Publications
Browse peer-reviewed literature, posters, webinars, blog articles, and more showing how we and others are using RepliGut Systems to support discovery.
2024
Pike, Colleen M.; Zwarycz, Bailey; McQueen, Bryan E.; Castillo, Mariana; Barron, Catherine; Morowitz, Jeremy M.; Levi, James A.; Phadke, Dhiral; Balik-Meisner, Michele; Mav, Deepak; Shah, Ruchir; Glasspoole, Danielle L. Cunningham; Laetham, Ron; Thelin, William; Bunger, Maureen K.; Boazak, Elizabeth M.
Characterization and optimization of variability in a human colonic epithelium culture model Journal Article
In: ALTEX, vol. 41, no. 3, pp. 425–438, 2024, ISSN: 1868-8551, (Number: 3).
Abstract | Links | BibTeX | Tags: epithelial cell culture, in vitro models, intestinal barrier, microphysiological systems, permeability
@article{pike_characterization_2024,
title = {Characterization and optimization of variability in a human colonic epithelium culture model},
author = {Colleen M. Pike and Bailey Zwarycz and Bryan E. McQueen and Mariana Castillo and Catherine Barron and Jeremy M. Morowitz and James A. Levi and Dhiral Phadke and Michele Balik-Meisner and Deepak Mav and Ruchir Shah and Danielle L. Cunningham Glasspoole and Ron Laetham and William Thelin and Maureen K. Bunger and Elizabeth M. Boazak},
url = {https://www.altex.org/index.php/altex/article/view/2686},
doi = {10.14573/altex.2309221},
issn = {1868-8551},
year = {2024},
date = {2024-07-16},
urldate = {2024-07-16},
journal = {ALTEX},
volume = {41},
number = {3},
pages = {425–438},
abstract = {Animal models have historically been poor preclinical predictors of gastrointestinal (GI) directed therapeutic efficacy and drug-induced GI toxicity. Human stem and primary cell-derived culture systems are a major focus of efforts to create biologically relevant models that enhance preclinical predictive value of intestinal efficacy and toxicity. The inherent variability in stem cell-based cultures makes development of useful models a challenge; the stochastic nature of stem cell differentiation interferes with the ability to build and validate reproducible assays that query drug responses and pharmacokinetics. In this study, we aimed to characterize and reduce sources of variability in a complex stem cell-derived intestinal epithelium model, termed RepliGut® Planar, across cells from multiple human donors, cell lots, and passage numbers. Assessment criteria included barrier formation and integrity, gene expression, and cytokine responses. Gene expression and culture metric analyses revealed that controlling cell passage number reduces variability and maximizes physiological relevance of the model. In a case study where passage number was optimized, distinct cytokine responses were observed among four human donors, indicating that biological variability can be detected in cell cultures originating from diverse human sources. These findings highlight key considerations for designing assays that can be applied to additional primary cell-derived systems, as well as establish utility of the RepliGut® Planar platform for robust development of human-predictive drug-response assays.
Plain language summary Animal models are frequently used as tools for studying gastrointestinal (GI) disease, but they inadequately replicate the complexities of the human gut, making them poor predictors of how humans respond to new drugs. Models using human stem cells are closer to human GI physiology, but their responses are not uniform owing to variability in the stem cells. We looked for the sources of this variability in the primary stem-cell derived RepliGut® Planar model. We found that limiting how long the cells were kept in culture reduced their variability and improved the physiological relevance of the model. These findings highlight key assay design considerations that also can be applied to other primary cell-derived systems. Reliable and physiologically relevant cell-based models can reduce animal testing, improve research accuracy, and ensure new treatments are more relevant and effective for patients.},
note = {Number: 3},
keywords = {epithelial cell culture, in vitro models, intestinal barrier, microphysiological systems, permeability},
pubstate = {published},
tppubtype = {article}
}
Animal models have historically been poor preclinical predictors of gastrointestinal (GI) directed therapeutic efficacy and drug-induced GI toxicity. Human stem and primary cell-derived culture systems are a major focus of efforts to create biologically relevant models that enhance preclinical predictive value of intestinal efficacy and toxicity. The inherent variability in stem cell-based cultures makes development of useful models a challenge; the stochastic nature of stem cell differentiation interferes with the ability to build and validate reproducible assays that query drug responses and pharmacokinetics. In this study, we aimed to characterize and reduce sources of variability in a complex stem cell-derived intestinal epithelium model, termed RepliGut® Planar, across cells from multiple human donors, cell lots, and passage numbers. Assessment criteria included barrier formation and integrity, gene expression, and cytokine responses. Gene expression and culture metric analyses revealed that controlling cell passage number reduces variability and maximizes physiological relevance of the model. In a case study where passage number was optimized, distinct cytokine responses were observed among four human donors, indicating that biological variability can be detected in cell cultures originating from diverse human sources. These findings highlight key considerations for designing assays that can be applied to additional primary cell-derived systems, as well as establish utility of the RepliGut® Planar platform for robust development of human-predictive drug-response assays.
