Carcinogenesis in the pancreas. I. Long-term explant culture of human and bovine pancreatic ducts

Development of a polarized pancreatic ductular cell epithelium for physiological studies

Pancreatic ductular epithelial cells comprise the majority of duct cells in pancreas, control cystic fibrosis transmembrane conductance regulator (CFTR)-dependent bicarbonate ([Formula: see text]) secretion, but are difficult to grow as a polarized monolayer. Using NIH-3T3-J2 fibroblast feeder cells and a Rho-associated kinase inhibitor, we produced well-differentiated and polarized porcine pancreatic ductular epithelial cells. Cells grown on semipermeable filters at the air-liquid interface developed typical epithelial cell morphology and stable transepithelial resistance and expressed epithelial cell markers (zona occludens-1 and β-catenin), duct cell markers (SOX-9 and CFTR), but no acinar (amylase) or islet cell (chromogranin) markers. Polarized cells were studied in Ussing chambers bathed in Krebs-Ringer [Formula: see text] solution at 37°C gassed with 5% CO₂ to measure short-circuit currents ( I_sc). Ratiometric measurement of extracellular pH was performed with fluorescent SNARF-conjugated dextran at 5% CO₂. Cells demonstrated a baseline I_sc (12.2 ± 3.2 μA/cm²) that increased significantly in response to apical forskolin-IBMX (∆ I_sc: 35.4 ± 3.8 μA/cm², P < 0.001) or basolateral secretin (∆ I_sc: 31.4 ± 2.5 μA/cm², P < 0.001), both of which increase cellular levels of cAMP. Subsequent addition of apical GlyH-101, a CFTR inhibitor, decreased the current (∆ I_sc: 20.4 ± 3.8 μA/cm², P < 0.01). Extracellular pH and [Formula: see text] concentration increased significantly after forskolin-IBMX (pH: 7.18 ± 0.23 vs. 7.53 ± 0.19; [Formula: see text] concentration, 14.5 ± 5.9 vs. 31.8 ± 13.4 mM; P < 0.05 for both). We demonstrate the development of a polarized pancreatic ductular epithelial cell epithelium with CFTR-dependent [Formula: see text] secretion in response to secretin and cAMP. This model is highly relevant, as porcine pancreas physiology is very similar to humans and pancreatic damage in the cystic fibrosis pig model recapitulates that of humans. NEW & NOTEWORTHY Pancreas ductular epithelial cells control cystic fibrosis transmembrane conductance regulator (CFTR)-dependent bicarbonate secretion. Their function is critical because when CFTR is deficient in cystic fibrosis bicarbonate secretion is lost and the pancreas is damaged. Mechanisms that control pancreatic bicarbonate secretion are incompletely understood. We generated well-differentiated and polarized porcine pancreatic ductular epithelial cells and demonstrated feasibility of bicarbonate secretion. This novel method will advance our understanding of pancreas physiology and mechanisms of bicarbonate secretion.

In vitro models of pancreatic cancer for translational oncology research

BACKGROUND: Pancreatic cancer is a disease of near uniform fatality and the overwhelming majority of patients succumb to their advanced malignancy within a few months of diagnosis. Despite considerable advances in our understanding of molecular mechanisms underlying pancreatic carcinogenesis, this knowledge has not yet been fully translated into clinically available treatment strategies that yield significant improvements in disease free or overall survival. OBJECTIVE: Cell line-based in vitro model systems provide powerful tools to identify potential molecular targets for therapeutic intervention as well as for initial pre-clinical evaluation of novel drug candidates. Here we provide a brief overview of recent literature on cell line-based model systems of pancreatic cancer and their application in the search for novel therapeutics against this vicious disease. CONCLUSION: While in vitro models of pancreatic cancer are of tremendous value for genetic studies and initial functional screenings in drug discovery, they carry several imanent drawbacks and are often poor in predicting therapeutic response in humans. Therefore, in most instances they are successfully exploited to generate hypothesis and identify molecular targets for novel therapeutics, which are subsequently subject to further in-depth characterization using more advanced in vivo model systems and clinical trials.

