Generation of islet-like cells from mouse gall bladder by direct ex vivo reprogramming

Raymond D. Hickey; Feorillo Galivo; Jonathan Schug; Michael A. Brehm; Annelise Haft; Yuhan Wang; Eric Benedetti; Guoqiang Gu; Mark A. Magnuson; Leonard D. Shultz; Eric Lagasse; Dale L. Greiner; Klaus H. Kaestner; Markus Grompe

doi:10.1016/j.scr.2013.02.005

Generation of islet-like cells from mouse gall bladder by direct ex vivo reprogramming

Raymond D. Hickey, Feorillo Galivo, Jonathan Schug, Michael A. Brehm, Annelise Haft, Yuhan Wang, Eric Benedetti, Guoqiang Gu, Mark A. Magnuson, Leonard D. Shultz, Eric Lagasse, Dale L. Greiner, Klaus H. Kaestner, Markus Grompe

Surgery

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30 Scopus citations

Abstract

Cell replacement is an emerging therapy for type 1 diabetes. Pluripotent stem cells have received a lot of attention as a potential source of transplantable β-cells, but their ability to form teratomas poses significant risks. Here, we evaluated the potential of primary mouse gall bladder epithelial cells (GBCs) as targets for ex vivo genetic reprogramming to the β-cell fate. Conditions for robust expansion and genetic transduction of primary GBCs by adenoviral vectors were developed. Using a GFP reporter for insulin, conditions for reprogramming were then optimized. Global expression analysis by RNA-sequencing was used to quantitatively compare reprogrammed GBCs (rGBCs) to true β-cells, revealing both similarities and differences. Adenoviral-mediated expression of NEUROG3, Pdx1, and MafA in GBCs resulted in robust induction of pancreatic endocrine genes, including Ins1, Ins2, Neurod1, Nkx2-2 and Isl1. Furthermore, expression of GBC-specific genes was repressed, including Sox17 and Hes1. Reprogramming was also enhanced by addition of retinoic acid and inhibition of Notch signaling. Importantly, rGBCs were able to engraft long term in vivo and remained insulin-positive for 15. weeks. We conclude that GBCs are a viable source for autologous cell replacement in diabetes, but that complete reprogramming will require further manipulations.

Original language	English (US)
Pages (from-to)	503-515
Number of pages	13
Journal	Stem Cell Research
Volume	11
Issue number	1
DOIs	https://doi.org/10.1016/j.scr.2013.02.005
State	Published - Jul 2013

ASJC Scopus subject areas

Developmental Biology
Cell Biology

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@article{499636ae5c3b4afaa6bfd2f06e5992fb,

title = "Generation of islet-like cells from mouse gall bladder by direct ex vivo reprogramming",

abstract = "Cell replacement is an emerging therapy for type 1 diabetes. Pluripotent stem cells have received a lot of attention as a potential source of transplantable β-cells, but their ability to form teratomas poses significant risks. Here, we evaluated the potential of primary mouse gall bladder epithelial cells (GBCs) as targets for ex vivo genetic reprogramming to the β-cell fate. Conditions for robust expansion and genetic transduction of primary GBCs by adenoviral vectors were developed. Using a GFP reporter for insulin, conditions for reprogramming were then optimized. Global expression analysis by RNA-sequencing was used to quantitatively compare reprogrammed GBCs (rGBCs) to true β-cells, revealing both similarities and differences. Adenoviral-mediated expression of NEUROG3, Pdx1, and MafA in GBCs resulted in robust induction of pancreatic endocrine genes, including Ins1, Ins2, Neurod1, Nkx2-2 and Isl1. Furthermore, expression of GBC-specific genes was repressed, including Sox17 and Hes1. Reprogramming was also enhanced by addition of retinoic acid and inhibition of Notch signaling. Importantly, rGBCs were able to engraft long term in vivo and remained insulin-positive for 15. weeks. We conclude that GBCs are a viable source for autologous cell replacement in diabetes, but that complete reprogramming will require further manipulations.",

author = "Hickey, {Raymond D.} and Feorillo Galivo and Jonathan Schug and Brehm, {Michael A.} and Annelise Haft and Yuhan Wang and Eric Benedetti and Guoqiang Gu and Magnuson, {Mark A.} and Shultz, {Leonard D.} and Eric Lagasse and Greiner, {Dale L.} and Kaestner, {Klaus H.} and Markus Grompe",

note = "Funding Information: We thank Pamela Canaday (Flow Cytometry Resource at OHSU) for cell sorting. We thank Jessie Coleman for technical support with the mouse colony. We also thank Milton Finegold and Angela Major (NIDDK-sponsored Digestive Disease Core Laboratory of the Texas Medical Center (DK56338)) for histology support and to Elisabetta Manduchi (UPenn) for helping to transfer data. We are grateful to Craig Dorrell (OHSU) for thoughtful discussions. This work was supported by grants from NIH/NIDDK grants U01 DK072477 (MG), NIH grants AI46629 (DLG, LDS) and DK89572 (DLG, LDS), an institutional Diabetes Endocrinology Research Center (DERC) grant DK32520 (DLG, MAB, LDS), grants from the Helmsley Foundation (MG, DLG, LDS) and the Juvenile Diabetes Research Fund (MG).",

