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ABSTRACT
The present study was designed to investigate the relative contributions of FSH and testosterone in the initiation of testicular growth and function in primates. Four groups (n = 4/group) of juvenile rhesus monkeys (Macaca mulatta), 12–18 months old, were treated with vehicle, a highly purified human FSH preparation (hFSH; Fertinorm, 3 IU/kg per day), testosterone (testosterone enanthate, 125 mg/week) or FSH plus testosterone, for a period of 12 weeks. Compared with vehicle treatment, the administration of hormones significantly (P <0·05) increased testicular weight and volume, and the diameter of seminiferous tubules. The number of Sertoli cells per tubule cross-section also increased significantly (P <0·05). Numbers of Ad (dark) spermatogonia (reserve stem cells) were not significantly influenced by any treatment. In contrast, the numbers of Ap (pale) spermatogonia (renewing stem cells) were significantly (P <0·05) stimulated with hFSH and testosterone alone. Following the combined treatment, numbers of Ap spermatogonia were also higher compared with control but this effect did not attain statistical significance. In half of the animals in both testosterone-treated groups, a few prophase I spermatocytes were present. Inhibin concentrations reached adult levels in hFSH-treated groups but remained unaffected by testosterone. Conversely, testosterone failed to influence inhibin levels and, unlike hFSH, increased testicular androgen concentration and epididymal weights. Our observations suggest that hFSH and testosterone alone are capable of initiating testicular growth and gametogenesis in an immature primate. Both hormones probably act via activation of the proliferation of Ap spermatogonia, which are considered to be renewing stem cells within the testis. This study also suggests that androgens might be involved in the morphological differentiation of the immature primate Sertoli cell, whereas the secretory activity of the seminiferous tubule, in terms of peripheral inhibin levels, might be under the influence of FSH.
Journal of Endocrinology (1993) 136, 235–243
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The pancreatic ductal stem cells are known to differentiate into islets of Langerhans; however, their yield is limited and the islet population is not defined. Therefore, the aims of the present study were to improvise a methodology for obtaining large numbers of islets in vitro and to characterize their morphological and functional status for islet cell banking and transplantation. Pancreatic ductal epithelial cell cultures were set in serum-free medium. Monolayers of epithelial cells in culture gave rise to islet-like clusters within 3-4 weeks. The identity of neoislets was confirmed by dithizone staining and analysis of the gene expression for endocrine markers by reverse transcriptase-polymerase chain reaction (RT-PCR). The islet population obtained was analysed by image analysis and insulin secretion in response to secretagogues. The cellular extracts from neoislets were immunoreactive to anti-insulin antibody and expressed insulin, glucagon, GLUT-2, PDX-1 and Reg-1 genes. The islets generated within 3-4 weeks exhibited a mixed population of large- and small-sized islets with clear cut dichotomy in the pattern of their insulin secretion in response to L-arginine and glucose. These neoislets maintained their structural and functional integrity on cryopreservation and transplantation indicating their suitability for islet cell banking. Thus, the present study describes an improved method for obtaining a constant supply of large numbers of islets from pancreatic ductal stem cell cultures. The newly generated islets undergo functional maturation indicating their suitability for transplantation.
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In the adult, the insulin gene is expressed exclusively in the β cells of the islets of Langerhans. In order to understand the mechanisms involved in this cell-specific gene expression better, it is necessary to look at the molecular events controlling islet cell ontogeny. Although the timing of expression of each hormone during embryogenesis has been well documented, the exact cell lineage relationship among different islet cell types is not known in detail. In the developing mouse pancreas, glucagon immunoreactivity appears at day 12 (E12), insulin at E14·5 and somatostatin at E17, while pancreatic polypeptide immunoreactivity appears after birth (Teitelman & Lee, 1987). In transgenic mice, hybrid insulin genes are initially expressed in all cells of the embryonic endocrine pancreas (Alpert et al. 1988), suggesting a common pluripotent progenitor stem cell. This conclusion is supported by the observation that cell lines derived from islet cell tumours express multiple pancreatic hormones
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The limitation of available islets for transplantation is a major obstacle for the treatment of diabetes through islet therapy. However, islet monolayers expanded ex vivo may provide a source of progenitor cells and a model to help understand islet development from precursor cell types. The existence of progenitor cells within the islets is highly likely, yet, to date, no fully defined or characterized postnatal stem cell has been isolated, expanded or marked. Our study evaluates the expression of progenitor markers, including the haematopoietic stem cell marker c-Kit, in epithelial monolayers derived from postnatal rat islets through immunofluorescence and RT-PCR, and the ability of precursor-rich monolayers to reform islet-like structures. Islets formed confluent monolayers when cultured on a type I collagen gel which lacked endocrine phenotypes but were positive for cytokeratin 20 and contained an increased proportion of proliferating c-Kit-expressing cells, with the proportion reaching a maximum of 45+/-6% at 8 weeks of culture. Evaluation of transcription factors at the mRNA level revealed constant PDX-1, ngn3 and Pax4 expression, while undifferentiated cell markers, such as Oct4 and alpha-fetoprotein, were also detected frequently after 4 weeks of culture. Changing the extracellular matrix protein to laminin-rich Matrigel, the monolayers re-formed islet-like clusters that secreted insulin in a glucose-responsive fashion. Our data show that islets can be expanded ex vivo to form epithelial monolayers with rich undifferentiating cell populations that are characterized by cells expressing the progenitor markers. These monolayers are capable of extensive proliferation and retain plasticity to form new islet cells, and c-Kit-expressing cells may play an important role in new islet cluster formation.
