The effect of culture conditions on the fluidity of mouse neuroblastoma membranes as estimated by spin label studies

Gas chromatography and spin labeling were used to estimate the composition and fluidity of the lipid acyl chains in intact cell membranes of mouse C1300 neuroblastoma. Neurite formation and an increase in the specific activity of acetylcholinesterase are induced in this cell line by the removal of serum from the culture medium for one day prior to harvesting the cells. The fatty acid composition of induced cells was not significantly different from that of the non-induced controls. Each of the three fatty acid spin labels used in this study indicate that the membranes of induced cells are slightly more fluid than the membranes of control cells. This difference in fluidity appears to be a result of a reduction in the progressive decrease in fluidity occurring during growth in serum. A four-fold reduction in cell viability had no effect on the measured bilayer fluidity. Thus the changes in fluidity appear to be due to the presence or absence of serum rather than to cell type, age, or viability.     

Neurite outgrowth induced by an endothelial cell mitogen isolated from retina

Retina-derived growth factor (RDGF) is a polypeptide growth factor purified from salt extracts of bovine retinas on the basis of its mitogenic activity for capillary endothelial cells (EC) and BALB/c 3T3 cells. RDGF is angiogenic in vivo. We show here that RDGF induces neurite extension by PC12 cells and that this neurite outgrowth is dramatically potentiated by heparin. Neurite formation elicited by RDGF in the presence of heparin cannot be distinguished from that elicited by nerve growth factor (NGF) either by the time course of neurite formation or by the morphology of the neurites at the level of the light microscope. Neurite outgrowth induced by either purified RDGF or by a crude retinal extract is not blocked by antibodies to NGF. Furthermore, neurite outgrowth induced by NGF is not potentiated by heparin and NGF is not mitogenic for capillary EC. Thus, RDGF has profound regulatory effects on cell types of very different embryonic origins. These results indicate that the physiological role for this growth factor may be far more complex than previously suspected and suggest that the formation of neural connections and the process of vascularization may unexpectedly share common regulatory elements.     

Antisense Oligonucleotide of Clusterin mRNA Induces Apoptotic Cell Death and Prevents Adhesion of Rat ASC-17D Sertoli Cells

Clusterin has been known to play important roles in cell-cell and/or cell-substratum interactions. Recently we reported the transient expression of clusterin in pancreatic endocrine cells during the early developmental stages and suggested a role in aggregating the endocrine cells for islet formation. In the present study, we have investigated the involvement of clusterin in cell-substratum interaction by the inhibition of clusterin synthesis using antisense oligonucleotide. The expression of clusterin was transiently increased as early as 2–8 h after plating the ASC-17D Sertoli cells to the culture flask, which was the period of cell attachment. In addition, up-regulation of clusterin mRNA was so much greater when the Sertoli cells were plated on the petri dish for the bacterial culture instead of in a animal cell culture flask that therefore, the cells failed to attach to it. These findings suggested that interruption of cell to plate substratum interaction might lead to over-expression of clusterin from Sertoli cells to induce cell to cell aggregation or, perhaps, to re-establish attachment with the substratum. Transfection of ASC-17D Sertoli cells with a 20-base antisense oligonucleotide against clusterin mRNA resulted in extracellular release of LDH and DNA fragmentation. Sertoli cell death by antisense oligonucleotide of clusterin was sequence specific and dose dependent. Treatment of antisense oligonucleotide induced a marked reduction of synthesis for clusterin protein, but not for clusterin mRNA expression, suggesting the translational suppression of clusterin by antisense oligonucleotide. Further, microscopic observation showed that more noticeable cell death was induced by treating the antisense prior to plating the cells than by treating after cell attachment to the plate. From these results, we speculate that down-regulation of clusterin expression in the anchorage-dependent Sertoli cells prevents them from attaching to the plate, and therefore induces cell death.     

