Sorting of sphingolipids in epithelial (Madin-Darby canine kidney) cells

Uptake and metabolism of fluorescent ceramide analogs by rat oligodendrocytes in culture

We studied the metabolism of sphingolipids by oligodendrocytes derived from rat spinal cord by providing lipid vesicles with either N-lissamine-rhodaminyl-ceramide (LRh-Cer) or N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-ceramide (NBD-Cer) to the cells cultured in a chemically-defined medium. With both probes the major fluorescent product turned out to be sphingomyelin (SM). Most of LRh-SM was not cell-associated but recovered from the culture medium, probably due to back-exchange to the lipid vesicles. The accumulation of LRh-SM, both in the cells and in the medium, was inhibited in the presence of monensin or brefeldin A, whereas the production of NBD-SM was much less affected by these Golgi perturbing drugs. With LRh-Cer as substrate, LRh-labelled fatty acid (FA), galactosyl- and sulfogalactosyl-ceramides (GalCer and SGalCer) were also formed. NBD-Cer, however, was metabolized to glucosylceramide (GlcCer) and GalCer but not to SGalCer or NBD-FA. These data demonstrate that chemical modifications of ceramide alter its metabolism in oligodendrocytes and that the metabolites of LRh-Cer reflect the glycolipid composition of myelin more closely than those of NBD-Cer.

5'nucleotidase is sorted to the apical domain of hepatocytes via an indirect route

In hepatocytes, all newly synthesized plasma membrane (PM) proteins so far studied arrive first at the basolateral domain; apically destined proteins are subsequently endocytosed and sorted to the apical domain via transcytosis. A mechanism for the sorting of newly synthesized glycophosphatidylinositol (GPI)-linked proteins has been proposed whereby they associate in lipid microdomains in the trans-Golgi network and then arrive at the apical domain directly. Such a mechanism poses a potential exception to the hepatocyte rule. We have used pulse-chase techniques in conjunction with subcellular fractionation to compare the trafficking of 5' nucleotidase (5NT), an endogenous GPI-anchored protein of hepatocytes, with two transmembrane proteins. Using a one-step fractionation technique to separate a highly enriched fraction of Golgi-derived membranes from ER and PM, we find that both 5NT and the polymeric IgA receptor (pIgAR) traverse the ER and Golgi apparatus with high efficiency. Using a method that resolves PM vesicles derived from the apical and basolateral domains, we find that 5NT first appears at the basolateral domain as early as 30 min of chase. However the subsequent redistribution to the apical domain requires > 3.5 h of chase to reach steady state. This rate of transcytosis is much slower than that observed for dipeptidylpeptidase IV, an apical protein anchored via a single transmembrane domain. We propose that the slow rate of transcytosis is related to the fact that GPI-linked proteins are excluded from clathrin-coated pits/vesicles, and instead must be endocytosed via a slower nonclathrin pathway.

Regulation of cell surface polarity from bacteria to mammals

The generation of unique domains on the cell, cell surface polarity, is critical for differentiation into the diversity of cell structures and functions found in a wide variety of organisms and cells, including the bacterium Caulobacter crescentus, the budding yeast Saccharomyces cerevisiae, and mammalian polarized epithelial cells. Comparison of the mechanisms for establishing polarity in these cells indicates that restricted membrane protein distributions are generated by selective protein targeting to, and selective protein retention at, the cell surface. Initiation of these mechanisms involves reorientation of components of the cytoskeleton and protein transport pathways toward restricted sites at the cell surface and formation of a targeting patch at those sites for selective recruitment and retention of proteins.

Fluorescent phospholipids preferentially accumulate in sub-tegumental cells of schistosomula of Schistosoma mansoni

Schistosomes do not make sterols or fatty acids de novo and thus require host lipids for survival. The acquisition of host lipids may also be an important factor in the schistosome's defense from host immunity; however, little is known about the regulation of this process. Here we have examined binding of radiolabeled and fluorescently labeled liposomes to schistosomula, and followed incorporation of fluorescent phospholipids into the worm by both morphological and biochemical methods. Saturable binding of radiolabeled phosphatidylcholine containing liposomes was observed and epifluorescence microscopy showed binding of C6-NBD-phosphatidylcholine (C6-NBD-PC), C12-NBD-phosphatidylcholine (C12-NBD-PC) and C6-NBD-phosphatidyl-ethanolamine (C6-NBD-PE) containing liposomes on the surface of the parasite. Following back-exchange with unlabeled liposomes, NBD-PC and NBD-PE were observed to be preferentially incorporated into specific cell types within the worm. Furthermore, cells which had accumulated the fluorescent lipid formed an interconnecting cellular network immediately below the tegument, identified as cytons. By contrast, fluorescein-PE was found only on the surface of the parasite and in the gut but not in the cytons. Biochemical analysis demonstrated that > 90% of the C6-NBD-PC and C12-NBD-PC remained as the intact molecule after a one hour incubation with the parasite, but that greater than 70% of the NBD-PE was converted to other lipids. These studies demonstrate that incorporation of phospholipid analogs into schistosomula can be followed morphologically and biochemically. As there was little localization of NBD-PE or NBD-PC in the gut, these analogs must be assimilated by crossing the tegument.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of the influenza A virus M2 protein is restricted to apical surfaces of polarized epithelial cells

