Generation of islet-like hormone-producing cells in vitro from adult human pancreas

Transplantation of pancreatic islets can provide long-lasting insulin independence for diabetic patients, but the current islet supply is limited. Here we describe a new in vitro system that utilizes adult human pancreatic islet-enriched fractions to generate hormone-producing cells over 3-4 weeks of culture. By labeling proliferating cells with a retrovirus-expressing green fluorescent protein, we show that in this system hormone-producing cells are generated de novo. These hormone-producing cells aggregate to form islet-like cell clusters. The cell clusters, when tested in vitro, release insulin in response to glucose and other secretagogues. After transplantation into immunodeficient, nondiabetic mice, the islet-like cell clusters survive and release human insulin. We propose that this system will be useful as an experimental tool for investigating mechanisms for generating new islet cells from the postnatal pancreas, and for designing strategies to generate physiologically competent pancreatic islet cells ex vivo.     

Differentiation of transplanted microencapsulated fetal pancreatic cells

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.     

从人胚胎胰腺中分离获得巢蛋白表达阳性的细胞

目的 探讨从人胚胎胰腺组织分离巢蛋白（Nestin)阳性细胞并进行体外传代培养的方法。方法 取引产的16、18、20周人胚胎胰腺组织，分离胰岛样细胞簇（Ialet-like cell clusters,ICCs），进行体外培养。用免疫组织化学和逆转录-聚合酶链反应（RT-PCR）方法检测巢蛋白、胰十二指肠同源盒基因-1（Pancreatic and duodenal bomeobox gene-1,PDX-1/IPF-1)以及胰岛内分泌激素胰岛素和胰升糖素（Glucagon)的表达。结果 ICCs经体外培养可获得巢蛋白表达阳性细胞，这种细胞可进一步形成球状细胞簇，除有巢蛋白阳性细胞外，还有PDX-1，胰岛素和胰升糖素表达阳性的细胞。并且细胞可连续传代，结论 从人胚胎胰腺组织中可分离获得巢蛋白表达阳性细胞，这种细胞可在体外增殖并有向胰岛内分泌细胞分化的能力。     

糖尿病小鼠胰腺干细胞转分化为胰岛样细胞

目的 观察链脲佐菌素所致糖尿病小鼠胰腺干细胞是否能转分化为胰岛样细胞.方法 以链脲佐菌素建立糖尿病小鼠模型,分离培养其胰腺导管上皮细胞,经体外扩增及诱导培养后,以细胞免疫化学方法检测PDX1表达,行STZ染色和葡萄糖刺激的胰岛素释放试验鉴定其功能.结果 糖尿病小鼠胰腺干细胞经体外培养和诱导分化后,PDX1阳性,并形成胰岛样细胞团;胰岛样细胞对高糖刺激(15.0 mmol/L)的胰岛素释放较低糖(5.6 mmol/L)时增加了1.4倍(37.2±11.2比25.9±7.6,t =2.830,P＜0.05),DTZ染色阳性.结论 链脲佐菌素所致糖尿病小鼠胰腺干细胞在体外培养条件下可转分化为胰岛素分泌细胞.     

Characterization of endocrine progenitor cells and critical factors for their differentiation in human adult pancreatic cell culture

We have reproduced a previously described method for the in vitro generation of endocrine cells in adult human pancreatic tissue culture. The aim of this study was to characterize the nature of pancreatic progenitor cells and to identify the factors necessary for their differentiation in this model. During monolayer expansion, two types of cells proliferated sequentially; first cytokeratin 19 (CK19)-positive ductal epithelial cells and then nestin-positive fibroblastoid cells. After the bromodeoxyuridine-labeled cells were traced in differentiated islet buds, some of the proliferating ductal cells had differentiated into endocrine cells, whereas nestin-positive cells could not give rise to endocrine tissue. Serum-free culture was found to be an absolute requirement for the endocrine differentiation to occur. Also, overlay of the cells with Matrigel was essential, whereas nicotinamide had a potentiating effect. The in vitro-generated islet buds released insulin in response to glucose nearly as efficiently as native islets. When transplanted under the kidney capsule of nude mice, only one of five grafts demonstrated further growth with foci of both endocrine and exocrine differentiation. Our results support the previous notion that pancreatic progenitor cells represent a subpopulation of ductal epithelial cells. No evidence was found for the development of endocrine cells from nestin-positive stem cells.     

