Exocrine Differentiation Research Articles

Conversion of immortal liver progenitor cells into pancreatic endocrine progenitor cells by persistent expression of Pdx‐1

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.

Endocrine cells develop within pancreatic bud-like structures derived from mouse ES cells differentiated in response to BMP4 and retinoic acid

We have examined factors affecting the in vitro differentiation of Pdx1 GFP/w ESCs to pancreatic endocrine cells. Inclusion of Bone Morphogenetic Protein 4 (BMP4) during the first four days of differentiation followed by a 24-hour pulse of retinoic acid (RA) induced the formation of GFP + embryoid bodies (EBs). GFP expression was restricted to E-cadherin + tubes and GFP bright (GFP br) buds, reminiscent of GFP + early foregut endoderm and GFP br pancreatic buds observed in Pdx1 GFP/w embryos. These organoid structures developed without further addition of exogenous factors between days 5 and 12, suggesting that day 5 EBs contained a template for the subsequent phase of development. EBs treated with nicotinamide after day 12 of differentiation expressed markers of endocrine and exocrine differentiation, but only in cells within the GFP br buds. Analysis of Pdx1 GFP/w ESCs modified by targeting a dsRed1 gene to the Ins1 locus ( Pdx1 GFP/w Ins1 RFP/w ESCs) provided corroborating evidence that insulin positive cells arose from GFP br buds, mirroring the temporal relationship between pancreatic bud development and the formation of endocrine cells in the developing embryo. The readily detectable co-expression of GFP and RFP in grafts derived from transplanted EBs demonstrated the utility of Pdx1 GFP/w Ins1 RFP/w ESCs for investigating pancreatic differentiation in vitro and in vivo.

Viral-Mediated Coexpression of Pdx1 and p48 Regulates Exocrine Pancreatic Differentiation in Mouse ES Cells

Embryonic stem cells (ES) can spontaneously activate a pancreatic differentiation program in vitro, although with low efficiency. The aim was to improve such process by using viral mediated gene transduction. In this study, we have examined the suitability of using viral vectors to express key transcriptional factors involved in pancreatic development. ES cell lines that constitutively express Pdx1, a homeodomain protein involved in both exocrine and endocrine pancreatic development and differentiation, were established using a lentiviral vector. These cells were additionally infected with an adenovirus expressing p48, a bHLH factor that is also crucial for pancreatic development and acinar differentiation. Quantitative RT-PCR analysis demonstrated an increase in the expression of exocrine genes, including those coding for both digestive enzymes and transcription factors. Immunocytochemical staining also revealed an increase in the number of amylase-expressing cell clusters. However, other important genes involved in acinar cell maturation (i.e., Mist1) were not modulated under these conditions, suggesting that the cells display features of immature exocrine cells or because of an uncoupled gene expression of the exocrine differentiation program. Importantly, this effect was selective for the acinar lineage as the expression of a large set of endocrine markers remained unchanged. Therefore, combined expression of key genes involved in pancreatic development may be a promising approach to generate mature pancreatic exocrine cells.

Betacellulin inhibits amylase and glucagon production and promotes beta cell differentiation in mouse embryonic pancreas

Betacellulin, a member of the epidermal growth factor family, is expressed in the pancreas and is thought to regulate differentiation of beta cells during development. The aim of the present study was to investigate the effects of exogenous betacellulin on the development of the mouse embryonic pancreas. We used an in vitro culture model system based on the isolation and culture of the dorsal embryonic pancreas from day 11.5 embryos. Cultures were treated for up to 10 days with 10 ng/ml betacellulin and then analysed for changes in the expression of pancreatic exocrine, endocrine and ductal markers. Pancreases developed in culture and expressed the full complement of exocrine (both acinar and ductal) and endocrine cell types. Betacellulin enhanced branching morphogenesis and the proliferation of mesenchyme, increased Pdx1 and insulin production and inhibited the production of the exocrine cell marker amylase and the endocrine hormone glucagon. These results suggest betacellulin has distinct and separate effects on exocrine, endocrine and ductal differentiation. In the future, betacellulin could perhaps be utilised to increase the production of beta cells from embryonic pancreatic tissue for therapeutic transplantation.

