Diffusion-controlled reaction kinetics of the binding of carbon monoxide to the heme undecapeptide of cytochrome c (microperoxidase 11) in high viscosity solvents

Glycosphingolipids from human plasma with Le^a, Le^b, and H-type 1 (Le^dH) Lewis-blood-group activity have been analyzed after permethylation by electron impact mass spectrometry using an indirectly heated direct insertion probe. The spectra obtained are compared with that of permethylated neo-lactotetraosyl ceramide (Gl-3) from human plasma. The fragmentation patterns presented show clearly, that Le^a and H-type 1 glycosphingolipids are ceramide pentasaccharides while Le^b is a ceramide hexasaccharide. All Lewis-blood-group-active compounds investigated produced ions specific for type 1 carbohydrate chains. It is therefore concluded, that all compounds are derivatives of lacto-N-tetraose. The obtained spectra support the following sequences: Hexose-1→3-hexosamine[4←1-deoxyhexose]-hexose-hexose ceramide for the Le^a derivatives; deoxyhexose-hexose-1→3-hexosamine4←1-deoxyhexose]-hexose-hexose ceramide for the Le^b derivatives; and deoxyhexose-hexose-1→3-hexosamine-hexose-hexose ceramide for all H-type 1 (Le^dH) derivatives. In the case of the H-type 1 glycosphingolipids four subfractions were analyzed separately. While all four fractions contained the same carbohydrate sequence, significant differences were observed in the ceramide residues. Specific fragmentation patterns indicate the presence of sphingosine, icosasphingosine, and 4-hydroxysphinganine besides normal, unsaturated, and hydroxylated fatty acids in all Lewis-blood-group-active glycolipids.     

Structural characterization of glycosphingolipids by direct chemical ionization mass spectrometry

This report describes the use of direct chemical ionization mass spectrometry with ammonia as the reagent gas (NH3-DCI) for structure analysis of underivatized, permethylated and permethylated and reduced glycosphingolipids. In contrast to ionization by electron impact, the NH3-DCI mass spectra exhibit intense molecular and carbohydrate sequence-related ions using microgram amounts of sample. Underivatized glycosphingolipids with up to two sugar residues yield abundant protonated and ammonia-cationized molecular ions and structurally significant fragments. Permethylation in conjunction with NH3-DCI can be used to obtain molecular weight as well as oligosaccharide sequence and branching information on neutral, acidic and complex-type glycosphingolipids with up to five sugar residues. Reduction of the permethylated derivatives gives rise to several new, structurally significant fragments in the corresponding NH3-DCI mass spectra which enable fatty acid and base compositions to be determined. Isotopically labeled reagent gases have been used to confirm the assignment of fragment structures and to demonstrate that the ions observed are unique to the NH3-DCI mass spectra.     

Characterization of glycosphingolipid mixtures with up to ten sugars by gas chromatography and gas chromatography-mass spectrometry as permethylated oligosaccharides and ceramides released by ceramide glycanase

A novel, effective method for structural characterization of glycosphingolipids has been devised. It employs ceramide glycanase to release intact oligosaccharides followed by analysis using high-mass gas chromatography-mass spectrometry. The oligosaccharides and ceramides released by the glycanase were permethylated and analyzed. The capillary gas chromatography gave excellent resolution and separated, for example, two isomeric 10-sugar oligosaccharides with a molecular mass of 2150 daltons differing only by a Gal1-3GlcNAc and a Gal1-4GlcNAc linkage. The oligosaccharides released from sialic acid containing glycosphingolipids (gangliosides) were also analyzed for monosialo compounds. This analytical approach is simple, is quick, and can readily allow quantitation of individual glycosphingolipids.     

