Phosphatidylinositol 3-kinase is a negative regulator of cellular differentiation.

Phosphatidylinositol 3-kinase (PI3K) has been shown to be an important mediator of intracellular signal transduction in mammalian cells. We show here, for the first time, that the blockade of PI3K activity in human fetal undifferentiated cells induced morphological and functional endocrine differentiation. This was associated with an increase in mRNA levels of insulin, glucagon, and somatostatin, as well as an increase in the insulin protein content and secretion in response to secretagogues. Blockade of PI3K also increased the proportion of pluripotent precursor cells coexpressing multiple hormones and the total number of terminally differentiated cells originating from these precursor cells. We examined whether any of the recently described modulators of endocrine differentiation could participate in regulating PI3K activity in fetal islet cells. The activity of PI3K was inversely correlated with the hepatocyte growth factor/scatter factor-induced downregulation or nicotinamideinduced upregulation of islet-specific gene expression, giving support to the role of PI3K, as a negative regulator of endocrine differentiation. In conclusion, our results provide a mechanism for the regulation of hormone-specific gene expression during human fetal neogenesis. They also suggest a novel function for PI3K, as a negative regulator of cellular differentiation.

Expression and function of alpha(v)beta(3) and alpha(v)beta(5) integrins in the developing pancreas: roles in the adhesion and migration of putative endocrine progenitor cells.

Cell-cell and cell-matrix interactions play a critical role in tissue morphogenesis and in homeostasis of adult tissues. The integrin family of adhesion receptors regulates cellular interactions with the extracellular matrix, which provides three-dimensional information for tissue organization. It is currently thought that pancreatic islet cells develop from undifferentiated progenitors residing within the ductal epithelium of the fetal pancreas. This process involves cell budding from the duct, migration into the surrounding mesenchyme, differentiation, and clustering into the highly organized islet of Langerhans. Here we report that alpha(v)beta(3) and alpha(v)beta(5), two integrins known to coordinate epithelial cell adhesion and movement, are expressed in pancreatic ductal cells and clusters of undifferentiated cells emerging from the ductal epithelium. We show that expression and function of alpha(v)beta(3) and alpha(v)beta(5) integrins are developmentally regulated during pancreatic islet ontogeny, and mediate adhesion and migration of putative endocrine progenitor cells both in vitro and in vivo in a model of pancreatic islet development. Moreover, we demonstrate the expression of fibronectin and collagen IV in the basal membrane of pancreatic ducts and of cell clusters budding from the ductal epithelium. Conversely, expression of vitronectin marks a population of epithelial cells adjacent to, or emerging from, pancreatic ducts. Thus, these data provide the first evidence for the contribution of integrins alpha(v)beta(3) and alpha(v)beta(5) and their ligands to morphogenetic events in the human endocrine pancreas.

KSA antigen Ep-CAM mediates cell-cell adhesion of pancreatic epithelial cells: morphoregulatory roles in pancreatic islet development.

Cell adhesion molecules (CAMs) are important mediators of cell-cell interactions and regulate cell fate determination by influencing growth, differentiation, and organization within tissues. The human pancarcinoma antigen KSA is a glycoprotein of 40 kD originally identified as a marker of rapidly proliferating tumors of epithelial origin. Interestingly, most normal epithelia also express this antigen, although at lower levels, suggesting that a dynamic regulation of KSA may occur during cell growth and differentiation. Recently, evidence has been provided that this glycoprotein may function as an epithelial cell adhesion molecule (Ep-CAM). Here, we report that Ep-CAM exhibits the features of a morphoregulatory molecule involved in the development of human pancreatic islets. We demonstrate that Ep-CAM expression is targeted to the lateral domain of epithelial cells of the human fetal pancreas, and that it mediates calcium-independent cell-cell adhesion. Quantitative confocal immunofluorescence in fetal pancreata identified the highest levels of Ep-CAM expression in developing islet-like cell clusters budding from the ductal epithelium, a cell compartment thought to comprise endocrine progenitors. A surprisingly reversed pattern was observed in the human adult pancreas, displaying low levels of Ep-CAM in islet cells and high levels in ducts. We further demonstrate that culture conditions promoting epithelial cell growth induce upregulation of Ep-CAM, whereas endocrine differentiation of fetal pancreatic epithelial cells, transplanted in nude mice, is associated with a downregulation of Ep-CAM expression. In addition, a blockade of Ep-CAM function by KS1/4 mAb induced insulin and glucagon gene transcription and translation in fetal pancreatic cell clusters. These results indicate that developmentally regulated expression and function of Ep-CAM play a morphoregulatory role in pancreatic islet ontogeny.

