Reviews
Rev Diabet Stud,
2014,
11(1):6-18 |
DOI 10.1900/RDS.2014.11.6 |
Derivation of Insulin-Producing Beta-Cells from Human Pluripotent Stem Cells
Jacqueline V. Schiesser1, Suzanne J. Micallef1, Susan Hawes1, Andrew G. Elefanty1,2, Edouard G. Stanley1,2
1Monash Immunology and Stem Cell Laboratories (MISCL), Level 3, Building 75, STRIP1, West Ring Road, Monash University, Clayton, Victoria, 3800, Australia
2Murdoch Childrens Research Institute, The Royal Children’s Hospital, Flemington Road, Parkville, Victoria 3052, Australia
Address correspondence to: Edouard G. Stanley, e-mail: ed.stanley@mcri.edu.au
Abstract
Human embryonic stem cells have been advanced as a source of insulin-producing cells that could potentially replace cadaveric-derived islets in the treatment of type 1 diabetes. To this end, protocols have been developed that promote the formation of pancreatic progenitors and endocrine cells from human pluripotent stem cells, encompassing both embryonic stem cells and induced pluripotent stem cells. In this review, we examine these methods and place them in the context of the developmental and embryological studies upon which they are based. In particular, we outline the stepwise differentiation of cells towards definitive endoderm, pancreatic endoderm, endocrine lineages and the emergence of functional beta-cells. In doing so, we identify key factors common to many such protocols and discuss the proposed action of these factors in the context of cellular differentiation and ongoing development. We also compare strategies that entail transplantation of progenitor populations with those that seek to develop fully functional hormone expressing cells in vitro. Overall, our survey of the literature highlights the significant progress already made in the field and identifies remaining deficiencies in developing a pluripotent stem cell based treatment for type 1 diabetes.
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Rev Diabet Stud,
2014,
11(1):19-34 |
DOI 10.1900/RDS.2014.11.19 |
In Vitro Differentiation and Expansion of Human Pluripotent Stem Cell-Derived Pancreatic Progenitors
Jolanta Chmielowiec1,2,3,4, Malgorzata Borowiak1,2,3,4
1Stem Cells and Regenerative Medicine Center, Baylor College of Medicine, One Baylor Plaza, Houston, TX 77030, USA
2Center for Cell and Gene Therapy, Baylor College of Medicine, Texas
3Molecular and Cellular Biology Department, Baylor College of Medicine, Texas
4McNair Medical Institute, Baylor College of Medicine, Texas
Address correspondence to: Malgorzata Borowiak, e-mail: borowiak@bcm.edu
Abstract
Recent progress in understanding stem cell biology has been remarkable, especially in deciphering signals that support differentiation towards tissue-specific lineages. This achievement positions us firmly at the beginning of an era of patient-specific regenerative medicine and human disease modeling. It will be necessary to equip the progress in this era with a reliable source of self-renewing progenitor cells that differentiate into functional target cells. The generation of pancreatic progenitors that mature in vivo into functional beta-cells has raised the hope for new therapeutic options in diabetes, but key challenges still remain including the production of sufficient numbers of cells for research and transplantation. Recent approaches to this problem have shown that the presence of organ- and stage-specific mesenchyme improves the generation of progenitors, from endoderm to endocrine cells. Alternatively, utilization of three-dimensional culture may improve the efficiency and yield of directed differentiation. Here, we review the current knowledge of pancreatic directed differentiation and ex vivo expansion of pancreatic progenitors, including recent advances in differentiation strategies for the generation of pancreatic progenitors, and we discuss persistent challenges which will need to be overcome before personalized cell-based therapy becomes a practical strategy.
