Chris W.M. Grant

A model for ganglioside behaviour in cell membranes.

Gangliosides from beef brain have been spin-labeled using two different attaching groups and employed to investigate the physical nature of ganglioside behaviour in membranes. Results obtained using EPR spectroscopy indicate that, in phosphatidylcholine bilayers at physiological pH, ganglioside oligosaccharide chains are quite mobile and show a measurable tendency towards cooperative interaction amongst themselves. We suggest that the source of this interaction is the formation of H-bonds between sugar residues in adjacent ganglioside molecules. We present evidence that physiological (extracellular fluid) levels of Ca2+ and Mg2+ lead to cross-linking and condensing of ganglioside headgroups by complexing sialic acid carboxyl residues. Ganglioside headgroup interactions are not very sensitive to changes in the buffer ionic strength, suggesting that ionic interactions are of minor importance. We have found no measurable tendency for headgroup carbohydrate to penetrate hydrophobic regions of lipid bilayers. EPR spectroscopy was also used to follow the interaction of spin-labeled gangliosides with the glycoprotein, glycophorin, and with intact BHK cells. We suggest that these carbohydrate-based interactions should contribute significantly to the properties of the eucaryotic cell glycocalyx. We predict that laterally mobile carbohydrate-bearing components of cell surface will show a tendency to cluster about complex glycoprotein arrays, especially if the species involved bear accessible carboxylic acid functions.

Glycolipids in model membranes Spin label and Freeze-Etch studies

1. Several types of glycolipid are examined in lipid bilayer model membranes as part of a program to clarify their fuction in living cells. 2. Data obtained with three spin labelled derivatives of galactosyl ceramide is reported showing a fatty acid fluidity gradient similar to that obtained with phospholipid spin labels. Some possible structural implications of the observed differences are considered. 3. Results obtained using Freeze-Etch electron microscopy and hemagglutination inhibition are given showing beef brain gangliosides in lipid vesicles to be effective receptors for influenza virus.

Ganglioside headgroup dynamics.

Gangliosides, spin-labelled specifically on N-acetylneuraminic acid residues or on random-headgroup sugars, have been used to extend previous studies of headgroup behaviour. Headgroup sugar mobility is seen to be homogeneous and relatively unrestricted in a range of systems including three lines of cultured cells. The effects of temperature and pH have been considered. Binding of small quantities of the lectin, wheat germ agglutinin, was found to increase average headgroup mobility for gangliosides in lipid bilayers, most likely as a result of a disordering effect on ganglioside clusters.

A long chain spin label for glycosphingolipid studies: transbilayer fatty acid interdigitation of lactosyl ceramide

16-Carbon and 18-carbon fatty acids with covalently attached nitroxide free radicals have seen wide usage in membrane studies of phospholipid dynamics, orientation, and associations. However, they are inadequate for dealing with some very important questions that relate to glycosphingolipids. We report here the synthesis of a long chain (24-carbon) spin-labelled fatty acid designed for such problems. We have used both the new 24-carbon and the more conventional 18-carbon spin-labelled fatty acids to replace the natural fatty acid of lactosyl ceramide so that we may begin to compare short and long chain derivatives to analyse the molecular basis of their functional differences. Spectra seen are consistent with the view that in a bilayer host matrix the methyl end of the long fatty acid crosses the hydrophobic membrane center and interdigitates with fatty acids of phospholipids of the opposing monolayer.

A ganglioside spin label: Ganglioside head group interactions

Abstract A general procedure has been developed for covalent attachment of a nitroxide spin label in the head group region of gangliosides. Gangliosides so labeled and incorporated into lipid bilayer vesicles give a sharp, 3-line spectrum characteristic of a highly mobile structure. The molecular basis of apparent ganglioside-ganglioside head group interaction is briefly discussed.

A glycosphingolipid spin label: Ca2+ effects on sphingolipid distribution in bilayers containing phosphatidyl serine

A glycosphingolipid (galactosyl ceramide) has been synthesized which has a spin label covalently attached near the methyl end of the fatty acid chain. This is to our knowledge the first glycolipid spin label to be reported. It is being used to study glycosphingolipid behaviour in lipid bilayers — especially with a view to potential differences from phospholipids. Like phospholipids it assumes a random distribution in fluid lipid bilayers but tends to be excluded from regions rich in phosphatidyl serine in the face of a Ca2+-induced lateral phase separation.

