Internalization of indium-labeled LDL through a lipid chelating anchor in human pancreatic-cancer cells as a potential radiopharmaceutical for tumor localization.

Low-density lipoproteins (LDL) labeled with indium via a lipid-chelating agent, the bis(stearylamide) of diethylenetri-aminepentaacetic acid (L), were evaluated as a potential radiopharmaceutical (111In-L-LDL) for tumor localization by studying their internalization in human pancreatic cancer cells (Capan-1). Using Dil-LDL (1,1'-dioctadecyl-3,3,3',3'-tetramethylindodicarbocyanine perchlorate-LDL), this cell line was shown to bind human LDL with a high-affinity saturable component and a low-affinity non-saturable (40%) component. The single saturable high-affinity binding site had a KD of 27.5 +/- 2.1 micrograms/ml and a maximal binding of 610 +/- 7.5 ng/ml protein. Electron-microscopic examination of the In-L-LDL particles revealed the peripheral distribution of the electron-dense indium atoms at the outer surface of LDL. The modified LDL were then shown to be internalized by the cells. After conjugation of In-L-LDL to colloidal gold to follow the different stages of internalization, electron-microscopic examination showed that the In-L-LDL gold conjugates were stuck to the external sheet of the plasma apical and microvilli membrane, into earlier and later endosomes and into multivesicular bodies, suggesting the penetration of the In-L-LDL particles into lysosomal vacuoles. The observation of In-L-LDL-gold conjugates in deep-seated cytoplasm suggests that LDL could be employed as a drug-transport vehicle for targeting cytotoxics or radionuclides close to the cell nucleus.

Progressive development of gap junctions during growth of human pancreatic duct cells (Capan-1) in vitro and in vivo.

Among their numerous functions, gap junctions play a crucial role in proliferation, differentiation and secretion processes, although their existence and potential role in ion secretion in human pancreatic ducts have yet to be established. To investigate the morphogenesis and the role of gap junctions in human pancreatic duct cells, the Capan-1 cell line maintained in culture or heterotransplanted into nude mice was employed as model system. Capan-1 cells polarize during their growth in vivo and in vitro forming duct-like structures. Furthermore in culture, after confluence, these cells form domes, which is indicative of ion exchange processes. After treatment with tannic acid and freeze-fracture, gap junctions were observed along the basolateral membranes of Capan-1 cells on electron microscopic examination. The presence of alkaline phosphatases on gap junctions was demonstrated cytoenzymatically. In addition, cell-to-cell communication was visualized by microinjection of Lucifer yellow. During differentiation of Capan-1 cells in culture, the frequency of intercellular communications increased markedly over the period (days 11-13) when the cells form duct-like structures. The increase in gap junctions was demonstrated by analysis of the polarized cells organized in duct-like structures that are commonly observed in the tumors formed by heterotransplantation of Capan-1 cells into nude mice. Furthermore, gap junctions associated with tight junctions were also observed in the cells forming such structures. The role of gap junctions in ion exchange was evaluated by counting the number of domes in cultures treated with heptanol. Heptanol (an uncoupling agent of gap junction communication) completely inhibited dome formation in a reversible way, and reduced the frequency of intracellular communications by 44%. These results suggest that the gap junctions expressed by Capan-1 cells are involved in ion secretion by the human cancerous pancreatic duct cell line, Capan-1. In the present study, we show that: i) the expression of gap junctions is linked to development of the spatial conformation of the cells; and ii) gap junctions may be involved in ion secretion.

Combined magnetic resonance imaging and spectrometry for characterization of human pancreatic adenocarcinoma (Capan-1) heterotransplanted in nude mice.

Human pancreatic cancer cells (Capan-1 cell line) were heterotransplanted subcutaneously into nude mice. The resulting macroscopically visible tumours were analyzed by proton nuclear magnetic resonance spectrometry in a search for characteristic parameters. The Capan-1 xenografts were visualized by nuclear magnetic resonance imaging and were characterized by a significantly increased transverse relaxation time T2 (125 +/- 32 ms) compared with that recorded from ex vivo healthy human pancreatic tissue (60 +/- 11 ms). Three characteristic signals at 2.73, 3.23 and 3.5 ppm were observed by nuclear magnetic resonance spectrometry. They corresponded to unsaturated fatty acids, phosphatidylcholine, glycerophosphorylcholine and/or taurine respectively. These peaks were not observed in the spectra recorded from healthy human or mouse pancreas. On the basis of these parameters, small intraperitoneal Capan-1 xenografts (less than 0.5 cm diam), which were only visible at the macroscopic level after opening the abdominal cavity, were accurately localized by magnetic resonance imaging and spectrometry.