Pancreatic cell lines: a review

Pancreatic cancer has an extremely poor prognosis and lacks early diagnostic and therapeutic possibilities, mainly because of its silent course and explosive fatal outcome. The histogenesis of the disease and early biochemical and genetic alterations surrounding carcinogenesis are still controversial. In vitro studies offer a useful tool to study physiologic, pathophysiologic, differentiation, and transformation processes of cells and to understand some of these shortcomings. The extreme difficulties in isolating individual pancreatic cells and their purification by maintaining their native characteristics have limited research in this area. This review is intended to present and discuss the current availability of rodent and pancreatic cell lines, their differences as well as the difficulties, limitations, and characteristics of these cultured cells. Discussed are in vitro models; ductal, islet, and acinar cell culture; cell differentiation; cell transformation, including genetic and chromosomal alterations; as well as tumor cell markers. Also addressed are the advantages and problems associated with the cell culture in humans and rodents. Advancements in tissue culture technique and molecular biology offer steady progress in this important line of research. The improved methods not only promise the establishment of beta-cell cultures for the treatment of diabetes, but also for studying sequential genetic alterations during pancreatic carcinogenesis and in understanding the tumor cell origin.

Establishment of human pancreatic ductal cells in a long-term culture

Cultivation and preservation of human pancreatic ductal cells have remained a challenge. With a defined culture medium and refinement of culturing techniques, we have been able to maintain human pancreatic ductal cells without any genetic manipulation in culture for more than 16 months. Freshly isolated ductal fragments were placed on a rocker in M3:5 medium free of collagen for 14 days to remove fibroblasts and endocrine cells before allowing them to attach. The cells produced an excessive amount of mucin and expressed the duct specific cytokeratins (CK) 7 and 19, DU-PAN2, CA19-9, carbonic anhydrase II (CA II), and secretin receptors. During the course of the culture, however, the cells gradually lost the expression of CA II, secretin receptors, DU-PAN2, and CA 19-9 and assumed an undifferentiated phenotype, which showed an upregulation of transforming growth factor alpha (TGFalpha) and epidermal growth factor receptor (EGFR), an increase in the expression of Ki-67, and an increased binding to Phaseolus vulgaris leucoagglutinin (PHA-L) and tomato lectin. These ductal cells present a useful source with which to study physiologic aspects of ductal cells including differentiation.

Morphology of the pancreatic duct system in mammals

The morphology of pancreatic excretory duct segments was reviewed in mammals. The fine structure of the epithelial lining was described in intercalated ducts, intra- and extralobular ducts, and in major pancreatic ducts. Morphological characteristics of the various cell types comprising to the duct epithelium were detailed. Principal cells in the epithelial linings of interlobular and major pancreatic ducts ("Wirsungiocytes") were discussed with respect to their appearance as either clear or dark variety. In addition, the capacity of both these cell types in elaborating mucoid glycoprotein, secretions was considered and intra- and extraepithelial mucoid glands of major pancreatic ducts (ductular glands, accessory glands) was described. Finally, the wall composition of the various excretory duct segments was described. The presence of smooth muscle cells, myofibroblasts, and a peculiar periductal vascular plexus in major interlobular ducts and in main pancreatic ducts was emphasized.

Morphogenesis of "duct-like" structures in three-dimensional cultures of human cancerous pancreatic duct cells (Capan-1)

Pancreatic duct cells secrete water and ions, bicarbonate in particular. The study of these secretion processes is hindered by the unavailability of human pancreatic tissue. In this study, pancreatic human cells of the Capan-1 cell line were employed to investigate secretion in vitro. These cells are of ductal origin because in standard culture they polarize spontaneously forming domes in the culture dishes, indicating the existence of transepithelial exchange of water and electrolytes. In culture in suspension, Capan-1 cells form hollow spheroids bounded by a cell monolayer in a radial organization. These three-dimensional structures could be maintained in culture for more than 140 days. In young cultures, the cells of these spheroids grew rapidly (mitotic index = 9.2% on Day 2). Their cytologic features were analyzed by immunocytochemical, cytoenzymatic methods, and by electron microscopy. We showed that they are: a) polarized with an apical pole facing the culture medium; b) organized in a monolayer; c) bound by tight junctions and desmosomes; d) characterized by a particular distribution of enzyme systems known to play a role in ion exchanges, with placental-type alkaline phosphatases and carbonic anhydrases IV on their apical membranes and Ca(2+)-ATPases on their basolateral membranes. Crystalline structures were detected histochemically in the closed cavities and in the intercellular spaces of the spheroids. X-ray emission spectroscopy and electron diffraction showed that they consisted of calcium phosphate in an apatite structure. They were assumed to derive from a raised concentration of Ca2+ and phosphate ions under the impermeable monolayer of the spheroids. In addition, numerous cells secreted M1 gastric-type mucins, and acquired the ability to produce colonic-type M3 mucins. These hollow spheroids swelled during the culture period. Taken together these results suggest that the Capan-1 cells organized in these hollow spheroids exchange ions. Their three-dimensional structure resembles that of human pancreatic ducts, and they may therefore represent a useful model system for investigation of Cl- and HCO3- ion exchange processes in the human pancreas.