Sonic Hedgehog and Other Soluble Factors from Differentiating Embryoid Bodies Inhibit Pancreas Development

Success of cell-replacement therapy for diabetes will largely depend on the establishment of alternative sources of pancreatic islet grafts. Embryonic stem (ES) cell differentiation toward pancreatic insulin-producing cells offers such perspectives, but there are still many challenges to overcome. Our previous studies suggested that the limited amount of insulin-positive cells derived from ES cells is related to the activation of pancreas inhibitory signals. To confirm this hypothesis, we report here that exposure of mouse embryonic pancreas explants to soluble factors from embryoid bodies (EBs) inhibits growth, morphogenesis, and endocrine and exocrine differentiation as evaluated by explant size and mRNA and protein expression. Sonic Hedgehog (Shh), an established pancreas repressor both at early and late developmental stages, was produced and secreted by EBs, and participated in the inhibitory effect by inducing its target Gli1 in the explants. Inhibition of Hedgehog pathway rescued the differentiation of Insulin-positive cells in the explants. In contrast to pancreatic cells, hepatic progenitors exposed to EB-conditioned medium showed improved differentiation of albumin-positive cells. In a model system of ES cell differentiation in vitro, we found that definitive endoderm induction by serum removal or activin A treatment further increased Hedgehog production and activity in EBs. Concomitantly, downregulation of the pancreas marker Pdx1 was recorded in activin-treated EBs, a phenomenon that was prevented by antagonizing Hedgehog signaling with Hedgehog interacting protein. These data strongly suggest that Hedgehog production in EBs limits pancreatic fate acquisition and forms a major obstacle in the specification of pancreatic cells from ES-derived definitive endoderm. Disclosure of potential conflicts of interest is found at the end of this article.

All-trans retinoic acid suppresses exocrine differentiation and branching morphogenesis in the embryonic pancreas

Recent evidence has shown that retinoic acid (RA) signalling is required for early pancreatic development in zebrafish and frog but its role in later development in mammals is less clear cut. In the present study, we determined the effects of RA on the differentiation of the mouse embryonic pancreas. Addition of all-trans retinoic acid (atRA) to embryonic pancreatic cultures induced a number of changes. Branching morphogenesis and exocrine differentiation were suppressed and there was premature formation of endocrine cell clusters (although the total area of β cells was not different in control and atRA-treated buds). We investigated the mechanism of these changes and found that the premature formation of β cells was associated with the early expression of high-level Pdx1 in the endocrine cell clusters. In contrast, the suppressive effect of RA on exocrine differentiation may be due to a combination of two mechanisms (i) up-regulation of the extracellular matrix component laminin and (ii) enhancement of apoptosis. We also demonstrate that addition of fibroblast growth factor (FGF)-10 is able to partially prevent apoptosis and rescue exocrine differentiation and branching morphogenesis in atRA-treated cultures but not in mice lacking the FGF receptor 2-IIIb, suggesting the effects of FGF-10 are mediated through this receptor.

The grey zone between pure (neuro)endocrine and non-(neuro)endocrine tumours: a comment on concepts and classification of mixed exocrine–endocrine neoplasms

