Your search keyword '"Insulin-Secreting Cells transplantation"' showing total 426 results

351. Development of insulin-producing cells from primitive biologic precursors.

Author

Evans-Molina C, Vestermark GL, and Mirmira RG

Subjects

Adult, Animals, Cell Culture Techniques, Cell Differentiation, Cell Proliferation, Diabetes Mellitus, Type 1 metabolism, Embryonic Stem Cells metabolism, Embryonic Stem Cells transplantation, Glucose metabolism, Humans, Islets of Langerhans Transplantation, Mice, Multipotent Stem Cells metabolism, Multipotent Stem Cells transplantation, Pluripotent Stem Cells metabolism, Pluripotent Stem Cells transplantation, Diabetes Mellitus, Type 1 surgery, Insulin metabolism, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells transplantation, Regenerative Medicine, Stem Cell Transplantation, Stem Cells metabolism

Abstract

Purpose of Review: The differentiation of pluripotent and multipotent stem cells into insulin-producing cells has the potential to create a renewable supply of replacement beta cells with tremendous utility in the treatment of diabetes. The purpose of this review is to summarize recent advancements in the field, with emphasis on the limitations of this technology as it relates to the beta cell., Recent Findings: Multiple groups have developed successful in-vitro protocols to differentiate human embryonic stem cells and selected tissue specific stem cells into progenitors capable of insulin production and glucose-stimulated insulin secretion. The resulting cells are immature beta cell-like cells that coexpress multiple islet hormones and lack the full complement of genes necessary for normal function. Protocols that include in-vivo maturation in immune-compromised mice produce cells with a more mature phenotype., Summary: Although tremendous progress has been made in differentiating stem cells into insulin-producing cells, there is still more research needed to produce a fully functional adult beta cell.

Published

2009

352. Insulin producing cells derived from embryonic stem cells: are we there yet?

Author

Raikwar SP and Zavazava N

Subjects

Animals, Cell Differentiation, Endoderm cytology, Humans, Insulin-Secreting Cells transplantation, Organ Specificity, Transcription Factors metabolism, Embryonic Stem Cells cytology, Insulin-Secreting Cells cytology

Abstract

Derivation of insulin producing cells (IPCs) from embryonic stem (ES) cells provides a potentially innovative form of treatment for type 1 diabetes. Here, we discuss the current state of the art, unique challenges, and future directions on generating IPCs., ((c) 2008 Wiley-Liss, Inc.)

Published

2009

353. A new strategy to generate functional insulin-producing cell lines by somatic gene transfer into pancreatic progenitors.

Author

Ravassard P, Emilie Bricout-Neveu, Hazhouz Y, Pechberty S, Mallet J, Czernichow P, and Scharfmann R

Subjects

Animals, Cell Line, Genetic Vectors, Insulin genetics, Insulin-Secreting Cells metabolism, Insulinoma, Lentivirus genetics, Mice, Mice, Transgenic, Promoter Regions, Genetic, Rats, Stem Cell Transplantation, Stem Cells metabolism, Insulin-Secreting Cells cytology, Insulin-Secreting Cells transplantation, Pancreas cytology, Stem Cells cytology, Transduction, Genetic

Abstract

Background: There is increasing interest in developing human cell lines to be used to better understand cell biology, but also for drug screening, toxicology analysis and future cell therapy. In the endocrine pancreatic field, functional human beta cell lines are extremely scarce. On the other hand, rodent insulin producing beta cells have been generated during the past years with great success. Many of such cell lines were produced by using transgenic mice expressing SV40T antigen under the control of the insulin promoter, an approach clearly inadequate in human. Our objective was to develop and validate in rodent an alternative transgenic-like approach, applicable to human tissue, by performing somatic gene transfer into pancreatic progenitors that will develop into beta cells., Methods and Findings: In this study, rat embryonic pancreases were transduced with recombinant lentiviral vector expressing the SV40T antigen under the control of the insulin promoter. Transduced tissues were next transplanted under the kidney capsule of immuno-incompetent mice allowing insulinoma development from which beta cell lines were established. Gene expression profile, insulin content and glucose dependent secretion, normalization of glycemia upon transplantation into diabetic mice validated the approach to generate beta cell lines., Conclusions: Somatic gene transfer into pancreatic progenitors represents an alternative strategy to generate functional beta cell lines in rodent. Moreover, this approach can be generalized to derive cells lines from various tissues and most importantly from tissues of human origin.

Published

2009

354. Stems cells and the price of immortality.

Author

Holland AM and Stanley EG

Subjects

Cell Culture Techniques, Diabetes Mellitus therapy, Humans, Insulin-Secreting Cells transplantation, Regeneration, Insulin-Secreting Cells cytology, Stem Cells cytology

Published

2009

355. [Cell therapy for type I diabete].

Author

Sokolova IB

Subjects

Animals, Bone Marrow Transplantation, Humans, Insulin-Secreting Cells transplantation, Stem Cell Transplantation, Diabetes Mellitus, Type 1 surgery, Islets of Langerhans Transplantation

Abstract

Cell therapy is a modern and promising approach to type I diabetes mellitus treatment. Nowadays a wide range of cells is used in laboratory experiments and clinical studies, including allogeneic and xenogeneic cells of Langergance islets, bone marrow cells, haematopoietic stem cells, mesenchymal stem cells, and cord blood stem cells. Any type of the cells named could correct the status of the patients to a certain extent. However, full recovery after cell therapy has not been achieved yet.

Published

2009

356. Regenerative medicine for diabetes mellitus.

Author

Kobayashi N, Yuasa T, and Okitsu T

Subjects

Gene Transfer Techniques, Humans, Insulin metabolism, Insulin Resistance, Insulin-Secreting Cells transplantation, Diabetes Mellitus, Type 1 therapy, Diabetes Mellitus, Type 2 therapy, Regenerative Medicine

Abstract

In diabetes, a loss of pancreatic beta-cells causes insulin dependency. When insulin dependency is caused by type 1 diabetes or pancreatic diabetes, for example, pancreatic beta-cells need to be regenerated for definitive treatment. The methods for generating pancreatic beta-cells include a method of creating pancreatic beta-cells in vitro and implanting them into the body and a method of regenerating pancreatic beta-cells in the body via gene introduction or the administration of differential proliferation factors to the body. Moreover, the number of pancreatic beta-cells is also low in type 2 diabetes, caused by the compounding factors of insulin secretory failure and insulin resistance; therefore, if pancreatic beta-cells can be regenerated in a living body, then a further amelioration of the pathology can be expected. The development of pancreatic beta-cell-targeting regenerative medicine can lead to the next generation of diabetes treatment.

Published

2009

357. Derivation of functional insulin-producing cell lines from primary mouse embryo culture.

Author

Li G, Luo R, Zhang J, Yeo KS, Xie F, Way Tan EK, Caille D, Que J, Kon OL, Salto-Tellez M, Meda P, and Lim SK

Subjects

Animals, C-Peptide biosynthesis, Cell Culture Techniques, Cell Differentiation, Cell Line, Embryo, Mammalian, Hyperglycemia chemically induced, Insulin analysis, Insulin biosynthesis, Insulin-Secreting Cells transplantation, Mice, Mice, SCID, Streptozocin, Treatment Outcome, Cell Transplantation, Hyperglycemia therapy, Insulin-Secreting Cells cytology

Abstract

We have previously described the derivation of insulin-producing cell lines from mouse embryonic stem cells (mESCs) by differentiation of an intermediate lineage-restricted E-RoSH cell line through nutrient depletion in the presence of nicotinamide followed by limiting dilution. Here we investigated whether insulin-producing cell lines could be similarly derived directly from mouse embryo cells or tissues. Using a similar approach, we generated the RoSH2.K and MEPI-1 to -14 insulin-producing cell lines from the 5.5-dpc embryo-derived E-RoSH-analogous RoSH2 cell line and a 6.0-dpc mouse embryo culture, respectively. Insulin content was approximately 8 microg/10(6) MEPI-1 cells and 0.5 microg/10(6) RoSH2.K cells. Like insulin-producing mESC-derived ERoSHK cell lines, both MEPI and RoSH2.K lines were amenable to repeated cycles of freeze and thaw, replicated for months with a doubling time of 3-4 days, and exhibited genomic, structural, biochemical, and pharmacological properties of pancreatic beta-cells, including storage and release of insulin and C-peptide in an equimolar ratio. Transplantation of these cells also reversed hyperglycemia in streptozotocin-treated SCID mice and did not induce teratoma. Like ERoSHK cells, both RoSH2.K and MEPI-1 cells also induced hypoglycemia in the mice. Therefore, our protocol is robust and could reproducibly generate insulin-producing cell lines from different embryonic cell sources.

Published

2009

358. Purification method using iodixanol (OptiPrep)-based density gradient significantly reduces cytokine chemokine production from human islet preparations, leading to prolonged beta-cell survival during pretransplantation culture.

