胰岛细胞分化与胚体发育的相关性研究

目的探讨胚胎发育中胎龄及胚体大小与胰岛细胞分化的相关性。方法收集妊娠6～14周的胚胎20例,测其重量,顶臀径并通过免疫组织化学染色观察胰高血糖素（glucagon）在胰岛细胞分化过程中的表达。结果妊娠9周左右,胚体重约2．89±0．12g,顶臀径约80．0±2．8mm,此时胰腺导管上皮细胞开始分化出胰岛细胞,并且具有内分泌功能。结论妊娠发育的胚胎在胎龄9w、顶臀径30mm、重量约为2．89g左右时,胰岛细胞开始从胰腺导管上皮细胞分化。     

Formation of pancreatic duct epithelium from bone marrow during neonatal development

Recent reports suggest that bone marrow-derived cells engraft and differentiate into pancreatic tissue at very low frequency after pancreatic injury. All such studies have used adult recipients. The aim of our studies was to investigate the potential of bone marrow to contribute to the exocrine and endocrine components of the pancreas during the normal rapid growth of the organ that occurs during the neonatal period. Five to ten million bone marrow cells from adult, male, transgenic, green fluorescent protein (GFP) mice were injected into neonatal nonobese diabetic/severely compromised immunodeficient/beta2microglobulin-null mice 24 hours after birth. Two months after bone marrow transplantation, pancreas tissue was analyzed with fluorescence immunohistochemistry and fluorescence in situ hybridization (FISH). Co-staining of GFP, with anticytokeratin antibody, and with FISH for the presence of donor Y chromosome indicated that up to 40% of ducts (median 4.6%) contained epithelial cells derived from donor bone marrow. In some of these donor-derived ducts, there were clusters of large and small ducts, all comprised of GFP+ epithelium, suggesting that whole branching structures were derived from donor bone marrow. In addition, rare cells that coexpressed GFP and insulin were found within islets. Unlike pancreatic damage models, no bone marrow-derived vascular endothelial cells were found. In contrast to the neonatal recipients, bone marrow transplanted into adult mice rarely generated ductal epithelium or islet cells (p<.05 difference between adult and neonate transplants). These findings demonstrate the existence in bone marrow of pluripotent stem cells or epithelial precursors that can migrate to the pancreas and differentiate into complex organ-specific structures during the neonatal period.     

Nestin、CK19及insulin等在胚胎胰腺发育中的表达

目的:研究Nestin、CK19、胰岛素、胰高血糖素及生长抑素在胚胎胰腺发育中的表达,探讨胰岛细胞分化发育的机制。方法:采用免疫组化SABC法及免疫组化双染法(LAB SA),对30例6～14wk人胚胎胰腺中,Nestin、CK19、胰岛素,胰高血糖素及生长抑素阳性的细胞进行定位。结果:(1)胚胎胰腺发育中Nestin阳性细胞存在于胰腺的间质,数量极少;CK19在胰腺导管上皮分化中持续表达,呈强阳性;(2)7wk胰腺导管上皮开始分化出胰岛细胞,胰岛素、胰高血糖素及生长抑素表达阳性,三者的表达并无时段差异性;随着胎龄的增加,阳性细胞数增加,14wk时胰岛逐渐形成,表达达到高峰。结论:胚胎胰腺的发育中,胰腺间质存在胰腺干细胞;胚胎早期胰腺导管上皮细胞开始分化并分泌胰岛素,其自分泌的激素可能参与调节胰岛细胞的迁移和胰岛的形成。     

Hnf6 and Tcf2 (MODY5) are linked in a gene network operating in a precursor cell domain of the embryonic pancreas

During pancreatic organogenesis endocrine cells arise from non self-renewing progenitors that express Ngn3. The precursors that give rise to Ngn3+ cells are presumably located within duct-like structures. However, the nature of such precursors is poorly understood. We show that, at E13-E18, the embryonic stage during which the major burst of beta-cell neogenesis takes place, pancreatic duct cells express Hnf1beta, the product of the maturity-onset diabetes of the young type 5 (MODY5) gene. Ngn3+ cells at this stage invariably cluster with mitotically competent Hnf1beta+ cells, and are often intercalated with these cells in the epithelium that lines the lumen of primitive ducts. We present several observations that collectively indicate that Hnf1beta+ cells are the immediate precursors of Ngn3+ cells. We furthermore show that Hnf1beta expression is markedly reduced in early pancreatic epithelial cells of Hnf6-deficient mice, in which formation of Ngn3+ cells is defective. These findings define a precursor cellular stage of the embryonic pancreas and place Hnf1beta in a genetic hierarchy that regulates the generation of pancreatic endocrine cells.     