The M2 protein of influenza A virus is a small, nonglycosylated transmembrane protein that is expressed on surfaces of virus-infected cells. A monoclonal antibody specific for the M2 protein was used to investigate its expression in polarized epithelial cells infected with influenza virus or a recombinant vaccinia virus that expresses M2. The expression of M2 on the surfaces of influenza virus-infected cells was found to be restricted to the apical surface, closely paralleling that of the influenza virus hemagglutinin (HA). Membrane domain-specific immunoprecipitation indicated that the M2 protein was inserted directly into the apical membrane with transport kinetics similar to those of HA. In polarized cells infected with a recombinant vaccinia virus that expresses M2, we found that 86 to 93% of surface M2 was restricted to the apical domain compared with 88 to 90% of HA in a similar assay. These results indicate that the M2 protein undergoes directional transport in the absence of other influenza virus proteins and that M2 contains the structural features required for apical transport in polarized epithelial cells. The ultrastructural localization of the M2 protein in influenza virus-infected MDCK cells was investigated by immunoelectron microscopy using M2 antibody and a gold conjugate. In cells in which extensive virus budding was occurring, the apical cell membrane was labeled with gold particles evenly distributed between microvilli and the surrounding membrane. In addition, a significant fraction of the M2 label was apparently associated with virions. A monoclonal antibody specific for HA demonstrated a similar labeling pattern. These results indicate that M2 is localized in close proximity to budding and assembled virions.

Cultured oligodendrocytes metabolize a fluorescent analogue of sulphatide; inhibition by monensin

It has been suggested that oligodendrocytes can actively phagocytose myelin debris during active myelination or after injury and experimental demyelination. Therefore, we have used a fluorescent analogue (N-lissamine rhodaminyl-(12-aminododecanoyl) cerebroside 3-sulphate) to study the metabolic fate of sulphatide, a galactosphingolipid that is highly enriched in myelin membranes. The fluorescent sulphatide was incorporated in small unilamellar vesicles and administered to cultured oligodendrocytes. The association of the lipid probe to the cells in culture was saturable in time and with the concentration of the probe. The processes of association, internalization and subcellular distribution were followed by confocal scanning laser microscopy and appeared to be very rapid. Within 20 min a marked perinuclear staining was seen. After prolonged incubation the fluorescence distributed gradually over the cytoplasm and into cellular branches along structures suggestive of cytoskeletal elements. Lipid analysis demonstrated that ceramide was the major metabolite present in the cells but galactosylceramide, sphingomyelin and free fatty acid were also detected. In the culture medium only free fatty acid and sphingomyelin were found. Monensin did not affect the cellular association and internalization of the fluorescent sulphatide but markedly reduced its conversion to metabolic products. These results indicate that exogenous sulphatide is targeted to the Golgi apparatus prior to its lysosomal degradation.

Epithelial sphingolipid sorting allows for extensive variation of the fatty acyl chain and the sphingosine backbone

In kidney MDCK and intestinal Caco-2 epithelial cells, glucosylceramide (GlcCer) and sphingomyelin (SPH) synthesized from the short-chain sphingolipid analogue N-6-[7-nitro-2,1,3-benzoxadiazol-4-yl]aminodecanoyl (C6-NBD)-ceramide are delivered to the cell surface with apical/basolateral polarities of 2-4 and 0.6-0.9 respectively. We have tested how variations in the lipid backbone affect these polarities. First, the C6-NBD moiety was replaced by a bare [14C]octanoyl chain or by the even more bulky fluorophores 8-bimanoylthio-octanoyl (C8-bimane) and 8-diethylaminocoumarin-octanoyl (C8-DECA). In addition, the sphingosine in C6-NBD-ceramide was changed in stereoconfiguration (L-threo) or saturation (dihydro). In all cases, GlcCer and SPH were produced and appeared on the cell surface at 37 degrees C, as assayed by back-exchange. The apical/basolateral polarity of the delivery of GlcCer was variable, but always exceeded 1. GlcCer was apically enriched over SPH (2-6 times for MDCK and 3-9 times for Caco-2). Even GlcCer synthesized from a highly water-soluble truncated ceramide (octanoyl-D-erythro-sphingosine analogue with C8 backbone) was enriched apically by a factor of greater than or equal to 2 both in absolute polarity and compared with SPH. Sphingolipid sorting was quantitatively but not qualitatively affected by dramatic changes in the lipid backbone.

The impenetrability of 5-(N-hexadecanoyl)aminofluoroscein through endothelial cell monolayers is dependent upon its solution properties, not the presence of tight junctions

The solution properties of two fluorescent lipophilic analogues were examined in conjunction with their ability to penetrate the tight junctions of bovine aortic endothelial cell monolayers. 5-(N-dodecanoyl)aminofluoroscein was shown to label both the apical and basolateral plasma membrane domains of confluent monolayers at 4 degrees C and pH 7.3, but 5-(N-hexadecanoyl)aminofluoroscein was shown to label only the apical membrane domain. When used under more soluble conditions at 20 degrees C and pH 8.5, both probes labeled apical and basolateral plasma membrane domains more equally. This indicates that solubility conditions, and not tight junctions, dictate the penetration of 5-(N-hexadecanoyl)aminofluoroscein from the apical to the basolateral plasma membrane domain.

Sphingolipid transport from the trans-Golgi network to the apical surface in permeabilized MDCK cells

We have measured the transport of de novo synthesized fluorescent analogs of sphingomyelin and glucosylceramide from the trans-Golgi network (TGN) to the apical membrane in basolaterally permeabilized Madin-Darby canine kidney (MDCK) cells. Sphingolipid transport was temperature, ATP and cytosol dependent. Introduction of bovine serum albumin (BSA), which binds fluorescent sphingolipid monomer, into the permeabilized cells, did not affect lipid transport to the apical membrane. Both fluorescent sphingomyelin and glucosylceramide analogs were localized to the lumenal bilayer leaflet of isolated TGN-derived vesicles. These results strongly suggest that both sphingolipids are transported from the TGN to the apical membrane via vesicular traffic.

