A calorimetric study of the thermotropic behaviour of mixtures of brain cerebrosides with other brain lipids

We have used a computer-controlled differential scanning calorimeter to determine the phases present in mixtures of the brain galactocerebrosides with other representative brain lipids. There are two types of brain galactocerebroside, those which possess an alpha-hydroxy substituent on the acyl chain (HFA) and those that do not (NFA). In the liquid crystalline state both cerebrosides were miscible with all the lipids studied, but in the gel state they were immiscible with cholesterol and the brain phosphatidylcholines. However, cholesterol mixtures in which the cholesterol mole fraction exceeded one third formed homogeneous metastable gel states on cooling from above the melting point of the cerebroside. Relaxation to the stable two phase state took place slowly over several hours. The solubilities of the galactocerebrosides in the other main brain sphingolipid, sphingomyelin, were much higher. Only in the case of the NFA galactocerebroside and at low mole fractions of sphingomyelin was immiscibility detected. Ternary mixtures of the two cerebrosides with sphingomyelin/cholesterol and phosphatidylcholine/cholesterol (PC/Chol) showed different miscibility characteristics. On cooling from 80 degrees C all mixtures formed homogeneous gel states. However, on standing the cerebrosides separated into discrete gel phases in all mixtures but one, that in which HFA galactocerebrosides were mixed with sphingomyelin and cholesterol. The cerebroside in the mixture with the composition closest to that of myelin, HFA/PC/Chol, melted at 38 degrees C. On scanning guinea pig CNS myelin which had been equilibrated at 5 degrees C a transition was detected with Tmax 33 degrees C. On the basis of comparison with the HFA/PC/Chol mixture we propose that the transition in myelin at this temperature is due to the melting of a galactocerebroside gel phase.

Interdigitated lipid bilayers of long acyl chain species of cerebroside sulfate. A fatty acid spin label study

The metastable phase behavior of semi-synthetic species of cerebroside sulfate (CBS), with hydroxy and non-hydroxy fatty acids from 16 to 26 carbons in length, was compared in Li+ and K+ using differential scanning calorimetry. The structure of the metastable and various stable phases formed in the presence of these two cations was investigated using a fatty acid spin label, 16-doxylstearate. A number of stable phases with successively higher phase transition temperatures and enthalpies occur in the presence of K+ (see the preceding paper). Li+ prevents formation of the most stable phases with the highest transition temperatures and enthalpies for all species of CBS. However, it does not prevent a transition from the metastable phase to the first stable phase of the longer chain C24 and C26 species. Furthermore, it allows C24:0h-CBS to undergo a similar transition, in contrast to a high K+ concentration, which prevents it. The spin label has anisotropic motion in the metastable gel phase formed by all species of CBS on cooling from the liquid crystalline phase. The spectra resemble those in gel phase phospholipids. The spin label is partially insoluble in the most stable phases formed by all the lipids, including the unsaturated C24:1 species, preventing further elucidation of their structure using this technique. However, the spin label is soluble in the first stable phase formed on cooling by the longer chain C24:0 and C26:0-CBS in Li+ and K+ and by C24:0h-CBS in Li+, and is motionally restricted in this phase. The motional restriction is similar to that observed in the mixed interdigitated bilayers of asymmetric species of phosphatidylcholine and fully interdigitated bilayers formed by symmetric phospholipids. It strongly suggests that the highly asymmetric long chain species of CBS form a mixed interdigitated bilayer in their first stable gel phases while the metastable phase of these and the shorter chain lipids may be partially interdigitated. The metastable phase of C24:1-CBS is more disordered suggesting that it may not be interdigitated at all. Thus the results suggest that (i) the hydroxy fatty acid inhibits but does not prevent formation of a mixed interdigitated bilayer by long chain species of CBS, (ii) an increase in non-hydroxy fatty acid chain length from 24 to 26 carbons promotes it, and (iii) a cis double bond probably prevents any form of interdigitation. These results may be relevant to the physiological and pathological roles of these structural modifications of CBS.