Tissue culture of human fetal pancreas. Development and function of B-cells in vitro and transplantation of explants to nude mice

The present study evaluates the development and function of human fetal B-cells in vitro with a view to using such cells in future attempts for transplantation of human fetal pancreas to diabetic patients. A method previously described in our laboratory for preparing islets in vitro from the fetal rat pancreas has been applied and modified for use with human fetal pancreas. Pancreatic glands of different gestational ages were obtained from 37 consecutive prostaglandin-induced abortions. After a mild collagenase treatment, the partially disintegrated tissue was maintained in culture for 7 days in tissue culture medium RPMI 1640 plus 20% fetal calf serum to permit cell attachment and out-growth of endocrine cells. In 17 of the 37 consecutively cultured fetal pancreatic glands, islet-like cell clusters were formed. The 20 remaining glands were lost because of either bacterial contamination or lack of viability already before dissection had occurred. Sections of the newly formed cell clusters revealed well-preserved pancreatic cells showing frequent mitotic figures. The tissue exhibited a high rate of (pro)insulin biosynthesis and a modest insulin response to secretory stimuli, suggesting that the mechanism of glucose regulation by the fetal B-cells is not yet fully developed. Electron micrographs showed a large number of granule-containing cells, some of which were identified as B-cells. In nine cases, harvested cell clusters were implanted beneath the kidney capsule of nude mice. When these animals were killed after 2 mo, seven mice showed a considerable growth of the grafts with numerous islet-like structures containing insulin- and glucagon-positive cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Production and characterization of fetal sheep pancreatic islet-like cell clusters

Explants of fetal sheep pancreas transplanted into diabetic athymic mice survive for many months but there is only partial differentiation of the endocrine cells. As an alternative form of graft we examined the possibility of creating islet-like cell clusters (ICCs) by collagenase digestion of the fetal sheep pancreas, as has been described for human and porcine fetal pancreas. Such ICCs did form at the rate of 6–23 per 10 mg pancreas; their size varied between 65 and 474 μm (median 232 μm) and their insulin content was 1.6 ± 0.2 mU per 20 ICCs. Laser scanning confocal analysis showed that 4.6 ∓ 0.7% of the cells contained insulin. Insulin was secreted from ICCs maintained in culture at the daily rate of 2.5 mU per 30 ICCs. Arginine but not glucose or theophylline enhanced acute insulin secretion in vitro. Transplantation of up to 1000 ICCs into athymic and scid mice resulted in sparse growth of the epithelialike cells in the graft and only partial differentiation of the endocrine cells. Hyperglycaemia in diabetic recipients was not normalized. Thus, while functioning ICCs can be created from fetal sheep pancreas, they do not appear to be appropriate for transplantation to reverse diabetes in mice.     

Combination therapy with glucagon-like peptide-1 and gastrin induces beta-cell neogenesis from pancreatic duct cells in human islets transplanted in immunodeficient diabetic mice

Pancreatic islet transplantation as a treatment for type 1 diabetes is limited by human donor tissue availability. We investigated whether the beta-cell mass in human isolated islets could be expanded by treatments with glucagon-like peptide-1 (GLP-1) and gastrin, peptides reported to stimulate beta-cell growth in mice and rats with deficits in beta-cell mass. Human islets with low endocrine cell purity (7% beta-cells, 4% alpha-cells) and abundant exocrine cells (29% duct cells and 25% acinar cells) were implanted under the renal capsule of nonobese diabetic-severe combined immune deficiency (NOD-scid) mice made diabetic with streptozotocin. The mice were treated with GLP-1 and gastrin, separately and together, daily for 5 weeks. Blood glucose was significantly reduced only in mice implanted with human pancreatic cells and treated with GLP-1 plus gastrin. Correction of hyperglycemia was accompanied by increased insulin content in the human pancreatic cell grafts as well as by increased plasma levels of human C-peptide in the mice. Immunocytochemical examination revealed a fourfold increase in insulin-positive cells in the human pancreatic cell grafts in GLP-1 plus gastrin-treated mice, and most of this increase was accounted for by the appearance of cytokeratin 19-positive pancreatic duct cells expressing insulin. We conclude that combination therapy with GLP-1 and gastrin expands the beta-cell mass in human islets implanted in immunodeficient diabetic mice, largely from pancreatic duct cells associated with the islets, and this is sufficient to ameliorate hyperglycemia in the mice.     