Nicotinamide is a potent inducer of endocrine differentiation in cultured human fetal pancreatic cells.

The effects of nicotinamide (NIC) on human fetal and adult endocrine pancreatic cells were studied in tissue culture. Treatment of the fetal cells with 10 mM NIC resulted in a twofold increase in DNA content and a threefold increase in insulin content. This was associated with the development of beta cell outgrowths from undifferentiated epithelial cell clusters and an increase in the expression of the insulin, glucagon, and somatostatin genes. DNA synthesis was stimulated only in the undifferentiated cells. Half-maximal doses for the insulinotropic and mitogenic effects of NIC were 5-10 and 1-2 mM, respectively. Islet-like cell clusters cultured with NIC responded to glucose stimulation with a biphasic increase in insulin release (fourfold peak), whereas control cells were unresponsive to glucose. Both control and NIC-treated cells developed into functional islet tissue after transplantation into athymic nude mice. As compared with adult islets, the insulinotropic action of NIC could only be demonstrated in the fetal cells. Our results indicate that NIC induces differentiation and maturation of human fetal pancreatic islet cells. This model should be useful for the study of molecular mechanisms involved in beta cell development.

Induction of T- and B-lymphocyte responses in antigenically stimulated athymic mice.

Antigenic stimulation of athymic mice on the BALB/c background by infection with the pinworms Aspiculuris tetraptera and Syphacia obvelata or by xenografts of human tumors induced a proliferation of T- and B-lymphocytes in spleen and lymph nodes and occasional germinal center formation. The proliferating T-lymphocytes showed greater fluorescence per cell than the Thy 1-positive cells from unstimulated athymic mice when examined by cytofluorography using anti-Thy 1 antiserum. The proliferating T-lymphocytes were shown to be functional by their ability to help mount an in vivo antibody response to sheep erythrocytes and other thymus-dependent antigens. Spleen cells cultures taken from mice at early stages of antigenic stimulation responded in vitro to the thymus-dependent mitogens concanavalin A and phytohemagglutinin. However, spleen cell cultures taken from mice chronically stimulated by foreign antigens were apparently already maximally stimulated and showed no further stimulation when incubated with concanavalin A or phytohemagglutinin in vitro.

Amplification of the murine leukemia virus Mr 70,000 glycoprotein gene product by human xenografts in athymic mice.

Passage of human tumors in athymic mice is accompanied by an increase in serum levels of the Mr 70,000 murine leukemia virus envelope protein, gp70. Elevated levels of gp70 can be detected in tissues of the hematopoietic systems of mice bearing human xenografts, but there is no evidence of synthesis of gp70 in these tissues. By far, the highest concentration of gp70 is in the human xenografts themselves. When assayed for gp70, 8 human xenografts and 12 cell lines established from human xenografts were all positive. In the plasma membrane of the human astrocytoma xenograft, T24, the gp70 was found to be approximately 10% of the total membrane protein. In contrast, the concentration of the Mr 30,000 viral core protein, p30, was 17-fold less. Only trace amounts of complete infectious virus could be detected. A human prostate carcinoma line that had not been grown in the athymic mice was found to have no gp70, but was shown to be able to synthesize gp70 after a single passage in the athymic mice.

Induction of lymphoma in antigenically stimulated athymic mice.

Athymic mice infected with pinworms or carrying human tumor xenografts frequently develop a lymphoproliferative disorder which eventually leads to lymphoma. By immunofluorescent analysis of involved tissues, the lymphomas appear to be mixtures of null cells, B-cells, and T-cells. When each lymphoma is established in tissue culture, a predominant cell type grows out. We have now established lymphoma lines of null cells, B-cells, and T-cells. Lymphoma development is preceded by the secretion into the bloodstream of large amounts of murine leukemia virus M.W. 70,000 glycoprotein antigen; however, very little virus is produced. In vivo, the expression of viral envelope antigen appears within a few days after human tumor transplantation and precedes the development of lymphoma by about a month. Cells expressing viral antigens are first seen in the diffuse cortex of lymph nodes and the periarteriolar white sheath of the spleen, the tissue domains in which lymphomas also first appear.