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Rev Diabet Stud,
2014,
11(1):35-50 |
DOI 10.1900/RDS.2014.11.35 |
Colony-Forming Progenitor Cells in the Postnatal Mouse Liver and Pancreas Give Rise to Morphologically Distinct Insulin-Expressing Colonies in 3D Cultures
Liang Jin1,2, Tao Feng1,2, Jing Chai1,2, Nadiah Ghazalli1,3, Dan Gao1, Ricardo Zerda4, Zhuo Li4, Jasper Hsu1, Alborz Mahdavi5, David A. Tirrell6, Arthur D. Riggs1, Hsun Teresa Ku1,3
1Department of Diabetes and Metabolic Diseases Research, Beckman Research Institute, City of Hope, Duarte, California 91010, USA
2These authors contributed equally to this work
3Irell and Manella Graduate School of Biological Sciences, Beckman Research Institute, City of Hope, Duarte, California 91010, USA
4Electron Microscopy Core, Beckman Research Institute, City of Hope, Duarte, California 91010, USA
5Department of Bioengineering, California Institute of Technology, Pasadena, California 91125, USA
6Division of Chemistry and Chemical Engineering, California Institute of Technology, Pasadena, California 91125, USA
Address correspondence to: Hsun Teresa Ku, e-mail: hku@coh.org
Abstract
In our previous studies, colony-forming progenitor cells isolated from murine embryonic stem cell-derived cultures were differentiated into morphologically distinct insulin-expressing colonies. These colonies were small and not light-reflective when observed by phase-contrast microscopy (therefore termed “Dark” colonies). A single progenitor cell capable of giving rise to a Dark colony was termed a Dark colony-forming unit (CFU-Dark). The goal of the current study was to test whether endogenous pancreas, and its developmentally related liver, harbored CFU-Dark. Here we show that dissociated single cells from liver and pancreas of one-week-old mice give rise to Dark colonies in methylcellulose-based semisolid culture media containing either Matrigel or laminin hydrogel (an artificial extracellular matrix protein). CFU-Dark comprise approximately 0.1% and 0.03% of the postnatal hepatic and pancreatic cells, respectively. Adult liver also contains CFU-Dark, but at a much lower frequency (~0.003%). Microfluidic qRT-PCR, immunostaining, and electron microscopy analyses of individually handpicked colonies reveal the expression of insulin in many, but not all, Dark colonies. Most pancreatic insulin-positive Dark colonies also express glucagon, whereas liver colonies do not. Liver CFU-Dark require Matrigel, but not laminin hydrogel, to become insulin-positive. In contrast, laminin hydrogel is sufficient to support the development of pancreatic Dark colonies that express insulin. Postnatal liver CFU-Dark display a cell surface marker CD133+CD49flowCD107blow phenotype, while pancreatic CFU-Dark are CD133-. Together, these results demonstrate that specific progenitor cells in the postnatal liver and pancreas are capable of developing into insulin-expressing colonies, but they differ in frequency, marker expression, and matrix protein requirements for growth.
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Rev Diabet Stud,
2014,
11(1):51-83 |
DOI 10.1900/RDS.2014.11.51 |
Sox9: A Master Regulator of the Pancreatic Program
Philip A. Seymour
The Danish Stem Cell Center (DanStem), University of Copenhagen, Panum Institute, Blegdamsvej 3B, DK-2200, Copenhagen N, Denmark
Abstract
Over the last decade, it has been discovered that the transcription factor Sox9 plays several critical roles in governing the development of the embryonic pancreas and the homeostasis of the mature organ. While analysis of pancreata from patients affected by the Sox9 haploinsufficiency syndrome campomelic dysplasia initially alluded to a functional role of Sox9 in pancreatic morphogenesis, transgenic mouse models have been instrumental in mechanistically dissecting such roles. Although initially defined as a marker and maintenance factor for pancreatic progenitors, Sox9 is now considered to fulfill additional indispensable functions during pancreogenesis and in the postnatal organ through its interactions with other transcription factors and signaling pathways such as Fgf and Notch. In addition to maintaining both multipotent and bipotent pancreatic progenitors, Sox9 is also required for initiating endocrine differentiation and maintaining pancreatic ductal identity, and it has recently been unveiled as a key player in the initiation of pancreatic cancer. These functions of Sox9 are discussed in this article, with special emphasis on the knowledge gained from various loss-of-function and lineage tracing mouse models. Also, current controversies regarding Sox9 function in healthy and injured adult pancreas and unanswered questions and avenues of future study are discussed.
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Rev Diabet Stud,
2014,
11(1):84-101 |
DOI 10.1900/RDS.2014.11.84 |
Islet and Stem Cell Encapsulation for Clinical Transplantation
Rahul Krishnan1, Michael Alexander1, Lourdes Robles1, Clarence E. Foster 3rd1,2, Jonathan R.T. Lakey1,3
1Department of Surgery, University of California Irvine, Orange, CA 92868, USA
2Department of Transplantation, University of California Irvine, Orange, CA 92868, USA
3Biomedical Engineering, University of California Irvine, Irvine, CA 92697, USA
Address correspondence to: Jonathan R.T. Lakey, Director of Research and Clinical Islet Program, University of California Irvine, 333 City Blvd. West, Suite 1600, Orange, CA 92868, USA, e-mail: jlakey@uci.edu
Abstract
Over the last decade, improvements in islet isolation techniques have made islet transplantation an option for a certain subset of patients with long-standing diabetes. Although islet transplants have shown improved graft function, adequate function beyond the second year has not yet been demonstrated, and patients still require immunosuppression to prevent rejection. Since allogeneic islet transplants have experienced some success, the next step is to improve graft function while eliminating the need for systemic immunosuppressive therapy. Biomaterial encapsulation offers a strategy to avoid the need for toxic immunosuppression while increasing the chances of graft function and survival. Encapsulation entails coating cells or tissue in a semipermeable biocompatible material that allows for the passage of nutrients, oxygen, and hormones while blocking immune cells and regulatory substances from recognizing and destroying the cell, thus avoiding the need for systemic immunosuppressive therapy. Despite advances in encapsulation technology, these developments have not yet been meaningfully translated into clinical islet transplantation, for which several factors are to blame, including graft hypoxia, host inflammatory response, fibrosis, improper choice of biomaterial type, lack of standard guidelines, and post-transplantation device failure. Several new approaches, such as the use of porcine islets, stem cells, development of prevascularized implants, islet nanocoating, and multilayer encapsulation, continue to generate intense scientific interest in this rapidly expanding field. This review provides a comprehensive update on islet and stem cell encapsulation as a treatment modality in type 1 diabetes, including a historical outlook as well as current and future research avenues.