Studies on the action of nerve growth factor: I. Characterization of a simplified in vitro culture system for dorsal root and sympathetic ganglia

Neurite outgrowth from dorsal root (DRG) and sympathetic ganglia has been studied utilizing a simplified in vitro culture system for intact ganglia. Attachment of ganglia to tissue culture plates was achieved after a brief incubation of ganglia on the plates in the presence of 100% fetal calf serum or 5% ovalbumin in F12 medium. Neurite outgrowth from dorsal root and sympathetic ganglia was dependent on the continued presence of nerve growth factor (NGF) and on the NGF concentration. The NGF induced neurite outgrowth from DRG cultured in serum-free medium was delayed approximately 24 hr compared to the outgrowth in serum-containing medium.     

Studies on the action of nerve growth factor. III. Role of RNA and protein synthesis in the process of neurite outgrowth.

Chick embryo dorsal root and sympathetic ganglia cultured on untreated tissue culture plates exhibited a dependence upon both RNA and protein synthesis for the expression of nerve growth factor-mediated neurite outgrowth. Neurite outgrowth was no longer dependent upon RNA synthesis, but remained dependent upon continued protein synthesis when ganglia were cultured in plasma clots, or on either collagen or poly-l-lysine coated plates. Nerve growth factor-induced neurite outgrowth was dependent upon the presence of either microexudates, which may play an important role as functional components of the substratum across which neurites migrate, or exogenous substrata such as collagen, fibrin, or poly-l-lysine.     

Thyroid hormone directly induces hepatocyte competence for estrogen-dependent vitellogenin synthesis during the metamorphosis of Xenopus laevis

Hepatocytes competent for estrogen-dependent vitellogenin synthesis appeared and increased in number in the liver at the metamorphic climax of Xenopus laevis (A. Kawahara, S. Kohara, Y. Sugimoto, and M. Amano, 1987, Dev. Biol. 122, 139-145). The present study was conducted to determine whether cells competent for vitellogenin synthesis could be induced by thyroid hormone in a primary culture of larval hepatocytes. The thyroid hormone, triiodothyronine (T3), directly induced the competent cells in a primary culture of premetamorphic larval hepatocytes in a dose- and duration-dependent manner. The competency acquired in response to T3 persisted after removal of the hormone. Aphidicholin, an inhibitor of DNA synthesis, failed to block this induction, suggesting the presence of a "precursor cell fraction." This cell fraction in the hepatocyte population increased with the progress of metamorphosis. The thyroid hormone is thus considered the cause of competent cell formation at metamorphic climax.     

Promotion of neurite and filopodium formation by CD47: roles of integrins, Rac, and Cdc42

Axon extension during development is guided by many factors, but the signaling mechanisms responsible for its regulation remain largely unknown. We have now investigated the role of the transmembrane protein CD47 in this process in N1E-115 neuroblastoma cells. Forced expression of CD47 induced the formation of neurites and filopodia. Furthermore, an Fc fusion protein containing the extracellular region of the CD47 ligand SHPS-1 induced filopodium formation, and this effect was enhanced by CD47 overexpression. SHPS-1-Fc also promoted neurite and filopodium formation triggered by serum deprivation. Inhibition of Rac or Cdc42 preferentially blocked CD47-induced formation of neurites and filopodia, respectively. Overexpression of CD47 resulted in the activation of both Rac and Cdc42. The extracellular region of CD47 was sufficient for the induction of neurite formation by forced expression, but the entire structure of CD47 was required for enhancement of filopodium formation by SHPS-1-Fc. Neurite formation induced by CD47 was also inhibited by a mAb to the integrin beta3 subunit. These results indicate that the interaction of SHPS-1 with CD47 promotes neurite and filopodium formation through the activation of Rac and Cdc42, and that integrins containing the beta3 subunit participate in the effect of CD47 on neurite formation.     