Author

Mita A, Ricordi C, Miki A, Barker S, Khan A, Alvarez A, Hashikura Y, Miyagawa S, and Ichii H

Subjects

Adenosine, Allopurinol, Automation, Cell Culture Techniques methods, Cell Survival drug effects, Chemokines biosynthesis, Cytokines biosynthesis, Glutathione, Humans, Insulin, Insulin-Secreting Cells drug effects, Islets of Langerhans drug effects, Islets of Langerhans physiology, Organ Preservation Solutions, Raffinose, Cell Survival physiology, Contrast Media pharmacology, Insulin-Secreting Cells cytology, Insulin-Secreting Cells transplantation, Islets of Langerhans cytology, Triiodobenzoic Acids pharmacology

Abstract

Purification is one of the most important steps in human islet isolation. Although Ficoll-based density gradients are widely used, OptiPrep-based density gradients are used in few centers. Cytokine/chemokine production from human islet preparations varies widely. Some cytokines/chemokines have been reported to have adverse effects on human islet preparations. Control of cytokine/chemokine production may be a key to improve islet quality and quantity, leading to better transplantation outcomes. The aim of the present study was to investigate the effects on islet preparations of purification methods using various density gradients on viability, cellular composition, and proinflammatory cytokine/chemokine production. After the digestion phase, the extracts were divided into 2 groups for purification using a semiautomated cell processor with Ficoll-based or OptiPrep-based density gradients. Islet preparations cultured for 2 days were assessed regarding islet cell viability (fluorescein diacetate/propidium iodide [FDA/PI]), fractional beta-cell viability by FACS, and beta-cell content using iCys. Cytokine/chemokine production from islet preparations was also measured by Bio-plex. After purification, the purity, islet equivalents (IEQ), and islet recovery rates were comparable between the 2 groups. Although FDA/PI and fractional beta-cell viability showed no significant difference, survival of beta cells during culture was significantly higher in the OptiPrep compared with the Ficoll-based density gradient group. There were significantly lower tumor necrosis factor (TNF)-alpha, interleukin (IL)-1beta, interferon (IFN)-gamma, IL-6, and MIP-1beta productions from the OptiPrep-based density gradient group. OptiPrep-based density gradients reduced cytokine/chemokine production by islet preparations. In addition, OptiPrep-based density gradient purification significantly reduced the loss of beta-cell mass during pretransplantation culture.

Published

2009

359. Islet alpha cell number is maintained in microencapsulated islet transplantation.

Author

Bohman S and King AJF

Subjects

Animals, Blood Glucose, Capsules, Cell Count, DNA analysis, Diabetes Mellitus, Experimental blood, Diabetes Mellitus, Experimental complications, Diabetes Mellitus, Type 1 blood, Diabetes Mellitus, Type 1 complications, Glucagon blood, Hyperglycemia blood, Hyperglycemia etiology, Hyperglycemia therapy, Insulin blood, Male, Mice, Mice, Inbred BALB C, Mice, Inbred C57BL, Diabetes Mellitus, Experimental therapy, Diabetes Mellitus, Type 1 therapy, Glucagon-Secreting Cells cytology, Insulin-Secreting Cells cytology, Insulin-Secreting Cells transplantation, Islets of Langerhans Transplantation methods

Abstract

Islet transplantation can reverse hyperglycaemia in Type 1 diabetes patients. One problem in islet transplantation is a loss of beta cell mass as well as blunted glucagon responses from the grafted islets. It has been suggested that alpha cell loss is associated with close contact of the alpha cells with the implantation organ. In the present study we made use of microencapsulation, where transplanted islets are not in direct contact with the host implantation site. After transplantation, the number of glucagon cells stained per microencapsulated islet section was increased whereas the number of insulin cells stained was decreased. DNA content of the islets was reduced, as was insulin content, whereas glucagon content was unchanged. This indicates that cell number in transplanted microencapsulated islets diminishes, which can be accounted for by loss of beta cells. However, in contrast to previous studies using non-encapsulated islets, alpha cell number seems to be maintained.

Published

2008

360. Islet cell transplantation.

Author

Vaithilingam V, Sundaram G, and Tuch BE

Subjects

Animals, Apoptosis, Cell Proliferation, Cells, Cultured, Collagenases chemistry, Diabetes Mellitus, Type 1 pathology, Exenatide, Graft Rejection pathology, Graft Rejection physiopathology, Humans, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells transplantation, Islets of Langerhans blood supply, Islets of Langerhans pathology, Neovascularization, Physiologic, Peptides therapeutic use, Staining and Labeling methods, Thermolysin chemistry, Tissue Donors, Tissue Scaffolds, Venoms therapeutic use, Diabetes Mellitus, Type 1 surgery, Graft Rejection prevention & control, Graft Survival drug effects, Immunosuppressive Agents therapeutic use, Islets of Langerhans drug effects, Islets of Langerhans Transplantation methods

Abstract

Purpose of Review: The transplantation of human islets has come a long way since the first diabetic person became insulin independent in 1989. The advent of a steroid-free immunosuppressive protocol in 2000 resulted in most recipients becoming insulin independent and remaining so for a year. However, beta-cell function declines thereafter. Strategies to enhance the islet mass transplanted and preserve beta-cell function are necessary., Recent Findings: This review covers recent advances in determining the selection of appropriate enzymes for islet isolation, use of pancreases from heart-dead donors and techniques for predicting the functional capacity of isolated islets prior to transplantation. Changing the transplantation site away from the liver, where many islets are destroyed by an inflammatory process, is reviewed, and the possibility of seeding islets onto three-dimensional biodegradable scaffolds discussed. A method of preventing apoptosis of the beta cells prior to transplantation is detailed, as is the beneficial effect of using exenatide, after transplantation. Novel techniques to image islets are discussed, and this requires the labelling of the islets prior to implantation. Enhancing the vascularization of islets is shown to enhance functional outcomes. Encapsulation of the islets should obviate the need for using antirejection drugs, and it may be possible to expand beta cells in vitro., Summary: The above strategies are likely to enhance the outcomes of clinical islet transplants.

Published

2008

361. Humanized mice for the study of type 1 diabetes and beta cell function.

Author

King M, Pearson T, Rossini AA, Shultz LD, and Greiner DL

Subjects

Animals, Autoimmunity physiology, Diabetes Mellitus, Type 1 immunology, Humans, Immune System physiology, Insulin-Secreting Cells transplantation, Mice, SCID, Stem Cells physiology, Transplantation, Heterologous methods, Diabetes Mellitus, Type 1 pathology, Diabetes Mellitus, Type 1 physiopathology, Disease Models, Animal, Insulin-Secreting Cells physiology, Mice

Abstract

Our understanding of the basic biology of diabetes has been guided by observations made using animal models, particularly rodents. However, humans are not mice, and outcomes predicted by murine studies are not always representative of actual outcomes in the clinic. In particular, investigators studying diabetes have relied heavily on mouse and rat models of autoimmune type 1-like diabetes, and experimental results using these models have not been representative of many of the clinical trials in type 1 diabetes. In this article, we describe the availability of new models of humanized mice for the study of three areas of diabetes. These include the use of humanized mice for the study of (1) human islet stem and progenitor cells, (2) human islet allograft rejection, and (3) human immunity and autoimmunity. These humanized mouse models provide an important preclinical bridge between in vitro studies and rodent models and the translation of discoveries in these model systems to the clinic.

Published

2008

362. [Study on differentiation of mesenchymal stem cells derived from human umbilical cord blood into insulin secreting cells].

Author

Chi ZH, Lu Y, and Zhang Y

Subjects

Animals, Cell Differentiation drug effects, Cells, Cultured, Diabetes Mellitus, Experimental surgery, Humans, Insulin metabolism, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells transplantation, Mesenchymal Stem Cells drug effects, Mice, Mice, Nude, Fetal Blood cytology, Insulin-Secreting Cells cytology, Mesenchymal Stem Cells cytology

Abstract

Objective: To investigate the differential potential of mesenchymal stem cells (MSCs) derived from human umbilical cord blood (hUCB) into insulin-secreting cells and its inducing condition., Methods: UCB nucleated cells (NCs) were isolated and cultured in Mesencult media. The obtained UCB MSC were purified by adherence method and expanded. Then they were induced with epidermal growth factor (EGF), B-mercaptoethanol and high concentration of glucose. The induced cells were identified by RT-PCR. Intracellular insulin was examined by immunocytochemistry. The quantity of insulin secretion and glucose-simulated insulin release were examined by chemiluminescence immunoassay. The induced cells were also transplanted into renal subcapsular space of STZ-induced hyperglycemic mice to observe the in vivo lowering effect on hyperglycemia., Results: The induced cells morphologically became round and were gathering into a mass. The expression of some genes related to pancreatic islet was found by RT-PCR. Chemiluminescence immunoassay showed insulin positivity and the cells secreted a low concentration of insulin [(0.37 +/- 0.06) mU/L]. The induced cells responded to high glucose challenge with a stimulation index of 1.76. After those cells grafted into renal sub-capsule there was an in vivo lowering effect on blood glucose level on STZ hyperglycemic mice., Conclusion: MSCs from UCB can differentiated into insulin secreting cells.

Published

2008

363. Human amnion epithelial cells can be induced to differentiate into functional insulin-producing cells.

Author

Hou Y, Huang Q, Liu T, and Guo L

Subjects

Amnion surgery, Amnion transplantation, Animals, C-Peptide metabolism, Cells, Cultured, Culture Media, Serum-Free, Diabetes Mellitus, Experimental metabolism, Diabetes Mellitus, Experimental surgery, Diabetes Mellitus, Type 1 therapy, Epithelial Cells transplantation, Glucose metabolism, Humans, Hyperglycemia metabolism, Hyperglycemia surgery, Hyperglycemia therapy, Insulin-Secreting Cells transplantation, Male, Mice, Mice, Inbred C57BL, Radioimmunoassay, Time Factors, Amnion metabolism, Cell Differentiation drug effects, Epithelial Cells metabolism, Glucose pharmacology, Insulin-Secreting Cells metabolism

Abstract

Pancreatic islet transplantation has demonstrated that long-term insulin independence may be achieved in patients suffering from diabetes mellitus type 1. However, limited availability of islet tissue means that new sources of insulin-producing cells that are responsive to glucose are required. Here, we show that human amnion epithelial cells (HAEC) can be induced to differentiate into functional insulin-producing cells in vitro. After induction of differentiation, HAEC expressed multiple pancreatic beta-cell genes, including insulin, pancreas duodenum homeobox-1, paired box gene 6, NK2 transcription factor-related locus 2, Islet 1, glucokinase, and glucose transporter-2, and released C-peptide in a glucose-regulated manner in response to other extracellular stimulations. The transplantation of induced HAEC into streptozotocin-induced diabetic C57 mice reversed hyperglycemia, restored body weight, and maintained euglycemia for 30 d. These findings indicated that HAEC may be a new source for cell replacement therapy in type 1 diabetes.