Normal relationship of beta- and non-beta-cells not needed for successful islet transplantation

Islets are composed mostly of beta-cells, and therefore stem cell research has concentrated on generating purified beta-cells, neglecting the other endocrine cell types in the islet. We investigated the presence of endocrine non-beta-cells after islet transplantation. In addition, we studied whether the transplantation of pure beta-cells, in volumes similar to that used in islet transplantation, would suffice to reverse hyperglycemia in diabetic mice. Rat islets were dispersed and beta-cells were purified by fluorescence-activated cell sorting according to their endogenous fluorescence. After reaggregation, 600 islet equivalents of the purified beta-cell aggregates were implanted into diabetic SCID mice. In mice implanted with beta-cell-enriched aggregates, the hyperglycemia was reversed and good graft function over a 12-week period was observed with regard to glucose and insulin levels, glucose tolerance tests, and graft insulin content. The endocrine cell composition of the beta-cell-enriched aggregates remained constant; before and 12 weeks after transplantation, the beta-cell-enriched aggregates comprised 95% beta-cells and 5% endocrine non-beta-cells. However, islet grafts, despite originally having comprised 75% beta-cells and 25% endocrine non-beta-cells, comprised just 5% endocrine non-beta-cells after transplantation, indicating a loss of these cells. beta-Cell-enriched aggregates can effectively reverse hyperglycemia in mice, and transplanted intact islets are depleted in non-beta-cells. It is therefore likely that islet non-beta-cells are not essential for successful islet transplantation.     

Cell therapy for diabetes using piscine islet tissue

The islet tissue, called Brockmann bodies, in certain teleost fish is anatomically distinct from the pancreatic exocrine tissue and can be easily identified macroscopically. Expensive islet isolation procedures, such as required when procuring islet tissue from mammalian pancreases, are unnecessary. Tilapia islets transplanted into diabetic athymic nude mice will produce long-term normoglycemia and mammalian-like glucose tolerance profiles. Encapsulated tilapia islets function well after transplantation into euthymic recipients. Additionally, tilapia are potentially ideal xenogeneic donors because of markedly lower donor production costs, minimal islet procurement costs, and possibly decreased xenozoonotic potential relative to mammalian donors. Tilapia islets appear to be appropriately glucose responsive with high insulin output, can be cryopreserved, and are much more resistant to hypoxia than mammalian islets. Because tilapia and human insulin differ by 17 amino acids, we have cloned, sequenced, and modified the tilapia insulin gene by site-directed mutagenesis resulting in a tilapia insulin gene that codes for "humanized" insulin while still maintaining all of the tilapia regulatory (noncoding) sequences. We have now produced small numbers of founder transgenic tilapia with incorporation of our humanized tilapia insulin gene construct, and we have shown transmission and expression of the transgene in the beta cells and serum of their Fl offspring. Our ultimate goal is to achieve homologous recombination and to breed for homozygosity for the hybrid insulin gene. Subsequent generations of transgenic tilapia will undergo a program of genomic optimization selecting for growth, survival, and fecundity as well as stability of the transgene. Islets from the resulting transgenic fish, after extensive characterization, could be harvested, encapsulated, and then transplanted into diabetic patients.     

Limited capacity of human adult islets expanded in vitro to redifferentiate into insulin-producing beta-cells

Limited organ availability is an obstacle to the widespread use of islet transplantation in type 1 diabetic patients. To address this problem, many studies have explored methods for expanding functional human islets in vitro for diabetes cell therapy. We previously showed that islet cells replicate after monolayer formation under the influence of hepatocyte growth factor and selected extracellular matrices. However, under these conditions, senescence and loss of insulin expression occur after >15 doublings. In contrast, other groups have reported that islet cells expanded in monolayers for months progressed through a reversible epithelial-to-mesenchymal transition, and that on removal of serum from the cultures, islet-like structures producing insulin were formed (1). The aim of the current study was to compare the two methods for islet expansion using immunostaining, real-time quantitative PCR, and microarrays at the following time points: on arrival, after monolayer expansion, and after 1 week in serum-free media. At this time, cell aliquots were grafted into nude mice to study in vivo function. The two methods showed similar results in islet cell expansion. Attempts at cell differentiation after expansion by both methods failed to consistently recover a beta-cell phenotype. Redifferentiation of beta-cells after expansion is still a challenge in need of a solution.     

