Generation of insulin-producing cells from PDX-1 gene-modified human mesenchymal stem cells

Islet cell replacement is considered as the optimal treatment for type I diabetes. However, the availability of human pancreatic islets for transplantation is limited. Here, we show that human bone marrow-derived mesenchymal stem cells (hMSCs) could be induced to differentiate into functional insulin-producing cells by introduction of the pancreatic duodenal homeobox-1 (PDX-1). Recombinant adenoviral vector was used to deliver PDX-1 gene into hMSCs. After being infected with Ad-PDX-1, hMSCs were successfully induced to differentiate into insulin-secreting cells. The differentiated PDX-1+ hMSCs expressed multiple islet-cell genes including neurogenin3 (Ngn3), insulin, GK, Glut2, and glucagon, produced and released insulin/C-peptide in a weak glucose-regulated manner. After the differentiated PDX-1+ hMSCs were transplanted into STZ-induced diabetic mice, euglycemia can be obtained within 2 weeks and maintained for at least 42 days. These findings validate the hMSCs model system as a potential basis for enrichment of human beta cells or their precursors, and a possible source for cell replacement therapy in diabetes.     

Differentiation of insulin-producing cells from human neural progenitor cells

BackgroundSuccess in islet-transplantation-based therapies for type 1 diabetes, coupled with a worldwide shortage of transplant-ready islets, has motivated efforts to develop renewable sources of islet-replacement tissue. Islets and neurons share features, including common developmental programs, and in some species brain neurons are the principal source of systemic insulin.Methods and FindingsHere we show that brain-derived human neural progenitor cells, exposed to a series of signals that regulate in vivo pancreatic islet development, form clusters of glucose-responsive insulin-producing cells (IPCs). During in vitro differentiation of neural progenitor cells with this novel method, genes encoding essential known in vivo regulators of pancreatic islet development were expressed. Following transplantation into immunocompromised mice, IPCs released insulin C-peptide upon glucose challenge, remained differentiated, and did not form detectable tumors.ConclusionProduction of IPCs solely through extracellular factor modulation in the absence of genetic manipulations may promote strategies to derive transplantable islet-replacement tissues from human neural progenitor cells and other types of multipotent human stem cells.     

Induction of differentiation of undifferentiated cells into pancreatic beta cells in vertebrates

The beta cells of the pancreatic islets, which maintain glucose homeostasis by secreting insulin, are important cells for sustaining life. In recent years, islet transplantation has been performed as a treatment for type I diabetes. Since there are not enough donors for patients awaiting transplantation, beta cells grown in vitro are expected to be utilized as a substitute for islets. To obtain the cells with properties of human beta cells, it is necessary to understand the process by which human pancreatic islets are formed, as well as their structural characteristics. By using undifferentiated cells, such as Xenopus laevis animal caps and mouse ES cells, pancreatic tissue has shown to be able to be induced in vitro. Various attempts have been made to obtain human beta cells from human ES/iPS cells. Versatile methods have been developed and improved efficiency has been achieved by the use of low molecular weight compounds, but the challenge remains to prevent tumor formation and achieve functional maturation. Inducing the differentiation of somatic stem cells into insulin-producing cells has also brought us closer to clinical application. There are still many challenges related to the practical use of beta cells derived from undifferentiated cells, such as the development of methods to substitute these cells for host beta cells, standardization of the treatment protocol, quality control, and confirmation of safety. Research on the methods of inducing undifferentiated cells to differentiate into beta cells has shown definite progress, suggesting that cell therapy for diabetes may become a preferred therapeutic option over islet transplantation.     

Isolation and in vitro characterization of pancreatic progenitor cells from the islets of diabetic monkey models

Recent studies on the identification of stem/progenitor cells within adult mouse and human pancreatic islets have raised the possibility that autologous transplantation might be used in treating type 1 diabetes. However, it is not yet known whether such stem/progenitor cells are impaired in type 1 diabetic patients or diabetic animal models. The latter would also allow us to test the efficacy of autologous transplantation in large animal models prior to clinical applications. The present study aims to determine the existence of stem/progenitor cells in the islets of diabetic monkey models and to assess the proliferation and differentiation potential of such cells in vitro. Our results indicate that there are pancreatic progenitor cells in the adult pancreatic islets in both normal and type 1 diabetic monkeys. The isolated pancreatic progenitor cells can be greatly expanded in culture. Upon the removal of growth medium, these cells spontaneously form islet-like cell clusters, which could be further induced to secrete insulin by inductive factors. Furthermore, the secretion of insulin and C-peptide from the islet-like cell clusters responds to glucose and other stimuli, indicating that the differentiated cells not only resemble beta-cells but also possess the unique biological function of beta-cells. This study provides a foundation for further characterization of adult pancreatic progenitor cells and autologous transplantation using pancreatic progenitor cells in treating diabetic monkeys.     