Influence of structural modifications on the phase behavior of semi-synthetic cerebroside sulfate

Cerebroside sulfate (galactosylceramide I3-sulfate) containing alpha-hydroxy lignoceric acid (C24:0h-CBS), nervonic acid (C24:1-CBS), or hexacosanoic acid (C26:0-CBS) was prepared by a semi-synthetic procedure and studied by differential scanning calorimetry. The phase behavior of these species in 2 M KCl was compared to that of shorter chain length hydroxy and non-hydroxy fatty acid species reported earlier. All three of the new lipids undergo metastable phase behavior similar but not identical to the other species. In addition, the metastable phase behavior of all of the non-hydroxy fatty acid species was found to be more complex than previously thought, with several phases of high transition temperatures and enthalpies possible. Fatty acid hydroxylation inhibits the transition from the metastable to some of the more stable phases. It also significantly increases the phase transition temperatures of both the metastable and stable phases indicating that it contributes to the hydrogen bonding network formed between the lipid molecules and helps overcome the lateral repulsive effect of the negatively charged sulfate. The C-15 cis double bond significantly lowers the temperature and enthalpy of the phase transition indicating that it increases the lateral separation of the lipid molecules and decreases the intermolecular hydrogen bonding interactions. However, it does not prevent formation of a more stable phase. By comparing the effect of various structural modifications reported here and earlier it could be concluded that fatty acid chain length has little effect on the phase transition temperature and enthalpy. This suggests that the forces between the lipid molecules may be dominated by head group interactions rather than interactions between the lipid chains. However, fatty acid chain length has a significant effect on the tendency of the hydroxy fatty acid species to form the more stable phase. The ease of formation of the stable phase increases with increase in chain length. Thus an increase in chain length helps overcome the kinetic barrier to stable phase formation presented by hydroxylation of the fatty acid.

Gaucher disease: accurate identification of asymptomatic French-Canadian carrier using nonlabeled authentic sphingolipid substrate N-palmitoyl dihydroglucocerebroside

Gaucher disease is an autosomal recessive sphingolipidosis associated with deficient glucocerebroside beta-glucosidase activity. It is a panethnic metabolic disorder, but the carrier frequency is particularly high among Ashkenazi Jews (estimated between 1:12-1:25). In order to establish a reliable and convenient biochemical assay method for differentiating asymptomatic Gaucher carriers from normal individuals, glucocerebroside beta-glucosidase activity was determined in peripheral blood lymphocytes and cultured skin fibroblasts of 11 Gaucher obligate heterozygotes using the authentic nonlabeled sphingolipid substrate N-palmitoyl dihydroglucocerebroside and the artificial fluorogenic substrate 4-methylumbelliferyl-beta-D-glucopyranoside (4MUGP). The level of lymphocyte beta-glucosidase activity on the glucocerebroside substrate was observed to range from 42-65% of that of the control mean, and there was no overlap of enzyme activity between the Gaucher heterozygotes and controls. However, when the artificial fluorogenic substrate 4MUGP was used, the level of beta-glucosidase activity in 2 of the Gaucher obligate heterozygotes was noted to overlap with that of the control individuals. Contrary to findings in the lymphocytes, cultured skin fibroblasts appear to be a reliable enzyme source for Gaucher carrier detection even when the artificial fluorogenic 4MUGP substrate was used, as the level of beta-glucosidase activity in all of the Gaucher obligate heterozygotes tested was intermediate and distinctly separated from that of the control persons. Using the lymphocyte glucocerebroside beta-glucosidase assay and fibroblast 4MUGP beta-glucosidase assay methods, we identified the carrier status in 3 other relatives and ruled it out in 4 others. These data suggest that nonlabeled glucocerebroside is a reliable and highly specific substrate for either lymphocyte or fibroblast beta-glucosidase activity assay in identifying asymptomatic Gaucher carriers. Use of the 4MUGP substrate for differentiating Gaucher heterozygotes from control persons, on the other hand, should be restricted to the fibroblast enzyme assay method, as considerable overlap of enzyme activity was noted in lymphocytes.

