N18 Cells Research Articles

Sphingomyelinase activities in neuronal cell cultures

Human and rat brains have been previously demonstrated to contain three sphinomyelinases, one lysosomal with a pH optimum of 5.0, one with a pH optimum of 7.4 and a dependence on magnesium and another with a pH optimum of 7.0 and no divalent cation requirement. Using brain cell cultures and clonal cell lines of both neuronal and glial origin the activities of the pH 5.0 and pH 7.4 (magnesium-dependent) sphingomyelinase were examined. Sphingomyelinase activity measured at pH 5.0 was found in all the cell lines tested including G26, C6, N18 (differentiated and undifferentiated), mouse “L” cells, human skin fibroblasts, fetal mouse brain surface cultures and fetal mouse brain reaggregate cultures. However, pH 7.4 (magnesium-dependent) sphingomyelinase activity was found only in the N18 cell lines and the reaggregate cultures suggesting the probable localization of this activity in neurons. Although the pH 7.4 sphingomyelinase activity was found in the fetal mouse brain used for the surface cultures this activity was rapidly lost. This enzyme may play an important role in neuronal development and maturation.

Identification of a high molecular weight nervous system specific cell surface glycoprotein on murine neuroblastoma cells

An antiserum to N18 neuroblastoma cells has been used to identify a glycoprotein of apparent molecular weight greater than 200 000 D in SDS-polyacrylamide gels. This glycoprotein (Band 1) is found in culture medium of N18 cells. An immunologically similar component can be immunoprecipitated from detergent extracts of enzymatically iodinated or biosynthetically labelled viable cells. Anti-band 1 activity can be adsorbed from the antiserum by intact N18 cells but not four other cultured murine cell lines. Normal adult murine brain also adsorbs anti-band 1 activity but adult murine adrenal, heart, kidney, liver, lung, and spleen do not. Several experiments indicate that band 1 is not myosin heavy chain or the fibroblast LETS protein. Thus band 1 is a newly identified high molecular weight nervous system specific glycoprotein.

Proteins from morphologically differentiated neuroblastoma cells promote tubulin polymerization.

Clonal cells (N18) of the mouse neuroblastoma C-1300 can be induced to undergo a morphological differentiation characterized by the outgrowth of very long neurites (> 150 microns) that contain many microtubules. Because the marked increase in the number and length of microtubules is apparently not due to an increase in the concentration of tubulin subunits, the possible role of additional macromolecules in the regulation of tubulin polymerization during neurite formation by N18 cells was examined. Using an in vitro system where the polymerization of low concentrations (< 4 mg/ml) of purified brain tubulin requires microtubule-associated proteins (MAPs), high-speed supernates (250,000 g) from neuroblastoma and glioma cells were assayed for their ability to replace MAPs in the polymerization of brain tubulin. Only the supernates from "differentiated" N18 cells were polymerization competent. Electron microscope observations of these supernates failed to demonstrate the presence of nucleation structures (rings or disks). The active factor(s) sedimented at approximately 7S on sucrose gradient centrifugation and eluted from 4B Sepharose in the region of 170,000 mol wt proteins. Furthermore, the inactive supernates from other cells did not inhibit polymerization when tested in the presence of limiting MAPs. Thus, microtubule formation accompanying neurite outgrowth in neuroblastoma cells appears to be regulated by the presence of additional macromolecular factor(s) that may be functionally equivalent to the MAPs found with brain microtubules.

GANGLIOSIDE COMPOSITION AND BIOSYNTHESIS IN CULTURED CELLS DERIVED FROM CNS

Abstract— Cultured mouse neuroblastoma cells (clone N18) contained a homologous series of gangliosides, GM3, GM2, GM1 and GD1a; the total lipid bound sialic acid (LBSA) was 3.3 nmol per mg of protein, of which GD1a comprised two‐thirds. In contrast, neonatal hamster astrocytes (clone NN) and human glioblastoma cells (Cox clone) contained mainly GM3, which represented 95% of the 2 nmol of LBSA per mg protein in these cells. When the cells were grown in the presence of [14C]galactose, label was incorporated into all of the gangliosides isolated from the cells. The labeling pattern corresponded to the ganglioside composition of the cell lines; GD1a was more extensively labeled in N18 cells and GM3 was the major labeled ganglioside extracted from glial cells. In addition to in rivo biosynthesis, in vitro synthesis of gangliosides was also determined. The activities of five glycosyltransferases of the ganglioside biosynthetic pathway were measured in homogenates of the three cell lines. The neuroblastoma cells contained all five enzyme activities whereas the two glial cell lines were deficient in UDP‐N‐acetylgalactosamine: GM3N‐acetylgalactosaminyltransferase activity, which catalyzes the synthesis of GM2 from GM3. The results indicated that cells of neuronal origin contain the more complex gangliosides associated with CNS and the requisite biosynthetic enzymes and that cells of glial origin are missing these complex gangliosides and the key glycosyltransferase required for their synthesis.

Properties of ecto-(inoganic) pyrophosphatase of nervous system cells in culture. Activation upon partial release of sialic acid from the cell surface.

Clonal line NN hamster astroblasts and clonal line N18 neuroblasts were treated with phospholipase C-free, protease-free, and hemolysin-free Clostridium perfringens sialidase, at a low level (5 X 10(-3) units/ml) so as to maintain cell intactness and to avoid spurious protein effects. A rapid, regular release of sialic acid was achieved. An approximately 9-fold increase in ecto-pyrophosphatase activity could be brought about by action of C. perfringens sialidase for 10 min. Since the sialidase preparations were employed at a level which gave a very low concentration of extraneous protein, and the preparations were free of demonstrable phospholipase C and protease activities, these effects appear to relate specifically to removal of cell surface sialic acid. Neutral p-nitrophenyl phosphatase was activated under the same conditions, but activity remained low compared with pyrophosphatase. Progress curves for activation of the two enzymes were dissimilar. Ecto-pyrophosphatase of NN and N18 cells had an absolute requirement for Mg2+ both before and after removal of cell surface sialic acid. In the presence of near optimum Mg2+ (5 mM), other divalent cations were inhibitory at a low level (10(-1)mM). The effect of Mg2+ concentration, as well as inorganic pyrophosphate concentration, upon ecto-pyrophosphatase activity was shown to obey Michaelis-Menten kinetics for the control activity and for the sialidase-enhanced activity of both cell types. Km for Mg2+ and for pyrophosphate remained constant upon ecto-pyrophosphatase enhancement by sialic acid removal; increase in enzymatic activity was accounted for entirely by an increase in Vmax.