Subcutaneous transplantation of macroencapsulated porcine pancreatic endocrine cells normalizes hyperglycemia in diabetic mice

BACKGROUND: The ultimate goal of islet transplantation is the unlimited availability of insulin-secreting cells to be transplanted in a simple procedure that requires no use of immunosuppressive drugs. Immunoisolation of xenogeneic pig islets for transplantation has great potential therapeutic benefits for treatment of diabetes. METHODS: Approximately 4 x 10(6) porcine pancreatic endocrine cells (PEC) isolated from 6-month-old pigs were macroencapsulated in agarose-poly(styrene sulfonic acid) mixed gel and implanted into a prevascularized subcutaneous site in streptozotocin-induced C57BL/6 diabetic mice. Animals receiving an equal number of free porcine PEC were used as controls. After transplantation, nonfasting blood glucose, body weight, intraperitoneal glucose tolerance test, and immunohistologic evaluations were processed. RESULTS: All 10 animals receiving the subcutaneous xenografts of the macroencapsulated porcine PEC normalized hyperglycemia within 5 days after transplantation, maintained the duration of normoglycemia for 24 to 76 days, and gradually gained weight. The subcutaneous xenografts of free porcine PEC could not reverse hyperglycemia. The recipient became hyperglycemic again when the implanted graft was retrieved at day 45 after transplantation. The glucose clearances were significantly ameliorated at day 21 and day 45 after transplantation when compared with those in diabetic mice. The immunohistochemical results revealed an inherent intact structure of the macroencapsulated porcine PEC and positive double-immunofluorescence staining for insulin and glucagon. CONCLUSIONS: Subcutaneous transplantation of macroencapsulated porcine PEC normalized hyperglycemia in diabetic mice. Our results identified a potential for a favorable development of subcutaneous transplantation of porcine PEC as a cure for diabetes.     

Influence of VEGF on the viability of encapsulated pancreatic rat islets after transplantation in diabetic mice

After pancreatic islet transplantation, insufficient blood supply is responsible for the loss of islet viability. The aim of our study was: 1) to determine the influence of vascular endothelial growth factor (VEGF) on the survival of encapsulated rat islets transplanted into healthy and diabetic mice and 2) to evaluate the metabolic efficiency of the VEGF-supplemented grafts. Twenty-four hours after culture, 50 rat islets immobilized into collagen in the presence of VEGF (100 ng/ml) and encapsulated (AN69 membrane, HOSPAL) were grafted in the peritoneal cavity of healthy or streptozotocin-induced diabetic mice (n = 6). Seven, 14, and 28 days after implantation, the encapsulation device and tissue surrounding the device were removed and the following parameters were analyzed: the number and the diameter of buds, the distance between devices and buds, the amount of cellular adhesion on the capsule surface, and the level of insulin secreted by encapsulated islet. For reversal of diabetes, 1000 rat islets encapsulated in the presence of VEGF were implanted in the peritoneal cavity of diabetic mice and fasting glycemia was analyzed. After 7 days of islet implantation in the absence of VEGF, the bud diameter was 16.1 +/- 6.9 microm in diabetic mice and 34.4 +/- 3.9 microm in healthy mice. However, the number of buds increased by a factor 2.5 in the presence of VEGF in both types of mice. Furthermore, when islets were transplanted in the presence of VEGF, the distance between the device and the buds was significantly decreased in both types of mice (p < 0.001) after 7, 14, and 28 days of islet implantation. Capsule analysis showed a decrease in cellular adhesion when the islets were encapsulated in the presence of VEGF. Insulin secretion of the islets was higher in the presence of VEGF compared with islets alone at all steps of the study. When 1000 rat islets were transplanted in the presence of VEGF, the glycemia level decreased to 6.2 +/- 0.8 mmol/L after 3 days and remained stable until at least 28 days. In contrast, in the absence of VEGF, the initial decrease in the glucose level was rapidly followed by a relapse in hyperglycemia. In summary, VEGF increased the viability of engrafted encapsulated islets, increasing the duration of a normalized glycemia in diabetic mice following transplantation. Local adjunction of VEGF may therefore improve the clinical outcome of islet transplantation.     