Glucosylceramide is synthesized at the cytosolic surface of various Golgi subfractions

In our attempt to assess the topology of glucosylceramide biosynthesis, we have employed a truncated ceramide analogue that permeates cell membranes and is converted into water soluble sphingolipid analogues both in living and in fractionated cells. Truncated sphingomyelin is synthesized in the lumen of the Golgi, whereas glucosylceramide is synthesized at the cytosolic surface of the Golgi as shown by (a) the insensitivity of truncated sphingomyelin synthesis and the sensitivity of truncated glucosylceramide synthesis in intact Golgi membranes from rabbit liver to treatment with protease or the chemical reagent DIDS; and (b) sensitivity of truncated sphingomyelin export and insensitivity of truncated glucosylceramide export to decreased temperature and the presence of GTP-gamma-S in semiintact CHO cells. Moreover, subfractionation of rat liver Golgi demonstrated that the sphingomyelin synthase activity was restricted to fractions containing marker enzymes for the proximal Golgi, whereas the capacity to synthesize truncated glucosylceramide was also found in fractions containing distal Golgi markers. A similar distribution of glucosylceramide synthesizing activity was observed in the Golgi of the human liver derived HepG2 cells. The cytosolic orientation of the reaction in HepG2 cells was confirmed by complete extractability of newly formed NBD-glucosylceramide from isolated Golgi membranes or semiintact cells by serum albumin, whereas NBD-sphingomyelin remained protected against such extraction.

ADH-induced depolymerization of F-actin in the toad bladder granular cell: a confocal microscope study

Antidiuretic hormone (ADH) induces the fusion of cytoplasmic vesicles containing water channels with the apical membrane of the toad bladder granular cell. Fusion is accompanied by a 30% depolymerization of F-actin. We have used confocal microscopy to determine the region in the cell that undergoes depolymerization. Bladders were mounted in a split chamber, and control halves and halves stimulated by ADH for 15 min were fixed and then stained with rhodamine phalloidin. Vertical sections through the cells were obtained by confocal microscopy, and the fluorescence intensity of the apical and side regions of the cells was determined. To normalize the data, the apex-side intensity was determined for each cell, and these ratios measured for control and ADH-treated halves. In six paired experiments, the ratio for control halves was 3.69 +/- 0.50 and for ADH-treated halves was 2.61 +/- 0.33; the decrease was significant and in good agreement with earlier studies. Thus actin depolymerization takes place in a hormone-sensitive apical pool where vesicle fusion occurs and supports the view that actin depolymerization may be required for fusion.

Two separate pools of sphingomyelin in BHK cells

In BHK cells labelled to equilibrium with [3H]choline and treated with sphingomyelinase the surface pool of sphingomyelin is degraded very rapidly (half-time 10 min) but the internal pool of sphingomyelin which accounts for about 30% of the total is only degraded slowly (half-time about 80 h) showing that the internal pool does not normally reach the surface. In [3H]choline incorporation experiments the internal pool begins to accumulate radioactivity at about the same time as phosphatidylcholine (30 min) but label does not enter the surface pool of sphingomyelin for a further 90 min. The internal and external pools reach the same specific activity only after about 20 h. Pulse-chase analysis with [3H]choline shows that radioactivity in each pool of sphingomyelin continues to increase when the specific radioactivity of phosphatidylcholine is decreasing, consistent with both pools being synthesised from a phosphatidylcholine precursor. The results suggest that sphingomyelin in BHK cells is present not only in the plasma membrane but also in a more rapidly labelling pool which does not mix with the surface pool.

Uptake and metabolism of a fluorescent sulfatide analogue in cultured skin fibroblasts

The sulfatide fluorescent analogue N-lissamine rhodaminyl-(12-aminododecanoyl) cerebroside 3-sulfate was administered in the form of albumin complex to normal human skin fibroblasts and its metabolic fate was investigated. Ceramide, galactosylceramide, glucosylceramide, sphingomyelin and free acid, all containing the fluorophore lissamine rhodamine, have been synthesized as reference standards for the identification of the metabolic products. Ceramide appeared to be the main metabolic product present both in cell extract and medium, followed by galactosylceramide and sphingomyelin. Fluorescence microscopy of cells showed a marked perinuclear fluorescence.

Hypoxic injury to oligodendrocytes: reversible inhibition of ATP-dependent transport of ceramide from the endoplasmic reticulum to the Golgi

Previous studies have shown that gradual progressive hypoxia specifically inhibits the synthesis of the major myelin lipid galactosylceramide (GalCer) in cultured neonatal rat oligodendrocytes (OLG) (Kendler and Dawson, J Biol Chem 265:12259-12266, 1990). The inhibition of de novo synthesized GalCer (measured by [3H]palmitate incorporation) was accompanied by an increase in the [3H]labeled pool of nonhydroxy fatty acid ceramide, the precursor of GalCer. The decreased galactosylation of NFACer was not due to an inhibition of UDP-Gal:ceramide:galactosyltransferase activity or to a depletion in available UDP-Gal. Analysis of subcellular fractionations of OLG membranes on Percoll gradients indicated that NFA ceramide was accumulating in the endoplasmic reticulum (ER) during hypoxia, suggesting that the transport of NFACer from its site of synthesis (ER) to its site of galactosylation, presumably the Golgi, was blocked by hypoxia. This accumulation of ceramide was replicated by lowering ATP levels to 80-90% of control by treating OLG with 12 nM oligomycin, and was reversed by reoxygenation of the cells. Conversion of [3H]palmitate-labeled NFACer to GalCer in semi-intact OLG required both exogenous UDP-Gal and ATP, further suggesting that the transport of NFACer from the ER to its site of synthesis (cis-Golgi) is an energy-dependent step that is highly susceptible to relatively minor ATP depletion associated with early hypoxic injury. Our results further suggest that ceramide appears to be a good marker for ER and GalCer is a good marker for the cis-Golgi.