Characterization of a specific signal from human pancreatic tumors heterotransplanted into nude mice. Study by high resolution 1H NMR and HPLC.

In a previous study, we demonstrated the existence of a 3.2 +/- 0.2 ppm peak in the 1H NMR spectrum at 60 MHz from human pancreatic adenocarcinomas (Capan-1 cell) heterotransplanted into nude mice. This peak, which is not present in normal human pancreas, was attributed to enhanced membrane fluidity and/or or an increase in phospholipid turnover. The present study was designed to identify this signal by comparing the 1H NMR spectra recorded in vivo at 100 MHz from Capan-1 tumors, after suppression of the tissular water proton peak, to those recorded from normal pancreatic tissue, and to those recorded at 300 MHz from lipid extracts. The 1H NMR spectra at 100 MHz of the Capan-1 tumors in vivo exhibited three main peaks in the 3.2 +/- 0.2 ppm region: 1. A peak at 2.8 +/- 0.1 ppm from CH2 protons of the acyl chains of unsaturated phospholipids; 2. A peak at 3.2 +/- 0.1 ppm from the protons of the N(CH3)3 group of choline; and 3 A peak at 3.5 +/- 0.1 ppm attributed to GPC. The NMR 1H 300 MHz spectrum of phospholipid extracts of Capan-1 tumors displayed 12 principal resonances, of which only the N(CH3)3 peak of PC had a similar chemical shift to that observed at low resolution (3.2 +/- 0.2 ppm). This peak had a higher intensity in the xenografts than in normal human pancreatic tissue. HPLC analysis of the same lipid extracts from Capan-1 cells in culture, of tumors derived from these cells and from normal pancreas showed: 1. Identical concentrations of the different phospholipids from cancerous human pancreatic cells in vivo and in culture; and 2. A significantly higher level of PC in the extracts of normal human pancreatic tissue. The increase in intensity of the N(CH3)3 peak of PC in the Capan-1 tumors was not thought to be caused by an increase in PC concentration, but to a difference in conformation or mobility of the PC protons in the xenografts. The increase in relaxation time in cancerous tissue (from 60 to 125 ms) was also taken to be evidence in favor of a high mobility of protons.(ABSTRACT TRUNCATED AT 400 WORDS)

Creatine phosphate as energy source in the cerulein-stimulated rat pancreas study by 31P nuclear magnetic resonance.

Stimulation of the rat exocrine pancreas by cerulein induces a variety of cellular processes, some of which require the expenditure of energy. In this study, changes in the amounts of various energy metabolites, including creatine phosphate (PCr), ATP, and ADP were determined by high-resolution 31P NMR spectroscopy. The spectrum of a perchloric acid extract of pancreas from the 48 h fasted rat was taken as a reference for comparison of 31P NMR spectra recorded after stimulation by cerulein. The NMR results obtained from rat pancreas stimulated in vivo by cerulein (3, 5, 10, 20, 40 min) were compared to those determined by HPLC. We show that during hormonal stimulation, the relative concentrations of PCr in the pancreas of the fasted rat rise significantly (p less than 0.02), reach a maximum at 10 min, fall between the 10th and 20th min, and then return to the relatively low levels observed in controls. On the other hand, the relative concentrations of ATP fall during the first 10 min after stimulation by cerulein, then rise significantly between the 10th and 20th min, whereas the levels of ADP rise during the first 10 min and fall between the 10th and 20th min. The energy required for exocytosis was assumed to be supplied by ATP synthesized in acinar cells. The 31P NMR results indicated that this ATP was derived from phosphorylation of ADP by PCr, and that large amounts of PCr are synthesized during the first minutes after cerulein stimulation. In addition, a significant rise in glycerophosphocholine was observed after cerulein stimulation, which was attributed to an enhanced catabolism of membranes and an increase in phospholipid turnover. Injection of cerulein antagonists, such as asperlicin or lorglumide, inhibited the effects of cerulein stimulation on energy metabolites. Furthermore, no changes were observed after injection of secretin, a hormone that stimulates secretion of bicarbonate. However, the analog of cerulein, pentagastrin, produced the same effects as cerulein, although to a lesser extent.