year = "2013",

month = jul,

doi = "10.1016/j.scr.2013.02.005",

language = "English (US)",

volume = "11",

pages = "503--515",

journal = "Stem Cell Research",

issn = "1873-5061",

publisher = "Elsevier",

number = "1",

}

TY - JOUR

T1 - Generation of islet-like cells from mouse gall bladder by direct ex vivo reprogramming

AU - Hickey, Raymond D.

AU - Galivo, Feorillo

AU - Schug, Jonathan

AU - Brehm, Michael A.

AU - Haft, Annelise

AU - Wang, Yuhan

AU - Benedetti, Eric

AU - Gu, Guoqiang

AU - Magnuson, Mark A.

AU - Shultz, Leonard D.

AU - Lagasse, Eric

AU - Greiner, Dale L.

AU - Kaestner, Klaus H.

AU - Grompe, Markus

N1 - Funding Information: We thank Pamela Canaday (Flow Cytometry Resource at OHSU) for cell sorting. We thank Jessie Coleman for technical support with the mouse colony. We also thank Milton Finegold and Angela Major (NIDDK-sponsored Digestive Disease Core Laboratory of the Texas Medical Center (DK56338)) for histology support and to Elisabetta Manduchi (UPenn) for helping to transfer data. We are grateful to Craig Dorrell (OHSU) for thoughtful discussions. This work was supported by grants from NIH/NIDDK grants U01 DK072477 (MG), NIH grants AI46629 (DLG, LDS) and DK89572 (DLG, LDS), an institutional Diabetes Endocrinology Research Center (DERC) grant DK32520 (DLG, MAB, LDS), grants from the Helmsley Foundation (MG, DLG, LDS) and the Juvenile Diabetes Research Fund (MG).

PY - 2013/7

Y1 - 2013/7

N2 - Cell replacement is an emerging therapy for type 1 diabetes. Pluripotent stem cells have received a lot of attention as a potential source of transplantable β-cells, but their ability to form teratomas poses significant risks. Here, we evaluated the potential of primary mouse gall bladder epithelial cells (GBCs) as targets for ex vivo genetic reprogramming to the β-cell fate. Conditions for robust expansion and genetic transduction of primary GBCs by adenoviral vectors were developed. Using a GFP reporter for insulin, conditions for reprogramming were then optimized. Global expression analysis by RNA-sequencing was used to quantitatively compare reprogrammed GBCs (rGBCs) to true β-cells, revealing both similarities and differences. Adenoviral-mediated expression of NEUROG3, Pdx1, and MafA in GBCs resulted in robust induction of pancreatic endocrine genes, including Ins1, Ins2, Neurod1, Nkx2-2 and Isl1. Furthermore, expression of GBC-specific genes was repressed, including Sox17 and Hes1. Reprogramming was also enhanced by addition of retinoic acid and inhibition of Notch signaling. Importantly, rGBCs were able to engraft long term in vivo and remained insulin-positive for 15. weeks. We conclude that GBCs are a viable source for autologous cell replacement in diabetes, but that complete reprogramming will require further manipulations.

AB - Cell replacement is an emerging therapy for type 1 diabetes. Pluripotent stem cells have received a lot of attention as a potential source of transplantable β-cells, but their ability to form teratomas poses significant risks. Here, we evaluated the potential of primary mouse gall bladder epithelial cells (GBCs) as targets for ex vivo genetic reprogramming to the β-cell fate. Conditions for robust expansion and genetic transduction of primary GBCs by adenoviral vectors were developed. Using a GFP reporter for insulin, conditions for reprogramming were then optimized. Global expression analysis by RNA-sequencing was used to quantitatively compare reprogrammed GBCs (rGBCs) to true β-cells, revealing both similarities and differences. Adenoviral-mediated expression of NEUROG3, Pdx1, and MafA in GBCs resulted in robust induction of pancreatic endocrine genes, including Ins1, Ins2, Neurod1, Nkx2-2 and Isl1. Furthermore, expression of GBC-specific genes was repressed, including Sox17 and Hes1. Reprogramming was also enhanced by addition of retinoic acid and inhibition of Notch signaling. Importantly, rGBCs were able to engraft long term in vivo and remained insulin-positive for 15. weeks. We conclude that GBCs are a viable source for autologous cell replacement in diabetes, but that complete reprogramming will require further manipulations.

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Generation of islet-like cells from mouse gall bladder by direct ex vivo reprogramming

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