Localization of neutral,magnesium-stimulated sphingomyelinase in plasma membrane of cultured neuroblastoma cells

A parallel is shown between the distribution of neutral sphingomyelinase and plasma membrane enzymes (5′-nucleotidase and (Na⁺ + K⁺)-activated ATPase) in cultured neuroblastoma cells. In contrast there is no evidence of localization in lysosomes (β-hexosaminidase and acid sphingomyelinase), mitochondria (carnitine palmitoyltransferase), or cytosol. Activity in the microsomal fraction is attributed primarily to plasma membrane contamination.     

Evidence that neutral sphingomyelinase of cultured murine neuroblastoma cells is oriented externally on the plasma membrane

The activity of the neutral, Mg2+-stimulated sphingomyelinase of cultured neuroblastoma cells (N1E-115) is enriched in the plasma membrane fraction and is reduced following treatment of intact or broken cells with trypsin, alpha-chymotrypsin, papain, and protease. Two protease-sensitive enzymes of the cell interior (lactate dehydrogenase and NADPH-cytochrome c reductase) are not affected by protease treatment of intact cells. These results indicate that the neutral, Mg2+-stimulated sphingomyelinase is oriented externally on the plasma membrane of the cultured neuroblastoma cell.     

Evidence that neutral spingomyelinase of cultured murine neuroblastoma cells is oriented externally on the plasma membrane

The activity of the neutral, Mg²⁺-stimulated sphingomyelinase of cultured neuroblastoma cells (N1E-115) is enriched in the plasma membrane fraction and is reduced following treatment of intact or broken cells with trypsin, α-chymotrypsin, papain, and protease. Two protease-sensitive enzymes of the cell interior (lactate dehydrogenase and NADPH-cytochrome c reductase) are not affected by protease treatment of intact cells. These results indicate that the neutral, Mg²⁺-stimulated sphingomyelinase is oriented externally on the plasma membrane of the cultured neuroblastoma cell.     

A neutral sphingomyelinase in spermatozoal plasma membranes

A highly active neutral sphingomyelinase was observed for the first time in ram spermatozoal plasma membranes. The optimal conditions for the enzyme activity are pH 7.4, 40 mM MgCl2, 40 min of incubation, and 267 nmol sphingomyelin. Ca2+ and cholesterol were found to inhibit sphingomyelinase activity.     

Analysis of membrane topology of neutral sphingomyelinase 2

Neutral sphingomyelinase 2 (nSMase2), which has two hydrophobic segments at its NH(2)-terminus, plays an important role in ceramide-mediated cell regulation. Here, we investigated the membrane topology of nSMase2. When a double-tagged nSMase2 at both the NH(2) and COOH termini, was overexpressed in MCF-7 cells, the signals from both tags were detected in the inner leaflet of the plasma membrane. Furthermore, insertion of a tag into the internal sequence and green fluorescent protein-fused deletion mutants revealed that the entire catalytic region of the protein was located on the cytosolic face of the membranes and each hydrophobic segment is integrated into the membranes, but unlikely to span the entire membrane. These results indicate the presence of the enzyme in the inner leaflet of plasma membrane.     

Inhibition of neutral Mg2+-dependent sphingomyelinase by ubiquinol-mediated plasma membrane electron transport

Summary.  Sphingomyelin is an abundant constituent of the plasma membranes of mammalian cells. Ceramide, its primary catabolic intermediate, has emerged as an important lipid signaling molecule. Previous work carried out by our group has documented that plasma membrane Mg²⁺-dependent neutral sphingomyelinase can be effectively inhibited by exogenous ubiquinol. In this work, we have tested whether or not plasma-membrane-associated electron transport can also achieve this inhibition through endogenous ubiquinol. Our results have shown that Mg²⁺-dependent neutral sphingomyelinase in isolated plasma membranes was inhibited by NAD(P)H under conditions where ubiquinone is reduced to ubiquinol. This inhibition was potentiated in the presence of an extra amount of NAD(P)H:(quinone acceptor) oxidoreductase 1 (EC 1.6.99.2). Depletion of plasma membranes from lipophilic antioxidants by solvent extraction abolished the inhibition by reduced pyridine nucleotides without affecting the sensitivity of the neutral sphingomyelinase to exogenous ubiquinol. Reconstitution of plasma membranes with ubiquinone restored the ability of NAD(P)H to inhibit the enzyme. Our results support that the reduction of endogenous ubiquinone to ubiquinol by NAD(P)H-driven electron transport may regulate the activity of the plasma membrane neutral sphingomyelinase. Received May 20, 2002; accepted September 20, 2002; published online May 21, 2003 RID="**" ID="**" Present address: Department of Biomedical Engineering, School of Medicine, University of Baltimore, Maryland, U.S.A. RID="*" ID="*" Correspondence and reprints: Departamento de Biología Celular, Fisiología e Inmunología, Facultad de Ciencias, Edificio C-6, Campus Rabanales, Universidad de Córdoba, 14014 Córdoba, Spain.     