Use of N-([1-14C]hexanoyl)-D-erythro-sphingolipids to assay sphingolipid metabolism

An advantage of using N-([1-14C]hexanoyl)sphingolipids to assay sphingolipid metabolism is their ability to rapidly and spontaneously transfer into biological membranes without destroying membrane integrity. This property allows analysis of the activity of enzymes of sphingolipid metabolism under conditions in which the rate of product formation is not limited by availability of substrate, as is often the case with naturally occurring lipids whose rates of spontaneous transfer are extremely slow. Thus, the use of N-([1-14C]hexanoyl)sphingolipids provides an alternative means for studying sphingolipid metabolism in vitro.

Organelle biogenesis and intracellular lipid transport in eukaryotes

The inter- and intramembrane transport of phospholipids, sphingolipids, and sterols involves the most fundamental processes of membrane biogenesis. Identification of the mechanisms involved in these lipid transport reactions has lagged significantly behind that for intermembrane protein traffic until recently. Application of methods that include fluorescently labeled and spin-labeled lipid analogs, new cellular fractionation techniques, topographically specific chemical modification techniques, the identification of organelle-specific metabolism, permeabilized cell methodology, and yeast molecular genetics has contributed to revealing a diverse biochemical array of transport processes for lipids. Compelling evidence now exists for ATP-dependent, ATP-independent, vesicle-dependent, and vesicle-independent transport processes that are lipid and membrane specific. ATP-dependent transport processes include the transbilayer movement of phosphatidylserine and phosphatidylethanolamine at the plasma membrane and the transport of phosphatidylserine from its site of synthesis to the mitochondria. ATP-independent processes include the transbilayer movement of virtually all lipids at the endoplasmic reticulum, the movement of phosphatidylserine between the inner and outer mitochondrial membranes, and the transfer of nascent phosphatidylcholine and phosphatidylethanolamine to the plasma membrane. The ATP-independent movement of lipids between organelles is believed to be due to the action of lipid transfer proteins, but this still remains to be proved. Vesicle-based transport mechanisms (which are also inherently ATP dependent) include the transport of nascent cholesterol, sphingomyelin, and glycosphingolipids from the Golgi apparatus to the plasma membrane and the recycling of sphingolipids and selected pools of phosphatidylcholine from the plasma membrane to the cell interior. The vesicles involved in cholesterol transport to the plasma membrane are different from those involved in bulk protein transport to the cell surface. The vesicles involved in recycling sphingomyelin to and from the cell surface are different from those involved in the assembly of newly synthesized sphingolipids into the plasma membrane. The preliminary characterization of these lipid translocation processes suggests divergent rather than unifying mechanisms for lipid transport in organelle assembly.

Subcellular localization of Forssman glycolipid in epithelial MDCK cells by immuno-electronmicroscopy after freeze-substitution

Forssman antigen, a neutral glycosphingolipid carrying five monosaccharides, was localized in epithelial MDCK cells by the immunogold technique. Labeling with a well defined mAb and protein A-gold after freeze-substitution and low temperature embedding in Lowicryl HM20 of aldehyde-fixed and cryoprotected cells, resulted in high levels of specific labeling and excellent retention of cellular ultrastructure compared to ultra-thin cryosections. No Forssman glycolipid was lost from the cells during freeze-substitution as measured by radio-immunostaining of lipid extracts. Redistribution of the glycolipid between membranes did not occur. Forssman glycolipid, abundantly expressed on the surface of MDCK II cells, did not move to neighboring cell surfaces in cocultures with Forssman negative MDCK I cells, even though they were connected by tight junctions. The labeling density on the apical plasma membrane was 1.4-1.6 times higher than basolateral. Roughly two-thirds of the gold particles were found intracellularly. The Golgi complex was labeled for Forssman as were endosomes, identified by endocytosed albumin-gold, and lysosomes, defined by double labeling for cathepsin D. In most cases, the nuclear envelope was Forssman positive, but the labeling density was 10-fold less than on the plasma membrane. Mitochondria and peroxisomes, the latter identified by catalase, remained free of label, consistent with the notion that they do not receive transport vesicles carrying glycosphingolipids. The present method of lipid immunolabeling holds great potential for the localization of other antigenic lipids.

An internal deletion in the cytoplasmic tail reverses the apical localization of human NGF receptor in transfected MDCK cells

A cDNA encoding the full-length 75-kD human nerve growth factor receptor was transfected into MDCK cells and its product was found to be expressed predominantly (80%) on the apical membrane, as a result of vectorial targeting from an intracellular site. Apical hNGFR bound NGF with low affinity and internalized it inefficiently (6% of surface bound NGF per hour). Several mutant hNGFRs were analyzed, after transfection in MDCK cells, for polarized surface expression, ligand binding, and endocytosis. Deletionof juxta-membrane attachment sites for a cluster of O-linked sugars did not alter apical localization. A mutant receptor lacking the entire cytoplasmic tail (except for the five proximal amino acids) was also expressed on the apical membrane, suggesting that information for apical sorting was contained in the ectoplasmic or transmembrane domains. However, a 58 amino acid deletion in the hNGFR tail that moved a cytoplasmic tyrosine (Tyr 308) closer to the membrane into a more charged environment resulted in a basolateral distribution of the mutant receptor and reversed vectorial (basolateral) targeting. The basolateral mutant receptor also internalized 125I-NGF rapidly (90% of surface bound NGF per hour), exhibited a larger intracellular fraction and displayed a considerably shortened half-life (approximately 3 h). We suggest that hNGFR with the internal cytoplasmic deletion expresses a basolateral targeting signal, related to endocytic signals, that is dominant over apical targeting information in the ecto/transmembrane domains. These results apparently contradict a current model that postulates that basolateral targeting is a default mechanism.