Co-encapsulation of Sertoli enriched testicular cell fractions further prolongs fish-to-mouse islet xenograft survival

BACKGROUND: We previously demonstrated that alginate microencapsulation can prolong fish (tilapia) islet xenograft survival in diabetic animals. However, at present, microencapsulation does not provide complete immune protection to discordant islet xenografts, and long-term graft survival requires supplemental low-dose systemic immunosuppression. In the present study, fish islets were co-encapsulated with Sertoli enriched testicular cell fractions to find out whether this would further prolong fish islet graft survival in diabetic mice. METHODS: Sertoli enriched testicular cell fractions were enzymatically harvested from adult Balb/c or Wistar-Furth rats. They were cultured and co-encapsulated with fragmented tilapia islets in alginate microcapsules. Encapsulated islets alone or islets co-encapsulated with Sertoli cells were then intraperitoneally transplanted into streptozotocin-diabetic Balb/c mice, and graft survival times were compared. Encapsulated and co-encapsulated islet function was also confirmed in streptozotocin-diabetic athymic nude mice. RESULTS: Co-encapsulation with Sertoli enriched testicular cell fractions further prolonged mean fish islet graft survival time from 21+/-6.7 days (encapsulated islet cells alone) to >46+/-6.3 days (co-encapsulated with syngeneic murine Sertoli cells), without additional systemic immunosuppression. Testicular cells harvested from xenogeneic Wistar-Furth rats produced similar protective results (>46+/-10.9 days). CONCLUSIONS: Our results support the theory that Sertoli cells produce local immunosuppressive factors. These factors supplement the immune protective feature of alginate microcapsules in our model. Testicular cell fractions may be an important naturally occurring facilitator in the development of new microencapsulation systems for islet xenotransplantation.     

微囊化大鼠胰岛异种移植治疗小鼠实验性糖尿病的研究

目的 研究海藻酸钠－聚赖氨酸－海藻酸钠包裹胰岛进行移植的效果。方法 将Ｗｉｓｔａｒ大鼠的胰腺先行胶原酶胰管内注射消化,然后分离,纯化,所得胰岛经培养后制成微囊包膜的胰岛,微囊直径为０．４￣０．５ｍｍ,每个微囊内包１个胰岛。     

High glucose is necessary for complete maturation of Pdx1-VP16-expressing hepatic cells into functional insulin-producing cells

Pdx1 has been shown to convert hepatocytes into both exocrine and endocrine pancreatic cells in mice, but it fails to selectively convert hepatocytes into pure insulin-producing cells (IPCs). The molecular mechanisms underlying the transdifferentiation remain unclear. In this study, we generated a stably transfected rat hepatic cell line named WB-1 that expresses an active form of Pdx1 along with a reporter gene, RIP-eGFP. Our results demonstrate that Pdx1 induces the expression of multiple genes related to endocrine pancreas development and islet function in these liver cells. We do not however find any expression of the late-stage genes (Pax4, Pax6, Isl-1, and MafA) related to beta-cell development, and the cells do not secrete insulin upon the glucose challenge. Yet when WB-1 cells are transplanted into diabetic NOD-scid mice, these genes become activated and hyperglycemia is completely reversed. Detailed comparison of gene expression profiles between pre- and posttransplanted WB-1 cells demonstrates that the WB-1 cells have similar properties as that seen in pancreatic beta-cells. In addition, in vitro culture in high-glucose medium is sufficient to induce complete maturation of WB-1 cells into functional IPCs. In summary, we find that Pdx1-VP16 is able to selectively convert hepatic cells into pancreatic endocrine precursor cells. However, complete transdifferentiation into functional IPCs requires additional external factors, including high glucose or hyperglycemia. Thus, transdifferentiation of hepatocytes into functional IPCs may serve as a viable therapeutic option for patients with type 1 diabetes.     