Expression and characterization of alkaline phosphatases during differentiation of human pancreatic cancer (Capan-1) cells in culture.

Human pancreatic cells of the Capan-1 cell line differentiate in culture. During the exponential growth phase, the cells are undifferentiated, only becoming differentiated during the stationary phase. The formation of domes in this phase is related to the exchange of water and electrolytes. The present study was designed to characterize the localization and expression of alkaline phosphatases (AP) in Capan-1 cells during growth in culture. Biochemical, cytoenzymatic and immunocytochemical methods were employed combined with light and electron microscopic examination. AP essentially of the placental type were expressed progressively during the exponential growth phase, and were seen to be distributed over the surface of the Capan-1 cells. In the stationary phase, the AP became localized on the surface of microvilli. The precipitates of the enzyme reaction highlighted regular four-bodied structures. Biochemical assays showed a progressive increase in activity of this enzyme in cells during both the exponential and stationary growth phases. However, in the stationary phase between days 7 and 8, there was a fall in enzyme activity, with a corresponding increase in this activity in the culture medium. Cytological examination indicated that this fall could be accounted for by loss of AP-positive membranes by vesiculization of apical microvilli and release of microvesicles into the culture medium. Immunoblots showed that Capan-1 cells expressed two types of AP, a placental type (70 kDa) and to a lesser extent a liver type (80 kDa). Expression of the placental type was attributed to a neoplastic derepression of the coding gene, while the liver type was assumed to be a normal gene expression of human duct cells. The placental type AP might thus serve as a marker of transformation, and the liver type as a marker of differentiation.

Calcium phosphate deposits in domes of human pancreatic adenocarcinoma (Capan-1) cell cultures.

Human pancreatic cells of the Capan-1 line form domes in culture during the stationary growth stage. The domes are thought to be a result of the transport of water and electrolytes by the Capan-1 cells. In older Capan-1 cultures, the epithelial sheets formed thickenings from several layers of cells of which the outermost ones were joined by tight type junctions. In the intracellular space, deposits of insoluble calcium salts were observed. Culture of Capan-1 cells in the presence of fibroblasts prolonged survival of the cultures with intact domes for more than 80 days. The Capan-1 cells proliferated forming multilayers and closed cavities which we called super-domes. X-ray spectrometry and electron diffraction analysis showed that the abundant deposits inside these cavities consisted of calcium phosphate in an apatite structure. The number of these deposits increased with time in culture, and they appeared to be formed at the sites of contact with an extracellular matrix consisting of cell debris. Deposits were not observed within the culture medium. Cells from domes were stained cytochemically for ATPases and alkaline phosphatases and examined by light and electron microscopy. The Capan-1 cells surrounding the domes were differentiated, polarized cells containing placental type alkaline phosphatases on their apical membranes and Ca2(+)-ATPases on their basolateral membranes. These enzymes were thought to play a role in the accumulation of phosphate and Ca2+ ions in the dome cavities, which then formed crystals in the presence of organic compounds produced by lysis of cells of the deepest layers of the super-domes. The crystals of hydroxyapatite observed in standard Capan-1 cell cultures and those cocultured with fibroblasts were assumed to be a result of transepithelial transport of Ca2+ and phosphate ions by these cells.

Culture of islets of Langerhans from an infant with intractable neonatal hypoglycemia: cytochemical and radioimmunological studies.

Extralobular islet of Langerhans cells were isolated from the pancreas of an infant with intractable neonatal hypoglycemia (nesidioblastosis) by digestion with a mixture of trypsin and collagenase, and subsequent purification on a gradient of fetal calf serum. These islet cells cultured in Eagle's medium containing 20% fetal calf serum formed confluent endocrine cell monolayers within 15 days. These endocrine cells were studied immunocytochemically, and their secretion products were assayed by radioimmunological methods. The large numbers of beta, alpha and delta cells present in the islets before explanation remained functional in the cultures for 30 days. The beta cells secreted large amounts of insulin throughout this period, and secretion was stimulated by raising the glucose concentration in the medium from 5.6 to 16.8 mM. Initially there was little secretion of glucagon, but this increased during the subsequent 10 days in culture. It was not inhibited when the glucose concentration was raised from 5.6 to 16.8 mM. Somastostatin secretion remained stable throughout the period of culture, but tended to rise when the glucose concentration was increased. These results show that the culture of pancreatic cells from infants with nesidioblastosis provides an interesting in vitro system for studying the biological and biochemical characteristics of endocrine cells in the human pancreas.