The accumulation and metabolism of a fluorescent ceramide derivative in Plasmodium falciparum-infected erythrocytes

We have examined the accumulation and metabolism of N-[7-(4-nitrobenzo-2-oxa-1,3-diazole)]aminocaproyl sphingosine (C6-NBD-cer) in Plasmodium falciparum FCR-3/A2-infected erythrocytes. C6-NBD-cer transferred to live infected erythrocytes at 2 degrees C to label the infected red cell surface and intracellular parasite membranes. Subsequent incubation for 30 min at 2 degrees C, resulted in a depletion of the ceramide label from the red cell membrane and an accumulation of fluorescence in parasite membranes, by an energy independent process. When the cells were subsequently warmed to 37 degrees C for 30 min, virtually all of the ceramide was converted to N-[7-(4-nitrobenzo-2-oxa-1,3- diazole)]aminocaproyl sphingosine-1-phosphocholine (C6-NBD-Sm). Uninfected erythrocytes were incapble of sphingomyelin synthesis. By fluorescence microscopy, sphingomyelin synthesis in infected erythrocytes occurred in compartments morphologically similar to those accumulating ceramide. To examine the intracellular sites of ceramide accumulation glutaraldehyde fixed cells were labeled with C6-NBD-ceramide and subsequently back extracted to remove excess probe. This resulted in a depletion of label at the red cell membrane but prominent fluorescence remained associated with the parasite. Photobleaching in the presence of diaminobenzidine resulted in precipitates in intraerythrocytic cisternae and the vacuolar membrane surrounding the parasite, rather than a perinuclear Golgi apparatus within the organism. The results support a novel organisation of plasmodial membranes regulating the accumulation and metabolism of C6-NBD-cer in infected erythrocytes.

Working with the confocal scanning UV-laser microscope: specific DNA localization at high sensitivity and multiple-parameter fluorescence

The use of fast-staining DNA-specific dyes such as DAPI or Hoechst 33342/33258 has been a major problem for confocal scanning laser microscopy (CSLM) studies of intranuclear chromatin organization. Moreover, the availability of a confocal ultraviolet scanning laser microscope configuration, which allows an excitation at wavelengths of 364 nm as well as 488, 514 and 543 nm, is a prerequisite for single as well as multiple fluorescence parameter studies, especially if these studies are concerned with the precise localization of intranuclear signals. Here we report the characteristics and application of a CSLM, which was adapted for UV-excitation and therefore enables comparison of the spatial distribution of several types of signals within one preparation. In addition to multiple-parameter studies, we have also investigated the sensitivity of the system with regard to the identification of the double-stranded DNA of lampbrush chromosome loops in germinal vesicles of amphibian oocytes.

Sorting of sphingolipids in the endocytic pathway of HT29 cells

The intracellular flow and fate of two fluorescently labeled sphingolipids, 6-[N-(7-nitro-2,1,3-benzoxadiazol-4-yl) amino]hexanoyl glucosyl sphingosine (C6-NBD-glucosylceramide) and C6-NBD-sphingomyelin, was examined in the human colon adenocarcinoma cell line HT29. After their insertion into the plasma membrane at low temperature and subsequent warming of the cells to 37 degrees C, both sphingolipid analogues were internalized by endocytosis, but their intracellular site of destination differed. After 30 min of internalization, C6-NBD-glucosylceramide was localized in the Golgi apparatus, as demonstrated by colocalization with fluorescently labeled ceramide, a Golgi complex marker, and by showing that monensin-induced disruption of the Golgi structure was paralleled by a similar perturbation of the fluorescence distribution. By contrast, C6-NBD-sphingomyelin does not colocalize with the tagged ceramide. Rather, a colocalization with ricin, which is internalized by endocytosis and predominantly reaches the lysosomes, was observed, indicating that the site of delivery of this lipid is restricted to endosomal/lysosomal compartments. Also, in monensin-treated cells no change in the distribution of fluorescence was observed. Thus, these results demonstrate that (sphingo)lipid sorting can occur in the endocytic pathway. Interestingly, the observed sorting phenomenon was specific for glucosylceramide, when compared to other glycolipids, while only undifferentiated HT29 cells displayed the different routing of the two lipids. In differentiated HT29 cells the internalization pathway of sphingomyelin and glucosylceramide was indistinguishable from that of transferrin.

Incorporation of exogenous phosphatidylcholine in the plasma membrane of MDCK cells by a specific transfer protein

The possibility to introduce exogenous phosphatidylcholine (PC) in the plasma membrane of Madin-Darby canine kidney (MDCK) cells other than by fusion of liposomes with virus-infected cells (Van Meer, G. and Simons, K. (1983) J. Cell Biol. 97, 1365-1374) was studied. Monolayers of confluent MDCK cells grown on a permeable support were exposed to unilamellar vesicles of dipalmitoylphosphatidylcholine (DPPC), a phospholipid that does not exchange spontaneously, and were incubated with or without the PC-specific transfer protein (PC-TP), at 4 and 37 degrees C. Added either on the apical or basolateral side of monolayers grown in the presence of [14C]choline, PC-TP stimulated the transfer of 14C-labeled PC from the cell membrane to the liposomes, even at 4 degrees C. Conversely, PC-TP promoted the transfer, by a temperature-dependent process, of [3H]DPPC from liposomes to the cell plasma membrane. The amount of DPPC imported at 37 degrees C was higher than 100 pmol/well for apical incubations. The data demonstrate that, in MDCK cells: (a) PC-TP can modify the PC species present in the plasma membrane; (b) PC accounts for a significant amount of the polar lipids present in the external leaflet of the apical membrane domain.

