cycling ISCs. Our data provide new evidence that IGF1 activates 2 ISC populations via distinct regulatory pathways to promote growth of normal intestinal epithelium and crypt regeneration after irradiation. [ABSTRACT FROM AUTHOR]

Published

2015

3. In vitro generation of colonic epithelium from primary cells guided by microstructures.

Author

Wang, Yuli, Ahmad, Asad A., Sims, Christopher E., Magness, Scott T., and Allbritton, Nancy L.

Subjects

EPITHELIUM, MICROSTRUCTURE, POLYDIMETHYLSILOXANE, CELL proliferation, CENTRIFUGATION

Abstract

The proliferative compartment of the colonic epithelium in vivo is located in the basal crypt where colonic stem cells and transit-amplifying cells reside and fuel the rapid renewal of non-proliferative epithelial cells as they migrate toward the gut lumen. To mimic this tissue polarity, microstructures composed of polydimethylsiloxane (PDMS) microwells and Matrigel micropockets were used to guide a combined 2-dimensional (2D) and 3-dimensional (3D) hybrid culture of primary crypts isolated from the murine colon. The 2D and 3D culture of crypts on a planar PDMS surface was first investigated in terms of cell proliferation and stem cell activity. 3D culture of crypts with overlaid Matrigel generated enclosed, but highly proliferative spheroids (termed colonoids). 2D culture of crypts produced a spreading monolayer of cells, which were non-proliferative. A combined 2D/3D hybrid culture was generated in a PDMS microwell platform on which crypts were loaded by centrifugation into microwells (diameter = 150 μm, depth = 150 μm) followed by addition of Matrigel that formed micropockets locking the crypts within the microwells. Embedded crypts first underwent 3D expansion inside the wells. After the cells filled the microwells, they migrated onto the surrounding surface forming a 2D monolayer in the array regions without Matrigel. This unique 2D/3D hybrid culture generated a continuous, millimeter-scale colonic epithelial tissue in vitro, which resembled the polarized architecture (i.e. distinct proliferative and non-proliferative zones) and geometry of the colonic epithelium in vivo. This work initiates the construction of a “colon-on-a-chip” using primary cells/tissues with the ultimate goal of producing the physiologic structure and organ-level function of the colon. [ABSTRACT FROM AUTHOR]

Published

2014

4. Sox9 expression marks a subset of CD24-expressing small intestine epithelial stem cells that form organoids in vitro.

Author

Gracz, Adam D., Ramalingam, Sendhilnathan, and Magness, Scott T.

Subjects

EPITHELIAL cells, STEM cells, CELLULAR therapy, EPITHELIUM, CELL culture, ANIMAL models in research, LABORATORY mice

Abstract

The inability to identify, isolate, and culture intestinal epithelial stem cells (IESCs) has been prohibitive to the study and therapeutic utilization of these cells. Using a Sox9EGFP mouse model, we demonstrate that Sox9EGFP fluorescence signatures can be used to differentiate between and enrich for progenitors (Sox9EGFPsubLo) and multipotent IESCs (Sox9EGFPlo). Sox9EGFPlo cells generate "organoids" in a recently defined culture system that mimics the native IESC niche. These organoids possess all four differentiated cell types of the small intestine epithelium, demonstrating the multipotent capacity of Sox9EGFPlo cells. Our results are consistent with the previously reported observation that single IESCs generate cryptlike units without a detectable mesenchymal cell component. A prospective search revealed that CD24 is expressed in the Sox9EGFPlo population and marks IESCs that form organoids in culture. CD24 represents the first cell surface marker that facilitates fluorescence-activated cell sorting enrichment of IESCs with widely available antibodies without requiring a specialized fluorescent reporter gene mouse model. [ABSTRACT FROM AUTHOR]

Published

2010

5. Distinct SOX9 levels differentially mark stem/progenitor populations and enteroendocrine cells of the small intestine epithelium.

Author

Formeister, Eric J., Sionas, Ayn L., Lorance, David K., Barkley, Carey L., Lee, Ginny H., and Magness, Scott T.

Subjects

EPITHELIUM, SMALL intestine, CELLS, STEM cells, GREEN fluorescent protein

Abstract

SOX transcription factors have the capacity to modulate stem/progenitor cell proliferation and differentiation in a dose-dependent manner. SOX9 is expressed in the small intestine epithelial stem cell zone. Therefore, we hypothesized that differential levels of SOX9 may exist, influencing proliferation and/or differentiation of the small intestine epithelium. Sox9 expression levels in the small intestine investigated using a Sox9 enhanced green fluorescent protein (Sox9EGFP) transgenic mouse. Sox9EGFP levels correlate with endogenous SOX9 levels, which are expressed at two steady-state levels, termed Sox9EGFPLO and Sox9EGFPHI. Crypt-based columnar cells are Sox9EGFPLO and demonstrate enriched expression of the stem cell marker, Lgr5. Sox9EGFPHI cells express chromogranin A andi substance P but do not express Ki67 and neurogenin3, indicating that cells are postmitotic enteroendocrine cells. Overexpres- sion of SOX9 in a crypt cell line stopped proliferation and induced morphological changes. These data support a bimodal role for SOX9 in the intestinal epithelium, where low SOX9 expression supports proliferative capacity, and high SOX9 expression suppresses proliferation. [ABSTRACT FROM AUTHOR]

Published

2009

6. 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