CD56 expression aids in the differential diagnosis of cholangiocarcinomas and benign cholangiocellular lesions

CD56 (neuronal cell adhesion molecule, N-CAM) has been reported in neuroendocrine tumours and as a marker of reactive biliary epithelial cells. However, up to date, it is not used to distinguish malignant from non-malignant biliary lesions. In this study, we systematically examined CD56 expression on 98 tumours arising from the biliary tree as well as intrahepatic conditions with reactive neoductules. When neuroendocrine carcinomas are excluded, only 4 of 32 (12.5%) cholangiocarcinomas expressed CD56, 2 of which showed clear cell morphology. Reactive bile ductules adjacent to cirrhotic nodules as well as in focal nodular hyperplasia were CD56 positive. Twelve of 17 (70.5%) bile duct adenomas were CD56 positive, whereas von Meyenburg complexes expressed CD56 only very focally in less than 5% of lesional cells. Bile duct cysts were negative for CD56 with the exception of focally interspersed neuroendocrine cells, similar to that seen in segmental bile ducts. Thus, if van Meyenburg complexes are excluded, CD56 can be used to differentiate intrahepatic non-neoplastic from neoplastic proliferations, which is a helpful diagnostic tool in small liver biopsies.     

Stem cell properties and repopulation of the rat liver by fetal liver epithelial progenitor cells

The potential of embryonal day (ED) 14 fetal liver epithelial progenitor (FLEP) cells from Fischer (F)344 rats to repopulate the normal and retrorsine-treated liver was studied throughout a 6-month period in syngeneic dipeptidyl peptidase IV (DPPIV-) mutant F344 rats. In normal liver, FLEP cells formed: 1) hepatocytic clusters ranging in size up to approximately 800 to 1000 cells; 2) bile duct structures connected to pre-existing host bile ducts; and 3) mixed clusters containing both hepatocytes and bile duct epithelial cells. Liver repopulation after 6 months was moderate (5 to 10%). In retrorsine-treated liver, transplanted cells formed large multilobular structures containing both parenchymal and bile duct cells and liver repopulation was extensive (60 to 80%). When the repopulating capacity of ED 14 FLEP cells transplanted into normal liver was compared to adult hepatocytes, three important differences were noted: 1) FLEP cells continued to proliferate at 6 months after transplantation, whereas adult hepatocytes ceased proliferation within the first month; 2) both the number and size of clusters derived from FLEP cells gradually increased throughout time but decreased throughout time with transplanted mature hepatocytes; and 3) FLEP cells differentiated into hepatocytes when engrafted into the liver parenchyma and into bile epithelial cells when engrafted in the vicinity of the host bile ducts, whereas adult hepatocytes did not form bile duct structures. Finally, after transplantation of ED 14 FLEP cells, new clusters of DPPIV+ cells appeared after 4 to 6 months, suggesting reseeding of the liver by transplanted cells. This study represents the first report with an isolated fetal liver epithelial cell fraction in which the cells exhibit properties of tissue-determined stem cells after their transplantation into normal adult liver; namely, bipotency and continued proliferation long after their transplantation.     

Differentiation and proliferation of endocrine cells in the regenerating rat pancreas after 90% pancreatectomy

The transplantation of pancreatic tissue has been anticipated to serve as a radical treatment for diabetes mellitus. However, the identification of the stem cells, and elucidation of their differential lineage and controlling mechanisms are prerequisites to ensure effective transplantation. We conducted an immunohistochemical study to determine the proliferation and differentiation dynamics of pancreatic endocrine cells in the rat pancreas 1 to 28 days after a 90% pancreatectomy. Regeneration of endocrine cells started immediately after pancreatectomy. The process of regeneration included the proliferation of preexisting islet cells and neogenesis of endocrine cells from epithelial cells of the most peripheral duct. Intercalated ductal cells and centroacinar cells were speculated to be the major sources of neogenesis, from which islet tissue was formed. Glucagon cells were the first endocrine cells differentiated, some of which transformed to insulin cells by a mechanism of non-replication. These results indicate that endocrine stem cells exist among the intercalated ductal and/or centroacinar cells, and these special regions should be utilized in transplantation for the successful treatment of diabetes.     