Explant organ culture: a review

Organ explant culture models offer several significant advantages for studies of patho-physiologic mechanisms like cell injury, secretion, differentiation and structure development. Organs or small explants/slices can be removed in vivo and maintained in vitro for extended periods of time if careful attention is paid to the media composition, substrate selection, and atmosphere. In the case of human tissues obtained from autopsy or surgery, additional attention must be paid to the postmortem interval, temperature, hydration, and cause of death. Explant organ culture has been effectively utilized to establish outgrowth cell cultures and characterize the histiotypic relationships between the various cell types within an organ or tissue.

Characterization of differentiated Syrian golden hamster pancreatic duct cells maintained in extended monolayer culture

Epithelial cells isolated from fragments of hamster pancreas interlobular ducts were freed of fibroblast contamination by plating them on air-dried collagen, maintaining them in serum-free Dulbecco's modified Eagle's (DME):F12 medium supplemented with growth factors, and selecting fibroblast-free aggregates of duct cells with cloning cylinders. Duct epithelial cells plated on rat type I collagen gel and maintained in DME:F12 supplemented with Nu Serum IV, bovine pituitary extract, epidermal growth factor, 3,3',5-triiodothyronine, dexamethasone, and insulin, transferrin, selenium, and linoleic acid conjugated to bovine serum albumin (ITS+), showed optimal growth as monolayers with a doubling time of about 20 h and were propagated for as long as 26 wk. Early passage cells consisted of cuboidal cells with microvilli on their apical surface, complex basolateral membranes, numerous elongated mitochondria, and both free and membrane-bound ribosomes. Cells grown as monolayers for 3 mo. were more flattened and contained fewer apical microvilli, mitochondria, and profiles of rough surfaced endoplasmic reticulum; in addition, there were numerous autophagic vacuoles. Functional characteristics of differentiated pancreatic duct cells which were maintained during extended monolayer culture included intracellular levels of carbonic anhydrase and their capacity to generate cyclic AMP (cAMP) after stimulation by 1 X 10(-6) M secretin. From 5 to 7 wk in culture, levels of carbonic anhydrase remained stable but after 25 to 26 wk decreased by 1.9-fold. At 5 to 7 wk of culture, cyclic AMP increased 8.7-fold over basal levels after secretin stimulation. Although pancreatic duct cells cultured for 25 to 26 wk showed lower basal levels of cAMP, they were still capable of generating significant levels of cAMP after exposure to secretin with a 7.0-fold increase, indicating that secretin receptors and the adenyl cyclase system were both present and functional. These experiments document that pancreatic duct monolayer cultures can be maintained in a differentiated state for up to 6 mo. and suggest that this culture system may be useful for in vitro physiologic and pathologic studies.

Cell injury and regeneration of human epithelium in organ culture

Human esophageal, tracheal, and pancreatic ductal fragments were collected at autopsy after a postmortem interval of 12 hours or less and maintained in explant organ culture for 30 days. The viability and growth of the explants was assessed by morphology, LDH enzyme release, and cellular outgrowth. The viability and growth of the bronchial explant epithelium was directly related to the postmortem interval. Esophageal epithelial regeneration followed the desquamation of the superficial cell layers. Pancreatic epithelia appeared to grow more slowly and with less outgrowth than the other tissues. Epithelial cell growth along the explant surface and onto the culture dish appeared to proceed through the well-characterized process that follows cell injury, i.e., flattening, migration, replication, and differentiation. Thus, sufficient numbers of viable epithelial cells capable of regeneration were present in routine autopsy epithelium, but there was considerable variation from tissue to tissue and case to case. The most effective and accurate approach to follow when evaluating and predicting the growth and viability of these explants is by using a combination of morphologic, enzymatic and biologic assays. Errors in the interpretation of viability are possible when only one assay method is utilized. These tissues grown in explant organ culture are suitable for studies on the mechanism and response of epithelia to cell injury, recovery and wound healing.

