Removal of fibroblastoid cells from primary monolayer cultures of rat neonatal endocrine pancreas by sodium ethylmercurithiosalicylate

Development and retroviral transduction of porcine neonatal pancreatic islet cells in monolayer culture

To learn more about the potential of neonatal porcine pancreatic duct and islet cells for xenotransplantation, the development of these cells when cultured as monolayers was evaluated. Immunostaining for islet hormones and cytokeratin-7 revealed that day eight monolayers consisted of approximately 70% duct cells and less than 10% beta cells. Using Ki-67 immunostaining as a proliferation marker, the fraction of beta cells in the cell cycle was shown to decrease from 20% at day three to 10% at day eight, and for duct cells from 36 to 19%. Insulin secretion increased 2.4-fold upon glucose stimulation, and 38-fold when 10 mm theophylline was added, showing the responsiveness of the neonatal beta cells. Reaggregated monolayers consisted mostly of duct cells, but 4 weeks after transplantation, grafts contained predominantly endocrine cells, with duct cells being almost absent, suggesting in vivo differentiation of duct cells to endocrine cells. Monolayer susceptibility to retroviral transduction was also investigated using a Moloney Murine Leukemia Virus-based vector. Approximately 60% of duct cells but less than 5% of beta cells expressed the transgene, indicating that precursor duct cells are better targets for transgene expression. These results show that porcine neonatal pancreatic cells can be cultured as monolayers in preparation for transplantation. Furthermore, in such a culture setting, precursor duct cells have a high rate of proliferation and are more efficiently transduced with a retrovirus-based reporter gene than are beta cells.

Evidence for the presence of prolyl oligopeptidase and its endogenous inhibitor in neonatal rat pancreatic beta-cells

Prolyl oligopeptidase (PE), an enzyme that may be involved in the maturation and degradation of hormones and neuropeptides has been detected in neonatal rat pancreatic islet cell monolayer cultures. PE activity was not observed in islet cell homogenates but when cellular extracts were subjected to gel-filtration, a such activity with a molecular mass about 70 kDa can be detected. Gel-filtration experiment has led to the finding of a PE inhibitor in these extracts with an estimated molecular mass of 6.5 kDa. After separation of the endogenous inhibitor from PE enzyme by gel-filtration, PE inhibitor was partially purified in a single activity peak by reverse-phase high-performance liquid chromatography (HPLC). It inhibited the fluorogenic substrate Z-Gly-Pro-beta Na degradation by partially purified PE in a competitive manner. Inhibitor is shown to be specific for PE enzyme and it is not released by potassium depolarization of islet cell membrane. These findings indicated that inhibitor is localized in the cytosolic compartment as prolyl oligopeptidase. The specific activity of the inhibitor in beta-cell cultures derived from donor rats varying from 3-20 days of age was unchanged. In contrast, PE inhibitor can only be detected in pancreatic tissue from 3-day-old rats compared with tissue from 20-day-old and adult rats after gel filtration. This discrepancy can be relevant to the different endocrine/exocrine tissue ratios in the pancreas during developing rats. Furthermore, pancreatic tissue from streptozotocin-treated 3-day-old rats did not show PE inhibitory activity indicating that PE inhibitor was principally contained in beta-cells. Based on the biochemical characteristics of the beta-cell PE inhibitor, the enhancement of PE activity observed in neonatal pancreas of STZ-treated rat as previously described (P. Salers, Regul. Pept., 50 (1994) 101-111), appears to be due to the presence of the endogenous PE inhibitor in neonatal rat pancreatic beta-cells that disappears following STZ-treatment.

Effects of dissociation and culture on the maintenance of insulin, glucagon and somatostatin release by neonatal rat islets of Langerhans

The ability of the principal islet cell types to maintain their differentiated function in vitro was assessed in a tissue culture system using neonatal rat pancreata. The effects of tissue dissociation and culture on the yield of islet tissue was measured at various times during the preparation and maintenance of cultures for 8 days. As estimated by the radioimmunoassay of insulin, glucagon and somatostatin in tissue extracts, the amount of islet tissue available for culture was reduced 50-70% following dissociation; an additional loss occurred after the first day in vitro. Only the insulin content of the tissue increased during culture. The hormone content of the media indicated that B-, A- and D-cell function was maintained throughout the culture period. The concentrations of insulin and glucagon in the medium approximately doubled and somatostatin increased 3-fold. This system has been shown to be a useful tool for the simultaneous study of the three major islet cell types and their secretory products.