The lateral distribution of pyrene-labeled sphingomyelin and glucosylceramide in phosphatidylcholine bilayers

The lateral distribution of N-[10(1-pyrenyl)decanoyl]-sphingomyelin (PyrSPM) and N-[10(1-pyrenyl)decanoyl]-glucocerebroside (PyrGlcCer) was studied in multilamellar vesicles of 1,2-dipalmitoyl-, 1,2-dimyristoyl-, and 1-palmitoyl-2-oleoyl-phosphatidylcholine (DPPC, DMPC, and POPC, respectively) under anaerobic conditions by determining the excimer-to-monomer fluorescence intensity ratio (E/M) as a function of temperature. The E/M(T) curves for PyrSPM and PyrGlcCer in the three phosphatidylcholine matrices are qualitatively similar to the curves reported for 1-palmitoyl-2-[10-(1-pyrenyl)decanoyl]-phosphatidylcholine (PyrPC) in the same three matrix phospholipids (Hresko, R. C., I. P. Sugár, Y. Barenholz, and T. E. Thompson, 1986, Biochemistry, 25:3813-3823). However, there is independent evidence to suggest that sphingomyelin and glucocerebroside are organized in POPC, DPPC, and DMPC in a more complex manner than is PyrPC. In an effort to examine further the relationship between the lateral distribution of the labeled lipid and the shape of an E/M(T) curve, E/M vs. temperature simulations were carried out together with an analysis of the equation that relates E/M to the system parameters. The results indicate that information about the lateral distribution of the pyrene-labeled lipid can be obtained from an E/M(T) curve only for those systems in which the gel to liquid crystalline phase transition temperature of the matrix lipid is higher than that of the pyrene-labeled lipid. However, very little can be known about the system from an E/M(T) curve if the matrix lipid has the lower phase transition temperature.

Application of a simple methylation procedure for the analyses of glycosphingolipids

Acid and neutral glycosphingolipids (0.01-1 mumol) were completely methylated in high yields and with little formation of by-products in 10 min at room temperature, using methyl sulphoxide, methyl iodide, and powdered NaOH. Re-methylation of methylated and LiAlH4-reduced gangliosides gave a new derivative that was useful for the analysis of gangliosides by mass spectrometry.

The effects of cerebrosides on model membrane shape

Model membranes composed of phosphatidylcholine, various cerebrosides, and cholesterol have been studied by electron microscopy, deuterium NMR, and phosphorus-31 NMR. Large variations in phosphatidylcholine membrane morphology are observed when cerebrosides are present in phosphatidylcholine bilayers. Large spherical liposomes, small spherical liposomes, and long tubular liposomes are formed, depending on the relative acyl chain lengths of the phosphatidylcholine and cerebroside. In some cases, cholesterol can reverse the morphological effects of cerebrosides. These results suggest that cerebrosides, which are found in high concentrations in certain highly specialized membranes, can affect membrane shape and may be involved in the mechanism of formation of membranes with unusual morphology, e.g. neural myelin and the brush border membrane of the intestinal epithelium.

Spontaneous vesicularization of myelin lipids is counteracted by myelin basic protein

Hand-vortexed dispersions of several lipids (cerebrosides, sulfatides, PC, PE, PS and sphingomyelin), mixed in the ratios found for these categories of lipids in myelin, exhibit 31P-NMR spectra which have contributions from both isotropic and lamellar resonances. Investigation of this system by freeze-fracture electron microscopy and X-ray diffraction revealed that this lipid mixture has spontaneously formed small unilamellar vesicles (SUVs) (diam. approximately 400 A) and large highly convoluted unilamellar vesicles (LUVs) (diam. approximately 1000 A), the latter possibly resulting from aggregation and fusion of the SUV structures. This vesicularization of the myelin lipids was reversed by the addition of myelin basic protein: only large multilamellar aggregates were formed in the presence of protein, as shown by all three experimental methods. Although no rigorous physical-chemical explanation for these phenomena is yet available, the possibility is suggested that the high concentration of cerebrosides and/or phosphatidylethanolamine in this particular mixture of myelin lipids play pivotal roles in the formation of these unusual vesicles. Spontaneous vesicularization of myelin lipids is discussed as a potential pathway toward destabilization of the myelin sheath.

Effect of ethylene glycol on the phase transition kinetics of gluco- and galactocerebrosides

The effect of different concentrations of ethylene glycol in water on the phase transition (metastable----stable state) of Gaucher's glucocerebroside, of bovine brain cerebroside type II (non hydroxy acyl chains only) and of N-palmitoylgalactocerebroside has been investigated. The phase transition and its kinetics were inferred from the thermograms at different heating and cooling rates and confirmed by FTIR spectra of the cerebrosides in the different states. The significance of the conformational differences of the glucose and of the galactose residues with respect to their solvation, and the subsequent effect on the intermolecular interactions and the phase transition is discussed.