Purification and structures of branched blood-group-B-active glycosphingolipids from human erythrocyte membranes

Three different variants of complex, branched, highly blood-group-B-active glycosphingolipids (B-III, B-IV, and B-V) have been isolated from human erythrocytes by means of partition of their membranes in n-butanol/phosphate buffer, subsequent removal of nonpolar lipids and proteins by several steps of phase distribution, acetone or sodium acetate precipitation, peracetylation and repeated fractionation of all crude extracts by silicic acid and ion exchange column chromatography. Finally, peracetylated B-glycolipid fractions were purified to homogeneity by preparative silica gel high-performance thin-layer chromatography. Their structures were elucidated by gas chromatographical sugar analysis, by combined gas chromatography/mass spectrometry of partially methylated alditol acetates for the identification of glycosidic linkages, and by fast atom bombardment and electron impact mass spectrometry of the undegraded, permethylated substances in order to establish the molecular mass, sugar sequence, type of oligosaccharide chain, position of hexosyl branching points, number of N-acetyllatosamine units, as well as sphingosine and fatty acid patterns of the ceramide residues. 360-MHz 1H nuclear magnetic resonance spectroscopy in (2H)dimethylsulfoxide of deuterium-exchanged native B-III and B-IV identified all carbohydrate components, their sites of attachment, the anomeric nature of their glycosidic linkages and the sequential arrangement within the oligosaccharide chain. Furthermore, it established the nature of branching points within the carbohydrate sequence, and assigned the different typical saccharide branches to either the position 2 versus 3, or position 3 versus 6 of the 2,3-disubstituted or 3,6-disubstituted galactoses. The nature of the anomeric linkages and branching points of B-V was based upon the series of NMR data obtained from the B-I--B-IV analogues. All results thus establish the following structures: (formula; see text)     

Mass spectrometric analysis of permethylated glycosphingolipids I. Sequence analysis of two blood-group B active glycosphingolipids from human B erythrocyte membranes.

Two blood group B active glycosphingolipids (B-I and B-II) formerly isolated and purified from human B erythrocytes (16) were investigated by mass spectrometry after permethylation. B-I yielded fragments up to m/e 1266 and B-II up to m/e 1495, showing the sequence of six and seven carbohydrate residues respectively. In combination with additional experimental evidence (18) the glycosphingolipids are demonstrated to be a gal-[ fuc ]-gal-glcNAc-gal-glc-ceramide (B-I) and a gal-[ fuc ]-gal-glcNAc-gal-glcNAc-gal-glc-ceramide (B-II). Mass spectrometric evidence for the ceramide residues are also obtained indicating besides spingosine C24-,C24:1-, and C22-fatty acids as main constituents.     

Analysis of gangliosides using fast atom bombardment mass spectrometry

The native gangliosides GM3, GM1, Fuc-GM1, GD1a, GD1b, Fuc-GD1b, GT1b and GQ1b were analysed by fast atom bombardment mass spectrometry (FAB-MS) in the negative ion mode in a matrix of thioglycerol. After permethylation the same gangliosides were analysed by electron impact (EI) and FAB-MS in the positive ion mode. The negative ion mass spectra furnished information on the molecular weight, the ceramide moiety and the sequence of carbohydrate residues. The sites of attachment and the number of sialic acids present could be deduced directly from the pattern of sequence ions. After addition of sodium acetate positive ion FAB-spectra of the permethylated samples show intense pseudomolecular ions M + Na, that provide evidence on the homogeneity of the samples. In addition, the ceramide part, the oligosaccharide moiety obtained after cleavage of the glycosidic bond of the hexosamine residue, the whole carbohydrate chain and the sialic acids are represented by specific fragment ions. With EI-MS further information can be obtained on the sphingosine and fatty acid components of the ceramide residue. The data show, that the combination of soft ionization mass spectrometry with classical EI-MS gives valuable information on the structure and homogeneity of gangliosides. The method is also applicable to the structural elucidation or quantitation of more complex gangliosides or glycolipid mixtures using only micrograms of material.     