Generation of beta cells from human pluripotent stem cells: Potential for regenerative medicine

The loss of beta cells in Type I diabetes ultimately leads to insulin dependence and major complications that are difficult to manage by insulin injections. Given the complications associated with long-term administration of insulin, cell-replacement therapy is now under consideration as an alternative treatment that may someday provide a cure for this disease. Over the past 10 years, islet transplantation trials have demonstrated that it is possible to replenish beta cell function in Type I diabetes patients and, at least temporarily, eliminate their dependency on insulin. While not yet optimal, the success of these trials has provided proof-of-principle that cell replacement therapy is a viable option for treating diabetes. Limited access to donor islets has launched a search for alternative source of beta cells for cell therapy purposes and focused the efforts of many investigators on the challenge of deriving such cells from human embryonic (hESCs) and induced pluripotent stem cells (hiPSCs). Over the past five years, significant advances have been made in understanding the signaling pathways that control lineage development from human pluripotent stem cells (hPSCs) and as a consequence, it is now possible to routinely generate insulin producing cells from both hESCs and hiPSCs. While these achievements are impressive, significant challenges do still exist, as the majority of insulin producing cells generated under these conditions are polyhormonal and non functional, likely reflecting the emergence of the polyhormonal population that is known to arise in the early embryo during the phase of pancreatic development known as the 'first transition'. Functional beta cells, which arise during the second phase or transition of pancreatic development have been generated from hESCs, however they are detected only following transplantation of progenitor stage cells into immunocompromised mice. With this success, our challenge now is to define the pathways that control the development and maturation of this second transition population from hPSCs, and establish conditions for the generation of functional beta cells in vitro.     

Effects of sodium butyrate on the differentiation of pancreatic and hepatic progenitor cells from mouse embryonic stem cells

Recently significant progress has been made in differentiating embryonic stem (ES) cells toward pancreatic cells. However, little is known about the generation and identification of pancreatic progenitor cells from ES cells. Here we explored the influence of sodium butyrate on pancreatic progenitor differentiation, and investigated the different effects of sodium butyrate on pancreatic and hepatic progenitor formation. Our results indicated that different concentration and exposure time of sodium butyrate led to different differentiating trends of ES cells. A relatively lower concentration of sodium butyrate with shorter exposure time induced more pancreatic progenitor cell formation. When stimulated by a higher concentration and longer exposure time of sodium butyrate, ES cells differentiated toward hepatic progenitor cells rather than pancreatic progenitor cells. These progenitor cells could further mature into pancreatic and hepatic cells with the supplement of exogenous inducing factors. The resulting pancreatic cells expressed specific markers such as insulin and C‐peptide, and were capable of insulin secretion in response to glucose stimulation. The differentiated hepatocytes were characterized by the expression of a number of liver‐associated genes and proteins, and had the capability of glycogen storage. Thus, the current study demonstrated that sodium butyrate played different roles in inducing ES cells toward pancreatic or hepatic progenitor cells. These progenitor cells could be further induced into mature pancreatic cells and hepatocytes. This finding may facilitate the understanding of pancreatic and hepatic cell differentiation from ES cells, and provide a potential source of transplantable cells for cell‐replacement therapies. J. Cell. Biochem. 109: 236–244, 2010. © 2009 Wiley‐Liss, Inc.     