Isolation and incorporation into lipid vesicles of a concanavalin A receptor from human erythrocytes.

Affinity chromatography has been used to isolate a concanavalin A receptor portion of Band 3 from humen erythrocytes in the presence of the readily-dialysable detergent, dodecyltrimethylammonium bromide. Addition of phospholipids to the isolated fraction and removal of detergent by dialysis leads to formation of vesicles containing the receptor. Intramembranous particles similar in size and shape to those seen in intact erythrocytes are a characteristic of the reconstituted preparations. Vesicles containing receptor bind concanavalin A with high affinity.

Physical biochemistry of a liposomal amphotericin B mixture used for patient treatment

There seems little doubt now that intravenous liposomal amphotericin B can be a useful treatment modality for the management of immunocompromised patients with suspected or proven disseminated fungal infections. Interestingly, the very significant reduction in toxicity reported when amphotericin B is part of a bilayer membrane is closely tied to the physical characteristics of the liposomes involved, although these are poorly understood at the molecular level. We record here an examination by spectroscopy and freeze-etch electron microscopy of unsonicated amphotericin B multilamellar vesicles prepared along the lines that we and others have followed for samples used in clinical trials and preclinical in vivo or in vitro studies. Our study has focussed on liposomes of 7:3 dimyristoylphosphatidylcholine/dimyristoylphosphatidylglycerol (DMPC/DMPG) bearing 0-25 mol% amphotericin B, since this lipid mixture has been the choice for the first clinical trials. Phase transition behaviour of these liposomes was examined by electron paramagnetic resonance (EPR) spectroscopy of a nitroxide spin label partitioning into the bilayers. The same experiments were then performed on similarly prepared liposomes of the disaturated species, dipalmitoylphosphatidylcholine (DPPC), and the diunsaturated species, dielaidoylphosphatidylcholine (DEPC). Partial phase diagrams were constructed for each of the lipid/drug mixtures. Melting curves and derived phase diagrams showed evidence that amphotericin B is relatively immiscible with the solid phase of bilayer membranes. The phase diagram for DEPC/amphotericin B was very similar to that of DPPC/amphotericin B, and both exhibited less extensive temperature ranges of phase separation than did the 7:3 DMPC/DMPG mixture with amphotericin B. Between 25 and 37 degrees C the measured fluidity of the 7:3 DMPC/DMPG liposomes was similar to that of the (unsaturated fatty acid) DEPC liposomes, and considerably higher than that seen for (saturated fatty acid) DPPC liposomes. Preparations of 7:3 DMPC/DMPG, DPPC, and DEPC containing 0-25 mol% amphotericin B were examined by freeze-etch electron microscopy at 35 and 22 degrees C (to cover the temperature range of the mammalian body core and periphery). The same liposome features were present in all three liposome types studied. The appearance of individual liposomes at x 100,000 magnification reflected their molecular characteristics, which were found to be significantly heterogeneous within each batch. The lipid/drug structures were bilayer in nature, although liposomes showing considerable disruption were common, particularly at the highest drug concentrations.(ABSTRACT TRUNCATED AT 400 WORDS)

Co-operative binding of concanavalin A to A glycoprotein in lipid bilayers

Lectin-binding curves are reported for a concanavalin A receptor glycoprotein in lipid bilayers and intact cells. The results are consistent with previous studies of the structurally dissimilar transmembrane glycoprotein, glycophorin. High-affinity lectin binding to model membranes was influenced by the presence of apparently unrelated macromolecules, which we suggest is an example of receptor modulation by local interactions. Furthermore, high-affinity binding to the model membranes displayed characteristics, including positive cooperativity, similar to those seen with intact cells.

Control of high affinity lectin binding to an integral membrane glycoprotein in lipid bilayers.

Abstract High affinity binding of wheat germ agglutinin to glycophorin is demonstrated to be potently affected by non-specific interaction of the receptor with other protein and oligosaccharide structures present at the membrane surface. It is suggested that this may represent a significant general mechanism of receptor control.