Characterization of B and H blood-group active glycosphingolipids from human B erythrocyte membranes

Two blood group B active glycosphingolipids (B-I and B-II) previously isolated and highly purified from human B erythrocytes [21] were analysed first by degradation with α-D-galactosidase from coffee beans, α-L-fucosidase from bovine kidney and with 0,1 N trichloracetic acid; the native B-glycolipids as well as their degradation products were then investigated by methylation analysis with combined gas chromatography-mass spectrometry, by thin layer chromatography, twodimensional immunodiffusion and by the hemagglutination inhibition technique. Together with the results obtained by mass spectrometry of permethylated glycolipids [26] the following structures were elucidated: α-D-galactopyranosyl-(1 → 3)-[α-L-fucopyranosyl-(1 → 2)]-D-galactopyranosyl-(1 → 4)-N-acetyl-D-glucosaminosyl-(1 → 3)-D-galactopyranosyl-(1 → 4)-D-glucopyranosyl-(1 → 1)-ceramide for the B-I glycosphingolipid and α-D-galactopyranosyl-(1 → 3)-[α-L-fucopyranosyl-(1 → 2)]-D-galactopyranosyl-(1 → 4)-N-acetyl-D-glucosaminosyl-(1 → 3)-D-galactopyranosyl-(1 → 4)-N-acetyl-D-glucosaminosyl-(1 → 3)-D-galactopyranosyl-(1 → 4)-D-glucopyranosyl-(1 → 1)-ceramide for the B-II glycosphingolipid. A H active glycolipid fraction from B erythrocytes further purified by thin layer chromatography was also investigated by methylation analysis. The pattern of its partially methylated alditol acetates was essentially the same as that of the α-galactosidase treated and permethylated B-I glycolipid. It also exhibited strongly precipitating and hemagglutination inhibiting H properties as well as the two α-galactosidase treated B-I and B-II glycosphingolipids. Based upon these data the following tentative structure was proposed: α-L-fucopyranosyl-(1 → 2)-D-galactopyranosyl-(1 → 4)-N-acetyl-D-glucosaminosyl-(1 → 3)-D-galactopyranosyl-(1 → 4)-D-glucopyranosyl-(1 → 1)-ceramide. Gas chromatographic analysis revealed sphingosine and lignoceric, nervonic and behenic acids to be the main components of the ceramide residues of the three glycosphingolipids. From the data presented the H active substance very probably can be regarded as the immediate precursor of the B-I glycosphingolipid from human B erythrocyte membranes.     

Mass spectrometric analysis of permethylated glycosphingolipids II. Comparative studies on different blood-group active and related erythrocyte membrane glycosphingolipids

Three isomeric ceramide tetrasaccharides — P blood-group active globoside, lacto-N-neotetraosyl ceramide as ABH blood-group precursor, both isolated from human erythrocytes and “asiologanglioside” from human brain as reference standard — and two ceramide pentasaccharides — H blood-group active glycosphingolipid, obtained from blood-group B active ceramide hexasaccharide of human B erythrocytes after α-galactosidase treatment and ceramide pentasaccharide from rabbit erythrocytes with B-like blood-group activity — were investigated by mass spectrometry after permethylation. The carbohydrate moiety exhibits differences not only concerning the sugar sequence but also with regard to the position of some glycosidie linkages: Oligosaccharides containing N-acetylhexosamine substituted at position 4 produce spectra that are distinctly different from those containing C-3 substituted N-acetylhexosamines, thus allowing the differentiation between type 1 and type 2 carbohydrate chains. Moreover, oligosaccharide ions with a hexose at the cleavage site exhibit a fragmentation pattern different from those with a N-acetylhexosamine at the “reducing terminal”. The intensity ratio between parent ion and parent ion — 32 mass units is Q ? 3 in the first case, whereas in the latter case Q is <1. The Q-values are given for 14 oligosaccharide ions. Differences in the composition of the ceramide residues can also be deduced from the mass spectra.     

Rapid and sensitive GC/MS characterization of glycolipid released Galalpha1,3Gal-terminated oligosaccharides from small organ specimens of a single pig