Terms such as "mixed endocrine-exocrine carcinoma" (MEEC) and "adenocarcinoma with neuroendocrine (NE) differentiation" (ADC-NE) identify tumours belonging to the spectrum of neoplasms with divergent exocrine and (neuro)endocrine differentiation. These tumours display variable quantitative extent of the two components, potentially ranging from 1 to 99%, and variable structural patterns, ranging from single scattered NE cells to a well-defined NE tumour cell population organized in organoid, trabecular or solid growth patterns. In the present report, the grey zone of tumours/carcinomas with mixed NE and non-NE features is explored for various organs. From a practical point of view, MEECs differ from carcinomas with focal NE differentiation by (1) the extension of each component (more than 30%) and (2) the structural pattern of the NE component, either organoid for well-differentiated or solid/diffuse for poorly differentiated cases. In MEECs, the most aggressive cell population drives the clinical behaviour. Conversely, ADC-NE generally do not show a different clinical outcome, compared to the corresponding conventional forms, except for prostatic adenocarcinoma, in which NE cells are a negative prognostic factor. The recognition of MEECs may be of relevance for a targeted therapeutic strategy, foreseeing the use of biotherapies similar to those proposed for pure NE tumours.

Middle Ear Adenoma

Abstract Middle ear adenoma is a benign tumor of the middle ear that can have exocrine (mucinous) and/or neuroendocrine differentiation. Early authors described a separate tumor with predominantly neuroendocrine differentiation as a middle ear carcinoid tumor, but these are now known to be the same tumor. We review the literature of this tumor, including the clinical presentation, gross pathology, histopathology, immunohistochemistry, differential diagnosis, and prognosis.

Analyses of pancreas development by generation of gfp transgenic zebrafish using an exocrine pancreas-specific elastaseA gene promoter

In contrast to what we know on development of endocrine pancreas, the formation of exocrine pancreas remains poorly understood. To create an animal model that allows observation of exocrine cell differentiation, proliferation, and morphogenesis in living animals, we used the zebrafish elastaseA ( elaA) regulatory sequence to develop transgenic zebrafish that display highly specific exocrine pancreas expression of GFP in both larvae and adult. By following GFP expression, we found that the pancreas in early development was a relatively compact organ and later extended posterior along the intestine. By transferring the elaA:gfp transgene into slow muscle omitted mutant that is deficient in receiving Hedgehog signals, we further showed that Hedgehog signaling is required for exocrine morphogenesis but not for cell differentiation. We also applied the morpholino knockdown and toxin-mediated cell ablation approaches to this transgenic line. We showed that the development of exocrine pancreas is Islet-1 dependent. Injection of the diphtheria toxin A ( DTA) construct under the elastaseA promoter resulted in selective ablation of exocrine cells while the endocrine cells and other endodermal derivatives (liver and intestine) were not affected. Thus, our works demonstrated the new transgenic line provided a useful experimental tool in analyzing exocrine pancreas development.

Interactions between Hairy/Enhancer of Split-related proteins and the pancreatic transcription factor Ptf1-p48 modulate function of the PTF1 transcriptional complex

In the developing pancreas, the onset of exocrine differentiation is driven by the activity of the PTF1 (pancreas transcription factor 1) transcriptional complex, which is comprised of the class II bHLH (basic helix-loop-helix) protein, Ptf1-p48 [also known as Ptf1a (pancreas specific transcription factor 1a)], and a class I E-box binding partner. Activity of the PTF1 complex is normally inhibited by the Notch signalling pathway, a process mediated by Notch effector proteins in the HES (Hairy/Enhancer of Split) family of bHLH transcriptional repressors. In the present study, we show that this inhibitory effect occurs through direct interaction between HES family members and Ptf1-p48. The HES family members Hey1 (hairy/enhancer-of-split related with YRPW motif 1) and Hey2 co-immunoprecipitate with Ptf1-p48, and Ptf1-p48 binding by Hes1 is also evident in yeast two-hybrid and GST (glutathione S-transferase) pull-down assays. The ability of Hes1 to interact with Ptf1-p48 resides within a fragment comprised of the bHLH, Orange and C-terminal domains, and does not require the N-terminal or WRPW elements. The ability of truncated versions of Hes1 to bind Ptf1-p48 correlates with their ability to down-regulate the activity of the PTF1 transcriptional complex, defining Ptf1-p48 binding as the most likely mechanism by which Notch effector proteins delay exocrine pancreatic differentiation.