The MUC6 secretory mucin gene is expressed in a wide variety of epithelial tissues

Secretory mucins play an important role in the cytoprotection of epithelial surfaces and are used as tumour markers in a variety of cancers. The MUC6 secretory mucin was originally isolated from a gastric cDNA library. The aim was to determine the specific type and location of MUC6 mucin gene expression in a wide range of human adult and fetal epithelial tissues. In situ hybridization, RNA analysis, and immunohistochemistry were used to quantify and localize mucin gene expression. The data obtained show that MUC6 is highly expressed in gastric mucosa, duodenal Brunner's glands, gall bladder, seminal vesicle, pancreatic centroacinar cells and ducts, and periductal glands of the common bile duct; focal expression is seen in basal endometrial and endocervical glands. MUC6 epitopes were also highly expressed in 7/10 pancreatic cancers and 7/10 cholangiocarcinomas and focally expressed in 4/10 endocervical adenocarcinomas. Expression of MUC6 occurs early in fetal development and was observed in Brunner's glands and pancreatic ducts at 18-19 weeks and in gastric glands at 20 weeks' gestation. The tissue distribution of the MUC6 secretory mucin indicates that it may function to protect epithelial tissues from a wide range of substances. Expression of MUC6 is frequently preserved in pancreatic and bile duct adenocarcinomas, but it is only sparsely expressed in endocervical carcinomas.     

Two distinct types of islet abnormalities associated with endocrine pancreatic tumours

Summary Morphological and immunocytochemical studies of pancreatic material from eighteen patients with endocrine pancreatic tumours revealed two distinct types of islet abnormalities, both of which were associated with neoformation of endocrine cells from duct epithelium. Due to this phenomenon and the occurrence of greatly increased numbers of certain endocrine cell types the abnormalities were tentatively classified as hyperplasias. Hyperplasia type I was characterized by increases in number of all islet cell types. Increments in numbers of insulin and glucagon cells were most important quantitatively. Neoformation of islet cells from ducts (nesidioblastosis) was especially conspicuous with this type of hyperplasia. To some extent the islet cell neoformation resembled that seen in the human fetal pancreas. Hyperplasia type I was found in addition in two patients having hypergastrinemia due to achlorhydria. It is suggested that this type of abnormality results from a stimulatory effect of gastrin on the formation of pancreatic islet cells. Endocrine pancreatic tumours other than Zollinger-Ellison tumours were frequently, but not invariably, associated with hyperplasia type II, characterized by striking increases in frequency (and conceivably total mass) of pancreatic polypeptide (PP) cells. The variable occurrence of hyperplasia type II could not be related to any specific clinical abnormality. It seems possible that this hyperplasia may represent a non-specific response to pancreatic injury.     

Autoimmune pancreatitis-related diabetes: quantitative analysis of endocrine islet cells and inflammatory infiltrate