Pig to human xenotransplantation is considered a possible solution to the prevailing chronic lack of human donor organs for allotransplantation. The Galalpha1,3Gal determinant is the major porcine xenogeneic epitope causing hyperacute rejection following human antibody binding and complement activation. In order to characterize the tissue distribution of Galalpha1,3Gal-containing and blood group- type glycosphingolipids in pig, acid and nonacid glycosphingolipids were isolated from the kidney, small intestine, spleen, salivary gland, liver, and heart of a single pig obtained from a semi-inbred strain homozygous at the SLA locus. Glycolipids were analyzed by thin-layer immunostaining using monoclonal antibodies, and following ceramide glycanase cleavage as permethylated oligosaccharides by gas chromatography, gas chromatography-mass spectrometry, and matrix- assisted laser desorption/ionization mass spectrometry. The kidney contained large amounts of Galalpha1,3Gal-containing penta- and hexasaccharides having carbohydrate sequences consistent with the Galalpha1,3nLc4and Galalpha1,3Lexstructures, respectively. The former structure was tentatively identified in all organs by GC/MS. The presence of extended Galalpha1,3Gal-terminated structures in the kidney and heart was suggested by antibody binding, and GC/MS indicated the presence of a Galalpha1,3nLc6structure in the heart. The kidney, spleen, and heart contained blood group H pentaglycosylceramides based on type 1 (H-5-1) and type 2 (H-5-2) chains, and H hexaglycosylceramides based on the type 4 chain (H-6-4). In the intestine H-5-1 and H-6-4 were expressed, in the salivary gland H-5-1 and H-5-2, whereas only the H-5-1 structure was identified in the liver. Blood group A structures were identified in the salivary gland and the heart by antibody binding and GC/MS, indicating an organ- specific expression of blood group AH antigens in the pig.      

Fast atom bombardment-mass spectrometry of glycosphingolipids extracted from thin-layer chromatography plates

A method is described for analysis of glycosphingolipids extracted from thin-layer chromatography plates. Mixtures of glycolipids and gangliosides were separated by thin-layer chromatography and the individual bands were eluted, permethylated, and, after purification, analyzed by fast atom bombardment-mass spectrometry. The glycosphingolipids could be characterized from their fast atom bombardment mass spectra in terms of partial monosaccharide sequence, ceramide composition, and molecular weight. The sensitivity of the method allows characterization of 1-5 micrograms of glycosphingolipid.     

The chemistry and control of hereditary lipid diseases

Direct inlet mass spectrometry has been performed on different derivatives of a hematoside (a triglycosylceramide of a tumour) and the major monosialoganglioside of brain (a pentaglycosyl-ceramide). As a confirmation of earlier results it was shown that trimethylsilyl derivatives gave information on ceramide structure (fatty acids and long-chain bases) but no specific information on carbohydrate structure. Fully methylated derivatives on the other hand, not analyzed before, gave in addition to ceramide fragments, specific ions for the sialic acid as well as carbohydrate sequence and branching. Using these derivatives molecular ions were not obtained for the brain ganglioside. However, by reduction of the methylated derivatives with LiA1H₄ (amide groups of ceramide and amino sugars were reduced to the corresponding amines) and trimethylsilylation of the converted sialic acid ester group, molecular weight ions were obtained for both gangliosides. In addition very strong peaks were found for the complete carbohydrate plus the fatty acid, of importance for the determination of the type and exact ratio of sugars, and also the fatty acid composition of the molecules. Ions were also obtained for a conclusive information on carbohydrate sequence and branching. It is concluded that a combined mass spectrometric use of methylated and methylated plus reduced ganglioside derivatives affords structural information on the complete molecules, which will be of considerable help in the characterization of gangliosides on a microscale.     

Detailed structural features of glycan chains derived from alpha1-acid glycoproteins of several different animals: the presence of hypersialylated, O-acetylated sialic acids but not disialyl residues