Selective elimination of fibroblasts from pancreatic islet monolayers by basic fibroblast growth factor-saporin mitotoxin.

Fibroblast proliferation regularly impedes the initiation and maintenance of pancreatic islet monolayers in culture. We recently characterized a specific cytotoxin to cells expressing the basic fibroblast growth factor receptor by conjugating the growth factor to saporin-6, a ribosome-inactivating protein. In contrast to untreated islets, isolated adult rat islets grown on a substrate prepared from bovine corneal endothelial cells and incubated with the mitotoxin at 10-nM concentration for 96 h were free of contaminating fibroblasts. Histological and functional studies revealed there was no damage to the islets. The results suggest that treatment of this cell type with basic fibroblast growth factor mitotoxins may be an important tool for culture of pure islets for physiological and clinical studies.

Functional beta-cell mass after transplantation of human fetal pancreatic cells: differentiation or proliferation?

The scarcity of human adult islets available for transplantation in IDDM makes the use of human fetal pancreatic cells desirable. Human fetal pancreatic cells grow and differentiate after transplantation in nude mice. It is unclear whether proliferation of preexisting endocrine cells or differentiation of precursor cells is mainly responsible for the increased islet mass and if beta-cell enrichment before transplantation enhances the functional outcome of the graft. To answer these questions, we transplanted purified human fetal islets, islet-like cell clusters (ICCs), and fresh tissue under the kidney capsule of nude mice. Insulin content was highest in the fresh tissue but fell rapidly during culture as either fetal islets or ICCs. Although fetal islets contained fourfold more insulin than ICCs before transplantation, the insulin content of the resulting grafts was the same after 3 months in vivo. The degree of stimulation after glucose challenge was comparable; however, more tissue was needed to generate the fetal islets. Grafts of fresh tissue also had similar total insulin contents, but when normalized to DNA, insulin concentration was significantly higher in the grafts from cultured tissue. Moreover, there were distinct morphological differences; the grafts from fresh tissue were more fibrous, with prominent ductal and cystic elements. Grafts from cultured tissue were two- to threefold enriched in endocrine tissue when compared with grafts originating from fresh tissue. These results suggest that islet cells identified in the grafted ICCs are mainly derived through differentiation of endocrine precursors and that cultured ICCs are more preferable than either fetal islets or uncultured tissue for transplantation.

Hepatocyte growth factor/scatter factor has insulinotropic activity in human fetal pancreatic cells.

Fetal mesenchyme-derived factors are likely to play an important role in pancreatic islet development and growth. We have used primary cultures of human fetal pancreatic tissue to identify growth factors that have morphogenic, mitogenic, and insulinotropic activity. The formation of islet-like cell clusters (ICCs) during a 6-day culture was stimulated two- to threefold by hepatocyte growth factor/scatter factor (HGF/SF) basic fibroblast growth factor (FGF)-2, and to a lesser extent by keratinocyte growth factor (FGF-7) and insulin-like growth factor-II (IGF-II). In contrast, transforming growth factor-beta (TGF-beta) had a strong inhibitory effect. The ICCs formed during HGF/SF stimulation consisted mainly of epithelial cells, whereas FGF-2-induced ICCs were predominantly nonepithelial. Furthermore, although both FGF-2 and HGF/SF increased the total insulin content of the cultures, only HGF/SF increased the insulin content per DNA. Quantitatively, HGF/SF stimulated a 2.3-fold increase in the proportion of insulin-positive cells and a 3-fold higher number of replicating beta-cells. Blocking of the IGF-I receptor inhibited ICC formation but did not affect their insulin content. Immunoneutralizing TGF-beta resulted in increased cell growth and insulin content, indicating the presence of an endogenous inhibitory TGF-beta activity in the model system. Our results suggest that HGF/SF may be an important component of the fetal mesenchyme-derived factors responsible for pancreatic islet development. HGF/SF also may prove valuable for supporting the in vitro growth of islet cells.

Trehalose: a cryoprotectant that enhances recovery and preserves function of human pancreatic islets after long-term storage.