Enhanced membrane phospholipid metabolism in human pancreatic adenocarcinoma cell lines detected by low-resolution 1H nuclear magnetic resonance spectroscopy.

The low-resolution proton nuclear magnetic resonance (NMR) spectra of human pancreatic adenocarcinomas maintained in nude mice and in culture exhibit characteristic features. First, the high values of longitudinal (T1) and transverse (T2) relaxation times were attributed to disturbances in the exchange of ions and water molecules in cancerous cells. Second, a new peak situated at about 1.8 +/- 0.2 ppm from the peak of tissular water was observed. It was higher in spectra recorded from the proliferative peripheral zone of the tumor than from the central necrotic zone and was not observed in healthy control pancreatic tissue. Histological examination of the xenografts by transmission electron microscopy indicated intense phospholipid metabolism with marked development of the plasma membrane and the presence of numerous secretory granules, lysosomes, and multivesicular bodies in the cytoplasm. The new 1H NMR low-resolution peak was thought to reflect an increase in membrane viscosity stemming from alterations in the structure and metabolism of membrane phospholipids. Whatever its origin, the 1.8-ppm peak is a particular feature of cancerous pancreatic cells, which should be readily detectable by NMR in vivo.

Differentiation of the human pancreatic adenocarcinoma cell line (Capan-1) in culture and co-culture with fibroblasts dome formation.

This study was designed to investigate differentiation of human pancreatic duct carcinoma cells (Capan-1) in vitro. Observations on live cells, and electron microscopic examination, together with enzymological and immunocytochemical methods, have demonstrated that these cells differentiate spontaneously at an early stage. The cells are seen to be joined by apical junctions. High ATPase activity can be detected in the basolateral membranes, and the cells secrete a gastric type mucin (MI) bearing acidic groups. During differentiation in culture, they form domes which are thought to be the morphological expression of trans-epithelial transport of water and electrolytes. This particular structure is transitory, since after 6 days in culture all the cells lose their adhesivity, and form into floating cords. Co-culture of Capan-1 cells and human, nude mice or chick embryo fibroblasts leads to a higher degree of differentiation of epithelial cells, reflected by the earlier appearance of numerous domes. In addition, the anchorage of Capan-1 cells to fibroblasts prevents retraction of the monolayer, and enables the domes to be maintained in the cultures for more than one month. These findings suggest that Capan-1 cells are able to carry out trans-epithelial movement of water and electrolytes. It is suggested that excretion of ions (bicarbonate and/or chloride) is preserved after transformation of pancreatic duct cells. Mucins (MI) and the recently described VIP receptor sites are also thought to play a part in these exchange processes.

Noninvasive fluorine-19 NMR study of fluoropyrimidine metabolism in cell cultures of human pancreatic and colon adenocarcinoma.

Fluorine-19 NMR spectrometry was used to monitor the metabolism of two antineoplastic fluoropyrimidines, 5-fluorouracil (5FU) and 5'-deoxy-5-fluorouridine (5'dFUrd), in cell cultures of human pancreatic (Capan-1) and colon (HT-29) adenocarcinoma. The preliminary results showed, for the two tumor cell lines treated with 5FU, the presence in nonperfused cells of three signals corresponding to intracellular metabolites: 5FU, F-nucleotides and F-nucleosides. When the cells were perfused only the signals of F-nucleotides and 5FU were present. The F-nucleosides observed during the analysis of the nonperfused cells came from the conversion of F-nucleotides. During the NMR recording of Capan-1 cells at 37 degrees C the first metabolite of the catabolic pathway of 5FU, 5,6-dihydro-5-fluorouracil, occurred. At the beginning of the NMR recording of Capan-1 cells treated with 5'dFUrd, two signals corresponding to F-nucleotides and F-nucleosides (consistent with 5'dFUrd) were observed; during the analysis, a supplementary signal corresponding to 5FU appeared. Even after pretreatment with methotrexate the signal of 5FU incorporated into RNA was not detected. Our experiments, performed in attempts to observe the signal of the ternary complex between thymidylate synthetase (TS), 5-fluoro-2'-deoxyuridine-5'-monophosphate (FdUMP) and 5,10-methylene-tetrahydrofolate (5,10-CH2FH4), allowed detection in some cases of a broad signal, whose chemical shift was similar to that reported in the literature following incubation of TS with FdUMP and 5,10-CH2FH4, but our results were not always reproducible.