We analyzed carbohydrate chains of human, bovine, sheep, and rat alpha1-acid glycoprotein (AGP) and found that carbohydrate chains of AGP of different animals showed quite distinct variations. Human AGP is a highly negatively charged acidic glycoprotein (pKa = 2.6; isoelectic point = 2.7) with a molecular weight of approximately 37,000 when examined by matrix-assisted laser-desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) and contains di-, tri-, and tetraantennary carbohydrate chains. Some of the tri- and tetraantennary carbohydrate chains are substituted with a fucose residue (sialyl Lewis x type structure). In sheep AGP, mono- and disialo-diantennary carbohydrate chains were abundant. Tri- and tetrasialo-triantennary carbohydrate chains were also present as minor oligosaccharides, and some of the sialic acid residues were substituted with N-glycolylneuraminic acid. In rat AGP, very complex mixtures of disialo-carbohydrate chains were observed. Complexity of the disialo-oligosaccharides was due to the presence of N, O-acetylneuraminic acids. Triantennary carbohydrate chains carrying N,O-acetylneuraminic acid were also observed as minor component oligosaccharides. We found some novel carbohydrate chains containing both N-acetylneuraminic acid and N-glycolylneuraminic acid in bovine AGP. Interestingly, triantennary carbohydrate chains were hardly detected in bovine AGP, but diantennary carbohydrate chains with tri- or tetrasialyl residues were abundant. Furthermore the major sialic acid in these carbohydrate chains was N-glycolylneuraminic acid. It should be noted that these sialic acids are attached to multiple sites of the core oligosaccharide and are not present as disialyl groups.     

The use of gas chromatography and gas chromatography-mass spectrometry for the characterization of permethylated oligosaccharides with molecular mass up to 2300

Gas chromatography and gas chromatography-mass spectrometry were adapted for the analysis of large permethylated oligosaccharides of different types. Permethylated isomaltooligosaccharides with up to 11 sugar residues and a mass of 2291 Da and two branched blood group H-type decasaccharides derived from the corresponding glycosphingolipids with masses of 2150 Da were successfully analyzed. The capillary columns used have extremely good resolution exemplified by the separation of the two decasaccharides which only differed by one internal linkage position and by the separation of four isomeric tetrasaccharides. The combined information of retention times and mass spectra gave detailed information of 22 neutral oligosaccharides from porcine intestinal mucin and the approach thus allow quick screening of O-linked-type glycans. The procedure for permethylation of oligosaccharides using solid NaOH has been investigated and adapted for structures having a glucose alditol as in reduced oligosaccharides derived from milk and glycosphingolipids.     

Non-acid glycosphingolipid expression in plasma of an A1 Le(a-b+) secretor human individual: identification of an ALeb heptaglycosylceramide as major blood group component.

Total non-acid glycosphingolipids were isolated from plasma of an A1 Le(a-b+) secretor individual with Refsum's disease (phytanic acid storage disease). The glycolipids were separated into 11 fractions by open column chromatography and by HPLC. The fractions were analyzed by thin-layer chromatography and tested for different blood group A activities as well as blood group Le(a )and Leb activity. The fractions were structurally characterized by proton NMR spectroscopy and FAB mass spectrometry and in selected cases by EI mass spectrometry of the permethylated and permethylated-reduced derivatives. Degradation analysis was performed on partially permethylated or permethylated-reduced alditol acetates. The dominating blood group compound was found to be a blood group A active type 1 chain difucosylheptaglycosylceramide. Other blood group compounds were identified as a blood group A active type 1 chain monofucosylhexaglycosylceramide, a blood group Leb hexaglycosylceramide, a blood group H active type 1 chain pentaglycosylceramide, and a globotetraosylceramide (the P-antigen). The presence of a Le(a) glycosphingolipid and blood group A type 3/4 chain structures were also found by immunostaining. Glucosyl-, lactosyl-, and globotriaosylceramides were the dominating short chain compounds. The amount of phytanic acid incorporated into the monoglycosylceramide fraction was found to be less than 5% of the fatty acids.     

Immunochemistry of the Lewis blood-group system: isolation and structures of Lewis-c active and related glycosphingolipids from the plasma of blood-group O Le(a-b-) nonsecretors