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ABSTRACT
Thirty adult male rats were injected with 0·5 μCi [3H]thymidine/g body weight (specific activity 5 Ci/ mmol) and killed, in groups of five, 1 h and 14, 30, 60, 90 and 120 days after injection. The displacement of labelled adrenocytes with time was estimated in autoradiograms of adrenal sections. The radial distance of the labelled cell from the capsule was measured with an eyepiece micrometer and expressed in cell location units, i.e. the number of cells separating the labelled cell from the capsule. One hour after labelling, 95% of labelled cells were confined to the outer quarter of the cortex. During the following days, adrenocytes were displaced inwardly, approaching the medulla at a velocity of 0·24 locations/day. They traversed the three cortex zones, reaching the medulla after 104 days. The three adrenal zones represent three differentiation states of the adrenocyte. When young, the adrenocyte secretes aldosterone, after leaving the glomerulosa it produces corticosteroids and on reaching the reticularis it produces sex hormones. The adrenal cortex is a cell renewal system made of two compartments. A progenitor compartment extending between locations 1 and 15, and a functional compartment, covering locations 16–64. The first compartment produces 0·47 cells daily, which enter the second. Half of them die on their way while the rest are eliminated in the reticular zone. The cell stream is nourished by a subcapsular stem cell.
J. Endocr. (1986) 111, 477–482
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The transcription factor C/EBP alpha, a member of the CCAAT/enhancer-binding protein family, is highly expressed in the liver and in adipose tissue. The aim of this study was to determine if C/EBP alpha is expressed in rat growth cartilage. The expression pattern of C/EBP alpha in monolayer-cultured growth plate chondrocytes was similar to that of C/EBP alpha during hepatocyte and preadipocyte differentiation. Immunohistochemistry with a polyclonal antibody for C/EBP alpha revealed that the C/EBP alpha protein is present in the perichondrial ring, in the germinal layer of the growth plate and on the surface of the articular cartilage. The growth hormone (GH) receptor has a similar distribution in the rat tibial growth plate, and hypophysectomised rats were used to investigate a possible connection between C/EBP alpha and GH. C/EBP alpha mRNA levels were decreased in rib cartilage after hypophysectomy. However, GH treatment did not counteract this effect, indicating that other pituitary hormones regulate the C/EBP alpha mRNA levels in growth plate cartilage. We thus demonstrate, for the first time, that C/EBP alpha is expressed in cartilage. The finding that C/EBP alpha, like the GH receptor, is predominantly expressed in stem cell areas of the rat growth plate indicates a possible functional role for C/EBP alpha during early chondrogenic differentiation.
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The factors regulating the differentiation of the endocrine cells of the pancreas are still unknown. In previous studies, we have demonstrated that, like neurones, various beta-cell lines express functional neurotrophin receptors. Moreover, Trk-A, the nerve growth factor (NGF) high-affinity receptor, is expressed in vivo in mature rat islets and early during development in the pancreatic ductal network that represents the source of putative stem cells. Rat pancreatic AR42J cells possess both exocrine and neuroendocrine properties. Recent studies have shown that these cells can differentiate either into acinar cells or into insulin-expressing cells. In this study, we demonstrate that AR42J cells, in common with the embryonic ductal cells, do express Trk-A. Moreover, on treatment with NGF, Trk-A is phosphorylated and early responsive genes such as NGFI-A, c-fos and c-jun are induced. These results clearly show that the Trk-A receptor expressed in AR42J is functional. AR42J cells provide a model system with which to study the role of NGF in the development of the pancreatic cells.