Factors affecting surface expression of glycolipids: influence of lipid environment and ceramide composition on antibody recognition of cerebroside sulfate in liposomes

The reactivity of the acidic glycolipid cerebroside sulfate (CBS) with antibody was studied as a function of its lipid environment in vesicles and of its ceramide composition. The lipid environment was varied by using phosphatidylcholine of varying chain length with cholesterol in a phosphatidylcholine:cholesterol:cerebroside sulfate molar ratio to glycolipid of 1:0.75:0.1. The ceramide structure of CBS was varied by using synthetic forms containing palmitic acid, lignoceric acid, or the corresponding alpha-hydroxy fatty acids. Reactivity with antibody was determined by measuring complement-mediated lysis of the vesicles containing a spin-label marker, tempocholine chloride. The data were analyzed by a theoretical model which gives relative values for the dissociation constant and concentration of antibodies within the antiserum which are able to bind to the glycolipid. If the phosphatidylcholine chain length was increased, increasing the bilayer thickness, only a small population of high-affinity antibodies were able to bind to cerebroside sulfate, suggesting decreased surface exposure of the glycosyl head group. A larger population of lower affinity antibodies were able to bind to it in a shorter chain length phosphatidylcholine environment. However, if the chain length of the cerebroside sulfate was increased, it could be recognized by more antibodies of lower affinity than the short chain length form, suggesting that an increase in chain length of the glycolipid increased surface exposure. Hydroxylation of the fatty acid inhibited antibody binding; only a smaller population of higher affinity antibodies was able to bind to the hydroxy fatty acid forms.(ABSTRACT TRUNCATED AT 250 WORDS)

Interaction of bradykinin with sodium dodecyl sulfate and certain acidic lipids

The striking change in the circular dichroism (CD) of bradykinin (BK) occasioned by its interaction with sodium dodecyl sulfate (SDS) is evidently due in large part to a change in the conformation of the C-terminal tetrapeptide moiety of the hormone. The full change in CD is induced by the binding of two molecules of monomeric SDS per peptide molecule, the complex being aggregated. Formation of the 1:2 BK-SDS complex apparently proceeds via intermediates of stoichiometry 1:1 and 2:1. The cooperative nature of the interaction is attributed to the SDS-promoted aggregation of BK. Electrostatic interactions with the Arg residues appear important for the binding reaction per se. CD reveals that BK also interacts with acidic lipids which bear a net electrical charge (e.g., cerebroside sulfate and phosphatidyl inositol) but not with lipids bearing no net charge (e.g., cerebroside and phosphatidyl choline). The interactions are with particular mixed micelles of the lipid and the nonionic surfactant used for their solubilization, micellar size and structure being examined by surface tensiometry and electron microscopy.

Thermal and structural behavior of natural cerebroside 3-sulfate in bilayer membranes

Differential scanning calorimetry (DSC), polarizing microscopy and X-ray diffraction studies have been performed on dry and hydrated natural bovine brain sulfatides. Dry sulfatide fractions exhibit a high temperature transition (delta H = 6.6 kcal/mol sulfatide) at 87.3 degrees C. X-ray diffraction shows this transition to be associated with a hydrocarbon chain order-disorder transformation between two lamellar phases. Hydrated sulfatide dispersions undergo a complex chain order-disorder transition (delta H = 7.5 kcal/mol sulfatide) at 32 degrees C with two peak temperatures at 35 degrees C and 47 degrees C. Structural studies performed on hydrated liquid-crystal sulfatide dispersions at 75 degrees C verify the existence of a bilayer structure over the 16 wt.% to 50 wt.% phosphate buffer (pH = 7.4) range. The interbilayer separation between galactosyl-3-sulfate groups averages 48 A as the multilamellar bilayers swell with the addition of phosphate buffer. The formation of micellar phases is not observed at high water contents. The comparison of the structural characteristics of dry and hydrated sulfatides with structural data for dry and hydrated bovine brain non-sulfated glycolipid (cerebroside) is discussed in molecular terms.

An infrared spectroscopic study of metastable and stable forms of hydrated cerebroside bilayers

Fourier transform infrared spectroscopy has been used to study the stable and metastable forms of a range of cerebrosides in aqueous systems. The spectra provide evidence for different degrees of inter- and intra-molecular hydrogen bonding, involving principally the amide group, in these different states. A comparison has been made with the spectra of a cerebroside containing an alpha-hydroxyl group in the fatty acyl chain. This cerebroside does not show metastability and its hydrogen bonding characteristics are shown to be different.