The scarcity of available tissue for transplantation in diabetes and the need for multiple donors make it mandatory to use an optimal cryopreservation method that allows maximal recovery and preservation of beta-cell function. We have developed a method to cryopreserve islets with excellent survival of endocrine cells. Current methods use DMSO as cryoprotectant. Our method involves introducing both DMSO and the disaccharide trehalose into the cells during cooling. Uptake and release of trehalose occurred during the thermotropic lipid-phase transition measured in pancreatic endocrine cells between 5 degrees and 9 degrees C, using [14C]trehalose. Recovery of adult islets after cryopreservation with 300 mmol/l trehalose was 92 vs. 58% using DMSO alone. In vitro function, in terms of insulin content and release in response to secretagogues, was indistinguishable from fresh islets. Grafts from islets cryopreserved with trehalose contained 14-fold more insulin than grafts from islets cryopreserved without trehalose. Results with human fetal islet-like cell clusters (ICCs) were more pronounced: recovery from cryopreservation was 94%, compared with 42% without trehalose. Complete functionality of fetal cells was also restored; tritiated thymidine incorporation and insulin content and release were similar to fresh tissue. After transplantation in nude mice, there was a 15-fold increase in insulin content of grafts from ICCs cryopreserved with trehalose compared with ICCs cryopreserved without trehalose. Thus, the addition of trehalose to cryopreservation protocols leads to previously unobtainable survival rates of human pancreatic endocrine tissue.

Regulation of proliferation and differentiation of human fetal pancreatic islet cells by extracellular matrix, hepatocyte growth factor, and cell-cell contact.

Ex vivo expansion of human fetal pancreatic endocrine cells is important for biological studies and as a potential tissue source for transplantation in insulin-deficient states. In tissue culture experiments involving the use of hepatocyte growth factor/scatter factor and selected extracellular matrices, we obtained a 30-fold increase in cell number of human fetal pancreatic epithelial cells. This proliferation in monolayer culture was associated with marked downregulation of insulin and glucagon gene expression. However, gene expression increased when the cells were combined into three-dimensional aggregates, suggesting that cell-cell contact mediated mechanisms regulate the transcription of islet-specific genes, a process enhanced by nicotinamide (NIC). After transplantation into nude mice, either as cell suspensions or aggregates, only the cell aggregates treated with NIC developed into mature functional islet-like structures. These are the first experiments to describe the interactions of specific matrices and growth factors in the ex vivo expansion of human fetal pancreatic cells, and they also show the importance of cell aggregates in the context of cellular and molecular events that might positively influence islet cell transplantation.

Growth factor/matrix-induced proliferation of human adult beta-cells.

Proliferation of human beta-cells in vitro is desirable for both transplantation and biological studies. In this study, human pancreatic islets obtained from cadavers were kept in tissue culture plates that favored cell attachment. When the cells attached to the matrix produced by the rat-bladder carcinoma cell line 804G, 5'-bromo-2'-deoxyuridine (BrdU) labeling increased from 4.7 +/- 2.5 to 13.2 +/- 2.2%, while cells simultaneously labeled for insulin and BrdU increased from 0 to 32%. Addition of the growth factor hepatocyte growth factor/scatter (HGF/SF) increased BrdU labeling to 17.5 +/- 1.8 and the percentage of double positive (BrdU + insulin) cells to 69%. This is the first in vitro demonstration that human beta-cells grown in monolayer culture are able to replicate when exposed to selected matrices and growth factors. These experiments add further evidence that HGF/SF is an important mitogenic agent for human beta-cells.

Gene transfer to human pancreatic endocrine cells using viral vectors.