Published

2008

364. Toward a cell-based cure for diabetes: advances in production and transplant of beta cells.

Author

Claiborn KC and Stoffers DA

Subjects

Cell Differentiation, Cell Transdifferentiation, Diabetes Mellitus, Type 1 physiopathology, Humans, Signal Transduction, Cell- and Tissue-Based Therapy, Diabetes Mellitus, Type 1 therapy, Embryonic Stem Cells transplantation, Insulin-Secreting Cells transplantation, Islets of Langerhans Transplantation

Abstract

Type 1 diabetes results from autoimmune destruction of the insulin-producing beta cells of the pancreatic islets of Langerhans. Although developments in exogenous insulin therapy have greatly improved clinical outcomes in patients with diabetes, the ability of the pancreatic beta cell to exquisitely regulate the delivery of insulin and maintain normal levels of blood glucose is still far superior to what can be achieved by external delivery of insulin. As a result, the majority of patients with type 1 diabetes still experience the complications of chronic hyperglycemia or serious and potentially life-threatening hypoglycemia. The shortcomings of medical therapy have driven research toward more direct approaches of beta cell replacement. Indeed, the specificity of beta cell loss in type 1 diabetes makes this disease a particularly attractive candidate for cell-based therapies. In order for significant progress to be made, however, a thorough understanding of beta cell biology and more broadly islet biology is necessary. This review addresses recent advances in developmental biology that have expanded our understanding of islet cell differentiation, assesses the promise and limitations of islet transplantation, and discusses the future of alternative sources of beta cells, including directed differentiation of stem cells, replication of adult beta cells, and transdifferentiation of nonislet cells to a beta cell fate. =

Published

2008

365. A simple method to induce differentiation of murine bone marrow mesenchymal cells to insulin-producing cells using conophylline and betacellulin-delta4.

Author

Hisanaga E, Park KY, Yamada S, Hashimoto H, Takeuchi T, Mori M, Seno M, Umezawa K, Takei I, and Kojima I

Subjects

Adipocytes drug effects, Adipocytes physiology, Animals, Betacellulin, Blood Glucose analysis, Bone Marrow Cells physiology, Cells, Cultured, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells transplantation, Male, Mesenchymal Stem Cells drug effects, Mesenchymal Stem Cells physiology, Mice, Mice, Inbred C57BL, Mice, Nude, Bone Marrow Cells drug effects, Cell Culture Techniques, Cell Differentiation drug effects, Insulin metabolism, Insulin-Secreting Cells physiology, Intercellular Signaling Peptides and Proteins pharmacology, Vinca Alkaloids pharmacology

Abstract

The present study was conducted to establish a method to induce differentiation of bone marrow (MB)-derived mesenchymal cells into insulin-producing cells. When mouse BM-derived mesenchymal cells were cultured for 60 days in medium containing 10% fetal calf serum and 25 mM glucose, they expressed insulin. Addition of activin A and betacellulin (BTC) accelerated differentiation, and immunoreactive insulin was detected 14 days after the treatment. Insulin-containing secretory granules were observed in differentiated cells by electron microscopy. Treatment of BM-derived mesenchymal cells with conophylline (CnP) and BTC-delta4 further accelerated differentiation, and mRNA for insulin was detected 5 to 7 days after the treatment. Mesencymal cells treated with CnP and BTC-delta4 responded to a high concentration of glucose and secreted mature insulin. When these cells were transplanted into streptozotocin-treated mice, they markedly reduced the plasma glucose concentration, and the effect continued for at least 4 weeks. These results indicate an efficacy of the combination of CnP and BTC-delta4 in inducing differentiation of BM-derived mesenchymal cells into insulin-producing cells.

Published

2008

366. In vitro expansion of human beta cells.

Author

Efrat S

Subjects

Adult, Animals, Cell Differentiation, Humans, Insulin-Secreting Cells transplantation, Cell Culture Techniques methods, Cell Lineage, Insulin-Secreting Cells cytology

Published

2008

367. A peptide-major histocompatibility complex II chimera favors survival of pancreatic beta-islets grafted in type 1 diabetic mice.

Author

Casares S, Lin M, Zhang N, Teijaro JR, Stoica C, McEvoy R, Farber DL, Bona C, and Brumeanu TD

Subjects

Animals, CD4-Positive T-Lymphocytes immunology, CD4-Positive T-Lymphocytes pathology, Cell Proliferation, Diabetes Mellitus, Type 1 pathology, Dimerization, Disease Models, Animal, Hemagglutinins genetics, Hemagglutinins metabolism, Hyperglycemia pathology, Hyperglycemia prevention & control, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells transplantation, Mice, Mice, Transgenic, Th2 Cells immunology, Th2 Cells pathology, Chimera genetics, Diabetes Mellitus, Type 1 surgery, Genes, MHC Class II genetics, Graft Survival genetics, Graft Survival immunology, Islets of Langerhans Transplantation immunology, Peptides genetics

Abstract

Background: Transplantation of pancreatic islets showed a tremendous progress over the years as a promising, new therapeutic strategy in patients with type 1 diabetes. However, additional immunosuppressive drug therapy is required to prevent rejection of engrafted islets. The current immunosuppressive therapies showed limited success in maintaining long-term islet survival as required to achieve insulin independence in type 1 diabetes, and they induce severe adverse effects. Herein, we analyzed the effects of a soluble peptide-major histocompatibility complex (MHC) class II chimera aimed at devising an antigen-specific therapy for suppression of anti-islet T cell responses and to improve the survival of pancreatic islets transplants., Methods: Pancreatic islets from transgenic mice expressing the hemagglutinin antigen in the beta islets under the rat insulin promoter (RIP-HA) were grafted under the kidney capsule of diabetic, double transgenic mice expressing hemagglutinin in the pancreas and T cells specific for hemagglutinin (RIP-HA, TCR-HA). The recipient double transgenic mice were treated or not with the soluble peptide-MHC II chimera, and the progression of diabetes, graft survival, and T cell responses to the grafted islets were analyzed., Results: The peptide-MHC II chimera protected syngeneic pancreatic islet transplants against the islet-reactive CD4 T cells, and prolonged the survival of transplanted islets. Protection of transplanted islets occurred by polarization of antigen-specific memory CD4 T cells toward a Th2 anti-inflammatory response., Conclusions: The peptide-MHC II chimera approach is an efficient and specific therapeutic approach to suppress anti-islet T cell responses and provides a long survival of pancreatic grafted islets.

Published

2008

368. Insulin-secreting L-cells for the treatment of insulin-dependent diabetes.

Author

Bara H and Sambanis A

Subjects

1-Methyl-3-isobutylxanthine pharmacology, Animals, Cell Line, Colforsin pharmacology, Drug Resistance, Glucagon-Like Peptide 1 genetics, Glucagon-Like Peptide 1 metabolism, Humans, Insulin genetics, Insulin Secretion, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells transplantation, Mice, Neomycin pharmacology, Proinsulin genetics, Transfection, Diabetes Mellitus therapy, Insulin metabolism, Insulin-Secreting Cells metabolism

Abstract

Cell-based treatments for insulin-dependent diabetes (IDD) may provide more physiologic regulation of blood glucose levels than daily insulin injections, thereby reducing the occurrence of secondary complications associated with diabetes. An autologous cell source is especially attractive for regulatory and ethical reasons in addition to eliminating the need for immunosuppression. This study uses non-beta-cells, genetically modified for physiologic insulin secretion. Enteroendocrine L-cells, exhibit regulated secretion in response to physiologic stimuli and their endogenous products are fully compatible with prandial metabolism. Murine GLUTag L-cells were transfected with a plasmid co-expressing human insulin and neomycin resistance and the stable cell line, GLUTag-INS, was established. Secretion properties of GLUTag-INS cells were investigated in vitro through induced secretion tests using meat hydrolysate or 3-isobutyl-1-methylxanthine and forskolin as secretagogues. GLUTag-INS cells rapidly co-secreted recombinant insulin and endogenous glucagon-like peptide in response to metabolic cues from the surrounding medium and demonstrated efficient processing of proinsulin to insulin.

Published

2008

369. Intrahepatic glucose flux as a mechanism for defective intrahepatic islet alpha-cell response to hypoglycemia.

Author

Zhou H, Zhang T, Bogdani M, Oseid E, Parazzoli S, Vantyghem MC, Harmon J, Slucca M, and Robertson RP

Subjects

Animals, Diabetes Mellitus, Experimental surgery, Insulin metabolism, Insulin Secretion, Islets of Langerhans Transplantation physiology, Male, Rats, Rats, Inbred Lew, Transplantation, Isogeneic, Glucose metabolism, Hypoglycemia blood, Insulin-Secreting Cells physiology, Insulin-Secreting Cells transplantation, Liver metabolism

Abstract

Objective: Glucagon responses to hypoglycemia from islets transplanted in the liver are defective. To determine whether this defect is related to intrahepatic glycogen, islets from inbred Lewis rats were transplanted into the hepatic sinus (H group), peritoneal cavity (P group), omentum (O group), and kidney capsule (K group) of recipient Lewis rats previously rendered diabetic with streptozotocin (STZ)., Research Design and Methods: Glucagon responses to hypoglycemia were obtained before and after transplantation under fed conditions and after fasting for 16 h and 48 h to deplete liver glycogen., Results: Glucagon (area under the curve) responses to hypoglycemia in the H group (8,839 +/- 1,988 pg/ml per 90 min) were significantly less than in normal rats (40,777 +/- 8,192; P < 0.01). Fasting significantly decreased hepatic glycogen levels. Glucagon responses in the H group were significantly larger after fasting (fed 8,839 +/- 1,988 vs. 16-h fasting 24,715 +/- 5,210 and 48-h fasting 29,639 +/- 4,550; P < 0.01). Glucagon response in the H group decreased after refeeding (48-h fasting 29,639 +/- 4,550 vs. refed 10,276 +/- 2,750; P < 0.01). There was no difference in glucagon response to hypoglycemia between the H and the normal control group after fasting for 48 h (H 29,639 +/- 4,550 vs. control 37,632 +/- 5,335; P = NS). No intragroup differences were observed in the P, O, and K groups, or normal control and STZ groups, when comparing fed or fasting states., Conclusions: These data suggest that defective glucagon responses to hypoglycemia by intrahepatic islet alpha-cells is due to dominance of a suppressive signal caused by increased glucose flux and glucose levels within the liver secondary to increased glycogenolysis caused by systemic hypoglycemia.