Plain language summary Animal models are frequently used as tools for studying gastrointestinal (GI) disease, but they inadequately replicate the complexities of the human gut, making them poor predictors of how humans respond to new drugs. Models using human stem cells are closer to human GI physiology, but their responses are not uniform owing to variability in the stem cells. We looked for the sources of this variability in the primary stem-cell derived RepliGut® Planar model. We found that limiting how long the cells were kept in culture reduced their variability and improved the physiological relevance of the model. These findings highlight key assay design considerations that also can be applied to other primary cell-derived systems. Reliable and physiologically relevant cell-based models can reduce animal testing, improve research accuracy, and ensure new treatments are more relevant and effective for patients.
Plain language summary Animal models are frequently used as tools for studying gastrointestinal (GI) disease, but they inadequately replicate the complexities of the human gut, making them poor predictors of how humans respond to new drugs. Models using human stem cells are closer to human GI physiology, but their responses are not uniform owing to variability in the stem cells. We looked for the sources of this variability in the primary stem-cell derived RepliGut® Planar model. We found that limiting how long the cells were kept in culture reduced their variability and improved the physiological relevance of the model. These findings highlight key assay design considerations that also can be applied to other primary cell-derived systems. Reliable and physiologically relevant cell-based models can reduce animal testing, improve research accuracy, and ensure new treatments are more relevant and effective for patients.
Sharma, Abhinav; Jin, Liang; Wang, Xue; Wang, Yue-Ting; Stresser, David M.
Developing an adult stem cell derived microphysiological intestinal system for predicting oral prodrug bioconversion and permeability in humans Journal Article
In: Lab Chip, vol. 24, no. 2, pp. 339–355, 2024, ISSN: 1473-0189, (Publisher: The Royal Society of Chemistry).
Abstract | Links | BibTeX | Tags: absorption, Bioavailability, Biological Transport, Caco-2 Cells, drug absorption, drug metabolising enzymes ({DME}), drug permeability, intestinal barrier, oral bioavailability, permeability
@article{sharma_developing_2024,
title = {Developing an adult stem cell derived microphysiological intestinal system for predicting oral prodrug bioconversion and permeability in humans},
author = {Abhinav Sharma and Liang Jin and Xue Wang and Yue-Ting Wang and David M. Stresser},
url = {https://pubs.rsc.org/en/content/articlelanding/2024/lc/d3lc00843f},
doi = {10.1039/D3LC00843F},
issn = {1473-0189},
year = {2024},
date = {2024-01-17},
urldate = {2024-01-17},
journal = {Lab Chip},
volume = {24},
number = {2},
pages = {339–355},
abstract = {Microphysiological systems (MPS) incorporating human intestinal organoids have shown the potential to faithfully model intestinal biology with the promise to accelerate development of oral prodrugs. We hypothesized that an MPS model incorporating flow, shear stress, and vasculature could provide more reliable measures of prodrug bioconversion and permeability. Following construction of jejunal and duodenal organoid MPS derived from 3 donors, we determined the area under the concentration–time (AUC) curve for the active drug in the vascular channel and characterized the enzymology of prodrug bioconversion. Fosamprenavir underwent phosphatase mediated hydrolysis to amprenavir while dabigatran etexilate (DABE) exhibited proper CES2- and, as anticipated, not CES1-mediated de-esterification, followed by permeation of amprenavir to the vascular channel. When experiments were conducted in the presence of bio-converting enzyme inhibitors (orthovanadate for alkaline phosphatase; bis(p-nitrophenyl)phosphate for carboxylesterase), the AUC of the active drug decreased accordingly in the vascular channel. In addition to functional analysis, the MPS was characterized through imaging and proteomic analysis. Imaging revealed proper expression and localization of epithelial, endothelial, tight junction and catalytic enzyme markers. Global proteomic analysis was used to analyze the MPS model and 3 comparator sources: an organoid-based transwell model (which was also evaluated for function), Matrigel embedded organoids and finally jejunal and duodenal cadaver tissues collected from 3 donors. Hierarchical clustering analysis (HCA) and principal component analysis (PCA) of global proteomic data demonstrated that all organoid-based models exhibited strong similarity and were distinct from tissues. Intestinal organoids in the MPS model exhibited strong similarity to human tissue for key epithelial markers via HCA. Quantitative proteomic analysis showed higher expression of key prodrug converting and drug metabolizing enzymes in MPS-derived organoids compared to tissues, organoids in Matrigel, and organoids on transwells. When comparing organoids from MPS and transwells, expression of intestinal alkaline phosphatase (ALPI), carboxylesterase (CES)2, cytochrome P450 3A4 (CYP3A4) and sucrase isomaltase (SI) was 2.97-, 1.2-, 11.3-, and 27.7-fold higher for duodenum and 7.7-, 4.6-, 18.1-, and 112.2-fold higher for jejunum organoids in MPS, respectively. The MPS approach can provide a more physiological system than enzymes, organoids, and organoids on transwells for pharmacokinetic analysis of prodrugs that account for 10% of all commercial medicines.},
note = {Publisher: The Royal Society of Chemistry},
keywords = {absorption, Bioavailability, Biological Transport, Caco-2 Cells, drug absorption, drug metabolising enzymes ({DME}), drug permeability, intestinal barrier, oral bioavailability, permeability},
pubstate = {published},
tppubtype = {article}
}
Microphysiological systems (MPS) incorporating human intestinal organoids have shown the potential to faithfully model intestinal biology with the promise to accelerate development of oral prodrugs. We hypothesized that an MPS model incorporating flow, shear stress, and vasculature could provide more reliable measures of prodrug bioconversion and permeability. Following construction of jejunal and duodenal organoid MPS derived from 3 donors, we determined the area under the concentration–time (AUC) curve for the active drug in the vascular channel and characterized the enzymology of prodrug bioconversion. Fosamprenavir underwent phosphatase mediated hydrolysis to amprenavir while dabigatran etexilate (DABE) exhibited proper CES2- and, as anticipated, not CES1-mediated de-esterification, followed by permeation of amprenavir to the vascular channel. When experiments were conducted in the presence of bio-converting enzyme inhibitors (orthovanadate for alkaline phosphatase; bis(p-nitrophenyl)phosphate for carboxylesterase), the AUC of the active drug decreased accordingly in the vascular channel. In addition to functional analysis, the MPS was characterized through imaging and proteomic analysis. Imaging revealed proper expression and localization of epithelial, endothelial, tight junction and catalytic enzyme markers. Global proteomic analysis was used to analyze the MPS model and 3 comparator sources: an organoid-based transwell model (which was also evaluated for function), Matrigel embedded organoids and finally jejunal and duodenal cadaver tissues collected from 3 donors. Hierarchical clustering analysis (HCA) and principal component analysis (PCA) of global proteomic data demonstrated that all organoid-based models exhibited strong similarity and were distinct from tissues. Intestinal organoids in the MPS model exhibited strong similarity to human tissue for key epithelial markers via HCA. Quantitative proteomic analysis showed higher expression of key prodrug converting and drug metabolizing enzymes in MPS-derived organoids compared to tissues, organoids in Matrigel, and organoids on transwells. When comparing organoids from MPS and transwells, expression of intestinal alkaline phosphatase (ALPI), carboxylesterase (CES)2, cytochrome P450 3A4 (CYP3A4) and sucrase isomaltase (SI) was 2.97-, 1.2-, 11.3-, and 27.7-fold higher for duodenum and 7.7-, 4.6-, 18.1-, and 112.2-fold higher for jejunum organoids in MPS, respectively. The MPS approach can provide a more physiological system than enzymes, organoids, and organoids on transwells for pharmacokinetic analysis of prodrugs that account for 10% of all commercial medicines.
2019
Speer, Jennifer E.; Wang, Yuli; Fallon, John K.; Smith, Philip C.; Allbritton, Nancy L.
Evaluation of human primary intestinal monolayers for drug metabolizing capabilities Journal Article
In: J. Biol. Eng, vol. 13, pp. 82, 2019, ISSN: 1754-1611.