Polarized plasma membrane domains in cultured endothelial cells

To determine whether distinct plasma membrane domains exist in endothelial cells, we infected monolayer cultures of macro- and microvascular endothelial cells with enveloped RNA viruses known to bud selectively from either the apical or basal surface in polarized epithelial cells. We found that vesicular stomatitis (VSV) and Sendai virus emerge asymmetrically from cultured endothelial cells. This provides direct evidence for the existence of polarized plasma membrane domains in vascular endothelial cells.     

Phospholipid dependence of the neutral sphingomyelinase in rat liver plasma membranes

Investigations have been carried out on the influence of the phospholipid composition of rat liver plasma membranes and of their physico-chemical properties on the activity of membrane-bound neutral sphingomyelinase. The membrane phospholipid composition was modified by the incorporation of different phospholipids into the membrane bilayer by means of lipid transfer proteins, n-butanol delipidation or exogenous sphingomyelinase (Staphylococcus aureus) treatment. The results indicate that the activity of neutral sphingomyelinase in liver plasma membranes depends upon phosphatidyl choline presence in the membrane bilayer and not upon membrane fluidity.     

Ultrastructural aspects of rapid plasma membrane growth in mitotic neuroblastoma cells

In murine C1300 neuroblastoma cells, clone Neuro 2A, the major fraction of the necessary increase in cell surface area during the cell cycle occurs within a short period around mitosis. During this period cell cycle-related modulations in a number of structural, dynamic and transport properties are most prominent. In this study we have examined the mechanism of rapid plasma membrane growth during mitosis, and the resulting changes in the ultrastructural features of the plasma membrane, by scanning and freeze-fracture electron microscopy as well as by electron microscopy of ultrathin sections. Our observations show that plasma membrane growth occurs by the fusion with and the incorporation into the plasma membrane of cytoplasmic multilamellar, lipidic membrane vesicles. Such vesicles are not observed at other times in the cell cycle. As a consequence, IMP-free domains appear transiently in the mitotic and early post-mitotic plasma membrane. Comparison of replicas prepared from glutaraldehyde-fixed cells and unfixed, ultrarapidly frozen cells showed that aldehyde fixation artefactually induces a bleb-like appearance of these domains. The IMP-free domains disappear in the G1-phase as a result of the mobilization and lateral redistribution of membrane components. It is argued that mitotic membrane growth by preferential incorporation of membrane lipids not only serves to accomodate for the necessary increase in cell surface area, but also provides a mechanism for plasma membrane-mediated regulation of the cell cycle.     

Exocytosis of acid sphingomyelinase by wounded cells promotes endocytosis and plasma membrane repair

Rapid plasma membrane resealing is essential for cellular survival. Earlier studies showed that plasma membrane repair requires Ca²⁺-dependent exocytosis of lysosomes and a rapid form of endocytosis that removes membrane lesions. However, the functional relationship between lysosomal exocytosis and the rapid endocytosis that follows membrane injury is unknown. In this study, we show that the lysosomal enzyme acid sphingomyelinase (ASM) is released extracellularly when cells are wounded in the presence of Ca²⁺. ASM-deficient cells, including human cells from Niemann-Pick type A (NPA) patients, undergo lysosomal exocytosis after wounding but are defective in injury-dependent endocytosis and plasma membrane repair. Exogenously added recombinant human ASM restores endocytosis and resealing in ASM-depleted cells, suggesting that conversion of plasma membrane sphingomyelin to ceramide by this lysosomal enzyme promotes lesion internalization. These findings reveal a molecular mechanism for restoration of plasma membrane integrity through exocytosis of lysosomes and identify defective plasma membrane repair as a possible component of the severe pathology observed in NPA patients.     

Localization of neutral glycosphingolipids in human plasma.

1. The localization of the neutral glycosphingolipids glucosylceramide, lactosylceramide, trihexosylceramide and globoside in human plasma was investigated. Glycosphingolipids were isolated and analysed by gas-liquid chromatography. 2. After Sephadex gel chromatography of human plasma, about 75% of the glycosphingolipids were found in the fraction containing most of the lipoproteins. 3. After fractionation of the lipoproteins by ionic precipitation, 15-25% of each glycosphingolipid was found in the very low-density lipoprotein + chylomicron fraction, 30-45% in the low density lipoprotein fraction and 40-50% in the high density lipoprotein fraction. 4. After fractionation of lipoproteins by density-gradient ultracentrifugation, 15% of each glycosphingolipid was found in the very low-density lipoprotein + chylomicron fraction and 85% in the low density and high density lipoprotein fractions. No glycosphingolipids could be detected in the ultracentrifugal residue which contains the bulk of the albumin.     