Reprogramming liver-stem WB cells into functional insulin-producing cells by persistent expression of Pdx1- and Pdx1-VP16 mediated by lentiviral vectors

Adenovirus-mediated transient expression of the pancreatic duodenal homeobox transcription factor Pdx1 in mouse liver activates pancreatic endocrine and exocrine genes, the latter reportedly resulting in severe hepatitis. Expression of a super-active form of Pdx1 or Pdx1-VP16 selectively transdifferentiates hepatic WB cells into functional pancreatic beta-like insulin-producing cells, without evidence of exocrine differentiation. No study has systematically compared the transdifferentiation efficiency of Pdx1 and Pdx1-VP16 at the cellular and molecular level. Comparisons can be ambiguous when vectors harboring a transcription factor cDNA have differing extents and duration of gene expression. In view of the remarkable capacity of lentiviral vector (LV) for delivering and integrating transgene into both dividing and nondividing cells, we transduced rat hepatic stem cell-like WB cells with LV-Pdx1 or LV-Pdx1-VP16, and then used the limiting-dilution technique to clone single-cell-derived cell lines that stably express either Pdx1 or Pdx1-VP16. With these cell lines, we studied: (a) the expression of Pdx1 or Pdx1-VP16 protein by Western blotting and immunocytochemistry; (b) the repertoire of long-term expression of Pdx1- or Pdx1-VP16-induced pancreatic gene expression using RT-PCR methods; and (c) their capacity to serve as beta-cell surrogates in restoring euglycemia in streptozotocin-treated diabetic mice. We found that cell lines expressing either Pdx1 or Pdx1-VP16 long-term exhibited similar profiles for expression of genes related to pancreatic development and beta-cell function, and reversed hyperglycemia in diabetic mice. We also examined short-term expression of Pdx1 or Pdx1-VP16, and the results demonstrated that expression of Pdx1-VP16 is more efficient in initiating liver-to-endocrine pancreas transdifferentiation. Our findings demonstrate: (a) that the LV system is highly effective in producing persistent expression of Pdx1 or Pdx1-VP16 in WB hepatic cells; and (b) long-term, persistent expression of either Pdx1 or Pdx1-VP16 is similarly effective in converting hepatic stem cells into pancreatic endocrine precursor cells that, upon transplantation into diabetic mice, become functional insulin-producing cells and restore euglycemia.

Androgen Receptor Mediated Growth of Prostate (Cancer)

The understanding of the mode of action of androgens requires insight in the cell biological architecture of the prostate. In the prostate secretory acini, morphologically two cell layers can be discriminated; i.e. the basal and the luminal compartment. The stem cells are thought to be located in the basal compartment. The stem cells have the unique capacity of self-renewal, providing the full repertoire to develop the differentiated ductal system via transient proliferating/amplifying (TP/A) intermediate stem cells. These are in fact early and late progenitors for the exocrine/secretory and neuro-endocrine cells. Exocrine differentiation occurs in the majority of the luminal compartment and is identified by the expression of the androgen receptor (AR), keratin 18 (K18) and prostate specific antigen (PSA). Neuro-endocrine cells are dispersed in the prostate epithelium and express K5 and typical neuro-endocrine markers such as chromogranin A and/or bombesin. The exocrine lineage of differentiation is critically dependent on androgens and thus androgen deprivation therapy will result in declining numbers of secretory/exocrine cells, while the number of stem cells and TP/A intermediate stem cells remains stable. This implies that stem cells and TP/A intermediate stem cells are for their renewal androgen independent, although the TP/A intermediate stem cells are androgen sensitive for expanding the epithelial compartment. Recently, these TP/A intermediate stem cells gained attention because they are thought to play an important role in normal prostate growth as well as in neoplastic transformation. Current hypotheses suggest that from the TP/A cell population, the cancer stem cell develops. Hypothetically, the more committed the cancer stem cell is, the more sensitive the tumour might be for androgen ablation, which could explain why some patients are long-term hormone therapy responders, while others are intrinsically androgen independent. In conclusion, typing of the transformed TP/A intermediate stem cells could enable to discriminate long-term hormone responders from non-responders and could help individualisation of prostate cancer therapy in the future.