Published

2008

370. In vitro proliferation of cells derived from adult human beta-cells revealed by cell-lineage tracing.

Author

Russ HA, Bar Y, Ravassard P, and Efrat S

Subjects

Adult, Cell Culture Techniques methods, Cell Differentiation, Cell Division, Cell Survival, Cells, Cultured, Humans, Insulin-Secreting Cells transplantation, Insulin-Secreting Cells virology, Integrases genetics, Integrases metabolism, Kinetics, Lentivirus enzymology, Lentivirus genetics, Lentivirus physiology, Polymerase Chain Reaction, Insulin-Secreting Cells cytology

Abstract

Objective: Expansion of insulin-producing beta-cells from adult human islets could alleviate donor shortage for cell-replacement therapy of diabetes. A major obstacle to development of effective expansion protocols is the rapid loss of beta-cell markers in the cultured cells. Here, we report a genetic cell-lineage tracing approach for following the fate of cultured beta-cells., Research Design and Methods: Cells dissociated from isolated human islets were infected with two lentiviruses, one expressing Cre recombinase under control of the insulin promoter and the other, a reporter cassette with the structure cytomegalovirus promoter-loxP-DsRed2-loxP-eGFP., Results: Beta-cells were efficiently and specifically labeled by the dual virus system. Label(+), insulin(-) cells derived from beta-cells were shown to proliferate for a maximum of 16 population doublings, with an approximate doubling time of 7 days. Isolated labeled cells could be expanded in the absence of other pancreas cell types if provided with medium conditioned by pancreatic non-beta-cells. Analysis of mouse islet cells by the same method revealed a much lower proliferation of labeled cells under similar culture conditions., Conclusions: Our findings provide direct evidence for survival and dedifferentiation of cultured adult human beta-cells and demonstrate that the dedifferentiated cells significantly proliferate in vitro. The findings confirm the difference between mouse and human beta-cell proliferation under our culture conditions. These findings demonstrate the feasibility of cell-specific labeling of cultured primary human cells using a genetic recombination approach that was previously restricted to transgenic animals.

Published

2008

371. Conversion of immortal liver progenitor cells into pancreatic endocrine progenitor cells by persistent expression of Pdx-1.

Author

Jin CX, Li WL, Xu F, Geng ZH, He ZY, Su J, Tao XR, Ding XY, Wang X, and Hu YP

Subjects

Animals, Cell Culture Techniques, Cell Proliferation, Cell Transplantation, Epithelial Cells, Homeobox Protein Nkx-2.2, Homeodomain Proteins genetics, Homeodomain Proteins physiology, Hyperglycemia therapy, Insulin metabolism, Insulin Secretion, Insulin-Secreting Cells transplantation, Mice, Mice, SCID, Trans-Activators genetics, Trans-Activators physiology, Transcription Factors biosynthesis, Hepatocytes cytology, Homeodomain Proteins biosynthesis, Insulin-Secreting Cells cytology, Stem Cells cytology, Trans-Activators biosynthesis

Abstract

The conversion of expandable liver progenitor cells into pancreatic beta cells would provide a renewable cell source for diabetes cell therapy. Previously, we reported the establishment of liver epithelial progenitor cells (LEPCs). In this work, LEPCs were modified into EGFP/Pdx-1 LEPCs, cells with stable expression of both Pdx-1 and EGFP. Unlike previous work, with persistent expression of Pdx-1, EGFP/Pdx-1 LEPCs acquired the phenotype of pancreatic endocrine progenitor cells rather than giving rise to insulin-producing cells directly. EGFP/Pdx-1 LEPCs proliferated vigorously and expressed the crucial transcription factors involved in beta cell development, including Ngn3, NeuroD, Nkx2.2, Nkx6.1, Pax4, Pax6, Isl1, MafA and endogenous Pdx-1, but did not secrete insulin. When cultured in high glucose/low serum medium supplemented with cytokines, EGFP/Pdx-1 LEPCs stopped proliferating and gave rise to functional beta cells without any evidence of exocrine or other islet cell lineage differentiation. When transplanted into diabetic SCID mice, EGFP/Pdx-1 LEPCs ameliorated hyperglycemia by secreting insulin in a glucose regulated manner. Considering the limited availability of beta cells, we propose that our experiments will provide a framework for utilizing the immortal liver progenitor cells as a renewable cell source for the generation of functional pancreatic beta cells.

Published

2008

372. Regeneration of pancreatic beta cells.

Author

Jun HS

Subjects

Animals, Bone Marrow Cells cytology, Bone Marrow Cells physiology, Cell Differentiation, Cell Division, Embryonic Stem Cells cytology, Embryonic Stem Cells physiology, Humans, Insulin-Secreting Cells cytology, Intestines cytology, Intestines physiology, Liver cytology, Liver physiology, Transcription Factors metabolism, Diabetes Mellitus surgery, Insulin-Secreting Cells physiology, Insulin-Secreting Cells transplantation, Regeneration

Abstract

Diabetes mellitus results from inadequate mass of insulin-producing pancreatic beta cells. Type 1 diabetes is characterized by absolute loss of beta cells due to autoimmune-mediated destruction. Type 2 diabetes is characterized by relative deficiency of beta cells due to lack of compensation for insulin resistance. Restoration of deficient beta cell mass by transplantation from exogenous sources or by endogenous regeneration of insulin-producing cells would be therapeutic options. Mature beta cells have an ability to proliferate; however, it has been shown to be difficult to expand adult beta cells in vitro. Alternatively, regeneration of beta cells from embryonic and adult stem cells and pancreatic progenitor cells is an attractive method to restore islet cell mass. With information obtained from the biology of pancreatic development, direct differentiation of stem and progenitor cells toward a pancreatic beta cell phenotype has been tried using various strategies, including forced expression of beta cell-specific transcription factors. Further research is required to understand how endogenous beta cells differentiate and to develop methods to regenerate beta cells for clinically applicable therapies for diabetes.

Published

2008

373. Building better beta cells.

Author

Stanley EG and Elefanty AG

Subjects

Animals, Diabetes Mellitus, Type 1 therapy, Embryonic Stem Cells metabolism, Embryonic Stem Cells transplantation, Humans, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells transplantation, Stem Cell Transplantation, Embryonic Stem Cells cytology, Insulin-Secreting Cells cytology

Abstract

Type 1 diabetes represents an attractive target for human embryonic stem cell (hESC)-based cell replacement therapies. Recently, in Nature Biotechnology, Kroon et al. (2008) reported encouraging progress toward this goal with the development of functional islet-like structures in mice transplanted with hESC-derived pancreatic endoderm.

Published

2008

374. Pancreatic endoderm derived from human embryonic stem cells generates glucose-responsive insulin-secreting cells in vivo.

Author

Kroon E, Martinson LA, Kadoya K, Bang AG, Kelly OG, Eliazer S, Young H, Richardson M, Smart NG, Cunningham J, Agulnick AD, D'Amour KA, Carpenter MK, and Baetge EE

Subjects

Animals, Cell Differentiation, Cell Proliferation, Cells, Cultured, Embryonic Stem Cells metabolism, Embryonic Stem Cells transplantation, Endoderm cytology, Endoderm metabolism, Humans, Insulin-Secreting Cells transplantation, Mice, Pancreas, Artificial trends, Cell Culture Techniques trends, Embryonic Stem Cells cytology, Glucose metabolism, Insulin metabolism, Insulin-Secreting Cells cytology, Insulin-Secreting Cells metabolism, Tissue Engineering trends

Abstract

Development of a cell therapy for diabetes would be greatly aided by a renewable supply of human beta-cells. Here we show that pancreatic endoderm derived from human embryonic stem (hES) cells efficiently generates glucose-responsive endocrine cells after implantation into mice. Upon glucose stimulation of the implanted mice, human insulin and C-peptide are detected in sera at levels similar to those of mice transplanted with approximately 3,000 human islets. Moreover, the insulin-expressing cells generated after engraftment exhibit many properties of functional beta-cells, including expression of critical beta-cell transcription factors, appropriate processing of proinsulin and the presence of mature endocrine secretory granules. Finally, in a test of therapeutic potential, we demonstrate that implantation of hES cell-derived pancreatic endoderm protects against streptozotocin-induced hyperglycemia. Together, these data provide definitive evidence that hES cells are competent to generate glucose-responsive, insulin-secreting cells.

Published

2008

375. Decision time for pancreatic islet-cell transplantation.

Author

Ruggenenti P, Remuzzi A, and Remuzzi G

Subjects

Animals, Humans, Immunosuppressive Agents adverse effects, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Mice, Mice, Transgenic, Sirolimus adverse effects, Tacrolimus adverse effects, Diabetes Mellitus, Type 1 therapy, Insulin biosynthesis, Insulin-Secreting Cells transplantation

Published

2008

376. beta-Cell specific cytoprotection by prolactin on human islets.