Regulation of parthenogenetic activation of metaphase II mouse oocytes by pyruvate

We report that parthenogenetic activation (pronuclear formation) is induced during in vitro culture of recently ovulated (13-14 hr post-hCG) mouse oocytes in pyruvate deficient medium. Pronuclear formation occurred when oocytes were cultured in medium containing 1/10X (Pyr-) or lower concentrations of pyruvate but failed to occur either in oocytes cultured in the presence of 0.47 mM (1X, Pyr+) or 1/2X pyruvate or in oocytes cultured in the absence of pyruvate but with cumulus cells. Pronuclear formation was evident within 8 hr of culture and completed by 16 hr and remained intact during continuous culture in Pyr- medium. Transfer of pronuclear oocytes to Pyr+ medium resulted in pronuclear membrane disassembly and further parthenogenetic development. A similar incidence of parthenogenetic activation occurred when recently ovulated oocytes were cultured in the presence of cycloheximide but not following ethanol or hyaluronidase treatment. However, both ethanol and hyaluronidase induced pronuclear formation in in vivo aged oocytes. Results suggest that the type of activation induced varies with the age of the oocyte and the nature of the stimulus. Amino acid uptake ([35S]methionine) by oocytes was unaffected by Pyr- culture whereas incorporation into protein was markedly inhibited. Gel electrophoretic analysis of labeled egg extracts revealed a marked inhibition of egg protein synthesis after 4 hr of culture in Pyr-. The occurrence of a cortical reaction was monitored by binding of fluorescent labeled lectin to the oocyte surface. A cortical reaction occurred in response to ethanol treatment of freshly ovulated and in vivo aged oocytes cultured in Pyr+ medium but not in pronucleate oocytes induced by Pyr- culture. Suppression of ethanol-induced cortical reaction by Pyr- culture was restored following transfer of oocytes to Pyr+ medium. Results demonstrate that nuclear events as well as plasma membrane events can be simply regulated by controlling the amount of energy substrate available to the germ cell. Effects of Pyr- culture in inducing pronuclear formation appear to be mediated in a large part via inhibition of protein synthesis.     

Serum and insulin inhibit cell death induced by cycloheximide in the human breast cancer cell line MCF-7

Summary Continuous exposure of cells to cycloheximide (CHM) terminates in cell death. This may result from CHM’s inhibition of protein synthesis. In the present study we investigated the effect of serum and insulin on cell death induced by CHM in the human breast cancer cell line MCF-7, and correlated this effect to the inhibition of protein synthesis. Cell death was evaluated by measuring either dead cells by the trypan blue dye exclusion test or by the release of lactic dehydrogenase into the culture medium. CHM (0.1 to 50 μg/ml) was shown to induce cell death in a time- and concentration-dependent manner. Including either fetal bovine serum or insulin in the culture medium inhibited this cell death in a concentration-dependent manner. Protein synthesis as measured by [³H]leucine incorporation was inhibited by the increasing concentration of CHM, However, fetal bovine serum and insulin did not alter the protein synthesis inhibition rate induced by CHM. These results indicate that inhibition of protein synthesis is not enough for cell death to proceed. Insulin or factors present in serum may stabilize some crucial cell proteins (key enzymes, cytoskeletal or membrane components) which are vital for cell life.     

The induction and suppression of in vitro IgG anti-tetanus toxoid antibody synthesis by human lymphocytes stimulated with tetanus toxoid in the absence of in vivo booster immunizations