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The aim of this work was to study the possible relationship between pancreatic duodenal homeobox-1 (Pdx-1) and islet neogenesis-associated protein (INGAP) during induced islet neogenesis. Pregnant hamsters were fed with (S) and without (C) sucrose, and glycemia, insulin secretion in vitro, and pancreas immunomorphometric parameters were measured in their 7-day-old offspring. S offspring had significantly lower glycemic levels than C animals. Insulin release in response to increasing glucose concentrations in the incubation medium (2-16 mM glucose) did not increase in pancreata from either C or S offspring. However, pancreata from S offspring released more insulin than those from C animals. In S offspring, beta-cell mass, beta-cell replication rate and islet neogenesis increased significantly, with a simultaneous decrease in beta-cell apoptotic rate. INGAP- and Pdx-1-positive cell mass also increased in the islets and among acinar and duct cells. We found two subpopulations of Pdx-1 cells: INGAP-positive and INGAP-negative. Pdx-1/INGAP-positive cells did not stain with insulin, glucagon, somatostatin, pancreatic polypeptide, or neurogenin 3 antibodies. The increment of Pdx-1/INGAP-positive cells represented the major contribution to the Pdx-1 cell mass increase. Such increments varied among pancreas subsectors: ductal>insular>extrainsular. Our results suggested that INGAP participates in the regulation of islet neogenesis, and Pdx-1/INGAP-positive cells represent a new stem cell subpopulation at an early stage of development, highly activateable in neogenesis.
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Pancreatic regeneration after pancreatectomy has been well documented in animal models. However, the phenomenon of pancreatic regeneration in diabetes has not been exploited as yet. We report here the restoration of euglycaemic status in streptozotocin (STZ)-induced diabetic BALB/c mice, after 50% pancreatectomy. We observed that, after pancreatectomy, STZ-diabetic mice showed a rapid improvement in glycaemic status, starting from the 8th postoperative day, and remained normoglycaemic throughout a 90-day follow-up study. STZ-induced diabetic and control non-diabetic BALB/c mice underwent pancreatectomy and were monitored regularly for changes in body weight, plasma glucose and serum insulin concentrations and histological status of the pancreas. All the pancreatectomised animals showed euglycaemic status from about 20 days after operation, whereas a majority (around 70%) of the diabetic, sham-operated animals died of sustained hyperglycaemia by 20-30 days after operation. Examination of the regenerating pancreas indicated nesidioblastotic activity and supported the theory of a ductal origin of islet stem cells. Islets isolated from the regenerating pancreas showed a progressive increase in islet area (1227.9+/-173.2 micrometer(2) on day 5 compared with 2473.8+/-242.0 micrometer(2) by day 20). The increment in insulin concentrations and subsequent decrement in glycaemia of the diabetic pancreatectomised animals indicate islet neogenesis occurring after the operative insult, leading to a normoglycaemic status, probably recapitulating ontogeny. We have shown that induction of a regenerative stimulus (pancreatectomy) in conditions of STZ-induced diabetes may trigger pancreatic regenerative processes, thereby restoring a functional pancreas, in STZ-diabetic mice.
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The discovery of a pancreatic adult stem cell would have significant implications for cell-based replacement therapies for type 1 diabetes mellitus. Nestin, a marker for neural precursor cells, has been suggested as a possible marker for islet progenitor cells. We have characterized the expression and localization of nestin in both the intact human pancreas and clinical human pancreatic islet grafts. Nestin was found to be expressed at different levels in the acinar component of human pancreatic biopsies depending on donor, as well as in ductal structures and islets to some degree. In islets, insulin-producing beta-cells rarely co-expressed the protein, and in the ducts a small percentage (1-2%) of cells co-expressed nestin and cytokeratin 19 (CK19) while most expressed only CK19 (90%) or nestin (5-10%) alone. Assessment of nestin expression in neonatal pancreatic sections revealed an increased number of islet-associated positive cells as compared with adult islets. Nestin immunoreactivity was also found in cells of the pancreatic vasculature and mesenchyme as evidenced by co-localization with smooth muscle actin and vimentin. Samples from post-islet isolation clinical islet grafts revealed a pronounced heterogeneity in the proportion of nestin-positive cells (<1-72%). Co-localization studies in these grafts showed that nestin is not co-expressed in endocrine cells and rarely (<5%) with cytokeratin-positive ductal cells. However, relatively high levels of co-expression were found with acinar cells and cells expressing the mesenchymal marker vimentin. In conclusion we have shown a diffuse and variable expression of nestin in human pancreas that may be due to a number of different processes, including post-mortem tissue remodeling and cellular differentiation. For this reason nestin may not be a suitable marker solely for the identification of endocrine precursor cells in the pancreas.