Author

Yamamoto T, Ricordi C, Mita A, Miki A, Sakuma Y, Molano RD, Fornoni A, Pileggi A, Inverardi L, and Ichii H

Subjects

Animals, Cell Culture Techniques, Disease Models, Animal, Humans, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells transplantation, Islets of Langerhans Transplantation, Mice, Mice, Nude, Cell Survival drug effects, Diabetes Mellitus, Experimental surgery, Insulin-Secreting Cells cytology, Prolactin pharmacology

Abstract

Introduction: Many cytoprotective agents have been reported to improve islet isolation and transplantation outcomes. However, several of these agents improve all cell subsets within an islet preparation; selection of non-beta-cell components (eg, acinar cells) may have a negative effect on beta-cell function and survival. In this study, we examined the effect of prolactin (PRL) supplementation in the culture medium to determine whether it exerted beta-cell-selective cytoprotection on islet viability and function., Materials and Methods: Human islets were precultured with or without recombinant human PRL (500 microg/L) for 48 hours. The fractional viability and cellular composition of non-beta-cell and beta-cell-specific components were assessed using FACS and Laser Scanning Cytometry (LSC). Islet potency was assessed in vivo by transplantation into chemically induced diabetic immunodeficient mice., Results: The relative viable beta-cell mass and the relative islet beta-cell content in the PRL group were 28% higher (P = .018) and 19% higher (P = .029) than the control group, respectively. All transplanted mice achieved normoglycemia in both groups, indicating that PRL treatment did not alter islet function., Conclusion: PRL treatment improved beta-cell-specific viability and survival of human islets in vitro. The development of novel beta-cell-specific cytoprotective strategies may be of assistance in improving islet transplantation.

Published

2008

377. [Cellular transplantation laboratory: a new field of action for nurses].

Author

Corradi MI and da Silva SH

Subjects

Humans, Insulin-Secreting Cells transplantation, Nurse's Role, Nursing

Abstract

This article presents the experience of a nurse at a cellular transplantation laboratory. This laboratory goal is to isolate insulin producing cells for human transplantation. The nurse, as a member of an interdisciplinary team, took part in the planning of all work processes: working procedures and team training. The main activities under the nurse responsibilities include contamination control, on-the-job training and evaluation of the Quality of the procedures developed by the interdisciplinary team. Results have shown the effectiveness of the nurses' work in this new field.

Published

2008

378. Generation of insulin-producing beta cells from stem cells--perspectives for cell therapy in type 1 diabetes.

Author

Seissler J and Schott M

Subjects

Animals, Cell Differentiation, Humans, Insulin-Secreting Cells transplantation, Cell- and Tissue-Based Therapy, Diabetes Mellitus, Type 1 therapy, Insulin-Secreting Cells cytology, Stem Cells cytology

Abstract

Cell based therapy for the treatment of type 1 diabetes is limited by the overall shortage of donor organs for transplantation. This is the rationale for the research on the generation of insulin-producing beta cells from an inexhaustible source of cells such as the stem cells. Stem cells are progenitor cells which possess the capacity of self-renewing and differentiation in fully mature cells depending on the culture conditions. The fundamental question is how to make terminally matured pancreatic beta cells. During the last years different approaches for the neogenesis of beta cells have been described using embryonic stem cells, adult stem cells residing in the pancreas, or other nonpancreatic cell types. Although fully functional islets have not yet been derived from any stem cells, the use of stem cells is still the most promising approach on the way to establish a treatment protocol for the cure of type 1 diabetes in the future.

Published

2008

379. Beta-cell replacement for insulin-dependent diabetes mellitus.

Author

Efrat S

Subjects

Animals, Cell Differentiation, Diabetes Mellitus, Type 1 immunology, Embryonic Stem Cells cytology, Humans, Insulin-Secreting Cells cytology, Insulin-Secreting Cells immunology, Islets of Langerhans Transplantation methods, Stem Cells cytology, Diabetes Mellitus, Type 1 therapy, Insulin-Secreting Cells transplantation

Abstract

Beta-cell replacement is considered the optimal treatment for type 1 diabetes, however, it is hindered by a shortage of human organ donors. Given the difficulty of expanding adult beta cells in vitro, stem/progenitor cells, which can be expanded in tissue culture and induced to differentiate into multiple cell types, represent an attractive source for generation of cells with beta-cell properties. In the absence of well-characterized human pancreas progenitor cells, investigators are exploring the use of embryonic stem cells and stem/progenitor cells from other tissues. Once abundant surrogate beta cells are available, the challenge will be to protect them from recurring autoimmunity.

Published

2008

380. Induction of immune tolerance to facilitate beta cell regeneration in type 1 diabetes.

Author

Pasquali L, Giannoukakis N, and Trucco M

Subjects

Adoptive Transfer methods, Animals, Dendritic Cells cytology, Dendritic Cells immunology, Dendritic Cells transplantation, Diabetes Mellitus, Type 1 immunology, Humans, Immune Tolerance immunology, Insulin-Secreting Cells cytology, Insulin-Secreting Cells immunology, Insulin-Secreting Cells transplantation, Diabetes Mellitus, Type 1 therapy, Immunosuppression Therapy methods

Abstract

A definitive cure for type 1 diabetes is currently being pursued with enormous effort by the scientific community. Different strategies are followed to restore physiologic production of insulin in diabetic patients. Restoration of self-tolerance remains the milestone that must be reached in order to move a step further and recover a cell source capable of independent and functional insulin production. Multiple strategies aimed at modulation of both central and peripheral immunity must be considered. Promising results now show that the immune system can be modulated in a way that acquisition of a "diabetes-suppressive" phenotype is possible. Once self-tolerance is achieved, reversal of the disease may be obtained by simply allowing physiologic rescue and/or regeneration of the beta cells to take place. Given that these outcomes have already been confirmed in humans, refinement of existing protocols along with novel methods adapted to T1DM reversal will allow translation into clinical trials.

Published

2008

381. [Experimental pancreatic islet transplant into the genito-urinary tract simultaneous to kidney transplant].

Author

Gómez Dos Santos V, Burgos Revilla FJ, Pascual Santos J, Marcen Letosa R, Villafruela Gómez JJ, Correa Gorospe C, Cuevas Muñoz B, Mampaso F, and García Gonzalez R

Subjects

Animals, Swine, Insulin-Secreting Cells transplantation, Kidney Transplantation, Transplantation, Heterotopic methods, Urogenital System surgery

Abstract

Introduction and Objectives: Simultaneous kidney and pancreas transplant is a good treatment for both renal and pancreas insufficiency. Experimental apply of genitourinary tract for pancreas implantation is reported in this work., Material and Method: Twenty animals aged as average 5.5 monts (SD 1.1) and an average weight of 53 kgr were submitted to this protocol. In the day 1 a left nephrectomy is completed and the graft is perfused with University of Wisconsin solution. A partial pancreatectomy is completed at following, isolation of pancreatic islets by colagenase enzymatic digestion. Islets are dryed with Ditizone and culptured for 24 hours at 37 degrees C and 5% CO2. Day-2 a right nephrectomy is performed and orthotopic renal autotransplant using the left kidney is completed. Pancreatic islets are transplanted in 4 different locations of the genitourinary tract: renal subcapsular space, bladder submucosae, testis parenchyma and vas deferens. Day-7, all the animals were sacrifized to complete pathological study., Results and Conclusions: Viable islets were isolated in bladder submucosae and testis after transdeferential injection.

Published

2008

382. Imaging of gene expression in live pancreatic islet cell lines using dual-isotope SPECT.

Author

Tai JH, Nguyen B, Wells RG, Kovacs MS, McGirr R, Prato FS, Morgan TG, and Dhanvantari S

Subjects

Animals, Arabinofuranosyluracil metabolism, Cell Line, Genes, Reporter, Glucagon-Secreting Cells diagnostic imaging, Glucagon-Secreting Cells transplantation, Green Fluorescent Proteins biosynthesis, Green Fluorescent Proteins genetics, Insulin-Secreting Cells diagnostic imaging, Insulin-Secreting Cells transplantation, Mice, Radiopharmaceuticals metabolism, Thymidine Kinase biosynthesis, Thymidine Kinase genetics, Tomography, Emission-Computed, Single-Photon, Tomography, X-Ray Computed, Arabinofuranosyluracil analogs & derivatives, Glucagon-Secreting Cells metabolism, Indium Radioisotopes metabolism, Insulin-Secreting Cells metabolism, Iodine Radioisotopes metabolism, Tropolone metabolism

Abstract

Unlabelled: We are combining nuclear medicine with molecular biology to establish a sensitive, quantitative, and tomographic method with which to detect gene expression in pancreatic islet cells in vivo. Dual-isotope SPECT can be used to image multiple molecular events simultaneously, and coregistration of SPECT and CT images enables visualization of reporter gene expression in the correct anatomic context. We have engineered pancreatic islet cell lines for imaging with SPECT/CT after transplantation under the kidney capsule., Methods: INS-1 832/13 and alphaTC1-6 cells were stably transfected with a herpes simplex virus type 1-thymidine kinase-green fluorescent protein (HSV1-thymidine kinase-GFP) fusion construct (tkgfp). After clonal selection, radiolabel uptake was determined by incubation with 5-(131)I-iodo-1-(2-deoxy-2-fluoro-beta-d-arabinofuranosyl)uracil ((131)I-FIAU) (alphaTC1-6 cells) or (123)I-FIAU (INS-1 832/13 cells). For the first set of in vivo experiments, SPECT was conducted after alphaTC1-6/tkgfp cells had been labeled with either (131)I-FIAU or (111)In-tropolone and transplanted under the left kidney capsule of CD1 mice. Reconstructed SPECT images were coregistered to CT. In a second study using simultaneous acquisition dual-isotope SPECT, INS-1 832/13 clone 9 cells were labeled with (111)In-tropolone before transplantation. Mice were then systemically administered (123)I-FIAU and data for both (131)I and (111)In were acquired simultaneously., Results: alphaTC1-6/tkgfp cells showed a 15-fold greater uptake of (131)I-FIAU, and INS-1/tkgfp cells showed a 12-fold greater uptake of (123)I-FIAU, compared with that of wild-type cells. After transplantation under the kidney capsule, both reporter gene expression and location of cells could be visualized in vivo with dual-isotope SPECT. Immunohistochemistry confirmed the presence of glucagon- and insulin-positive cells at the site of transplantation., Conclusion: Dual-isotope SPECT is a promising method to detect gene expression in and location of transplanted pancreatic cells in vivo.