Stem/progenitor cells derived from adult tissues: potential for the treatment of diabetes mellitus

In view of the recent success in pancreatic islet transplantation, interest in treating diabetes by the delivery of insulin-producing beta-cells has been renewed. Because differentiated pancreatic beta-cells cannot be expanded significantly in vitro, beta-cell stem or progenitor cells are seen as a potential source for the preparation of transplantable insulin-producing tissue. In addition to embryonic stem (ES) cells, several potential adult islet/beta-cell progenitors, derived from pancreas, liver, and bone marrow, are being studied. To date, none of the candidate cells has been fully characterized or is clinically applicable, but pancreatic physiology makes the existence of one or more types of adult islet stem cells very likely. It also seems possible that pluripotential stem cells, derived from the bone marrow, contribute to adult islet neogenesis. In future studies, more stringent criteria should be met to clonally define adult islet/beta-cell progenitor cells. If this can be achieved, the utilization of these cells for the generation of insulin-producing beta-cells in vitro seems to be feasible in the near future.     

Nicotinamide induces differentiation of embryonic stem cells into insulin-secreting cells

The poly(ADP-ribose) polymerase (PARP) inhibitor, nicotinamide, induces differentiation and maturation of fetal pancreatic cells. In addition, we have previously reported evidence that nicotinamide increases the insulin content of cells differentiated from embryonic stem (ES) cells, but the possibility of nicotinamide acting as a differentiating agent on its own has never been completely explored. Islet cell differentiation was studied by: (i) X-gal staining after neomycin selection; (ii) BrdU studies; (iii) single and double immunohistochemistry for insulin, C-peptide and Glut-2; (iv) insulin and C-peptide content and secretion assays; and (v) transplantation of differentiated cells, under the kidney capsule, into streptozotocin (STZ)-diabetic mice. Here we show that undifferentiated mouse ES cells treated with nicotinamide: (i) showed an 80% decrease in cell proliferation; (ii) co-expressed insulin, C-peptide and Glut-2; (iii) had values of insulin and C-peptide corresponding to 10% of normal mouse islets; (iv) released insulin and C-peptide in response to stimulatory glucose concentrations; and (v) after transplantation into diabetic mice, normalized blood glucose levels over 7 weeks. Our data indicate that nicotinamide decreases ES cell proliferation and induces differentiation into insulin-secreting cells. Both aspects are very important when thinking about cell therapy for the treatment of diabetes based on ES cells.     

A stable analogue of glucose-dependent insulinotropic polypeptide, GIP(LysPAL16), enhances functional differentiation of mouse embryonic stem cells into cells expressing islet-specific genes and hormones

Embryonic stem (ES) cells can be differentiated into insulin-producing cells by conditioning the culture media. However, the number of insulin-expressing cells and amount of insulin released is very low. Glucose-dependent insulinotropic polypeptide (GIP) enhances the growth and differentiation of pancreatic beta-cells. This study examined the potential of the stable analogue GIP(LysPAL16) to enhance the differentiation of mouse ES cells into insulin-producing cells using a five-stage culturing strategy. Semi-quantitative PCR indicated mRNA expression of islet development markers (nestin, Pdx1, Nkx6.1, Oct4), mature pancreatic beta-cell markers (insulin, glucagon, Glut2, Sur1, Kir6.1) and the GIP receptor gene GIP-R in undifferentiated (stage 1) cells, with increasing levels in differentiated stages 4 and 5. IAPP and somatostatin genes were only expressed in differentiated stages. Immunohistochemical studies confirmed the presence of insulin, glucagon, somatostatin and IAPP in differentiated ES cells. After supplementation with GIP(LysPAL16), ES cells at stage 4 released insulin in response to secretagogues and glucose in a concentration-dependent manner, with 35-100% increases in insulin release. Cellular C-peptide content also increased by 45% at stages 4 and 5. We conclude that the stable GIP analogue enhanced differentiation of mouse ES cells towards a phenotype expressing specific beta-cell genes and releasing insulin.     

Identification of microRNAs expressed highly in pancreatic islet‐like cell clusters differentiated from human embryonic stem cells