In autoimmune pancreatitis (AIP), mechanism(s) of paradoxical glycemic control improvement (GCI) often occurring after pancreatic resection and steroid therapy are not fully elucidated. Using image quantitation, AIP cases (n = 10) with pre- and post-surgical glucose values were compared with chronic pancreatitis (CP) and normal pancreas (NP) regarding percent chromogranin immunohistochemistry (IHC) positivity as a surrogate marker of endocrine endowment; intra-islet T and B lymphocyte and plasma cell enumeration with CD3, CD20, and IgG4 IHC; and CD34 IHC islet vascularity quantitation. Postsurgical GCI, noted in 8/10 (80%) AIP cases, approached statistical significance (P = 0.07) compared to CP. Endocrine endowment reduction, noted by a lower percent of chromogranin + pancreatic parenchyma, was seen in AIP (4.54%) and CP (3.20%) compared to NP (7.95%); only the CP decrease was statistically significant (P = 0.02) since AIP often had ductular endocrine neogenesis. Regression suggested an inverse correlation between endocrine endowment and GCI in AIP (R = 0.62, P = 0.06). AIP islets were smaller and disrupted by inflammatory cell infiltration. Compared to CP, AIP islets had higher CD3 + and CD20 + cell densities. IgG4 + plasma cells were often present at a high density in AIP but typically preserved the islets. Intra-islet CD34 staining showed a lower average vascularity in AIP compared to NP (P = 0.05). This study reaffirms postsurgical GCI in AIP. Prominent intra-islet inflammation and decreased vascularity in AIP may contribute to diabetogenic effects. Endocrine cell neogenesis and relative islet preservation despite islet inflammatory infiltration may explain the paradoxical GCI in AIP.     

Long-term culture and immortalization of epithelial cells from normal adult human pancreatic ducts transfected by the E6E7 gene of human papilloma virus 16.

Pancreatic cancer is one of the most lethal cancers in humans. The majority of these cancers arise from the pancreatic duct epithelium. Research into the pathogenesis of pancreatic carcinoma has largely relied on animal models. In vitro models of pancreatic carcinogenesis using propagable cultured epithelial cells derived from the pancreatic ducts of rats and hamsters have been described. A human model, however, has been nonexistent due to the unavailability of propagable cultured duct epithelial cells derived from normal human pancreas. We report here a reproducible method for the long-term culture of pancreatic duct epithelial cells derived from normal and benign adult human pancreata by infection with a retrovirus containing the E6 and E7 genes of the human papilloma virus 16. One of these cell lines has become immortal and has propagated continuously for more than 20 passages. They remain anchorage dependent in their growth and nontumorigenic in nude mice. These cell lines and the methodology described here to establish them may provide new avenues for in vitro studies of the roles played by duct epithelium in human pancreatic diseases and cancers.     

Transplantation of the fetal rat pancreas: Quantitative morphological analysis of islet tissue growth

When pancreases from fetal rats were transplanted beneath the kidney capsule of isologous normal adult recipients, continued growth and differentiation of the endocrine portion of the pancreas occurred. While limited amounts of acinar tissue were identifiable in the early transplant period (7 days), such cells were absent in long term transplants (14 and 21 days). In contrast, while few definitive islet beta cells were present at the time of transplantation, following 21 days at the kidney site large circumscribed islets comprised of heavily granulated beta cells in association with duct epithelial cells predominated. Mitotic figures were seen in both these cell populations. Total islet mass had increased over 20-fold during the transplantation period. Similar results were observed if fetal pancreases were grown in organ culture for ten days prior to transplantation. Continued islet and duct cell growth, as evidenced by mitotic figures and an increase in absolute islet cell mass was obtained in such cultured explants when transplanted to either isogenic or allogenic recipients. These observations support the hypothesis that fetal pancreas may be the best source of donor material for transplantation to diabetic recipients, in part, due to the continued growth and differentiation of the islet tissue during the transplantation period.     

Progenitor cell niches in the human pancreatic duct system and associated pancreatic duct glands: an anatomical and immunophenotyping study