Explant organ culture of hamster alimentary tract epithelium

Adult Syrian Golden hamster alimentary tract maintained as explants in organ culture was studied using the model system for hamster pancreas described by Resau et al. (1983a). Explants of esophagus, stomach, duodenum and colon were maintained in organ culture on Gelfoam sponge rafts in a high-oxygen atmosphere with serum-supplemented CMRL-1066 medium. All of the tissues were observed to show evidence of sublethal acute cell injury during the first several days of culture. Subsequently, the epithelial tissues recovered from this injury, repopulated the denuded areas of the explants and replicated within the sponge matrix. Explants were maintained in a differentiated state for 30+ days and sampled for morphology to examine to process of cell injury, repair, differentiation and replication which occurs in mucosal epithelia. The percentage of basement membrane covered by epithelia in the explants from various tissues was compared to the level of LDH in the media to reveal the relationship between viability determined by biochemical and by morphological methods. Restitution of the mucosal surface occurred in all of the explants. We conclude that adequate populations of replicating cells are maintained within the epithelium of the hamster alimentary tract tissues in vitro so that restitution can occur through migration and subsequent differentiation of the epithelial cells within the mucosa of the explants.

Cytological studies of carcinogen-treated bovine pancreatic ductal organ explants

In order to develop a model to study cytological alterations in human pancreatic cancer, we have exposed bovine pancreatic ductal organ explants to a single dose of 2.5 micrograms per ml of N-methyl-N-nitroso-N'- nitroguanidine (MNNG). At serial time intervals, contact cytology smears of the explants were prepared and stained with the Papanicolaou stain. Control samples contained classic tall columnar and cuboidal ductal cells. Cells were uniform in size, shape, staining characteristics, and nuclear morphology. Ductal explants exposed to MNNG progressed through a series of dysplastic and atypical stages during the first 5 to 12 days in culture. Chromatin became increasingly more granular and nucleoli increased in both number and size. Exposed cells were larger than controls and had many dysplastic features. From day 15 to 30, the cells underwent changes morphologically consistent with those of human pancreatic adenocarcinomas .

Characterization of bovine pancreatic ductal cells isolated by a perfusion-digestion technique

Bovine pancreatic ductal cells isolated by perfusing an enzyme solution into the lumen of the main duct were obtained as sheets of cells. Morphologic features of these cells were those of pancreatic ductal epithelial cells. These cells also contained alcian blue/periodic acid-Schiff positive material and bound lectins, and they stained for keratin in the same manner as intact ductal epithelium. In culture, the plating efficiency was high (13.6%) as determined by DNA content before and after 24 h plating, perhaps due to the gentle isolation technique and the isolation of sheets of cells rather than a single cell. Cell doubling time was 34.4 h in Eagle's minimal essential medium with 10% heat inactivated fetal bovine serum and antibodies, and over 95% of the cells incorporated [3H]thymidine during a 6 h labeling period after 4 d in primary culture. Isolated cells grew best in medium CMRL 1066 with 10% heat inactivated fetal bovine serum as determined by measuring DNA content.

Organ explant culture of adult Syrian golden hamster pancreas

An organ explant culture system has been developed for long term maintenance of adult pancreatic tissue from the Syrian golden hamster. Gastric and duodenal lobe explants of up to 0.5 cm2 size were placed in tissue culture dishes (60 mm2) on Gelfoam sponge rafts to which was added 5 ml of CMRL medium 1066 supplemented with heat inactivated newborn bovine serum, L-glutamine, hydrocortisone, insulin, and antibiotics. Dishes were placed in a controlled atmosphere chamber, which was gassed with 45% O2, 50% N2, and 5% CO2 and incubated at 36.5 degrees C. Viability of the tissues was determined by light and electron microscopy as well as by [3]thymidine incorporation. Explants were viable for up to 70 d. Zymogen granule-containing cells characteristic of acinar cells and mucus-containing cells characteristic of ductal cells were present throughout this period. However, endocrine cells were only present for the 1st wk in culture.