Type 1 diabetes is an autoimmune destruction of pancreatic islet beta cell disease, making it important to find a new alternative source of the islet beta cells to replace the damaged cells. hES (human embryonic stem) cells possess unlimited self‐renewal and pluripotency and thus have the potential to provide an unlimited supply of different cell types for tissue replacement. The hES‐T3 cells with normal female karyotype were first differentiated into EBs (embryoid bodies) and then induced to generate the T3pi (pancreatic islet‐like cell clusters derived from T3 cells), which expressed pancreatic islet cell‐specific markers of insulin, glucagon and somatostatin. The expression profiles of microRNAs and mRNAs from the T3pi were analysed and compared with those of undifferentiated hES‐T3 cells and differentiated EBs. MicroRNAs negatively regulate the expression of protein‐coding mRNAs. The T3pi showed very high expression of microRNAs, miR‐186, miR‐199a and miR‐339, which down‐regulated the expression of LIN28, PRDM1, CALB1, GCNT2, RBM47, PLEKHH1, RBPMS2 and PAK6. Therefore, these microRNAs and their target genes are very likely to play important regulatory roles in the development of pancreas and/or differentiation of islet cells, and they may be manipulated to increase the proportion of beta cells and insulin synthesis in the differentiated T3pi for cell therapy of type I diabetics.     

Redifferentiation of insulin-secreting cells after in vitro expansion of adult human pancreatic islet tissue

Cellular replacement therapy holds promise for the treatment of diabetes mellitus but donor tissue is severely limited. Therefore, we investigated whether insulin-secreting cells could be differentiated in vitro from a monolayer of cells expanded from human donor pancreatic islets. We describe a three-step culture protocol that allows for the efficient generation of insulin-producing cell clusters from in vitro expanded, hormone-negative cells. These clusters express insulin at levels of up to 34% that of average freshly isolated human islets and secrete C-peptide upon membrane depolarization. They also contain cells expressing the other major islet hormones (glucagon, somatostatin, and pancreatic polypeptide). The source of the newly differentiated endocrine cells could either be indigenous stem/progenitor cells or the proliferation-associated dedifferentiation and subsequent redifferentiation of mature endocrine cells. The in vitro generated cell clusters may be efficacious in providing islet-like tissue for transplantation into diabetic recipients.     

Reversible immortalization of Nestin-positive precursor cells from pancreas and differentiation into insulin-secreting cells

Pancreatic stem cells or progenitor cells posses the ability of directed differentiation into pancreatic β cells. However, these cells usually have limited proliferative capacity and finite lifespan in vitro. In the present study, Nestin-positive progenitor cells (NPPCs) from mouse pancreas that expressed the pancreatic stem cells or progenitor cell marker Nestin were isolated to obtain a sufficient number of differentiated pancreatic β cells. Tet-on system for SV40 large T-antigen expression in NPPCs was used to achieve reversible immortalization. The reversible immortal Nestin-positive progenitor cells (RINPPCs) can undergo at least 80 population doublings without senescence in vitro while maintaining their biological and genetic characteristics. RINPPCs can be efficiently induced to differentiate into insulin-producing cells that contain a combination of glucagon-like peptide-1 (GLP-1) and sodium butyrate. The results of the present study can be used to explore transplantation therapy of type I diabetes mellitus.     

Human embryonic stem cell differentiation into insulin secreting β‐cells for diabetes

hESC (human embryonic stem cells), when differentiated into pancreatic β ILC (islet‐like clusters), have enormous potential for the cell transplantation therapy for Type 1 diabetes. We have developed a five‐step protocol in which the EBs (embryoid bodies) were first differentiated into definitive endoderm and subsequently into pancreatic lineage followed by formation of functional endocrine β islets, which were finally matured efficiently under 3D conditions. The conventional cytokines activin A and RA (retinoic acid) were used initially to obtain definitive endoderm. In the last step, ILC were further matured under 3D conditions using amino acid rich media (CMRL media) supplemented with anti‐hyperglycaemic hormone‐Glp1 (glucagon‐like peptide 1) analogue Liraglutide with prolonged t_½ and Exendin 4. The differentiated islet‐like 3D clusters expressed bonafide mature and functional β‐cell markers‐PDX1 (pancreatic and duodenal homoeobox‐1), C‐peptide, insulin and MafA. Insulin synthesis de novo was confirmed by C‐peptide ELISA of culture supernatant in response to varying concentrations of glucose as well as agonist and antagonist of functional 3D β islet cells in vitro. Our results indicate the presence of almost 65% of insulin producing cells in 3D clusters. The cells were also found to ameliorate hyperglycaemia in STZ (streptozotocin) induced diabetic NOD/SCID (non‐obese diabetic/severe combined immunodeficiency) mouse up to 96 days of transplantation. This protocol provides a basis for 3D in vitro generation of long‐term in vivo functionally viable islets from hESC.