Published

2008

383. [Regenerative cell therapy of the type I diabetes mellitus and its complications].

Author

Zakir'ianov AR, Onishchenko NA, Klimenko ED, and Pozdniakov OM

Subjects

Diabetes Complications prevention & control, Bone Marrow Transplantation methods, Diabetes Complications therapy, Diabetes Mellitus, Type 1 therapy, Insulin-Secreting Cells transplantation

Abstract

This review describes up-to-date concepts of the type I diabetes mellitus pathogenesis and its complications. The leading role of the immune system malfunction in pancreatic islet of Langerhans and in vessel wall regeneration impairment is emphasized. It is suggested, that cell therapy of the type I diabetes mellitus with pancreatic islet and bone marrow cell transplantation promote beta-cell regeneration due to normalization of intracellular interaction in these tissues and immune homeostasis in whole organism.

Published

2008

384. Isolating human islets of Langerhans causes loss of decay accelerating factor (CD55) on beta-cells.

Author

Tai JH, Sun H, Liu W, Melling CW, Hasilo C, and White DJ

Subjects

Animals, Cell Line, Gene Expression Regulation, Humans, Insulin-Secreting Cells physiology, Islets of Langerhans physiology, Kidney, RNA, Messenger genetics, Reverse Transcriptase Polymerase Chain Reaction, Swine, CD55 Antigens genetics, Insulin-Secreting Cells cytology, Insulin-Secreting Cells transplantation, Islets of Langerhans cytology

Abstract

It has previously been reported that human decay accelerating factor (DAF; CD55) is not expressed on cells isolated from human islets. We have investigated if this absence is caused by the islet isolation procedure and/or the single cell isolation technique. We focused on loss of DAF expression on beta-cells within the intact islet and on isolated individual beta-cells. We established that DAF was expressed in islets and on beta-cells prior to isolation by in situ analysis in the intact pancreas. In situ immunohistochemistry (IHC) was used to examine DAF expression on human pancreatic islets and isolated islets. A reverse transcriptase-polymerase chain reaction (RT-PCR) specific for human DAF mRNA was developed to measure mRNA levels in situ in islets within the intact pancreas, isolated islets, and purified beta-cells. beta-Cells were purified by fluorescence-activated cell sorting. DAF protein expression on these purified cells was measured using flow cytometry. Expression of DAF protein was present on the islets, including beta-cells within the human pancreas; however, comparative data from IHC and flow cytometry revealed the absence of DAF protein on beta-cells in both isolated islets and single cell preparations. Furthermore, compared to mRNA levels detected by in situ RT-PCR in the intact pancreas and in human HEK 293 cells, isolated islets, and purified human beta-cells showed downregulation of DAF mRNA. mRNA was detectable in both of these preparations by RT-PCR; levels were lower following both the islet isolation process (53%) and single cell preparation (a further 62%) compared to HEK 293 controls. Human islet allotransplantation might be more successful if either de novo transfer of DAF onto the isolated islets or novel techniques for islet isolation preserving DAF could be developed.

Published

2008

385. Cloning and characterization of recombinant rhesus macaque IL-10/Fc(ala-ala) fusion protein: a potential adjunct for tolerance induction strategies.

Author

Asiedu C, Guarcello V, Deckard L, Jargal U, Gansuvd B, Acosta EP, and Thomas JM

Subjects

Animals, Cell Line, Cloning, Molecular, Dose-Response Relationship, Drug, Graft Survival drug effects, Graft Survival immunology, Humans, Immunoglobulin Fc Fragments genetics, Immunoglobulin Fc Fragments immunology, Immunoglobulin G genetics, Immunoglobulin G immunology, Immunoglobulin G pharmacology, Insulin-Secreting Cells immunology, Insulin-Secreting Cells transplantation, Interleukin-10 genetics, Interleukin-10 immunology, Interleukin-10 pharmacokinetics, Lipopolysaccharides toxicity, Macaca mulatta, Mice, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins immunology, Recombinant Fusion Proteins pharmacokinetics, Shock, Septic chemically induced, Shock, Septic immunology, Swine, Transplantation, Heterologous, Cell Proliferation drug effects, Immunoglobulin Fc Fragments pharmacology, Interleukin-10 pharmacology, Mast Cells immunology, Recombinant Fusion Proteins pharmacology, Shock, Septic drug therapy, Transplantation Tolerance drug effects

Abstract

The powerful anti-inflammatory and immunosuppressive activities of IL-10 make it attractive for supplemental therapy in translational tolerance induction protocols. This is bolstered by reports of IL-10-mediated inhibition of innate immunity, association of human stem cell and nonhuman primate (NHP) islet allograft tolerance with elevated serum IL-10, and evidence that systemic IL-10 therapy enhanced pig islets survival in mice. IL-10 has not been examined as adjunctive immunosuppression in NHP. To enable such studies, we cloned and expressed rhesus macaque (RM) IL-10 fused to a mutated hinge region of human IgG1 Fc to generate IL-10/Fc(ala-ala). RM IL-10/Fc(ala-ala) was purified to approximately 98% homogeneity by affinity chromatography and shown to be endotoxin-free (<0.008 EU/microg protein). The biological activity of IL-10/Fc(ala-ala) was demonstrated by (1) costimulation of the mouse mast cell line, MC/9 proliferation in a dose-dependent fashion, (2) suppression of LPS-induced septic shock in mice and (3) abrogation of LPS-induced secretion of proinflammatory cytokines/chemokines in vitro and in vivo in NHP. Notably, RM IL-10/Fc(ala-ala) had significantly greater potency than human IL-10/Fc(ala-ala) and exhibited a circulating half-life of approximately 14 days. The availability of this reagent will facilitate definitive studies to determine whether supplemental therapy with RM IL-10/Fc(ala-ala) can influence tolerance outcomes in NHP.

Published

2007

386. Beta-cell replacement in immunosuppressed recipients: old and new clinical indications.

Author

Bertuzzi F and Ricordi C

Subjects

Algorithms, Diabetic Nephropathies surgery, Humans, Infusions, Parenteral, Kidney Transplantation, Waiting Lists, Diabetes Mellitus, Type 1 immunology, Diabetes Mellitus, Type 1 therapy, Immunosuppression Therapy, Insulin-Secreting Cells transplantation, Islets of Langerhans Transplantation methods

Abstract

Islet transplantation is an appealing procedure able to improve glycemic control in type 1 diabetic patients. However, the possible side effects that may be induced by immunosuppressive therapy limit its application to a select number of patients for whom the risk of immunosuppressants' side effects can be justified. For patients with type 1 diabetes mellitus-who will take immunosuppressants regardless, as they require a solid organ transplant-islet infusion can be an interesting therapeutic option for improving metabolic compensation, whenever pancreas transplant is not possible. Hence, islet infusion can be an important therapeutic option for patients with secondary diabetes mellitus even when a minor pancreatic endocrine function remains. For these patients, results may be better than those obtained with islet infusion for patients with type 1 diabetes mellitus thanks to the lack of autoimmune reaction to the infused islets. The final result is the improvement of the glycemic compensation and most likely also an extension of the graft survival.

Published

2007

387. Treatment of streptozotocin-induced diabetes mellitus in mice by intra-bone marrow bone marrow transplantation plus portal vein injection of beta cells induced from bone marrow cells.

Author

Li M, Inaba M, Guo KQ, Hisha H, Abraham NG, and Ikehara S

Subjects

Animals, Diabetes Mellitus, Experimental metabolism, Gene Expression Regulation, Humans, Insulin metabolism, Insulin-Secreting Cells metabolism, Mice, Mice, Inbred C3H, Portal Vein, Transplantation, Homologous, Bone Marrow Cells metabolism, Bone Marrow Transplantation, Diabetes Mellitus, Experimental therapy, Graft Survival, Insulin-Secreting Cells transplantation

Abstract

Curative therapy for diabetes mellitus mainly involves pancreas or islet transplantation to recruit insulin-producing cells. This approach is limited, however, because of both the shortage of donor organs and allograft rejection. Intra-bone marrow bone marrow transplantation (IBM-BMT) has recently been shown to be effective in inducing donor-specific tolerance in mice and rats without the use of immunosuppressants. After induction of diabetes in 15 C3H mice with streptozotocin, the mice received both allotransplants of bone marrow cells from C57BL/6 mice by IBM-BMT and injections via the portal vein of insulin-producing cells that were induced in vitro from stem cells derived from adult C57BL/6 bone marrow. We evaluated the expression of these cells by examining the expression of not only insulin but also the crucial transcription factors insulin I and insulin II. The diabetic mice were treated with IBM-BMT and precultured insulin-producing cells. Hyperglycemia was normalized by 5 days after the treatment and remained normal for more than 45 days. This strategy might be applicable to patients with type I diabetes mellitus.

Published

2007

388. Embryonic stem cell therapy for diabetes mellitus.

Author

Docherty K, Bernardo AS, and Vallier L

Subjects

Animals, Embryonic Stem Cells cytology, Humans, Insulin-Secreting Cells cytology, Insulin-Secreting Cells transplantation, Diabetes Mellitus therapy, Embryonic Stem Cells transplantation, Stem Cell Transplantation methods

Abstract

There is a compelling need to develop novel therapies for diabetes mellitus. Recent successes in the transplantation of islets of Langerhans are seen as a major breakthrough. However, there is huge disparity between potential recipients and the availability of donor tissue. Human embryonic stem cells induced to form pancreatic beta cells could provide a replenishable supply of tissue. Early studies on the spontaneous differentiation of mouse embryonic stem cells have laid the foundation for a more directed approach based on recapitulating the events that occur during the development of the pancreas in the mouse. A high yield of definitive endoderm has been achieved, and although beta-like cells can be generated in a step-wise manner, the efficiency is still low and the final product is not fully differentiated. Future challenges include generating fully functional islet cells under Xeno-free and chemically defined conditions and circumventing the need for immunosuppression.