We have studied the factors that influence the efficiency of infection of human fetal and adult pancreatic endocrine cells with adenovirus, murine retrovirus, and lentivirus vectors all expressing the green fluorescent protein (Ad-GFP, MLV-GFP, and Lenti-GFP, respectively). Adenoviral but not retroviral vectors efficiently infected intact pancreatic islets and fetal islet-like cell clusters (ICCs) in suspension. When islets and ICCs were plated in monolayer culture, infection efficiency with all three viral vectors increased. Ad-GFP infected 90-95% of the cells, whereas infection with MLV-GFP and Lenti-GFP increased only slightly. Both exposure to hepatocyte growth factor/scatter factor (HGF/SF) and dispersion of the cells by removal from the culture dish and replating had substantial positive effects on the efficiency of infection with retroviral vectors. Studies of virus entry and cell replication revealed that cell dispersion and stimulation by HGF/SF may be acting through both mechanisms to increase the efficiency of retrovirus-mediated gene transfer. Although HGF/SF and cell dispersion increased the efficiency of infection with MLV-GFP, only rare cells with weak staining for insulin were infected, whereas approximately 25% of beta-cells were infected with Lenti-GFP. We conclude that adenovirus is the most potent vector for ex vivo overexpression of foreign genes in adult endocrine pancreatic cells and is the best vector for applications where high-level but transient expression is desired. Under the optimal conditions of cell dispersion plus HGF/SF, infection with MLV and lentiviral vectors is reasonably efficient and stable, but only lentiviral vectors efficiently infect pancreatic beta-cells.

Sustained proliferation of PDX-1+ cells derived from human islets.

Ex vivo expansion of human beta-cells is an important step toward the development of cell-based insulin delivery systems in type 1 diabetes. Here, we report that human pancreatic endocrine cells can be expanded through 15 cell doublings in vitro for an estimated total 30,000-fold increase in cell number. We believe that the cells resulting from these cultures are of beta-cell origin, since they uniformly express the transcription factor PDX-1 (STF-1, IDX-1, IPF-1), which is initially seen only in cells positive for insulin and negative for the ductal cell marker cytokeratin (CK)-19. To rule out the possibility that PDX-1 expression might be induced by the culture conditions used here, cells from isolated human pancreatic ducts were cultured under the same conditions as the islet cells. Cells in these cultures expressed CK-19 but not PDX-1. Although the expanded beta-cells continued to express PDX-1, insulin expression was lost over time. Whether reexpression of islet-specific genes in vitro is essential for successful cell transplantation remains to be determined.

Transplantation of human fetal pancreas: fresh vs. cultured fetal islets or ICCS.

The paucity of human adult islets available for transplantation in IDDM makes the use of human fetal pancreas a potential alternative. Fetal pancreatic endocrine cells grow and differentiate over time when fresh explants or cultured islet-like cell clusters (ICCs) are transplanted under the kidney capsule in athymic nude mice. We have recently developed a procedure to isolate fetal islets, which differ from ICCs in their beta-cell content. This study was undertaken to compare the maturation and growth of grafts from purified fetal islets, containing mostly beta-cells, to grafts of mostly undifferentiated endocrine cell precursors, cultured as ICCs, and fresh, uncultured tissue. Total insulin content was highest in the fresh tissue pre-transplant while insulin levels fell precipitously during culture as either fetal islets or ICCs. Although 500 fetal islets contained more insulin than 500 ICCS before transplantation, the insulin content of the resulting grafts was the same 3 months post-transplantation. The degree of stimulation following glucose challenge was comparable, as was the histological appearance. However 70 mg of fresh tissue was needed to generate the fetal islets while only 30 mg was needed for the ICCs. Grafts of 30 mg fresh tissue also had similar total insulin contents and stimulation following glucose challenge, but, when normalized to DNA there was a significantly higher concentration of insulin in the grafts from ICCs or fetal islets. Moreover there were distinct morphological differences, with fibrous and ductal elements prominent in the grafts from fresh tissue, which were also much larger and more diffuse, with cystic elements evident macroscopically. Quantitative immunohistochemical analysis showed that grafts from cultured tissue were 48.3+/-5% positive for immunoreactive insulin compared with grafts from fresh tissue which were only 13.3+/-1.4% positive for insulin. In conclusion cultured ICCs, a heterogeneous mixture of hormone-containing and undifferentiated endocrine cells, are a preferable source for transplantation than either purified fetal islets or uncultured tissue.

PDX-1 and cell-cell contact act in synergy to promote delta-cell development in a human pancreatic endocrine precursor cell line.