Separation of VX-2 rabbit carcinoma-derived cells capable of releasing collagenase

Primary and secondary cultures of VX-2 carcinoma produced high levels of collagenase activity in both active and latent forms in serum-free media. These cultures appeared morphologically heterogeneous in phase-contrast microscopy and revealed the presence of mainly three distinct forms: epithelial-like cells (E cells), fibroblast-like cells (F cells), and large rounded-flat cells which may represent a subclass of the F cells. Cell separation techniques such as brief dispase treatment, Percoll gradient centrifugation, thimerosal treatment, and rabbit serum were used to obtain predominantly one form or the other. The E cells never formed a monolayer but rather grew as limited size clusters of intimately associated cells with large nuclei and often appeared multinucleated. These cells were difficult to maintain in culture or serially passed more than a few times. The F cells, rare in early cultures but having the highest growth potential, appeared in various morphological forms ranging from spindle- to stellate-shaped cells. The cells in their third passage were capable of producing palpable tumors, similar in light and electron microscopic studies to the original tumor from which they were derived, when injected intramuscularly into recipient rabbits and produced specific collagenase activity in active and latent forms in serum-free media. Ultrastructural studies suggested that the E cells were of epithelial origin whereas the F cells were similar to stromal fibroblasts. Cytogenetic studies demonstrated that almost all of the E cells showed both numerical and structural chromosomal changes in a modal number of 54 chromosomes. On the other hand, the major cell population of the F cells resembled normal rabbit fibroblasts; both contained a normal diploid (2n = 44). However, few cells (4-6%) in the F-cell population were hyperdiploid with a modal chromosome number of 54. These cells may represent inadvertent contaminating E cells and account for the apparent limited turmorigenicity observed in early F-cell cultures. The data suggested that the E cells were of tumor origin whereas the majority of the F-cell population appeared to be of host origin. Furthermore, it is suggested that the E cells stimulate tumor-associated stromal cells to produce elevated levels of collagenolytic activity and contribute to collagen degradation during tumor invasion.

Effects of 3-isobutyl-1-methylxanthine on neonatal pancreatic islets maintained in tissue culture

The phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (IBMX) promoted the formation of monolayers in cultured pancreatic islets isolated from neonatal rats. Immunofluorescence with specific antisera to insulin and glucagon revealed B-cells and A-cells in these monolayers. Glucose-mediated insulin release was increased by raising the glucose concentration from 5 to 10 mmoles/l. Addition of IBMX (0.1 mmoles/l) to medium containing 10 moles/l glucose produced a further increase in insulin release. Recovery of total insulin, i.e. intracellular insulin plus insulin secreted, was also increased by approximately 50% after 8 days of culture. The B-cells showed a marked biosynthetic response to an acute glucose challenge after prior culture with 10 mmoles/l glucose. Although both unstimulated (1.5 mmoles/l glucose) and stimulated rates (1.5 mmoles/l glucose) of [3H]leucine incorporation into (pro)insulin were significantly higher following culture in 10 mmoles/l glucose plus IBMX (0.1 mmoles/l) than after prior culture with 10 mmoles/l glucose alone, the percentage of (pro)insulin synthesized in relation to total protein synthesis was only increased at the low concentration of glucose. These studies demonstrate that monolayer cultures of neonatal B-cells can be readily produced by IBMX and maintained in a functional state, as defined by their secretory and biosynthetic response. It is suggested that the phosphodiesterase inhibitor exerts a sensitizing effect on the responsiveness of the B-cell to glucose. Moreover, the culture system employed in the present study may prove to be useful for further studies of various agents affecting the B-cell function.

Microcarriers: a new approach to pancreatic islet cell culture

Free islet cell suspensions were prepared from isolated fetal rat islets using a modified enzyme dispersion technique. The islet cells were dispensed into a culture flask containing microcarriers (Cytodex) suspended in culture medium RPMI 1640 by a slowly rotating bar magnet. Microscopical examination of the beads showed that the islet cells attached and then progressively proliferated on the surface of the beads as a monolayer. A highly sustained release of insulin from the beads to the medium was observed during the 7 d culture period. The functional viability of the cultured islet cells was further demonstrated by the ability of batches of the cell-coated beads to synthesize insulin and to increase the insulin release in response to an acute challenge (16.7 mmol/l glucose plus 5 mmol/l theophylline). The results suggest that bead microcarriers may provide a new approach to monolayer islet cell culture providing functional monolayers, which can easily be transferred to different test systems and further manipulated.

