Thomas W. Tillack

Localization of globoside and forssman glycolipids on erythrocyte membranes

Using the freeze-etch technique, the membrane localization of globoside, a principal glycolipid in human erythrocytes, and Forssman antigen, the chief glycolipid in sheep erythrocytes was evaluated using ferritin and colloidal gold as morphological markers for rabbit antibodies prepared against these glycolipids. Brief trypsinization of human red cell ghosts markedly aggregated intramembranous particles and permitted labeling of globoside, which appeared in a clustered arrangement. The aggregates of ferritin-anti-globoside differed from those of ferritin-wheat germ agglutinin, a label for glycophorin, which corresponded with the aggregates of intramembranous particles. Double-labeling of human trypsinized ghosts with anti-globoside/ Staphylococcal protein A-colloidal gold and ferritin-wheat germ agglutinin indicated that the patterns of labeling were different and that the aggregates of globoside did not bear a direct relationship to the intramembranous particles, which represent transmembrane proteins. Resealed sheep erythrocyte ghosts labeled with ferritin-conjugated rabbit anti-Forssman showed small clusters of Forssman glycolipid on the erythrocyte surface, which could be markedly aggregated with a second goat anti-rabbit antibody, indicating relative mobility of the small glycolipid domains. The distribution of ferritin-anti-Forssman label in sheep ghosts treated at pH 5.5 to aggregate intramembranous particles also did not show definite correspondence between intramembranous particles and the clusters of ferritin-anti-Forssman.

Organization of ganglioside GM1 in phosphatidylcholine bilayers

Molecules of the ganglioside GM1 are randomly distributed in liquid-crystalline 1-palmitoyl-2-oleoyl phosphatidylcholine bilayers. This conclusion is based on a freeze-etch electron microscopic study using ferritin-conjugated cholera toxin and cholera toxin alone as ganglioside labels. The average number of GM1 molecules under a label is calculated by a novel method from the dependence of the fraction of bilayer area covered by the label on the mole fraction of GM1 in the bilayer.

Organization of the glycosphingolipid asialo-GM1 in phosphatidylcholine bilayers.

An affinity purified monovalent ferritin conjugate of Ricinus communis agglutinin (RCA 60) is used with freeze-etch electron microscopy to study the ultrastructural localization of the glycosphingolipid asialo-GM1 in multilamellar phosphatidylcholine liposomes. Dimyristoylphosphatidylcholine (DMPC) liposomes containing up to 20 mol% asialo-GM1 and quenched below the main transition temperature show a striking linear localization of ferritin-RCA 60 between phospholipid ridges. The glycosphingolipid localization is similar to that postulated for up to 20 mol% cholesterol in pure phosphatidylcholine bilayers by Copeland, B.R. and McConnell, H.M. (Biochim. Biophys. Acta, 599, 95-109 (1980)). Above the main phase transition temperature, asialo-GM1 appears to be organized into clusters, especially in palmitoyloleoylphosphatidylcholine (POPC) liposomes. This clustered distribution of glycosphingolipids seen above the phase transition temperature suggests that this type of lipid may exhibit compositional domain structure in biological membranes.

Polarity of the Forssman glycolipid in MDCK epithelial cells.

To determine whether epithelial plasma membrane glycolipids are polarized in a manner analogous to membrane proteins, MDCK cells grown on permeable filters were analyzed for the expression of Forssman ceramide pentasaccharide, the major neutral glycolipid in these cells. In contrast to a recent report which described exclusive apical localization of the Forssman glycolipid (Hansson, G.C., Simons, K. and Van Meer, G. (1986) EMBO J. 5, 483-489), immunofluorescence and immunoelectron microscopic staining revealed the Forssman glycolipid on both the apical and basolateral surfaces of polarized cells. Immunoblots indicated that the Forssman antigen was detectable only on glycolipids and not on proteins. Analysis of metabolically labeled glycolipids released into the apical and basal culture medium, either as shed membrane vesicles or in budding viruses, also demonstrated the presence of the Forssman glycolipid on both apical and basolateral membranes of polarized cells. Quantitation of the released glycolipid indicated that the Forssman glycolipid was concentrated in the apical membrane. These results are consistent with previous reports which described quantitative enrichment of glycolipids in the apical domain of several epithelia.

Molecular Organization of Glycosphingolipids in Phosphatidylcholine Bilayers and Biological Membranes

Glycosphingolipids, in contrast to glycerol-based lipids, are relatively minor components of mammalian cell membranes. They are, however, confined to the external surface of the plasma membrane and in this surface may collectively be a major component (1–4). In some cell types very small amounts of these lipids have been found associated with Golgi membranes, their probable site of biosynthesis (1). Their location on the trans-cytoplasmic side of the plasma membrane causes them, together with glycosylated membrane proteins, to be the primary components of the cell to interact with the molecules and other cells of the immediate environment. Thus specific glycosphingolipids have been shown to serve as receptors for toxins, viruses and some hormones (2,5–11). They have long been known to act as antigenic determinants and to mediate immune responses (11–13). There is much evidence to suggest that glycosphingolipids play a role in cell-cell interaction and recognition (7). Alterations in the amounts and types of these lipids on the cell surface are very often associated with growth, differentiation, development, aging (7,14,15), and with oncogenic transformation (11,16). Although there is considerable information about the molecular structure of many glycosphingolipids, relatively little is known about the organization of molecules of this class in phospholipid bilayers and in the bilayers of biological membranes. It seems certain that their molecular organization is a critical parameter underlying many of the functions of glycosphingolipids (17).

Pulmonary Capillary Hemangiomatosis Associated with CREST Syndrome: A Case Report and Review of the Literature

This is a report of fatality immediately after administration of epoprostenol. The patient was previously diagnosed with CREST syndrome and associated interstitial lung disease. She developed worsening pulmonary hypertension and was clinically diagnosed with pulmonary veno-occlusive disease. The patient developed flash pulmonary edema and arrested after administration of low-dose epoprostenol in the intensive care unit. An autopsy revealed the patient suffered from pulmonary capillary hemangiomatosis. We review our case and what is known about this rare disease.

Glycolipids are not extracted from phospholipid bilayers by binding to ferritin-lectin conjugates

Abstract A radioactively-labelled glycosphingolipid, asialo-GM1, has been incorporated into phosphatidylcholine multilamellar vesicles. After incubation with ferritin-Ricinus communis agglutinin 60 (RCA 60) conjugate at different temperatures, the vesicles were separated from the conjugate by discontinuous density gradient ultracentrifugation. Measurement of the distribution of the radioactively-labelled asialo-GM1 in the pelleted conjugate fraction and freeze-etch electron microscopy of the vesicle fraction indicate that the decrease in labelling of asialo-G M 1 -containing vesicles by ferritin-RCA 60 conjugate with increasing temperatures (Tillack, T.W., Wong, M., Allietta, M. and Thompson, T.E. (1982) Biochim. Biophys. Acta 691, 261–273) reflects a decrease in apparent binding affinity rather than an ability of the conjugate to extract glycolipid from the phospholipid bilayer after binding.