A novel fluorescent ceramide analogue for studying membrane traffic in animal cells: accumulation at the Golgi apparatus results in altered spectral properties of the sphingolipid precursor

A series of ceramide analogues bearing the fluorophore boron dipyrromethene difluoride (BODIPY) were synthesized and evaluated as vital stains for the Golgi apparatus, and as tools for studying lipid traffic between the Golgi apparatus and the plasma membrane of living cells. Studies of the spectral properties of several of the BODIPY-labeled ceramides in lipid vesicles demonstrated that the fluorescence emission maxima were strongly dependent upon the molar density of the probes in the membrane. This was especially evident using N-[5-(5,7-dimethyl BODIPY)-1-pentanoyl]-D-erythro-sphingosine (C5-DMB-Cer), which exhibited a shift in its emission maximum from green (integral of 515 nm) to red (integral of 620 nm) wavelengths with increasing concentrations. When C5-DMB-Cer was used to label living cells, this property allowed us to differentiate membranes containing high concentrations of the fluorescent lipid and its metabolites (the corresponding analogues of sphingomyelin and glucosylceramide) from other regions of the cell where smaller amounts of the probe were present. Using this approach, prominent red fluorescent labeling of the Golgi apparatus, Golgi apparatus-associated tubulovesicular processes, and putative Golgi apparatus transport vesicles was seen in living human skin fibroblasts, as well as in other cell types. Based on fluorescence ratio imaging microscopy, we estimate that C5-DMB-Cer and its metabolites were present in Golgi apparatus membranes at concentrations up to 5-10 mol %. In addition, the concentration-dependent spectral properties of C5-DMB-Cer were used to monitor the transport of C5-DMB-lipids to the cell surface at 37 degrees C.

In vivo metabolism of fluorescent ceramide in central nervous system myelin of adult rats

The metabolism of sphingolipids in the central nervous system (CNS) has been studied in adult rats by intraventricular administration of fluorescent ceramide (CER). Rats were sacrificed at various time points post inoculation and the fluorescence of CER, cerebrosides (CB), sulfatides (SULF) and sphingomyelin (SPM) was determined in the CNS myelin and in the pellet, containing mainly microsomes, obtained by Norton myelin preparation. The incorporation of fluorescence was more in the pellet than in the myelin at all times studied. Initially the fluorescence present in the pellet was prevalently due to untransformed CER but an increase of fluorescent products with time was observed. CB was the main product up to 2 h post inoculation, then it decreased with concomitant increase of fluorescent SULF. In the myelin we did not observe differences in incorporation and transformation of fluorescent CER with time: CB was the main fluorescent product at all times studied. At 0.5 h post inoculation the fluorescence, observed by fluorescence microscope, was located in the cell lining the ventricles while after 24 h it appeared also in the paraventricular areas.

Endocytosis and intracellular transport of the glycolipid-binding ligand Shiga toxin in polarized MDCK cells

The glycolipid-binding cytotoxin produced by Shigella dysenteriae 1, Shiga toxin, binds to MDCK cells (strain 1) only after treatment with short-chain fatty acids like butyric acid or with the tumor promoter 12-O-tetradecanoylphorbol 13-acetate. The induced binding sites were found to be functional with respect to endocytosis and translocation of toxin to the cytosol. Glycolipids that bind Shiga toxin appeared at both the apical and the basolateral surface of polarized MDCK cells grown on filters, and Shiga toxin was found to be endocytosed from both sides of the cells. This was demonstrated by EM of cells incubated with Shiga-HRP and by subcellular fractionation of cells incubated with 125I-labeled Shiga toxin. The data indicated that toxin molecules are endocytosed from coated pits, and that some internalized Shiga toxin is transported to the Golgi apparatus. Fractionation of polarized cells incubated with 125I-Shiga toxin showed that the transport of toxin to the Golgi apparatus was equally efficient from both poles of the cells. After 1-h incubation at 37 degrees C approximately 10% of the internalized toxin was found in the Golgi fractions. The results thus suggest that glycolipids can be efficiently transported to the Golgi apparatus from both sides of polarized MDCK cell monolayers.

Transport of exogenous fluorescent phosphatidylserine analogue to the Golgi apparatus in cultured fibroblasts

We have examined intracellular transport and metabolism of the fluorescent analogue of phosphatidylserine, 1-palmitoyl-2-(N-[12[(7-nitrobenz-2-oxa-1,3-diazole-4-yl)amino] dodecanoyl])-phosphatidylserine ([palmitoyl-C12-NBD]-PS) in cultured fibroblasts. When monolayer cultures were incubated with liposomes containing (palmitoyl-C12-NBD)-PS at 37 degrees C, fluorescent PS was transported to the Golgi apparatus. NBD-containing analogues of phosphatidylcholine, phosphatidylethanolamine (PE), or phosphatidic acid did not accumulate in the Golgi apparatus under the same experimental conditions. We suggest that the transport is not due to endocytosis, but is the result of incorporation and trans-bilayer movement of the (palmitoyl-C12-NBD)-PS at the plasma membrane followed by translocation of the lipid from plasma membrane to the Golgi apparatus via nonvesicular mechanisms. Uptake of fluorescent PS was inhibited by depletion of cellular ATP and was blocked by structural analogues of the lipid or by pretreatment of cells with glutaraldehyde or N-ethylmaleimide. After incorporation into the cell, fluorescent PS was metabolized to fluorescent PE. The intracellular distribution of fluorescence changed during the conversion. In addition to the Golgi apparatus, mitochondria also became labeled.