Insulin synthesis in a clonal cell line of simian virus 40-transformed hamster pancreatic beta cells

A clonal hamster beta cell line (HIT) was established by simian virus 40 transformation of Syrian hamster pancreatic islet cells. Cytoplasmic insulin was detected in all cells by indirect fluorescent antibody staining, and membrane-bound secretory granules were observed ultrastructurally. Acidified-ethanol extracts of HIT cell cultures contained hamster insulin as determined by radioimmunoassay, radioreceptor assay, and bioassay. One subclone at passage 39 contained 2.6 micrograms of insulin per mg of cell protein. [3H]Leucine-labeled HIT insulin and proinsulin were identical to islet-derived proteins when compared by NaDodSO4/polyacrylamide gel electrophoresis of immunoprecipitates. HIT cell insulin secretion was stimulated by glucose, glucagon, and 3-isobutyl-1-methylxanthine. Insulin secretion at optimal glucose concentration (7.5 mM) was 2.4 milliunits per 10(6) cells per hr. Somatostatin and dexamethasone markedly inhibited HIT insulin secretion. The HIT cell line represents a unique in vitro system for studying beta cell metabolism and insulin biosynthesis.

Development in vitro of epithelial-cell monolayers derived from fetal rat pancreas

Purified epithelial-cell monolayers were generated in vitro from explants of fetal rat pancreas. The extent of the development of the epithelial monolayer, as determined by planimetric analysis, was enhanced by the application of two methodological procedures: (a) preincubation of fetal pancreas in situ at 27 degrees C for 5 hr prior to dissection and explantation; and (b) incubation of the explants in medium containing a high concentration (50% to 70%) of fetal bovine serum. By utilizing such culture conditions, sheets of contiguous epithelial cells, with little or no peripheral fibroblastic contamination, were maintained for 9 days. Whereas the majority of cells within the monolayer had morphological characteristics of pancreatic ductal cells, endocrine cells were identified by the specific immunocytochemical localization of insulin and glucagon. In addition, insulin could be detected in the incubation medium throughout the course of experiment. The simplicity of this preparation offers some advantages over other techniques including reduced chance of contamination and reduced cellular damage or death. It provides a model for future studies directed toward developing individual cell strains derived from pancreatic epithelial cells.

Hepatocyte suspensions and cultures as tools in experimental carcinogenesis

Isolation of preneoplastic cell populations would greatly facilitate analysis of the development of liver carcinogenesis. Suspensions of intact single cells can be prepared in an almost quantitative yield by two-step perfusion of the isolated liver. In the first step the liver is perfused with a Ca2+-free buffer (or with EGTA) in order to irreversibly cleave the desmosomes; in the second step perfusion with Ca2+-activated collagenase dissolves the collagenous extracellular matrix. The resulting single-cell suspension will be a mixture of intact normal and preneoplastic hepatocytes, other liver cell types (mostly Kupffer and endothelial cells), damaged cells, and subcellular debris. Intact hepatocytes can be purified--e.g., by differential centrifugation--but separation of preneoplastic from normal cells has not yet been achieved. Density gradient separation or selection in culture on the basis of the unique properties of preneoplastic hepatocytes (e.g., drug resistance) may prove useful. The use of hepatocyte cultures and liver-derived epithelial cell lines as test systems and models for chemical carcinogenesis in vitro is briefly reviewed.

Isolation and identification of epithelial-like cells in culture by a collagenase-separation technique

An operational criterion for the identification and isolation of epithelial-like (E) cells, based on their ability to cover and protect a collagen gel from the action of collagenase, has been developed. The E cells isolated by this collagenase-separation technique (CST) exhibited the ultrastructural features, including desmosomes and abundant tonofilaments, that are considered characteristic of this cell type. Unlike confluent cultures of fibroblast-like (F) cells, E cells were not found to have large external transformation-sensitive (LETS) protein on their surface membranes. The CST provides a nondestructive and efficient means of identifying and isolating E cells from mixed populations.

Purification of monolayer cell cultures of the endocrine pancreas

Experimental use of primary cultures of endocrine pancreas is constrained by early, vigorous proliferation of fibroblastoid cells. The addition of heavy metals, sodium ethylmercurithiosalicylate, phenyl mercuric acetate, phenyl mercuric nitrate and sodium aurothiomalate to the culture media selectively destroys these fibroblastoid cells yielding highly enriched, morphologically intact, functionally competent endocrine cells that are capable of cell replication. This action of heavy metals appears to be due to reversible inhibition of sulfhydryl enzymes since glutathione and thioglycolate were demonstrated to completely inhibit the cytotoxic effects of the mercury and gold containing agents, respectively. Certain variables in the application of the mercurial agents to pancreatic endocrine cell cultures were defined, most notably the enhanced sensitivity of fetal vs. neonatal tissue, and in inverse relationship of cell density to effective toxicity. After removal of the heavy metal agent from the culture media, many pancreatic islets send out cytoplasmic projections, containing large numbers of oriented microtubules which serve as bridging units to adjacent endocrine cells. The sustained availability of virtually pure pancreatic endocrine cell cultures, which results from the application of mercury to the culture media will undoubtedly permit many aspects of the cell biology of the endocrine pancreas to be directly and sequentially assailed.