Duct, exocrine, and endocrine components of cultured fetal mouse pancreas

Twenty to twenty-two days postcoitum mouse fetal pancreas organ bits were cultured on the dermal surface of irradiated pigskin as a substrate. The medium used for long term culture consisted of Eagle's Minimum Essential Medium with the addition of 10% bovine serum, 0.02 U/ml insulin, 0.025 microgram/ml glucagon, 3.63 microgram/ml hydrocortisone, 100 microgram/ml soybean trypsin inhibitor or 10(-8) M atropine. When the medium lacked trypsin inhibitor or atropine but contained the three hormones, the pigskin support began to be destroyed after 2 to 4 wk in culture. Thereafter, the cultured cells could not grow and survive on the digested pigskin. When 10(-6) M atropine was added to the medium, amylase secretion from cultured cells and destruction of pigskin were inhibited completely but pancreas cells could not grow or survive. In contrast, 100 microgram/ml soybean trypsin inhibitor or 10(-8) M atropine permitted cell growth, permitted amylase secretion from the cultured acinar cells, and prevented the destruction of pigskin. Under these conditions pancreas cells migrated or grew or both from the organ bits onto the surface of the pigskin dermis and organoid aggregations formed. Hydrocortisone was needed to permit growth for more than 2 wk. Glucagon and insulin had additive effects. Light and electron microscopic observations indicated the culture of at least five kinds of cells, i.e., duct, acinar, centroacinar, endocrine, and mesenchymal. The majority of cultured cells were duct cells and acinar cells. There were few mesenchymal cells. Mouse pancreas cells were cultured for at least 12 wk by this method.

Maintenance of adult hamster pancreas cells on fibroblastic cells

The maintenance of primary cultures of adult hamster pancreatic cells on layers of irradiated C3H/10T1/2 cells was studied. Various types of pancreatic cells, acinar, islet and ductular cells could be identified in the cultures by light and electron microscopy. Morphologically the various pancreatic cells retained many differentiated characteristics of their respective in vivo cells types. Insulin production was maintained at near Day 1 levels for the 16 d in culture for which it was measured. Colonies of epithelial cells continued to grow during a 20 d culture period. It is believed that this procedure for maintaining functional and growing pancreas cells in culture may be a useful in vitro model for studying the initiation of pancreatic carcinogenesis.

An in vitro model of human pancreas carcinogenesis: effects of nitroso compounds

It has been possible to maintain adult human pancreas in organ culture in a chemically defined medium. Under these conditions, all cell types demonstrated at least a limited ability to proliferate. This in vitro model was employed to study the effects of three nitroso compounds, DMNA, MNU, and BHP, on adult human pancreas. The major effects of three nitroso compounds, DMNA, MNU, and BHP, on adult human pancreas. The major effects of these compounds in cytotoxicity, proliferation, and oncogenicity was evaluated morphologically. DMNA and MNU were both carcinogenic but with varying rapidity of induction. MNU produced greater necrosis but gave more rapid induction. BHP produced cytotoxicity sufficient to prevent any rating of its oncogenic potential. Morphologically malignant tissue were tested for growth potential in nude mice. All nude mice developed multiple subcutaneous tumor nodules within eight weeks after inoculation. The tumor nodules ranged morphologically from undifferentiated scirrhous carcinoma to well-differentiated papillary adenocarcinoma.

Ducts of the rat pancreas in a agarose matrix culture

Interlobular and intralobular ducts isolated from the pancreas of the rat by digestion with collagenase and chymotrypsin were cultured in an agarose matrix containing CMRL-1066 supplemented with insulin, dexamethasone, L-glutamine, soybean trypsin inhibitor, antibiotics, and fetal bovine serum. The cut ends of most interlobular ducts sealed to create enclosed lumina. Some ducts retained their original cylindrical organization; others enlarged to varying degrees, resulting in structures that ranged from cylindrical to spherical in shape. The duct walls consisted of viable epithelium and connective tissue, although the amount of connective tissue declined with age. Both epithelial and connective tissue cells became flattened in the enlarged ducts. Intralobular and small interlobular ducts often remained associated with the larger interlobular ducts. These duct fragments have been cultured for as long as 6 weeks.

Morphological, growth, and chromosomal changes in bovine pancreatic duct epithelial cells exposed to N-methyl-N'-nitro-N-nitrosoguanidine

Epithelial cells cultured from bovine pancreatic ducts were given a single treatment of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). Multinucleated cells and giant cells were observed more frequently in carcinogen-treated cultures than in controls. The MNNG-treated cultures also contained a sizeable population of small, dense cells that were not observed in control cultures. At the concentration of 1.0 microgram/ml, MNNG caused an initial depression in the growth rate of the cells followed by growth stimulation for several weeks. The MNNG produced chromosomal damage in the cells as indicated by the observation that a substantial proportion of carcinogen-treated cells were heteroploid and contained a high frequency of metacentric and submetacentric chromosomes and a dicentric marker chromosome. The MNNG treated and control cultures did not acquire the ability to grow in soft agar or to produce tumors after transplantation into athymic, nude mice.