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Rev Diabet Stud,
2014,
11(1):102-114 |
DOI 10.1900/RDS.2014.11.102 |
Profiling of Embryonic Stem Cell Differentiation
Nobuaki Shiraki, Soichiro Ogaki, Shoen Kume
Department of Stem Cell Biology, Institute of Molecular Embryology and Genetics, Kumamoto University, Honjo 2-2-1, Kumamoto 860-0811, Japan
Address correspondence to: Shoen Kume, e-mail: skume@kumamoto-u.ac.jp
Abstract
Embryonic stem (ES) cells have been shown to recapitulate normal developmental stages. They are therefore a highly useful tool in the study of developmental biology. Profiling of ES cell-derived cells has yielded important information about the characteristics of differentiated cells, and allowed the identification of novel marker genes and pathways of differentiation. In this review, we focus on recent results from profiling studies of mouse embryos, human islets, and human ES cell-derived differentiated cells from several research groups. Global gene expression data from mouse embryos have been used to identify novel genes or pathways involved in the developmental process, and to search for transcription factors that regulate direct reprogramming. We introduce gene expression databases of human pancreas cells (Beta Cell Gene Atlas, EuroDia database), and summarize profiling studies of islet- or human ES cell-derived pancreatic cells, with a focus on gene expression, microRNAs, epigenetics, and protein expression. Then, we describe our gene expression profile analyses and our search for novel endoderm, or pancreatic, progenitor marker genes. We differentiated mouse ES cells into mesendoderm, definitive endoderm (DE), mesoderm, ectoderm, and Pdx1-expressing pancreatic lineages, and performed DNA microarray analyses. Genes specifically expressed in DE, and/or in Pdx1-expressing cells, were extracted and their expression patterns in normal embryonic development were studied by in situ hybridization. Out of 54 genes examined, 27 were expressed in the DE of E8.5 mouse embryos, and 15 genes were expressed in distinct domains in the pancreatic buds of E14.5 mouse embryos. Akr1c19, Aebp2, Pbxip1, and Creb3l1 were all novel, and none has been described as being expressed, either in the DE, or in the pancreas. By introducing the profiling results of ES cell-derived cells, the benefits of using ES cells to study early embryonic development will be discussed.
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Rev Diabet Stud,
2014,
11(1):115-132 |
DOI 10.1900/RDS.2014.11.115 |
Maturation of Stem Cell-Derived Beta-cells Guided by the Expression of Urocortin 3
Talitha van der Meulen, Mark O. Huising
The Salk Institute for Biological Studies, Clayton Laboratories for Peptide Biology, 10010 N. Torrey Pines Road, La Jolla, CA 92037, USA
Address correspondence to: Mark O. Huising, e-mail: huising@salk.edu
Abstract
Type 1 diabetes (T1D) is a devastating disease precipitated by an autoimmune response directed at the insulin-producing beta-cells of the pancreas for which no cure exists. Stem cell-derived beta-cells show great promise for a cure as they have the potential to supply unlimited numbers of cells that could be derived from a patient's own cells, thus eliminating the need for immunosuppression. Current in vitro protocols for the differentiation of stem cell-derived beta-cells can successfully generate pancreatic endoderm cells. In diabetic rodents, such cells can differentiate further along the beta-cell lineage until they are eventually capable of restoring normoglycemia. While these observations demonstrate that stem cell-derived pancreatic endoderm has the potential to differentiate into mature, glucose-responsive beta-cells, the signals that direct differentiation and maturation from pancreatic endoderm onwards remain poorly understood. In this review, we analyze the sequence of events that culminates in the formation of beta-cells during embryonic development. and summarize how current protocols to generate beta-cells have sought to capitalize on this ontogenic template. We place particular emphasis on the current challenges and opportunities which occur in the later stages of beta-cell differentiation and maturation of transplantable stem cell-derived beta-cells. Another focus is on the question how the use of recently identified maturation markers such as urocortin 3 can be instrumental in guiding these efforts.
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