Phosphoinositide metabolism in cultured glioma and neuroblastoma cells: subcellular distribution of enzymes indicate incomplete turnover at the plasma membrane

The hypothesis that the small portion of cellular phosphoinositide participating in signal transduction might be preferentially recycled within the plasma membrane was tested in rat glioma (C6) and murine neuroblastoma (N1E-115) cells. Percoll density gradient centrifugation was used to isolate a purified plasma membrane fraction and the subcellular distribution of all enzymes mediating phosphoinositide turnover was assessed. A small but significant proportion of PtdInsP2-specific phosphodiesterase was located in the plasma membrane but only two of the five enzymes required to replace PtdInsP2 (diacylglycerol kinase and PtdInsP kinase) also were present. CTP:phosphatidate cytidylyltransferase and CMP-phosphatidate:inositol phosphatidyltransferase were located exclusively in a microsomal fraction containing enriched levels of endoplasmic reticulum markers. Thus, diacylglycerol from agonist-stimulated cleavage of PtdInsP2, or phosphatidic acid formed from it, must be transferred to the endoplasmic reticulum for conversion to PtdIns. Plasma membrane also lacked PtdIns kinase. If the soluble PtdIns kinase has access to membrane-bound substrate, PtdIns may be phosphorylated to PtdInsP before or during transport to the plasma membrane. Phosphorylation by the predominantly plasma membrane PtdInsP kinase to form PtdInsP2 completes the cycle. PtdInsP phosphatase was present in all membrane fractions suggesting that PtdInsP can be returned to the PtdIns pool in plasma membrane and elsewhere. PtdInsP2 phosphatase was almost exclusively in the cytosol suggesting that reversible interchange between PtdInsP and PtdInsP2 in the plasma membrane may be modulated by the ability of this phosphatase to act on PtdInsP2 in the membrane. Thus, PtdIns resynthesis in the plasma membrane of these cells does not occur and is not required for phosphoinositide-mediated signal transduction.     

Selective ganglioside desialylation in the plasma membrane of human neuroblastoma cells*

Gangliosides of the plasma membrane are important modulatorsof cellular functions. Previous work from our laboratory hadsuggested that a plasma membrane sialidase was involved in growthcontrol and differentiation in cultured human neuroblastomacells (SK-N-MC), but its substrates had remained obscure. Wenow performed sialidase specificity studies in subcellular fractionsand found ganglioside GM3 desialylating activity in presenceof Triton X-100 to be associated with the plasma membrane, butabsent in lysosomes. This Triton-activated plasma membrane enzymedesialylated also gangliosides GDla, GD1b, and GT1b, therebyforming GM1; cleavage of GM1 and GM2, however, was not observed.Sialidase activity towards the glycoprotein fetuin with modifiedC-7 sialic acids and towards 4-methylumbelliferyl neuraminatewas solely found in lysosomal, but not in plasma membrane fractions. The role of the plasma membrane sialidase in ganglioside desialylationof living cells was examined by following the fate of [³H]galactose-labelledindividual gangliosides in pulse-chase experiments in absenceand presence of the extracellular sialidase inhibitor 2-deoxy-2,3-dehydro-N-acetylneuraminicacid. When the plasma membrane sialidase was inhibited, radioactivityof all gangliosides chased at the same rate. In the absenceof inhibitor, GM3, GD1a, GD1b, GD2, GD3 and GT1b were degradedat a considerably faster rate in confluent cultures, whereasthe GM1-pool seemed to be filled by the desialylation of highergangliosides. The results thus suggest that the plasma membranesialidase causes selective ganglioside desialylation, and thatsuch surface glycolipid modification triggers growth controland differentiation in human neuroblastoma cells. ganglioside neuroblastoma cells plasma membrane sialidase     

Studies on the turnover and subcellular localization of membrane gangliosides in cultured neuroblastoma cells

To compare the subcellular distribution of endogenously synthesized and exogenous gangliosides, cultured murine neuroblastoma cells (N1E-115) were incubated in suspension for 22h in the presence ofd-[1-³H]galactose or [³H]GM1 ganglioside, transferred to culture medium containing no radioisotope for periods of up to 72 hr, and then subjected to subcellular fractionation and analysis of lipidsialic acid and radiolabeled ganglioside levels. The results indicated that GM2 and GM3 were the principal gangliosides in the cells with only traces of GM1 and small amounts of disialogangliosides present. About 50% of the endogenously synthesized radiolabelled ganglioside in the four major subcellular membrane fractions studied was recovered from plasma membrane and only 10–15% from the crude mitochondrial membrane fraction. In contrast, 45% of the exogenous [³H]GM1 taken up into the same subcellular membrane fractions was recovered from the crude mitochondrial fraction; less than 15% was localized in the plasma membrane fraction. The results are similar to those obtained from previously reported studies on membrane phospholipid turnover. They suggest that exogenous GM1 ganglioside, like exogenous phosphatidylcholine, does not intermix freely with any quantitatively major pool of endogenous membrane lipid.     