Lipid polymorphism

In this review the polymorphic phase behaviour of several of the major classes of lipids found in biological membranes, both in isolation and also in mixtures, is briefly described. Emphasis is given to the ability of many membrane lipids to adopt non-lamellar phases in response to a variety of factors such as temperature, the presence of divalent cations or changes in pH. The phase behaviour of mixed lipid systems and factors which can modulate the phase preferences of such systems are considered in some detail particularly with regard to the effect of cholesterol upon lipid polymorphism.

Circular dichroism spectra of aqueous dispersions of sphingolipids

The circular dichroism (CD) spectra of a number of sphingolipids dispersed in water have been studied. The lipids include cerebrosides such as palmitoyl cerebroside, glucocerebroside from the spleen of Gaucher patients, bovine brain galactocerebrosides type I and type II, (BCI and BCII, respectively) and also sphingomyelins such as egg sphingomyelin and bovine brain sphingomyelin. Changes in the CD spectra of the lipids which occur upon heating and cooling and the effects of cholesterol, phosphatidylcholine and the opiate leucine enkephalin were studied.

Ricinus communis agglutinin-mediated agglutination and fusion of glycolipid-containing phospholipid vesicles: effect of carbohydrate head group size, calcium ions, and spermine

The glycolipids galactosylcerebroside (GalCer), lactosylceramide (LacCer), and trihexosylceramide (Gb3) were inserted into phospholipid vesicles, consisting of phosphatidylethanolamine and phosphatidic acid. The extent to which their carbohydrate head groups protruded beyond the vesicle surface and their interference with membrane approach were examined by determining vesicle susceptibility toward type I Ricinus communis agglutinin (RCA1) induced agglutination and Ca2+- and spermine-induced aggregation and fusion either in the presence or in the absence of the lectin. The initial agglutination rates increased in the order GalCer much less than LacCer less than Gb3, while a reversed order was obtained for Ca2+- and spermine-induced aggregation and fusion, indicating an enhanced steric interference on close approach of bilayers with increasing head group size. The lectin-mediated agglutination rates for LacCer- and Gb3-containing vesicles increased by an order of magnitude when Ca2+ was also included in the medium, at a concentration that did not induce aggregation per se. Charge neutralization could not account for this observation as the polyvalent cation spermine did not display this synergistic effect with RCA1. Addition of Ca2+ to preagglutinated vesicles substantially reduced the threshold cation concentration for fusion (micromolar vs. millimolar). Quantitatively, this concentration decreased with decreasing carbohydrate head group size, indicating that the head group protrusion determined the interbilayer distance within the vesicle aggregate. The distinct behavior of Ca2+ vs. spermine on RCA1-induced agglutination on the one hand and fusion on the other indicated that Ca2+ regulates the steric orientation of the carbohydrate head group, which appears to be related to its ability to dehydrate the bilayer. As a result, lectin agglutinability becomes enhanced while fusion will be interrupted as the interbilayer distance increases, the threshold head group size being three carbohydrate residues (Gb3). Finally, GalCer-containing vesicles were not agglutinated by RCA1 at ambient temperature, irrespective of the presence of Ca2+. Above 25 degrees C, RCA1 facilitated Ca2+-induced fusion of the vesicles, which was abolished by the haptenic sugar lactose. Since Gb3- and LacCer-containing vesicles displayed a similar behavior, a temperature-induced alteration in the supporting lipid matrix is suggested, which apparently affects lectin/glycolipid interaction.

Competitive binding of dynorphin-(1-13) and beta-endorphin to cerebroside sulfate in solution

Circular dichroism was used as a probe for competitive binding of two opioid peptides, dynorphin-(1-13) and beta-endorphin, with cerebroside sulfate, a membrane lipid thought to be part of the morphine receptor complex. The rationale was that bound beta-endorphin is partially helical but bound dynorphin-(1-13) remains unordered, thus making it possible to detect the degree of binding of beta-endorphin. The addition of dynorphin-(1-13) to a cerebroside sulfate solution of beta-endorphin invariably displaced beta-endorphin from the peptide-lipid complex, but the addition of beta-endorphin had little effect on dynorphin-(1-13) bound to the lipid. Similar results were obtained for competitive binding of the two peptides with two other amphiphiles, sodium dodecyl and decyl sulfate. The maximum number of binding sites on dynorphin-(1-13) and beta-endorphin was between five and six, which coincides with the five positively charged side chains plus an alpha NH+3 group at the NH2 terminus on both peptide molecules. The results support our working hypothesis that dynorphin-(1-13) may displace beta-endorphin bound to the receptor, which in turn can account for the inhibition of beta-endorphin-induced analgesia by dynorphin-(1-13).