Comparison of fetal porcine aggregates of purified beta-cells versus islet-like cell clusters as a treatment of diabetes

Fetal pig islet-like cell clusters (ICCs) have the potential to reverse diabetes 1-5 months after transplantation. In a fetal ICC, however, beta-cells constitute only 6-8% of the cells, in contrast to 65% in an adult pig islet. Attempts to purify fetal beta-cells from cell clusters and compare their function to that of ICCs have not been shown previously. Beta-cells were purified from ICCs isolated from the fetal pig pancreas. These were then aggregated and maintained in culture for 3 days. ICCs were isolated from fetal pig pancreas and allowed to round up in culture for 3 days. Transplantation of aggregates and ICCs (10,000 and 12,600, respectively) into diabetic immunoincompetent mice resulted in normoglycemia at 18 +/- 2 and 8 +/- 1 weeks, respectively (p = 0.0006). Removal of grafts after normalization of blood glucose levels resulted in rapid return of hyperglycemia in both groups. In conclusion, a purified population of immature beta-cells can be produced from the fetal pig pancreas. The reason these cells take longer than ICCs to reverse diabetes when transplanted is postulated to be because of the relative lack of precursor cells from which beta-cells differentiate. This finding may have implications for stem cell therapy, as other cell types, other than purified beta-cells, may be necessary for appropriate function in vivo.     

Short-term culture of adult pancreatic fragments for purification and transplantation of islets of Langerhans.

Minced adult human, rat, and dog pancreatic fragments were cultured under various conditions in an attempt to selectively purify pancreatic islet tissue from exocrine digestive enzymes. Islet purification was assessed by measuring tissue insulin and amylase concentrations, proportional to islet beta cell mass and exocrine enzyme content, respectively. Tissue amylase content decreased rapidly over a 24 hour culture period under all conditions. By addition of pilocarpine, cobalt chloride, and aprotinin to the culture medium, pancreatic tissue insulin levels stabilized. Under these conditions the tissue insulin: amylase ratio increased rapidly and a high ratio was maintained, indicating that islet tissue decontaminated of exocrine digestive enzymes was preserved in short-term culture. Fifteen dogs rendered diabetic with streptozotocin immediately following a partial pancreatectomy received an autotransplant of pancreatic tissue fragments maintained in culture for 24 hours. Seven dogs were rendered normoglycemic. Six of these dogs have survived for longer than 30 days. Only one of 14 control pancreatectomized dogs injected with streptozotocin and not transplanted survived and was normoglycemic. Viable islet tissue free of exocrine enzymes can be obtained by short-term culture of pancreatic fragments, and separation of islet and exocrine components of adult pancreas is not essential for successful islet transplantation.     

Differentiation and maturation of porcine fetal islet cells in vitro and after transplantation

BACKGROUND: Porcine fetal pancreas is a potential source of beta cells for transplantation. The immaturity of the cells is a problem. We have defined the optimal conditions for in vitro propagation of this tissue before transplantation. METHODS: Porcine fetal pancreas tissue was obtained for tissue culture at various stages of development. Serum-containing and serum-free media and a variety of potential differentiation factors were tested. In vitro, the numbers of endocrine islet cells and their proliferation were quantified and functional maturity of the beta cells was assessed by perifusion. Growth and maturation of the cells was assessed 3 months after transplantation into nude mice. RESULTS: Highest beta cell mass was obtained from end-gestational, as compared with early fetal or neonatal, pancreas. Nicotinamide and sodium butyrate effectively increased the insulin content and the number of endocrine cells in culture. In combination, these factors led up to a 90-fold increase in the insulin content of islet-like cell clusters (ICC) as compared with untreated controls. However, a high level of cell death through apoptosis was observed in these maximally stimulated endocrine cells, and they did not survive as grafts when transplanted into nude mice. Instead, a serum-free culture medium containing 10 mM nicotinamide and 0.1 mM isobutylmethylxanthine was found to support both differentiation and proliferation of endocrine cells as loose ICCs. Insulin release from these ICCs was sensitive to glucose. When transplanted under the kidney capsule of normoglycemic nude mice, a high level of beta cell differentiation and function was evident only in the ICCs cultured in the serum-free medium, and in freshly isolated ICCs. When transplanted to hyperglycemic nude recipients, the cells cultured in serum-free medium for 3 weeks reversed hyperglycemia more consistently and rapidly than freshly isolated ICCs. CONCLUSIONS: Optimal maturation of porcine fetal pancreatic cells is obtained in serum-free medium supplemented with nicotinamide. Butyrate is a potent stimulus for beta cell differentiation but leads to increased apoptotic cell death.