Published

2007

389. The replication of beta cells in normal physiology, in disease and for therapy.

Author

Butler PC, Meier JJ, Butler AE, and Bhushan A

Subjects

Animals, Cell Differentiation physiology, Diabetes Mellitus, Type 1 pathology, Diabetes Mellitus, Type 1 physiopathology, Diabetes Mellitus, Type 1 surgery, Diabetes Mellitus, Type 2 physiopathology, Diabetes Mellitus, Type 2 surgery, Humans, Insulin-Secreting Cells physiology, Cell Division physiology, Diabetes Mellitus, Type 2 pathology, Insulin-Secreting Cells cytology, Insulin-Secreting Cells transplantation

Abstract

Replication of beta cells is an important source of beta-cell expansion in early childhood. The recent linkage of type 2 diabetes with several transcription factors involved in cell cycle regulation implies that growth of the beta-cell mass in early childhood might be an important determinant of risk for type 2 diabetes. Under some circumstances, including obesity and pregnancy, the beta-cell mass is adaptively increased in adult humans. The mechanisms by which this adaptive growth occurs and the relative contributions of beta-cell replication or of mechanisms independent of beta-cell replication are unknown. Also, although there is interest in the potential for beta-cell regeneration as a therapeutic approach in both type 1 and 2 diabetes, little is yet known about the potential sources of new beta cells in adult humans. In common with other cell types, replicating beta cells have an increased vulnerability to apoptosis, which is likely to limit the therapeutic value of inducing beta-cell replication in the proapoptotic environment of type 1 and 2 diabetes unless applied in conjunction with a strategy to suppress increased apoptosis.

Published

2007

390. Allogeneic bone marrow supports human islet beta cell survival and function over six months.

Author

Luo L, Badiavas E, Luo JZ, and Maizel A

Subjects

Cell Survival, Coculture Techniques, Humans, Insulin metabolism, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells transplantation, Islets of Langerhans anatomy & histology, Islets of Langerhans growth & development, Time Factors, Bone Marrow Cells physiology, Insulin-Secreting Cells cytology

Abstract

In this study, we have established a new strategy increasing human islet longevity utilizing allogeneic whole bone marrow (BM) co-cultured with human islets. The cultured islets' function and survival have been evaluated by analysis of insulin secretion in response to high-glucose-challenge, morphological evaluation of cell growth. Human islet only culture failed to reveal evidence of long term survival, growth or function in terms of insulin release or insulin response to glucose challenge. These results indicate that BM increases islet survival and function with the eventual formation of pancreatic endocrine tissue capable of sustaining beta cell fuction.

Published

2007

391. Screening for insulitis in adult autoantibody-positive organ donors.

Author

In't Veld P, Lievens D, De Grijse J, Ling Z, Van der Auwera B, Pipeleers-Marichal M, Gorus F, and Pipeleers D

Subjects

Adult, Biomarkers, Diabetes Mellitus, Type 1 epidemiology, Genetic Markers, Humans, Insulin Antibodies blood, Insulin Secretion, Insulin-Secreting Cells transplantation, Patient Selection, Tissue Banks, Autoantibodies blood, Diabetes Mellitus, Type 1 immunology, Insulin metabolism, Insulin-Secreting Cells immunology, Mass Screening, Pancreatic Diseases epidemiology, Tissue Donors statistics & numerical data

Abstract

Antibodies against islet cell antigens are used as predictive markers of type 1 diabetes, but it is unknown whether they reflect an ongoing autoimmune process in islet tissue. We investigated whether organs from adult donors that are positive for autoantibodies (aAbs) against islet cell antigens exhibit insulitis and/or a reduced beta-cell mass. Serum from 1,507 organ donors (age 25-60 years) was analyzed for islet cell antibodies (ICAs), glutamate decarboxylase aAbs (GADAs), insulinoma-associated protein 2 aAbs (IA-2As), and insulin aAbs. Tissue from the 62 aAb+ donors (4.1%) and from matched controls was examined for the presence of insulitis and for the relative area of insulin+ cells. Insulitis was detected in two cases; it was found in 3 and 9% of the islets and consisted of CD3+/CD8+ T-cells and CD68+ macrophages; in one case, it was associated with insulin+ cells that expressed the proliferation marker Ki67. Both subjects belonged to the subgroup of three donors with positivity for ICA, GADA, and IA-2-Ab and for the susceptible HLA-DQ genotype. Comparison of relative beta-cell area in aAb+ and aAb- donors did not show a significant difference. Insulitis was found in two of the three cases that presented at least three aAbs but in none of the other 59 antibody+ subjects or 62 matched controls. It was only detected in <10% of the islets, some of which presented signs of beta-cell proliferation. No decrease in beta-cell mass was detected in cases with insulitis or in the group of antibody+ subjects.

Published

2007

392. Beta cell transplantation and immunosuppression: can't live with it, can't live without it.

Author

Kaestner KH

Subjects

Animals, Humans, Insulin-Secreting Cells pathology, Regeneration, Diabetes Mellitus pathology, Diabetes Mellitus surgery, Immunosuppression Therapy, Insulin-Secreting Cells transplantation

Abstract

Since the first diabetic was treated with insulin in 1922, millions of patients have relied on frequent insulin injections and glucose monitoring to combat the disease and its complications. Improved immunosuppressive regimens in islet transplantation developed in the Edmonton protocol raised the hopes of diabetics worldwide for a complete cure and insulin independence. However, transplant success has proven to be short-lived and accompanied by significant side effects. Using a clever genetic model for conditional ablation of pancreatic beta cells in vivo, Nir and colleagues show in this issue of the JCI that the immunosuppressant drugs clinically inhibit beta cell proliferation in the diabetic setting (see the related article beginning on page 2553). They also demonstrate that beta cells have a remarkable regenerative capacity and that normal beta cell mass can recover even in the setting of hyperglycemia. Their new mouse model should aid in the development of improved immunoregulatory strategies and in the elucidation of the molecular pathways that govern beta cell regeneration.

Published

2007

393. The rational design of beta cell cytoprotective gene transfer strategies: targeting deleterious iNOS expression.

Author

McCabe C and O'Brien T

Subjects

Adenoviridae genetics, Animals, Cell Line, Cell Line, Tumor, Diabetes Mellitus, Type 1 therapy, Genetic Vectors genetics, Green Fluorescent Proteins analysis, Green Fluorescent Proteins genetics, Humans, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells transplantation, Interleukin-1beta pharmacology, Lentivirus genetics, NF-KappaB Inhibitor alpha, Rats, Cytoprotection, Gene Transfer Techniques, I-kappa B Proteins genetics, Insulin-Secreting Cells enzymology, Nitric Oxide Synthase Type II antagonists & inhibitors

Abstract

Islet transplantation represents a promising therapeutic strategy for the treatment of type 1 diabetes mellitus (T1DM) [Hakim and Papalois (Ann Ital Chir 75:1-7, 2004); Jaeckel et al. (Internist (Berl) 45:1268-1280, 2004); Sutherland et al. (Transplant Proc 36:1697-1699, 2004)]. The insulin-secreting pancreatic beta cells of the islet allograft are, however, subject to recurrent immune-mediated damage. Principal among the molecular culprits involved in this destructive process is the proinflammatory cytokine IL-1beta. IL-1beta-induced beta cell destruction may be mediated by the generation of NO and/or ROS, although the relative importance of NO and ROS in this process remains unclear. This study broadly encompassed three arms of investigation: the first of these was geared toward the establishment of a robust in vitro cell system for the study of IL-1beta-induced pathophysiology; the second arm aimed to provide a comparative analysis of the gene transfer profiles of the three most commonly used gene transfer vehicles, namely plasmid vectors, adenoviral vectors, and lentiviral vectors, in the aforementioned cell system; the final arm aimed to screen an array of potentially cytoprotective gene transfer strategies incorporating the optimal gene transfer vectors. Briefly, we established an in vitro beta cell system that accurately reflected primary beta cell cytokine-induced pathophysiology. That is, IL-1beta exposure (100 U/ml) induced a time-dependent decrease in rat insulinoma (RIN) cell viability, which coincided with an induction in iNOS expression and nitrite accumulation. Gene transfer studies using plasmid, adenoviral, or lentiviral vectors underscored the superiority of viral vector-based gene transfer strategies for the manipulation of this beta cell line. Using these vectors, we provide evidence that NF-kappaB-based iNOS inhibition confers significant protection against IL-1beta-induced damage whereas antioxidant overexpression fails to provide protection. Conferred cytoprotection was associated with a suppression of iNOS expression and nitrite accumulation. From a therapeutic standpoint, gene transfer strategies employing efficient viral vectors to target iNOS activation may harbour therapeutic potential in preserving beta cell survival against proinflammatory cytokine exposure.