Calculation of the conformation of glycosphingolipids. 1. Beta-D-glucosyl-N-(2-D-hydroxyoctadecanoyl)-D-dihydrosphingosine (glucosyl-ceramide) and alpha-D-N-acetylneuraminyl-(2----3)-beta-D-galactose

The conformation of a glucosyl-ceramide, beta-D-galactosyl-N-(2-D-hydroxyoctadecanoyl)-D-dihydrosphingos in e, and of the disaccharide, N-acetylneuraminyl-galactose have been predicted by energy minimization techniques including an orbital force field approach. The predictions have been shown to be in excellent agreement with the results of X-ray single crystal analysis and structures postulated from nuclear magnetic resonance methods and have confirmed the utility of the computational approach to the study of glycosphingolipids.

Influence of vesicle size on complement-dependent immune damage to liposomes

Complement-dependent antibody-mediated damage to multilamellar lipid vesicles (MLVs) normally results in a maximum release of 50-60% of trapped aqueous marker. The most widely accepted explanation for this is that only the outermost lamellae of MLVs are attacked by complement. To test this hypothesis, complement damage to two different types of large unilamellar vesicles (LUVs), large unilamellar vesicles prepared by the reverse-phase evaporation procedure (REVs) and large unilamellar vesicles prepared by extrusion techniques (LUVETs), were determined. In the presence of excess antibody and complement the LUVs released a maximum of only approx. 25 to 40% of trapped aqueous marker, instead of close to 100% that would be expected. Since small unilamellar vesicles apparently differ from LUVs in that they can release 100% of trapped aqueous marker it appeared that the size of the vesicles was an important factor. Because of these observations the influence of MLV size on marker release was examined. Three populations of MLVs of different sizes were separated by a fluorescence activated cell sorter. Assays of the separated MLV populations showed that the degree of complement-dependent marker release was inversely related to MLV size. No detectable glucose was taken up by MLVs when glucose was present only outside the liposomes during complement lysis. Our results can all be explained by the closing, or loss, of complement channels. We conclude that complement channels are only transiently open in liposomes, and that loss of channel patency may be due to either channel closing or to loss of channels.

The effects of ethylene glycol and dimethyl sulfoxide on cerebroside metastability

Aqueous dispersions of n-acyl cerebrosides are known to exhibit metastable polymorphism of the type: (Formula: see text). The involvement of hydration in this metastable polymorphism has been investigated by differential scanning calorimetric studies of aqueous palmitoylgalactocerebroside (C16:0-CER) dispersions in the presence of agents which disrupt water structure. In the presence of 50 vol% ethylene glycol or 50 vol% dimethyl sulfoxide, only a single reversible ordered----liquid-crystalline transition is observed. This single ordered----liquid-crystalline transition exhibits a smaller enthalpy and occurs at a lower temperature than the major Polymorph II----liquid-crystal transition observed for dispersions in water alone. These results indicate that metastable polymorphism in C16:0-CER is related to hydration.

Use of mixed dispersion of fluorescent galactosylceramide and sodium dodecylsulfate for assaying galactosylceramide-beta-galactosidase and diagnosing Krabbe disease

A fluorescent derivative of galactosylceramide [NBD-GalCer: 12-N-methyl-N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)aminodecanoyl+ ++ galactosylceramide] was dispersed in sodium dodecylsulfate and used to determine the activity of galactosylceramide-beta-galactosidase. Optimal assay conditions were defined, compared to other assay procedures and found suitable for diagnosing Krabbe disease.