Pancreatic duct glands (PDGs) are tubule‐alveolar glands associated with the pancreatic duct system and can be considered the anatomical counterpart of peribiliary glands (PBGs) found within the biliary tree. Recently, we demonstrated that endodermal precursor niches exist fetally and postnatally and are composed functionally of stem cells and progenitors within PBGs and of committed progenitors within PDGs. Here we have characterized more extensively the anatomy of human PDGs as novel niches containing cells with multiple phenotypes of committed progenitors. Human pancreata (n = 15) were obtained from cadaveric adult donors. Specimens were processed for histology, immunohistochemistry and immunofluorescence. PDGs were found in the walls of larger pancreatic ducts (diameters > 300 μm) and constituted nearly 4% of the duct wall area. All of the cells identified were negative for nuclear expression of Oct4, a pluripotency gene, and so are presumably committed progenitors and not stem cells. In the main pancreatic duct and in large interlobular ducts, Sox9⁺ cells represented 5–30% of the cells within PDGs and were located primarily at the bottom of PDGs, whereas rare and scattered Sox9⁺ cells were present within the surface epithelium. The expression of PCNA, a marker of cell proliferation, paralleled the distribution of Sox9 expression. Sox9⁺ PDG cells proved to be Pdx1⁺/Ngn3^+/–/Oct4A^?. Nearly 10% of PDG cells were positive for insulin or glucagon. Intercalated ducts contained Sox9⁺/Pdx1⁺/Ngn3⁺ cells, a phenotype that is presumptive of committed endocrine progenitors. Some intercalated ducts appeared in continuity with clusters of insulin‐positive cells organized in small pancreatic islet‐like structures. In summary, PDGs represent niches of a population of Sox9⁺ cells exhibiting a pattern of phenotypic traits implicating a radial axis of maturation from the bottoms of the PDGs to the surface of pancreatic ducts. Our results complete the anatomical background that links biliary and pancreatic tracts and could have important implications for the common patho‐physiology of biliary tract and pancreas.     

Characterization of the endocrine cells in the pancreatic-bile duct system of the rat

Six types of endocrine cells showing immunolabelling against gut or pancreatic islet hormones were identified in the pancreatic-bile duct system of the normal adult rat at the light and electron microscopic levels. They were located within the epithelial lining of the duct system from the intercalated portion to its duodenal opening. However, the distribution and frequency of each endocrine cell varied along the length of the duct system. While insulin, glucagon, somatostatin, and pancreatic polypeptide cells were widely distributed along the entire duct system, small numbers of cholecystokinin and serotonin cells were confined to the terminal portion. A considerable number of somatostatin cells were concentrated in gland-like pouches of the terminal portion of the common pancreatic-bile duct. When the accessory pancreatic duct was present, insulin, glucagon, and somatostatin cells were also found in its epithelial lining. Electron microscopically, the specific content of the secretory granules of all endocrine cells was confirmed by immunolabelling or cytochemical staining. Further the characteristics of the secretory granules of each endocrine cell type corresponded to those present in the same kind of endocrine cells in gut or pancreatic islet. The duct endocrine cells displayed a particular ultrastructural appearance. The “open type cells” were highly polarized, with their apical cytoplasmic process reaching the duct lumen, whereas “closed type cells” showed long basal cytoplasmic processes with no connection with the duct lumen. In general, insulin, and somatostatin cells were of the “open type,” while no morphological connection with the duct lumen was found for glucagon and pancreatic polypeptide cells. The presence of various duct endocrine cells with their particular ultrastructural appearance implies that they may take part in modulating the function of the duct system.     

Characterization of the endocrine cells in the pancreatic-bile duct system of the rat.

Six types of endocrine cells showing immunolabelling against gut or pancreatic islet hormones were identified in the pancreatic-bile duct system of the normal adult rat at the light and electron microscopic levels. They were located within the epithelial lining of the duct system from the intercalated portion to its duodenal opening. However, the distribution and frequency of each endocrine cell varied along the length of the duct system. While insulin, glucagon, somatostatin, and pancreatic polypeptide cells were widely distributed along the entire duct system, small numbers of cholecystokinin and serotonin cells were confined to the terminal portion. A considerable number of somatostatin cells were concentrated in gland-like pouches of the terminal portion of the common pancreatic-bile duct. When the accessory pancreatic duct was present, insulin, glucagon, and somatostatin cells were also found in its epithelial lining. Electron microscopically, the specific content of the secretory granules of all endocrine cells was confirmed by immunolabelling or cytochemical staining. Further the characteristics of the secretory granules of each endocrine cell type corresponded to those present in the same kind of endocrine cells in gut or pancreatic islet. The duct endocrine cells displayed a particular ultrastructural appearance. The "open type cells" were highly polarized, with their apical cytoplasmic process reaching the duct lumen, whereas "closed type cells" showed long basal cytoplasmic processes with no connection with the duct lumen. In general, insulin, and somatostatin cells were of the "open type", while no morphological connection with the duct lumen was found for glucagon and pancreatic polypeptide cells. The presence of various duct endocrine cells with their particular ultrastructural appearance implies that they may take part in modulating the function of the duct system.