Intracellular transport and metabolism of sphingomyelin

SM is unique among the phospholipids because it is restricted to the lumenal aspect of organelles involved in the secretory and endocytic pathways. Given the intracellular sites of SM biosynthesis and hydrolysis, and the interconnections between these sites by vesicle-mediated transport pathways, the basic mechanism for maintaining the intracellular distribution of SM seems clear. It remains to be determined how SM metabolism and transport are coordinated to maintain the SM content of each organelle. For example, the size of the SM pool at the cell surface is maintained by regulation of at least five processes: transport of newly synthesized SM from the Golgi apparatus, plasma membrane lipid recycling, local SM synthesis, local SM hydrolysis, and SM transport from the cell surface to lysosomes. Although SM cannot undergo spontaneous transbilayer movement, SM metabolism generates both DAG, Cer and (indirectly) SPhB which can rapidly 'flip-flop', and thus gain access to the cytoplasmic leaflet of a membrane. It is of particular interest that these lipid species may be involved in the regulation of PK-C, suggesting that SM metabolism could play a role in signal transduction. However, physiological effects of endogenous Cer and SPhB remain elusive, even though the pharmacological effect of SPhB on PK-C is well established. Aside from the direct generation of second messengers, stimulation of SM hydrolysis has also been shown to induce cholesterol movement from the cell surface to intracellular membranes. It is not known whether this reflects the possibility that cholesterol may act as a second messenger. Alternatively, this phenomenon suggests that SM metabolism may cause rapid changes in the physical properties of the cell surface. For example, erythrocytes extensively treated with exogenously-added SMase will undergo endovesiculation It is tempting to speculate that any involvement of SM in the regulation of intracellular processes requires a combination of both the generation of biochemical second messengers and the alteration of membrane biophysical properties that can result from SM metabolism.

Thermotropic properties of phospholipid analogues

To understand the structural bases for the polymorphism of phospholipids, it is often essential to study the properties of "unnatural" phospholipid analogues with modified polar headgroups and or backbone structures. While the thermodynamic characteristics of the "classical" hydrated-gel-to-liquid-crystalline phase transition often appear surprisingly insensitive to these aspects of phospholipid structure, the rich and diverse solid-phase polymorphism of phospholipids is in fact exquisitely sensitive to the nature of both the polar headgroup and the backbone moieties. The tendencies of different phospholipids to form nonlamellar phases at higher temperatures also depend strongly (and in a sometimes surprising manner) on fine details of the headgroup and backbone structures. These points are illustrated by discussions of how the structures of headgroup- and backbone-modified phospholipid analogues influence their proclivities to form distinct types of hydrated solid phases, dehydrated "crystralline" phases and nonlamellar phases.

Cholesterol controls the clustering of the glycophospholipid-anchored membrane receptor for 5-methyltetrahydrofolate

The folate receptor is a glycosyl-phosphatidylinositol (GPI)-anchored membrane protein that mediates the delivery of 5-methyltetrahydrofolate to the cytoplasm of MA104 cells. Ordinarily the receptor is sequestered into numerous discrete clusters that are associated with an uncoated pit membrane specialization called a caveola. By using two different methodological approaches, we found that the maintenance of both receptor clusters and caveolae depends upon the presence of cholesterol in the membrane. These results suggest that cholesterol plays a critical role in maintaining the caveola membrane domain and modulates the interaction of GPI-anchored membrane proteins via their phospholipid anchors.

Vectorial insulin secretion by pancreatic beta-cells

Morphological studies of pancreatic beta-cells have suggested the presence of discrete sensory and secretory domains. In the present study we now provide functional evidence by demonstrating polarity of insulin release by HIT-T15 cells. A significant diffusion barrier across a twin chamber culture system was verified in the presence of confluent HIT-T15 cells. When stimulated with sulphonylurea, ionophore or high potassium, insulin was preferentially released into the lower chamber irrespective of whether secretagogues were added to the upper or lower chambers. Vectorial insulin secretion may be a significant determinant of islet hormone paracrine interactions in the maintenance of glucose homeostasis.

Generation of lipid polarity in intestinal epithelial (Caco-2) cells: sphingolipid synthesis in the Golgi complex and sorting before vesicular traffic to the plasma membrane

Generation of intestinal epithelial lipid polarity was studied in Caco-2 cells. Confluent monolayers on filters incorporated the exchangeable lipid N-6-NBD-aminocaproyl-sphingosine (C6-NBD-ceramide) from liposomes. The fluorescent ceramide was converted equally to C6-NBD-glucosylceramide and C6-NBD-sphingomyelin, analogues of lipids enriched on the apical and basolateral surface, respectively, of intestinal cells in vivo. Below 16 degrees C, where vesicular traffic is essentially blocked, each fluorescent product accumulated in the Golgi area. At 37 degrees C, 50% had been transported to the cell surface within 0.5 h, as measured by selective extraction of the fluorescent lipids onto BSA in the medium ("back-exchange") at 10 degrees C. Transport to the two surfaces could be assayed separately, as a diffusion barrier existed for both NBD-lipids and BSA. C6-NBD-glucosylceramide was enriched twofold apically, whereas C6-NBD-sphingomyelin was equally distributed over both domains. Polarities did not decrease when 37 degrees C incubations were carried out in the presence of increasing BSA concentrations to trap the fluorescent lipids immediately after their arrival at the cell surface. Within 10 min from the start of synthesis, both products displayed their typical surface polarity. Lipid transcytosis displayed a half time of hours. In conclusion, newly synthesized sphingolipids in Caco-2 cells are sorted before reaching the cell surface. Transcytosis is not required for generating the in vivo lipid polarity.