Published

2007

394. Evidence for allograft rejection in an islet transplant recipient and effect on beta-cell secretory capacity.

Author

Rickels MR, Kamoun M, Kearns J, Markmann JF, and Naji A

Subjects

Adult, Antibody Specificity, Arginine, Diabetes Mellitus, Type 1 immunology, Diabetes Mellitus, Type 1 metabolism, Female, Glucose, Graft Rejection metabolism, HLA Antigens immunology, Histocompatibility Testing, Humans, Insulin-Secreting Cells immunology, Postoperative Complications, Tissue Donors, Transplantation, Homologous, Diabetes Mellitus, Type 1 therapy, Graft Rejection immunology, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells transplantation, Islets of Langerhans Transplantation immunology

Abstract

Context: The majority of islet transplant recipients experience a gradual decline in islet graft function, but the identification of islet-specific immune responses remains uncommon., Objectives: The aim was to present a case in which decline in islet graft function was accompanied by the appearance of islet donor-specific alloantibodies and demonstrate the effect on beta-cell secretory capacity, an estimate of functional beta-cell mass., Setting: The study was conducted at the Transplant Center and General Clinical Research Center of the University of Pennsylvania., Results: A 42-yr-old woman with type 1 diabetes who had a living-related kidney transplant received two intraportal islet infusions of a total 17,525 islet equivalents per kg body weight under daclizumab, prednisone, tacrolimus, and rapamycin immunosuppression. She became insulin independent, but 4 months later, the rapamycin was discontinued for associated colitis. She remained normoglycemic for another 6 months before manifesting impaired fasting glucose and requiring 5-10 U insulin daily. The decline in clinical islet graft function coincided with the detection of islet donor-specific human leukocyte antigen class I antibodies. Beta-cell function and secretory capacity were assessed by the insulin secretory responses to iv glucose, arginine (AIR(arg)), and glucose-potentiated arginine (AIR(pot)) before and at alloantibody detection. The acute insulin response to glucose was almost entirely lost, whereas the AIR(arg) and AIR(pot) both decreased by approximately 50%., Conclusions: Because the AIR(pot), a measure of beta-cell secretory capacity, provides an estimate of functional beta-cell mass, this case documents that islet graft loss can coincide with donor human leukocyte antigen sensitization and that the effect on beta-cell mass may be best estimated from the AIR(arg) or AIR(pot).

Published

2007

395. Stem/Progenitor cell sources of insulin-producing cells for the treatment of diabetes.

Author

Lock LT and Tzanakakis ES

Subjects

Animals, Humans, Diabetes Mellitus therapy, Insulin-Secreting Cells transplantation, Stem Cell Transplantation

Abstract

Patients with diabetes experience decreased insulin secretion that is linked to a significant reduction in the number of islet cells. Reversal of diabetes can be achieved through islet transplantation, but the scarcity of donor islets severely hinders wide application of this therapeutic modality. Toward that end, embryonic stem cells, adult tissue-residing progenitor cells, and regenerating native beta-cells may serve as sources of islet cell surrogates. Insulin-producing cells generated from stem or progenitor cells display subsets of native beta-cell attributes, indicating the need for further development of methods for differentiation to completely functional beta-cells. Pharmacological approaches aiming at stimulating the in vivo/ex vivo regeneration of beta-cells have also been proposed as a way of augmenting islet cell mass. We review the current state of the generation of insulin-producing cells from different sources with emphasis on embryonic stem cells and adult progenitor cells. Challenges for the clinical use of these sources are also discussed.

Published

2007

396. Differentiation of affinity-purified human pancreatic duct cells to beta-cells.

Author

Yatoh S, Dodge R, Akashi T, Omer A, Sharma A, Weir GC, and Bonner-Weir S

Subjects

Adult, CA-19-9 Antigen, Cell Differentiation, Humans, Insulin-Secreting Cells cytology, Insulin-Secreting Cells transplantation, Pancreatic Ducts cytology, Insulin-Secreting Cells physiology, Pancreatic Ducts physiology, Stem Cells physiology

Abstract

To test whether pancreatic duct cells are in vitro progenitors, they were purified from dispersed islet-depleted human pancreatic tissue using CA19-9 antibody. The purified fraction was almost entirely CK19+ with no insulin+ cells, whereas the unpurified cells (crude duct) were 56% CK19+ and 0.4% insulin+ of total cells (0.7% of CK19+ cells). These cells were expanded as monolayers, aggregated under serum-free conditions, and transplanted into normoglycemic NOD/SCID mice. In crude duct grafts, insulin+ cells increased to 6.1% of CK19+ cells. Purified duct cells had slow expansion and poor aggregation, as well as engraftment. The addition of 0.1% cultured stromal cells improved these parameters. These stromal cells contained no CK19+ cells and no insulin by either quantitative RT-PCR or immunohistochemistry; stromal cell aggregates and grafts contained no insulin+ cells. Aggregation of purified duct plus stromal preparations induced insulin+ cells (0.1% of CK19+ cells), with further increase to 1.1% in grafts. Insulin mRNA mirrored these changes. In these grafts, all insulin+ cells were in duct-like structures, while in crude duct grafts, 85% were. Some insulin+ cells coexpressed duct markers (CK19 and CA19-9) and heat shock protein (HSP)27, a marker of nonislet cells, suggesting the transition from duct. Thus, purified duct cells from adult human pancreas can differentiate to insulin-producing cells.

Published

2007

397. Differentiation of transplanted microencapsulated fetal pancreatic cells.

Author

Foster JL, Williams G, Williams LJ, and Tuch BE

Subjects

Alginates, Animals, Blood Glucose metabolism, Capsules, Cell Aggregation, Cell Survival, Diabetes Mellitus, Experimental blood, Diabetes Mellitus, Experimental metabolism, Fluorescent Antibody Technique, Glucagon metabolism, Glucose pharmacology, Glucuronic Acid, Hexuronic Acids, Insulin metabolism, Insulin Secretion, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Islets of Langerhans embryology, Islets of Langerhans metabolism, Islets of Langerhans pathology, Male, Mice, Mice, SCID, Pancreas metabolism, Staining and Labeling, Time Factors, Cell Differentiation, Diabetes Mellitus, Experimental pathology, Diabetes Mellitus, Experimental surgery, Fetal Tissue Transplantation methods, Insulin-Secreting Cells pathology, Insulin-Secreting Cells transplantation

Abstract

Background: Fetal beta cells are a potential form of cell therapy for type 1 diabetes. To protect transplanted cells from cellular immune attack, microencapsulation using barium alginate can be employed. Whether microencapsulated fetal pancreatic cells will differentiate as occurs with nonencapsulated fetal pancreatic cells is presently unknown. It is suggested that such differentiation would occur in encapsulated cells, similar to previous experiments conducted using encapsulated embryonic stem cells., Methods: Streptozotocin-induced diabetic severe combined immunodeficient mice were transplanted with 5,000 to 38,000 fetal pig islet-like cell clusters (ICCs) within barium alginate microcapsules of diameter 300, 600, or 1000 microm. Viability, insulin secretion, and content of encapsulated cells were measured prior to transplantation. Blood glucose levels (BGL) were measured twice weekly and porcine C-peptide monthly. Encapsulated cells were recovered from mice at 6 months posttransplantation for analysis., Results: Encapsulated cells became glucose responsive and normalized BGL within 13 to 68 days posttransplantation, with 5,000 to 10,000 ICCs required. Microcapsule diameter did not affect the time required to achieve normoglycemia. BGL remained normal for the 6-month duration of the experiments. After removal of grafts at 25 weeks posttransplantation, glucose stimulated insulin secretion of the explants was enhanced 96-fold, insulin content was enhanced 34-fold, and the percentage of insulin and glucagon positive cells increased 10-fold and threefold, respectively, from the time of transplantation., Conclusions: This study demonstrates that fetal pancreatic cells differentiate and function normally when placed within barium alginate microcapsules and transplanted.

Published

2007

398. Placenta-derived multipotent stem cells induced to differentiate into insulin-positive cells.

Author

Chang CM, Kao CL, Chang YL, Yang MJ, Chen YC, Sung BL, Tsai TH, Chao KC, Chiou SH, and Ku HH

Subjects

Animals, Cell Culture Techniques methods, Cell Differentiation, Cells, Cultured, Diabetes Mellitus pathology, Female, Humans, Mice, Mice, Nude, Mice, SCID, Treatment Outcome, Diabetes Mellitus surgery, Insulin-Secreting Cells cytology, Insulin-Secreting Cells transplantation, Multipotent Stem Cells cytology, Multipotent Stem Cells transplantation, Placenta cytology, Tissue Engineering methods

Abstract

In the present study, we successfully isolated PDMSCs from human placental tissues. The RT-PCR results show that PDMSCs preserved the genetic characteristics of the primitive embryonic stage--Oct-4 and Nanog. By using serum-free medium supplemented essential growth factors and induction medium culture for 4 weeks, a monolayer of spindle-like PDMSCs gradually formed 3D spheroid bodies (SB-PDMSCs). By using real-time RT-PCR, early mRNA expressions of Pdx1, as well as the Sox17 and Foxa2 genes, were observed to be significantly activated in SB-PDMSCs, followed by the expression of mature pancreas-related genes (insulin, glucagon, and somatostatin). The high insulin content of SB-PDMSCs was further confirmed by ELISA assay, and the glucose dependency was demonstrated by the corresponding insulin secretion level. In a transplantation study of streptozotocin-pretreated nude mice, the restoration of normoglycemia in the SB-PDMSC treated group was further observed. In conclusion, these results indicate that PDMSCs are an excellent source for the induced differentiation of well-functioning insulin-positive cells. The potential of these insulin producing cells derived from PDMSCs was also demonstrated functionally by the demonstration of secreted insulin in vitro and effective control of blood glucose levels in vivo.

Published

2007

399. Critics slam Russian trial to test pig pancreas for diabetics.

Author

Grose S

Subjects

Animals, Humans, Sus scrofa, Diabetes Mellitus therapy, Insulin-Secreting Cells transplantation, Transplantation, Heterologous ethics

Published

2007

400. The genetic programme of pancreatic beta-cells: basic science for the development of beta-cell therapy. Workshop on programming pancreatic beta-cells.

Author

Grapin-Botton A, Heimberg H, and Lemaigre F

Subjects

Animals, Embryonic Stem Cells cytology, Embryonic Stem Cells physiology, Humans, Insulin-Secreting Cells transplantation, Mice, Pancreas cytology, Pancreas growth & development, Regeneration, Signal Transduction, Cell Differentiation genetics, Insulin-Secreting Cells cytology, Insulin-Secreting Cells metabolism, Islets of Langerhans Transplantation methods, Transcription Factors metabolism

Published

2007