Prox1 activity controls pancreas morphogenesis and participates in the production of “secondary transition” pancreatic endocrine cells

The development of the mammalian pancreas is governed by various signaling processes and by a cascade of gene activation events controlled by different transcription factors. Here we show that the divergent homeodomain transcription factor Prox1 is a novel, crucial regulator of mouse pancreas organogenesis. Loss of Prox1 function severely disrupted epithelial pancreas morphology and hindered pancreatic growth without affecting significantly the genesis of endocrine cells before E11.5. Conversely, the lack of Prox1 activity substantially decreased the formation of islet cell precursors after E13.5, during a period known as the “secondary transition”. Notably, this defect occurred concurrently with an abnormal increment of exocrine cells. Hence, it is possible that Prox1 contributes to the allocation of an adequate supply of islet cells throughout pancreas ontogeny by preventing exocrine cell differentiation of multipotent pancreatic progenitors. Prox1 thus appears to be an essential component of a genetic program destined to produce the cellular complexity of the mammalian pancreas.

Conversion of biliary system to pancreatic tissue: complete plasticity or same organ?

Conversion of biliary system to pancreatic tissue in Hes1-deficient mice. Sumazaki R, Shiojiri N, Isoyama S, Masu M, Keino-Masu K, Osawa M, Nakauchi H, Kageyama R, Matsui A. The biliary system, pancreas and liver all develop from the nearby foregut at almost the same time in mammals. The molecular mechanisms that determine the identity of each organ in this complex area are unknown. Hes1 encodes the basic helix-loop-helix protein Hes1 (ref. 1), which represses positive basic helix-loop-helix genes such as Neurog3 (ref. 3). Expression of Hes1 is controlled by the evolutionarily conserved Notch pathway. Hes1 operates as a general negative regulator of endodermal endocrine differentiation, and defects in Notch signaling lead to accelerated pancreatic endocrine differentiation. Mutations in JAG1, encoding a Notch ligand, cause the Alagille syndrome in humans, characterized by poor development of the biliary system, suggesting that the Notch pathway is also involved in normal biliary development. Here we show that Hes1 is expressed in the extrahepatic biliary epithelium throughout development and that Hes1-deficient mice have gallbladder agenesis and severe hypoplasia of extrahepatic bile ducts. Biliary epithelium in Hes1−/− mice ectopically expresses the proendocrine gene Neurog3 (refs. 12,13), differentiates into endocrine and exocrine cells and forms acini and islet-like structures in the mutant bile ducts. Thus, biliary epithelium has the potential for pancreatic differentiation and Hes1 determines biliary organogenesis by preventing the pancreatic differentiation program, probably by directly repressing transcription of Neurog3. [Abstract reproduced by permission of Nat Genet 2004;36:83–87]