Abstract | Links | BibTeX | Tags: Absorptive Enterocyte Monolayers, Bioavailability, drug metabolising enzymes ({DME}), epithelial barrier, Fg, Intestinal Epithelial Cells, permeability
@article{speer_evaluation_2019,
title = {Evaluation of human primary intestinal monolayers for drug metabolizing capabilities},
author = {Jennifer E. Speer and Yuli Wang and John K. Fallon and Philip C. Smith and Nancy L. Allbritton},
url = {https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6829970/},
doi = {10.1186/s13036-019-0212-1},
issn = {1754-1611},
year = {2019},
date = {2019-11-04},
urldate = {2019-11-04},
journal = {J. Biol. Eng},
volume = {13},
pages = {82},
abstract = {Background
The intestinal epithelium is a major site of drug metabolism in the human body, possessing enterocytes that house brush border enzymes and phase I and II drug metabolizing enzymes (DMEs). The enterocytes are supported by a porous extracellular matrix (ECM) that enables proper cell adhesion and function of brush border enzymes, such as alkaline phosphatase (ALP) and alanyl aminopeptidase (AAP), phase I DMEs that convert a parent drug to a more polar metabolite by introducing or unmasking a functional group, and phase II DMEs that form a covalent conjugate between a functional group on the parent compound or sequential metabolism of phase I metabolite. In our effort to develop an in vitro intestinal epithelium model, we investigate the impact of two previously described simple and customizable scaffolding systems, a gradient cross-linked scaffold and a conventional scaffold, on the ability of intestinal epithelial cells to produce drug metabolizing proteins as well as to metabolize exogenously added compounds. While the scaffolding systems possess a range of differences, they are most distinguished by their stiffness with the gradient cross-linked scaffold possessing a stiffness similar to that found in the in vivo intestine, while the conventional scaffold possesses a stiffness several orders of magnitude greater than that found in vivo.
Results
The monolayers on the gradient cross-linked scaffold expressed CYP3A4, UGTs 2B17, 1A1 and 1A10, and CES2 proteins at a level similar to that in fresh crypts/villi. The monolayers on the conventional scaffold expressed similar levels of CYP3A4 and UGTs 1A1 and 1A10 DMEs to that found in fresh crypts/villi but significantly decreased expression of UGT2B17 and CES2 proteins. The activity of CYP3A4 and UGTs 1A1 and 1A10 was inducible in cells on the gradient cross-linked scaffold when the cells were treated with known inducers, whereas the CYP3A4 and UGT activities were not inducible in cells grown on the conventional scaffold. Both monolayers demonstrate esterase activity but the activity measured in cells on the conventional scaffold could not be inhibited with a known CES2 inhibitor. Both monolayer culture systems displayed similar ALP and AAP brush border enzyme activity. When cells on the conventional scaffold were incubated with a yes-associated protein (YAP) inhibitor, CYP3A4 activity was greatly enhanced suggesting that mechano-transduction signaling can modulate drug metabolizing enzymes.
Conclusions
The use of a cross-linked hydrogel scaffold for expansion and differentiation of primary human intestinal stem cells dramatically impacts the induction of CYP3A4 and maintenance of UGT and CES drug metabolizing enzymes in vitro making this a superior substrate for enterocyte culture in DME studies. This work highlights the influence of mechanical properties of the culture substrate on protein expression and the activity of drug metabolizing enzymes as a critical factor in developing accurate assay protocols for pharmacokinetic studies using primary intestinal cells.
Graphical abstract},
keywords = {Absorptive Enterocyte Monolayers, Bioavailability, drug metabolising enzymes ({DME}), epithelial barrier, Fg, Intestinal Epithelial Cells, permeability},
pubstate = {published},
tppubtype = {article}
}
Background
The intestinal epithelium is a major site of drug metabolism in the human body, possessing enterocytes that house brush border enzymes and phase I and II drug metabolizing enzymes (DMEs). The enterocytes are supported by a porous extracellular matrix (ECM) that enables proper cell adhesion and function of brush border enzymes, such as alkaline phosphatase (ALP) and alanyl aminopeptidase (AAP), phase I DMEs that convert a parent drug to a more polar metabolite by introducing or unmasking a functional group, and phase II DMEs that form a covalent conjugate between a functional group on the parent compound or sequential metabolism of phase I metabolite. In our effort to develop an in vitro intestinal epithelium model, we investigate the impact of two previously described simple and customizable scaffolding systems, a gradient cross-linked scaffold and a conventional scaffold, on the ability of intestinal epithelial cells to produce drug metabolizing proteins as well as to metabolize exogenously added compounds. While the scaffolding systems possess a range of differences, they are most distinguished by their stiffness with the gradient cross-linked scaffold possessing a stiffness similar to that found in the in vivo intestine, while the conventional scaffold possesses a stiffness several orders of magnitude greater than that found in vivo.