Cell lines from the fetal and adult pancreas that were developed by retroviral transfer of the SV40T and ras(val12) oncogenes lose insulin expression but retain extremely low levels of somatostatin and glucagon mRNA. In contrast to expanded populations of primary human islet cells, none of them express the homeodomain transcription factor PDX-1. When that factor was expressed in the cell lines by retroviral-mediated gene transfer, one of the cell lines, TRM-6, derived from human fetal islets, exhibited a 10- to 100-fold increase in somatostatin gene expression. This is the first report of induction of the endogenous somatostatin gene by PDX-1. Promotion of cell-cell contact by aggregation of TRM-6/PDX-1 into islet-like clusters produced a further 10- to 100-fold increase in somatostatin mRNA, to a level similar to that of freshly isolated islets, which resulted in production of somatostatin protein. Thus, we demonstrate here that signals induced by cell-cell contact act in synergy with PDX-1 to up-regulate the endogenous somatostatin promoter in an immortalized cell line from human fetal islets. This system provides a powerful model for studying human islet cell development and, particularly, the role of cell-cell contact in the differentiation process.

E2A gene products are not required for insulin gene expression.

Transcripts for E2A gene products, ubiquitous basic helix-loop-helix transactivating proteins, are expressed at high levels in the pancreatic epithelium. E2A proteins have been shown to bind the cognate E box sequence (CANNTG) of the insulin promoter/enhancer. E2A gene products dimerize with cell-specific basic helix-loop-helix proteins and synergize with the homeodomain transcription factor, PDX-1, in insulin gene transactivation. PDX-1 is also required for normal pancreatic development in mice. We investigated whether pancreatic development and insulin production could occur in the absence of E2A gene products by studying mice with a null mutation for the gene. E2A(-/-) mice demonstrated normal formation of pancreatic endocrine and exocrine tissue in histochemical sections as well as positive and distinct immunostaining for insulin and glucagon in islet tissue, signifying development of mature beta- and alpha-cells. Moreover, E2A(-/-) mice displayed no significant difference in blood glucose levels or pancreatic insulin content compared with wild-type littermates. These data show that although E2A gene products probably play an important role in insulin gene expression, pancreatic development and insulin production can proceed in their absence.

Experimental transplantation of human fetal and adult pancreatic islets.

We examined morphology and function following transplantation of human fetal islet-like clusters (ICCs) in nude mice and compared the functional efficiency of human adult islets and fetal ICCs after transplantation. To assess the optimal site we first transplanted ICCs under the kidney capsule, pancreas, lung, and liver in nude mice. Grafts to the kidney and pancreas matured functionally and morphologically, as evidenced by a 4-fold increase in C peptide after glucose stimulation and the presence of insulin in the grafts of all animals. Grafts to the lung, liver, and spleen did poorly; C peptide was only measurable in two of eight, two of five, or three of five of mice grafted to the lung, liver, or spleen, respectively. Using chemically diabetic nude rats as recipients, we were able to restore normoglycemia using 15,000 ICCs/kg. Lastly, when transplanted under the kidney capsule of normal nude mice, ICCs had significantly higher insulin contents and C peptide release than equivalent grafts of adult islets. In summary, ICCs are an efficient source of insulin-producing cells of potential use in clinical transplantation. In nude mice, both the kidney and the pancreas provide suitable environments for the growth and maturation of undifferentiated human beta-cells.

Functional impact of attachment and purification in the short term culture of human pancreatic islets.

We have evaluated the effects on islet function of several manipulations of the substrate and tissue culture conditions in the short term culture of human islets. Specifically, we have studied the influence of several matrices, additions to the medium, and the use of basic fibroblast growth factor (FGF)-saporin mitotoxins to eliminate fibroblastoid cells from the cultures. The human islets were obtained from the Human Islet Transplant Center at Washington University Medical Center (St. Louis, MO). Substrates used to facilitate islet attachment were poly-L-lysine, gelatin, Matrigel, collagen, and bovine corneal endothelial cell matrix. RPMI-1640 medium was supplemented with either 22.2 mM glucose or 10 micrograms/mL human insulin. FGF-saporin mitotoxin was used at a concentration of 10 nM. The greatest improvement in islet cell function in either static or stimulated situations was obtained when we used bovine corneal endothelial cell matrix as the matrix, supplemented the medium with a high concentration of glucose or insulin, and eliminated fibroblast-like cells by exposing the cultures to basic FGF-saporin mitotoxin. The conditions described in this report could greatly improve the culture of human islets for use in clinical and laboratory research.