PTF1α/p48 and cell proliferation

The basic helix-loop-helix transcription factor pancreas-specific transcription factor 1alpha (PTF1alpha)/p48 is critical for committing cells to a pancreatic fate and for the maintenance of the differentiated state in acinar cells. The aim was to analyze the ability of p48 to modulate cell proliferation, its relationship with cell differentiation, and the mechanisms involved therein. Pancreatic and nonpancreatic cells were transfected with p48 cDNA, and the effects on cell proliferation were examined. The effects on cell cycle regulators were analyzed by Western blotting and RT-PCR; transient transfection assays were used to analyze promoter regulation. p48 Inhibited proliferation of acinar and nonacinar cells by inducing a delay in G1-S progression through the up-regulation of p21 CIP1/WAF1 and p27 KIP1 and the down-regulation of cyclin D2. A 2-fold increase in p21 CIP1/WAF1 mRNA and in the activity of the p21 CIP1/WAF1 promoter was observed. The growth inhibition action of p48 was not associated with exocrine differentiation or with apoptosis. The antiproliferative effects were dependent on the COOH-terminal region of p48 and did not require the bHLH domain. Loss of p48 expression occurring during acinar-to-ductal transitions, characteristic of chronic pancreatitis, was associated with an increase of cell proliferation in ductal complexes. The results indicate that p48 couples cell proliferation and cell differentiation in the exocrine pancreas, thus contributing to tissue homeostasis. These effects may play a role in the increased risk for pancreatic cancer associated with chronic pancreatitis.

Dissecting the role of glucocorticoids on pancreas development.

To determine whether glucocorticoids are involved in pancreas development, glucocorticoid treatment of rat pancreatic buds in vitro was combined with the analysis of transgenic mice lacking the glucocorticoid receptor (GR) in specific pancreatic cells. In vitro treatment of embryonic pancreata with dexamethasone, a glucocorticoid agonist, induced a decrease of insulin-expressing cell numbers and a doubling of acinar cell area, indicating that glucocorticoids favored acinar differentiation; in line with this, expression of Pdx-1, Pax-6, and Nkx6.1 was downregulated, whereas the mRNA levels of Ptf1-p48 and Hes-1 were increased. The selective inactivation of the GR gene in insulin-expressing beta-cells in mice (using a RIP-Cre transgene) had no measurable consequences on beta- or alpha-cell mass, whereas the absence of GR in the expression domain of Pdx-1 (Pdx-Cre transgene) led to a twofold increased beta-cell mass, with increased islet numbers and size but normal alpha-cell mass in adults. These results demonstrate that glucocorticoids play an important role in pancreatic beta-cell lineage, acting before hormone gene expression onset and possibly also modulating the balance between endocrine and exocrine cell differentiation.

Notch inhibits Ptf1 function and acinar cell differentiation in developing mouse and zebrafish pancreas.

Notch signaling regulates cell fate decisions in a variety of adult and embryonic tissues, and represents a characteristic feature of exocrine pancreatic cancer. In developing mouse pancreas, targeted inactivation of Notch pathway components has defined a role for Notch in regulating early endocrine differentiation, but has been less informative with respect to a possible role for Notch in regulating subsequent exocrine differentiation events. Here, we show that activated Notch and Notch target genes actively repress completion of an acinar cell differentiation program in developing mouse and zebrafish pancreas. In developing mouse pancreas, the Notch target gene Hes1 is co-expressed with Ptf1-P48 in exocrine precursor cells, but not in differentiated amylase-positive acinar cells. Using lentiviral delivery systems to induce ectopic Notch pathway activation in explant cultures of E10.5 mouse dorsal pancreatic buds, we found that both Hes1 and Notch1-IC repress acinar cell differentiation, but not Ptf1-P48 expression, in a cell-autonomous manner. Ectopic Notch activation also delays acinar cell differentiation in developing zebrafish pancreas. Further evidence of a role for endogenous Notch in regulating exocrine pancreatic differentiation was provided by examination of zebrafish embryos with homozygous mindbomb mutations, in which Notch signaling is disrupted. mindbomb-deficient embryos display accelerated differentiation of exocrine pancreas relative to wild-type clutchmate controls. A similar phenotype was induced by expression of a dominant-negative Suppressor of Hairless [Su(H)] construct, confirming that Notch actively represses acinar cell differentiation during zebrafish pancreatic development. Using transient transfection assays involving a Ptf1-responsive reporter gene, we further demonstrate that Notch and Notch/Su(H) target genes directly inhibit Ptf1 activity, independent of changes in expression of Ptf1 component proteins. These results define a normal inhibitory role for Notch in the regulation of exocrine pancreatic differentiation.