Characterization of ducts isolated from the pancreas of the rat

Rat pancreases were minced and treated with collagenase or collagenase supplemented with chymotrypsin to yield a mixture of ducts, islets, acinar cell clusters, blood vessels, and nerves. Histologically and ultrastructurally, the isolated tissues resembled their in situ counterparts in most respects, the major difference being the destruction of the basement membranes (basal laminae). Ducts ranging in size from the common bile/main pancreatic duct to the intercalated ducts were identified in the digest, although interlobular ducts were most frequently observed. Acinar tissue fragments were separated from nonacinar structures either by flotation through discontinuous gradients of Ficoll or by sieving, the latter technique being the more efficient. Common bile/main ducts, interlobular ducts, and blood vessels were selected manually from the nonacinar fractions. Biochemical analyses showed that the entire nonacinar fraction, as well as isolated ducts and blood vessels, contained larger alkaline phosphatase, carbonic anhydrase, and Mg-ATPase specific activities than acinar tissue, whereas acinar tissue contained larger gamma-glutamyltranspeptidase and amylase activities. However, greater than 63% of the total recovered activity of each enzyme was associated with the acinar tissue. Both the association of the majority of each of these enzyme activities with the acinar tissue and the similarity in specific activities associated with ducts and blood vessels indicate that none of the enzymes tested is a unique marker for interlobular and larger ducts of the pancreas of the rat.

Explant culture of rat colon: a model system for studying metabolism of chemical carcinogens

An explant culture system has been developed for the long-term maintenance of colonic tissue from the rat. Explants of 1 cm2 in size were placed in tissue-culture dishes to which was added 2 ml of CMRL-1066 medium supplemented with glucose, hydrocortisone, beta-retinyl acetate, and either 2.5% bovine albumin or 5% fetal bovine serum. The dishes were placed in a controlled-atmosphere chamber which was gassed with 95% O2 and 5% CO2. The chamber then was placed on a rocker platform which rocked at 10 cycles per min causing the medium to flow intermittently over the epithelial surface. The explants were incubated at 30 degrees C. The viability of the tissue was measured both by incorporation of specific precursors into cellular macromolecules and by monitoring of tissue morphology with light and electron microscopy. Cultured rat colon was able to metabolize benzo[alpha]pyrene, 7,12-dimethylbenz[alpha]anthracene, aflatoxin B1, dimethylnitrosamine, 1,2-dimethylhydrazine, and methylazoxymethanol acetate into chemical species that bind to cellular DNA and protein.

Isolation and characterization of epithelial cells from bovine pancreatic duct

Epithelial cells derived from bovine pancreatic duct have been grown continuously in culture for 30 weeks (approximately 90 doublings of the cell population). The cells were grown in Eagle's minimal essential medium supplemented with 10% heat-inactivated fetal bovine serum, 2 mM glutamine, 0.1 mM nonessential amino acids, and antibiotics. In confluent cultures, the cells are multilayered and form circular structures. When tested at various passages, the cells neither formed colonies in soft agar nor produced tumors after inoculation into athymic, nude mice. Hydrocortisone (1 and 5 microgram per ml) and insulin (1,5 and 10 microgram per ml) had no effect on the growth of the cells. beta-Retinyl acetate inhibited growth rate and cell yield at a concentration of 5 microgram per ml but was not growth-inhibitory at lower concentrations. By electron microscopy the cells have numerous mitochondria, Golgi and microvilli. Mucous droplets were observed in a small proportion of the cells. Desmosome-like structures and occluding junctions were observed more frequently between cells that had been transferred as aggregates than between cells transferred as single cells. Cytochemical studies indicated that some cells produce PAS positive granules that were not removed after treatment of the cultures with diastase. Eleven cell clones were isolated from the mass culture. The growth rates of the clones are different as well as the period of time in which the clones can be propagated in vitro.

Transplantable pancreatic carcinoma of the rat

Pancreatic carcinoma, which developed in a male Fischer 344 rat fed 0.1% nafenopin for 20 months, is being successfully transplanted into weanling rats. The tumor cells contain variable numbers of zymogen granules, and the endoplasmic reticulum and the Golgi apparatus appear prominent. This transplantable tumor, which displays substantial amylase and lipase activity, should serve as a useful model system for immuno- and chemotherapeutic experiments, as well as for the study of synthesis, storage, and release of zymogen proteins in neoplastic cells.