This report presents a new approach that by-passes booster immunizations with tetanus toxoid (TT) before in vitro studies of antibody (Ab) production. The methodology for optimal TT-induced synthesis of specific IgG anti-tetanus toxoid Ab (IgG anti-TT) by peripheral blood mononuclear cells (PBMC) from randomly selected TT immune individuals without recent booster immunizations is described. PBMC from most normal immune subjects could be repeatedly induced to produce in vitro IgG anti-TT; PBMC from subjects with high TT titers are not required for this new approach. This approach uses high cell concentrations in multiple replicate microcultures and TT washout to obtain optimal IgG anti-TT synthesis. Washed cultures produced more Ab than nonwashed cultures (p less than or equal to 0.005). The readdition of TT (2.5 to 250 ng/ml) to the culture media after washout of TT on day 4 suppressed specific Ab formation, whereas diphtheria toxoid added at comparable doses did not inhibit specific Ab formation. Suppression of antibody synthesis mediated by T cells could be induced by TT per se, and was not due to binding of synthesized Ab to TT in the latter 8 days of culture. In addition, suppression could not be induced in the first 4 days of culture by IgG anti-TT, IgG, or IgM. This approach permits the analysis of antigen-specific regulatory circuits in the steady and activated immune states, and the evaluation of in vivo and in vitro effects of biologic response modifiers on specific Ab production.     

Enhanced neurite outgrowth by human neurons grown on solid three-dimensional scaffolds

Growing and differentiating human stem cells in vitro can provide access to study the molecular mechanisms that control cellular development in a manner pertinent to human embryogenesis. To fully understand such processes, however, it is important to recreate culture conditions that most closely relate to those in living tissues. As step in this direction, we have developed a robust three-dimensional cell culture system using inert highly porous solid matrices manufactured from polystyrene that can be routinely used to study the differentiation of human pluripotent stem cell-derived neurons in vitro. Neurite outgrowth was significantly enhanced when neurons were grown in a three-dimensional environment compared to traditional flat surfaces and resulted in the formation of extensive neural networks. These data suggest that the topography within the culture environment can significantly alter cell development and will therefore be an important feature when investigating the potential of human stem cells.     

Metabolic requirements for differentiation of embryonic sympathetic ganglia cultured in the absence of exogenous nerve growth factor.

The embryonic mouse superior cervical ganglion (SCG) in culture was employed to define the role of ongoing metabolic processes in morphological and biochemical development. The 14 gestational day SCG does not require added nerve growth factor (NGF) for differentiation in vitro. Consequently, its use allows study of intraganglionic regulation of neuronal growth in the absence of complicating, exogenous growth factors. Ganglia were cultured without added NGF, in medium containing various metabolic inhibitors; neurite elaboration and development of tyrosine hydroxylase (T-OH) activity, a biochemical marker of adrenergic maturation, were evaluated. Neurite elaboration proceeded normally with inhibition of RNA synthesis by actinomycin D, or of protein synthesis by cycloheximide or puromycin. In contrast, inhibition of RNA or protein synthesis prevented normal development of T-OH activity. However, neurites and T-OH developed normally in the presence of DNA synthesis inhibition by cytosine arabinoside, which markedly reduced the nonneuronal cell population. These observations suggest that neurite elaboration and the ontogenetic increase in T-OH activity are regulated differently in ganglia cultured in the absence of exogenous NGF. Moreover, the initial outgrowth of neurites and increase in T-OH activity may occur independent of peripherally migrating support cells in this embryonic ganglion.     

N-acetylglucosaminyltranferase VB expression enhances beta1 integrin- dependent PC12 neurite outgrowth on laminin and collagen

N-acetylglucosaminyltransferase VB (GnT-VB, -IX) is a newly discovered glycosyltransferase expressed exclusively in high levels in neuronal tissue during early development. Its homolog, GnT-V, is expressed in many tissues and modulates cell-cell and cell-matrix adhesion. The ability of GnT-VB to regulate cell-matrix interactions was initially investigated using the rat pheochromocytoma PC12 neurite outgrowth model. PC12 cells stably transfected with GnT-VB consistently showed an enhanced rate of nerve growth factor (NGF)-induced neurite outgrowth on collagen and laminin substrates. Levels of TrkA receptor phosphorylation and downstream ERK activation induced by NGF were not influenced by GnT-VB expression. No significant difference was observed in the rate of neurite outgrowth when cells were cultured on non-coated culture dishes, indicating that integrin-ECM interaction is required for the stimulatory effects. Neurite outgrowth induced by manganese-dependent activation of beta1 integrin on collagen and laminin substrates, however, showed a significant increase in neurite length for the PC12/GnT-VB cells, compared with control cells, suggesting that the enhancement is most likely mediated by alteration of beta1 integrin-ECM interaction by GnT-VB. These results demonstrate that GnT-VB expression can modulate the rate of neurite outgrowth by affecting beta1 integrin-ECM interaction.     