Transcription factor GATA-6 is expressed in the endocrine and GATA-4 in the exocrine pancreas

GATA-4 and GATA-6 are zinc finger transcription factors that regulate gene expression, differentiation, and cell proliferation in various tissues. These factors have been implicated in the development of endodermal derivatives, including epithelial cells in the yolk sac, lung, and stomach. In the present study, we have characterized the expression of GATA-4 and GATA-6 during development of another endodermal derivative, the mouse pancreas, using a combination of in situ hybridization and immunohistochemistry. Neither GATA-4 nor GATA-6 antigen was detected in E10.5 pancreatic epithelial buds expressing Pdx-1. By E15.5, GATA-4 mRNA and protein were evident in developing pancreatic acini, but not in ductal or endocrine cells of the pancreas; GATA-6 mRNA and protein were present in both endocrine and exocrine cell precursors. In the newborn and adult pancreas, GATA-4 protein was seen in acinar cells, while GATA-6 antigen was found mainly in islet beta-cells. The amphicrine pancreatic AR42J-B13 cell line was used to study the expression of GATA-4 and GATA-6 during the differentiation of these cells towards an endocrine phenotype. Endocrine differentiation was associated with marked increase in GATA-6 but not GATA-4 mRNA levels. We conclude that GATA-4 is a marker of exocrine pancreatic differentiation, whereas GATA-6 is a marker of endocrine pancreatic development.

Retinoic acid signaling is essential for pancreas development and promotes endocrine at the expense of exocrine cell differentiation in Xenopus

How and when the vertebrate endoderm is first subdivided into discrete progenitor cell populations that will give rise to the different major organs, including pancreas and liver, are only poorly understood. We have used Xenopus laevis as a model system to characterize these events, since it is particularly suited to study the early embryonic patterning in vertebrates. Our experimental results support the notion that retinoic acid (RA) functions as an essential endodermal patterning signal in Xenopus and that it acts as early as during gastrulation. As a result of RA treatment, the expression of Sonic Hedgehog (Shh), a known inhibitor of pancreas development in other vertebrate systems, is negatively regulated in the dorsal prepancreatic endoderm. Furthermore, RA is found to promote endocrine at the expense of exocrine differentiation in the dorsal pancreas, correlating with a specific inhibition of Notch signaling activities in this territory. Conversely, RA enhances exocrine marker gene expression in the ventral pancreas.

Transforming growth factor (TGF)beta, fibroblast growth factor (FGF) and retinoid signalling pathways promote pancreatic exocrine gene expression in mouse embryonic stem cells

Extracellular signalling cues play a major role in the activation of differentiation programmes. Mouse embryonic stem (ES) cells are pluripotent and can differentiate into a wide variety of specialized cells. Recently, protocols designed to induce endocrine pancreatic differentiation in vitro have been designed but little information is currently available concerning the potential of ES cells to differentiate into acinar pancreatic cells. By using conditioned media of cultured foetal pancreatic rudiments, we demonstrate that ES cells can respond in vitro to signalling pathways involved in exocrine development and differentiation. In particular, modulation of the hedgehog, transforming growth factor beta, retinoid, and fibroblast growth factor pathways in ES cell-derived embryoid bodies (EB) resulted in increased levels of transcripts encoding pancreatic transcription factors and cytodifferentiation markers, as demonstrated by RT-PCR. In EB undergoing spontaneous differentiation, expression of the majority of the acinar genes (i.e. amylase, carboxypeptidase A and elastase) was induced after the expression of endocrine genes, as occurs in vivo during development. These data indicate that ES cells can undergo exocrine pancreatic differentiation with a kinetic pattern of expression reminiscent of pancreas development in vivo and that ES cells can be coaxed to express an acinar phenotype by activation of signalling pathways known to play a role in pancreatic development and differentiation.