Interaction of cholesterol with galactocerebroside and galactocerebroside-phosphatidylcholine bilayer membranes

The interaction of the galactocerebroside, N-palmitoylgalactosylsphingosine (NPGS), with cholesterol has been studied by differential scanning calorimetry (DSC) and x-ray diffraction. Thermal and structural studies demonstrate complex behavior characterized by two endothermic transitions: transition I (TI approximately equal to 50-60 degrees C) corresponding to an NPGS-cholesterol bilayer gel----bilayer liquid crystal transition II (TII where TI less than TII less than TNPGS) corresponding to an NPGS bilayer crystal (stable E form)----bilayer liquid crystal transition. For mixtures containing from 6 to 80 mol % cholesterol, x-ray diffraction studies at 22 degrees C (T less than TI) indicate two separate lamellar phases; an NPGS crystal bilayer phase and a cholesterol monohydrate phase. For cholesterol concentrations less than 50 mol % at TI less than T less than TII, NPGS-cholesterol liquid crystal bilayer and excess NPGS crystal bilayer phases are observed. For greater than 50 mol % cholesterol concentrations at these temperatures, an excess cholesterol monohydrate phase coexists with the NPGS-cholesterol liquid crystal bilayers. At T greater than TII, complete NPGS-cholesterol miscibility is only observed for less than 50 mol % cholesterol concentrations, whereas at greater than 50 mol % cholesterol an excess cholesterol phase is present. The solid phase immiscibility of cerebroside and cholesterol at low temperatures is suggested to result from preferential NPGS-NPGS associations via hydrogen bonding. The unique thermal and structural behavior of NPGS-cholesterol dispersions is contrasted with the behavior of cholesterol-phosphatidycholine and cholesterol-sphingomyelin bilayers. Thermal and structural studies of NPGS in dipalmitoylphosphatidylcholine (DPPC)/cholesterol (1:1, molar ratio) bilayers have been performed. For dispersions containing less than 20 mol % NPGS at 22 degrees C there are no observable calorimetric transitions and x-ray diffraction studies indicate complete lipid miscibility. At greater than 20 mol % NPGS, a high temperature transition is observed that is shown by x-ray diffraction studies to be due to an excess NPGS crystal bilayer----liquid crystal bilayer transition. Complete miscibility of NPGS in DPPC/cholesterol bilayers is observed at T greater than TNPGS. The properties of NPGS/DPPC/cholesterol bilayers are discussed in terms of the lipid composition of the myelin sheath.

Fast atom bombardment mass spectrometry of glycosphingolipids. Glycosphingolipids containing neutral sugars

Natural and synthetic glycosphingolipids containing neutral sugars have been analyzed by positive and negative ion fast atom bombardment mass spectrometry. Basic structural characterization including saccharide size and sequence and ceramide composition is possible on the basis of the fragment ions observed. The degree of fragmentation could be increased by using higher sample concentrations and lower fast atom beam energies. Commercially available synthetic compounds that had been presumed to be pure were shown to contain homologous fatty acids. Mixtures of glycosphingolipids such as those obtained from Gaucher's spleen and from human erythrocytes can be characterized and quantitated.

Carbohydrates as antigenic determinants of tumor-associated antigens recognized by monoclonal anti-tumor antibodies produced in a syngeneic system

Two monoclonal antibodies (KH-1 and KH-2) against a transplanted fibrosarcoma (KMT-17) in WKA rats were produced by fusing a mouse myeloma (P3-X63-Ag8.653) with spleen cells from syngeneic rats hyperimmunized with KMT-17. Both antibodies showed complement-dependent cytotoxicity against KMT-17. By absorption of cytotoxicity, KH-1 reacted with homologous tumor, other syngeneic fibrosarcomas (KMT-80 and KMT-75), and lung and kidney from normal rats. However, KH-2 reacted with many kinds of tumors and various normal tissues. Antigen specificity was tested by complement fixation and/or solid-phase radioimmunoassay using glycolipids isolated from KMT-17 cells and authentic glycolipids. KH-1 reacted with globotriglycosyl ceramide which was not detected on KMT-17 cells and in cross-reacted weakly with IV3-alpha-galactosyl-lactoneotetraglycosyl ceramide, one of the major glycolipids of KMT-17. The immune reaction was inhibited by alpha-methyl-galactose. KH-2 reacted with lactosyl ceramide and lactoneotetraglycosyl ceramide. The reaction was more potently inhibited by lactose than by beta-methyl-galactose. Antibodies with similar specificity to either KH-1 or KH-2 were elevated in syngeneic rat sera after serial immunization with viable KMT-17 cells.