T cell induction of membrane IL 1 on macrophages

We have studied the role of T cells in the induction of a membrane-associated form of interleukin 1 (mIL 1) in murine macrophages. T helper cell clones and a T cell hybridoma induced macrophages to express mIL 1 after an antigen-specific, Ia-restricted interaction. Induction of mIL 1 was proportional to antigen concentration and was increased in the early course of the response in macrophages pretreated in culture with interferon-gamma. mIL 1 activity was detectable 4 hr after interaction with T cells. mIL 1 induction was inhibited by antibodies to either class II molecules or the T cell receptor. Two pathways of T cell-mediated mIL 1 induction could be defined. In the first, T cells, whose protein synthesizing capacity was completely eliminated by pretreatment with the irreversible protein synthesis inhibitor emetine, induced levels of mIL 1 expression indistinguishable from controls. In the second, T cells stimulated by paraformaldehyde-fixed macrophages in the presence of concanavalin A or antigen secreted a soluble factor that induced macrophage mIL 1 expression. Thus, it appears that T cells may induce macrophages to express mIL 1 both by direct cell-cell contact mediated through binding of T cell receptor to the Ia/antigen complex, and through the release of a lymphokine after activation. This lymphokine does not appear to be IL 2, IFN-gamma, BSF-1, or CSF-1.     

Novel Madin Darby Canine Kidney cell clones exhibit unique phenotypes in response to morphogens

Summary Novel Madin Darby Canine Kidney cell clones were isolated. These cell clones exhibit differential responsiveness to inducers of tubule or cyst formation in collagen gel culture: hepatocyte growth factor or inducers of intracellular cAMP formation, respectively. In gel culture, clone OR93.22.D6 forms cysts and responds with morphological transformation to both hepatocyte growth factor and prostaglandin E₁, and is most typical of a previously described cell type except for its higher transepithelial electrical resistance. OR55.25.II20 forms tubules in culture, is unresponsive to hepatocyte growth factor, and forms prostaglandin-induced spherical cysts. OR55.28.V2 forms dense cell spheres under control conditions, is induced to form tubules by hepatocyte growth factor, and is unresponsive to prostaglandin. OR55.29 forms only cysts, and is the only clone to form domes in monolayer culture. Tubule formation induced by hepatocyte growth factor, in all clones except OR55.25.II20, is blocked by a neutralizing antibody. In defined medium, without hepatocyte growth factor or prostaglandin, OR55.25.II20 forms spontaneous tubules. This finding indicates that a tubulogenic serum factor is not responsible for the observed phenotype. Increasing prostaglandin concentrations lead to inhibition of tubule formation and increased cyst formation. This observation suggests that induction of intracellular cAMP formation negatively regulates tubule formation in these cells, and implies that cystogenesis may represent a “default pathway” for impaired tubulogenesis. These observations demonstrate that some facets of renal tubulogenesis may be independent of hepatocyte growth factor, and that care must be exercised when comparing biological studies utilizing different clones.     

The nature of unbalanced cell growth caused by cytotoxic agents

The volume of cells grown in tissue culture following exposure to a wide variety of cytotoxic drugs or x-rays increases at a rate of 1 to 10% of cell mass per hour. The same phenomenon is seen in animal neoplasias and human leukemias. This increase in cell volume is the result of unbalanced cell growth with a resulting disproportionate synthesis of proteins and possibly other macromolecules in the cytoplasm and nucleus. The dose response curve for a decrease in cell survival as measured by cloning efficiency in tissue culture is quantitatively correlated with the dose response curve for inducing an increase in cell volume. This quantitative relationship makes feasible the use of the phenomenon of unbalanced cell growth as a measure of cell death in screening for cytotoxic drugs or in monitoring response to therapy. An hypothesis to explain this increase in cell volume following chemotherapy is that cells are by the action of these drugs induced into an abortive or unbalanced pseudo-cycle which is characterized by synthesis of substantial amounts of protein without other preparative steps for cell division.     