Results
The monolayers on the gradient cross-linked scaffold expressed CYP3A4, UGTs 2B17, 1A1 and 1A10, and CES2 proteins at a level similar to that in fresh crypts/villi. The monolayers on the conventional scaffold expressed similar levels of CYP3A4 and UGTs 1A1 and 1A10 DMEs to that found in fresh crypts/villi but significantly decreased expression of UGT2B17 and CES2 proteins. The activity of CYP3A4 and UGTs 1A1 and 1A10 was inducible in cells on the gradient cross-linked scaffold when the cells were treated with known inducers, whereas the CYP3A4 and UGT activities were not inducible in cells grown on the conventional scaffold. Both monolayers demonstrate esterase activity but the activity measured in cells on the conventional scaffold could not be inhibited with a known CES2 inhibitor. Both monolayer culture systems displayed similar ALP and AAP brush border enzyme activity. When cells on the conventional scaffold were incubated with a yes-associated protein (YAP) inhibitor, CYP3A4 activity was greatly enhanced suggesting that mechano-transduction signaling can modulate drug metabolizing enzymes.
Conclusions
The use of a cross-linked hydrogel scaffold for expansion and differentiation of primary human intestinal stem cells dramatically impacts the induction of CYP3A4 and maintenance of UGT and CES drug metabolizing enzymes in vitro making this a superior substrate for enterocyte culture in DME studies. This work highlights the influence of mechanical properties of the culture substrate on protein expression and the activity of drug metabolizing enzymes as a critical factor in developing accurate assay protocols for pharmacokinetic studies using primary intestinal cells.
Graphical abstract
The intestinal epithelium is a major site of drug metabolism in the human body, possessing enterocytes that house brush border enzymes and phase I and II drug metabolizing enzymes (DMEs). The enterocytes are supported by a porous extracellular matrix (ECM) that enables proper cell adhesion and function of brush border enzymes, such as alkaline phosphatase (ALP) and alanyl aminopeptidase (AAP), phase I DMEs that convert a parent drug to a more polar metabolite by introducing or unmasking a functional group, and phase II DMEs that form a covalent conjugate between a functional group on the parent compound or sequential metabolism of phase I metabolite. In our effort to develop an in vitro intestinal epithelium model, we investigate the impact of two previously described simple and customizable scaffolding systems, a gradient cross-linked scaffold and a conventional scaffold, on the ability of intestinal epithelial cells to produce drug metabolizing proteins as well as to metabolize exogenously added compounds. While the scaffolding systems possess a range of differences, they are most distinguished by their stiffness with the gradient cross-linked scaffold possessing a stiffness similar to that found in the in vivo intestine, while the conventional scaffold possesses a stiffness several orders of magnitude greater than that found in vivo.
Results
The monolayers on the gradient cross-linked scaffold expressed CYP3A4, UGTs 2B17, 1A1 and 1A10, and CES2 proteins at a level similar to that in fresh crypts/villi. The monolayers on the conventional scaffold expressed similar levels of CYP3A4 and UGTs 1A1 and 1A10 DMEs to that found in fresh crypts/villi but significantly decreased expression of UGT2B17 and CES2 proteins. The activity of CYP3A4 and UGTs 1A1 and 1A10 was inducible in cells on the gradient cross-linked scaffold when the cells were treated with known inducers, whereas the CYP3A4 and UGT activities were not inducible in cells grown on the conventional scaffold. Both monolayers demonstrate esterase activity but the activity measured in cells on the conventional scaffold could not be inhibited with a known CES2 inhibitor. Both monolayer culture systems displayed similar ALP and AAP brush border enzyme activity. When cells on the conventional scaffold were incubated with a yes-associated protein (YAP) inhibitor, CYP3A4 activity was greatly enhanced suggesting that mechano-transduction signaling can modulate drug metabolizing enzymes.
Conclusions
The use of a cross-linked hydrogel scaffold for expansion and differentiation of primary human intestinal stem cells dramatically impacts the induction of CYP3A4 and maintenance of UGT and CES drug metabolizing enzymes in vitro making this a superior substrate for enterocyte culture in DME studies. This work highlights the influence of mechanical properties of the culture substrate on protein expression and the activity of drug metabolizing enzymes as a critical factor in developing accurate assay protocols for pharmacokinetic studies using primary intestinal cells.
Graphical abstract