The mucin box and signal/anchor sequence of rat neutral ceramidase recruit bacterial sphingomyelinase to the plasma membrane

Sphingolipid metabolites act as lipid mediators in various cellular events. We found that the mucin box and signal/anchor sequence of a rat neutral ceramidase recruit bacterial sphingomyelinase to the plasma membranes of mammalian cells. The mucin box-fused sphingomyelinase hydrolyzed cellular sphingomyelin efficiently to generate ceramide.     

Hypotonically induced changes in the plasma membrane of cultured mammalian cells

Summary Cells from three cell lines were electrorotated in media of osmotic strengths from 330 mOsm to 60 mOsm. From the field-frequency dependence of the rotation speed, the passive electrical properties of the surfaces were deduced. In all cases, the area-specific membrane capacitance (C _m) decreased with osmolality. At 280 mOsm (iso-osmotic), SP2 (mouse myeloma) and G8 (hybridoma) cells had C _mvalues of 1.01 ± 0.04 F/cm² and 1.09 ± 0.03 F/cm², respectively, whereas dispase-treated L-cells (sarcoma fibroblasts) exhibited C _m=2.18±0.10/F/cm². As the osmolality was reduced, the C _mreached a well-defined minimum at 150 mOsm (SP2) or 180 mOsm (G8). Further reduction in osmolality gave a 7% increase in C _m, after which a plateau close to 0.80F/cm2²was reached. However, the whole-cell capacities increased about twofold from 200 mOsm to 60 mOsm. L-cells showed very little change in C _mbetween 280 mOsm and 150 mOsm, but below 150 mOsm the C _mdecreased rapidly. The changes in C _mcorrelate well with the swelling of the cells assessed by means of van't Hoff plots. The apparent membrane conductance (including the effect of surface conductance) decreased with C _m, but then increased again instead of exhibiting a plateau. The rotation speed of the cells increased as the osmolality was lowered, and eventually attained almost the theoretical value. All measurements indicate that hypo-osmotically stressed cells obtain the necessary membrane area by using material from microvilli. However, below about 200 mOsm the whole-cell capacities indicate the progressive incorporation of extra membrane into the cell surface.We thank Mr. B.G. Klarmann for his help with the measurements. This work was supported by grants of the DFG (SFB 176 B5 to U.Z. and W.M.A.) and of the BMFT (DARA 50 WB 9212 to U.Z.). We also thank the Umweltbundesamt, Berlin, for support enabling the construction of some of the rotation generators used in this work.     

Localization of kinesin in cultured cells

Kinesin was isolated from bovine brain and used to elicit polyclonal antibodies in rabbits. The specificities of the resulting antibodies were evaluated by immunoblotting. Antibodies purified from these sera by their affinity for brain kinesin react with a polypeptide of approximately 120 kD in extracts from bovine brain, PtK1 cells, and mouse neuroblastoma cells. They bind to a pair of polypeptides of approximately 120 kD present in crude kinesin prepared from Xenopus eggs and with a single polypeptide of approximately 115 kD in extracts from Drosophila embryos. Antibodies raised against kinesin prepared from fruit fly embryos (by W. M. Saxton, Indiana University, Bloomington, IN) and from neural tissues of the squid (by M. P. Sheetz, Washington University, St. Louis, MO) cross react with the mammalian, the fly, and the frog polypeptides. Kinesin antigen was localized in cultured cells by indirect immunofluorescence. PtK1 cells in interphase showed dim background staining of cytoplasmic membranous components and bright staining of a small, fibrous, juxtanuclear structure. Double staining with antibodies to microtubules showed that the fibrous object was usually located near the centrosome. On the basis of shape, size, and location, we identify the kinesin-positive structure as a primary cilium. PtK1 cells in mitosis are stained at their poles during all stages of division. The structure stained is approximately spherical, but wisps of faint fluorescence also extend into the body of the spindle. Antibodies to squid or fruit fly kinesin produce identical patterns in PtK1 cells. Controls with preimmune and preabsorbed sera show that the centrosome staining is not due simply to the common tendency of rabbit antisera to stain this structure. Similar centrosome and spindle pole staining was visible when antibodies to bovine brain or squid kinesin were applied to the A6 cell line (kidney epithelial cells from Xenopus laevis). Some possible functions of kinesin localized at the spindle poles are discussed.