The role of cell proliferation and cellular shape change in branching morphogenesis of the embryonic mouse lung: analysis using aphidicolin and cytochalasins

The formation of induced supernumerary buds in the embryonic mouse tracheal epithelium has been used as a model system to analyse the respective roles of cell proliferation and microfilament-mediated cell shape change during branching morphogenesis. In order to analyse the mitotic events associated with the formation of epithelial buds, the induction of supernumerary tracheal buds by mesenchymal grafts was carried out with the inhibitor of DNA synthesis, aphidicolin, present in the culture medium for varying intervals of time during the 16-hour inductive process. The presence of aphidicolin for 10 to 16 hours of the inductive period blocks the formation of induced tracheal buds, whereas the presence of the inhibitor for half of that time (either the first 8 hours or the last 8 hours) does not prevent this morphogenetic event from taking place, although smaller buds resulted from induction under these conditions. Both the inhibition of DNA synthesis and the recovery from 10 microM aphidicolin treatment, as measured by 3H-thymidine incorporation, were found to occur rapidly. The addition of 2 microM dihydrocytochalasin B (or cytochalasin B) together with aphidicolin during the second half of the inductive period inhibits the formation of supernumerary buds and upon removal of the cytochalasin rapid formation of buds takes place. We conclude that the formation of epithelial buds during branching morphogenesis occurs as a result of enhanced localized cell proliferation coupled with epithelial cell shape change (or preservation of cell morphology) mediated by microfilaments, which have been observed in both the apical and basal cytoplasm of the epithelial cells in the region where branching of the trachea is taking place.     

Neurite outgrowth of neuroblastoma cells: dependence on adhesion surface--cell surface interactions

Neurite outgrowth of C 1300 neuroblastoma cells, which were dispersed from adherent cultures or grown in suspension, was studied on different protein-coated surfaces. Of 29 different surface structures studied, including surfaces treated with various fibronectins, lectins, glycosidases, or glycosyltransferases capable of stimulating fibroblast spreading, only the surfaces coated with plasma fibronectin or with a protein mixture secreted by C6 glioma cells displayed an extensive activity in the sprouting assay. Neurite outgrowth was inhibited by brain gangliosides and by colominic acid (a sialic acid polymer). A 50% inhibition of neurite outgrowth of N18 neuroblasts induced by the glioma cell proteins was observed at the following approximate concentration: 100 microM (0.2 mg/ml) GD1A ganglioside, 20 microM (0.04 mg/ml) GT1B ganglioside, and 5 mg/ml colominic acid. Specificity of inhibition was suggested by the finding that a few polyanionic substances tested were not inhibitory in the sprouting assay, and that the type of gangliosides inhibiting sprouting were found to be major sialoglycolipids of the neuroblasts. A hypothesis is discussed, according to which neurite outgrowth of neuroblasts is stimulated by adhesion involving interactions of the adhesion-mediating protein with cell surface carbohydrates characteristic of brain gangliosides.     

Synchronous culture of Magnetospirillum sp. AMB-1 by repeated cold treatment

Abstract We established a synchronous culture of Magnetospirillum sp. AMB-1 by repeated cold treatment at 5 °C. This is the first reported synchronous culture of a magnetic bacterium. Cold treatment did not affect magnetic particle synthesis or cell morphology. Iron uptake was observed both before and during cell division. The amount of iron uptake was almost equivalent to that of magnetite formation. The proportion of magnetosensitive cells did not change during cell division.