What's new in cytoskeleton-organelle interactions? Relationship between microtubules and the Golgi-apparatus

Several biochemical processes in animal cells are confined to distinct membrane-bounded compartments. Segregation of specialized functions into different compartments necessitates intercompartment transfer of material. This transfer is mediated by carrier vesicles which, by precise sorting and transport mechanisms, are targetted to their correct destinations. Microtubules, major constituents of the cytoskeleton, are involved both in these intracellular transport processes and in the spatial organization of cytoplasmic organelles. Accumulating evidence suggests that various classes of membranous organelles interact with microtubules. The positioning of several organelles, including the Golgi apparatus and lysosomes, depends on an intact interphase microtubule network. Furthermore, it has been shown that many of these organelles, for example Golgi elements, tubules of the endoplasmic reticulum, exocytic or secretory vesicles and lysosomes move along microtubules. In this article we will discuss the role of microtubules in the movement and positioning of elements of the Golgi complex. The first part will summarize structural and functional aspects of microtubules and the Golgi apparatus and review evidence for their interaction. In the second part, the possible physiological relevance of this interaction will be discussed and correlated with other membrane-microtubule interactions. Finally, emerging questions and perspectives in this field are outlined.

Sorting of an internalized plasma membrane lipid between recycling and degradative pathways in normal and Niemann-Pick, type A fibroblasts

We examined the metabolism and intracellular transport of a fluorescent sphingomyelin analogue, N-(N-[6-[(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino]caproyl])- sphingosylphosphorylcholine (C6-NBD-SM), in both normal and Niemann-Pick, type A (NP-A) human skin fibroblast monolayers. C6-NBD-SM was integrated into the plasma membrane bilayer by transfer of C6-NBD-SM monomers from liposomes to cells at 7 degrees C. The cells were washed, and within 3 min of warming to 37 degrees C, both normal and NP-A fibroblasts had internalized C6-NBD-SM from the plasma membrane, resulting in a punctate pattern of intracellular fluorescence. Rates for C6-NBD-SM internalization and transport from intracellular compartments to the plasma membrane (recycling) were similar for normal and NP-A cells. With increasing time at 37 degrees C, internalized C6-NBD-SM accumulated in the lysosomes of NP-A fibroblasts, while normal fibroblasts showed increasing Golgi apparatus fluorescence with no observable lysosomal labeling. Since NP-A fibroblasts lack lysosomal (acid) sphingomyelinase (A-SMase), this result suggested that hydrolysis of C6-NBD-SM prevented its accumulation in the lysosomes of normal fibroblasts during its transport along the degradative pathway. We used the amount of C6-NBD-SM hydrolysis by A-SMase in normal cells as a measure of C6-NBD-SM transported from the cell surface to the lysosomes. After a lag period, C6-NBD-SM was delivered to the lysosomes at a rate of approximately 8%/h. This rate was approximately 18-19 fold slower than the rate of C6-NBD-SM recycling from intracellular compartments to the plasma membrane. Thus, small amounts of C6-NBD-SM were transported along the degradative pathway, while most endocytosed C6-NBD-SM was sorted for transport along the plasma membrane recycling pathway.

Lipid transport pathways in mammalian cells

A major deficit in our understanding of membrane biogenesis in eukaryotes is the definition of mechanisms by which the lipid constituents of cell membranes are transported from their sites of intracellular synthesis to the multiplicity of membranes that constitute a typical cell. A variety of approaches have been used to examine the transport of lipids to different organelles. In many cases the development of new methods has been necessary to study the problem. These methods include cytological examination of cells labeled with fluorescent lipid analogs, improved methods of subcellular fractionation, in situ enzymology that demonstrates lipid translocation by changes in lipid structure, and cell-free reconstitution with isolated organelles. Several general patterns of lipid transport have emerged but there does not appear to be unifying mechanism by which lipids move among different organelles. Significant evidence now exists for vesicular and metabolic energy-dependent mechanisms as well as mechanisms that are clearly independent of cellular ATP content.

On the mechanism of transbilayer transport of phosphatidylglycerol in response to transmembrane pH gradients

Previous work [Hope et al. (1989) Biochemistry 28, 4181-4187] has shown that asymmetric transmembrane distributions of phosphatidylglycerol (PG) in PG-phosphatidylcholine (PC) large unilamellar vesicles can be induced in response to transbilayer pH gradients (delta pH). Here the mechanism of PG transport has been investigated. It is shown that PG movement in response to delta pH is consistent with permeation of the uncharged (protonated) form and that the half-time for transbilayer movement of the uncharged form can be on the order of seconds at 45 degrees C. This can result in rapid pH-dependent transmembrane redistributions of PG. The rate constant for transbilayer movement exhibits a large activation energy (31 kcal/mol) consistent with transport of neutral dehydrated PG where dehydration of the (protonated) phosphate presents the largest barrier to transmembrane diffusion. It is shown that acyl chain saturation, chain length, and the presence of cholesterol modulate the rate constants for PG transport in a manner similar to that observed for small nonelectrolytes.

Chemistry and biology of N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-labeled lipids: fluorescent probes of biological and model membranes

Lipids that are covalently labeled with the 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD) group are widely used as fluorescent analogues of native lipids in model and biological membranes to study a variety of processes. The fluorescent NBD group may be attached either to the polar or the apolar regions of a wide variety of lipid molecules. Synthetic routes for preparing the lipids, and spectroscopic and ionization properties of these probes are reviewed in this report. The orientation of various NBD-labeled lipids in membranes, as indicated by the location of the NBD group, is also discussed. The NBD group is uncharged at neutral pH in membranes, but loops up to the surface if attached to acyl chains of phospholipids. These lipids find applications in a variety of membrane-related studies which include membrane fusion, lipid motion and dynamics, organization of lipids and proteins in membranes, intracellular lipid transfer, and bilayer to hexagonal phase transition in liposomes. Use of NBD-labeled lipids as analogues of natural lipids is critically evaluated.