Five different glycosphingolipid fractions (GL-3, 285 micrograms; GL-5, 1090 micrograms; GL-6, 615 micrograms; GL-7, 555 micrograms; and GL-8, 155 micrograms) have been isolated from 25 liters of plasma of O Le(a-b-) nonsecretors by means of ethanol extraction, several steps of Folch distribution, and reversed-phase, silicic acid, and ion-exchange column chromatography of native or peracetylated substances. Final purification, accomplished by preparative silica gel high-performance thin-layer chromatography, led to chromatographic homogeneity of GL-3 and GL-6. In the hemagglutination inhibition as well as quantitative passive hemagglutination techniques two of these substances (GL-3, GL-5) exhibited distinct, and the other three (GL-6-GL-8) very strong, Lec blood-group activities when tested against two different Lec antisera of human or goat origin. The fragments' structures were elucidated by fast atom bombardment and electron impact mass spectrometry of permethylated derivatives in order to determine molecular weight, sugar sequence, position of branching points, and type of oligosaccharide chains, as well as fatty acid and sphingosine patterns of the ceramide residue. Combined gas-liquid chromatography and mass spectrometry of partially methylated alditol acetates identified sugar composition and glycosidic linkages. Thus, the following structures could be established: (formula; see text) In contrast to the structurally homogeneous GL-3, minor amounts of 4-O-substituted GlcNAc pointed to a small contamination of GL-6 by branched type 2 ceramide nonasaccharide analogs. Glycolipids containing hepta- or nonasaccharides as in GL-3 or GL-6 could also be identified in fractions GL-5 (ceramide heptasaccharide) and GL-7 and GL-8 (ceramide nonasaccharide). These latter fractions revealed, however, distinct heterogeneity due to the presence of a small amount of either a type 2 analog of GL-3 (GL-5) or linear, mainly type 2, ceramide hexa- (GL-5, GL-7) or octasaccharides (GL-8). In addition to previous immunochemical communications the presented Lec active structures of GL-3 and GL-6 provide evidence that 3-fucosyl-N-acetyllactosamine in combination with a type 1 based oligosaccharide sequence and a 3,6-galactosyl branching point are essential parts of the Lec antigenic determinant (as marked in the formula of GL-6).     

Lactotetraosylceramide, a novel glycosphingolipid receptor for Helicobacter pylori, present in human gastric epithelium

The binding of Helicobacter pylori to glycosphingolipids was examined by binding of (35)S-labeled bacteria to glycosphingolipids on thin-layer chromatograms. In addition to previously reported binding specificities, a selective binding to a non-acid tetraglycosylceramide of human meconium was found. This H. pylori binding glycosphingolipid was isolated and, on the basis of mass spectrometry, proton NMR spectroscopy, and degradation studies, were identified as Galbeta3GlcNAcbeta3Galbeta4Glcbeta1Cer (lactotetraosylceramide). When using non-acid glycosphingolipid preparations from human gastric epithelial cells, an identical binding of H. pylori to the tetraglycosylceramide interval was obtained in one of seven samples. Evidence for the presence of lactotetraosylceramide in the binding-active interval was obtained by proton NMR spectroscopy of intact glycosphingolipids and by gas chromatography-electron ionization mass spectrometry of permethylated tetrasaccharides obtained by ceramide glycanase hydrolysis. The lactotetraosylceramide binding property was detected in 65 of 74 H. pylori isolates (88%). Binding of H. pylori to lactotetraosylceramide on thin-layer chromatograms was inhibited by preincubation with lactotetraose but not with lactose. Removal of the terminal galactose of lactotetraosylceramide by galactosidase hydrolysis abolished the binding as did hydrazinolysis of the acetamido group of the N-acetylglucosamine. Therefore, Galbeta3GlcNAc is an essential part of the binding epitope.     

Structural characterization of Schistosoma mansoni adult worm glycosphingolipids reveals pronounced differences with those of cercariae

Immune responses induced by glycans upon infection with Schistosoma mansoni may be mediated by either schistosomal glycoproteins or glycosphingolipids. In this study, we have elucidated the structural features of both carbohydrate moieties and respective ceramide units of complex glycosphingolipids from adult S. mansoni. Obtained data revealed a vast structural heterogeneity due to manifold combinations of different oligosaccharides and ceramide entities. Observed carbohydrate moieties included Lewis(X) (Le(X); Gal(β1-4)[Fuc(α1-3)]GlcNAc) as well as, in part, multiply fucosylated LacdiNAc (LDN; GalNAc(β1-4)GlcNAc) carbohydrate epitopes. Corresponding lipid portions comprised predominantly C18-sphingosine as well as C18- and C20-phytosphingosine derivatives. Intriguingly, glycosphingolipids carrying an Le(X) epitope contained predominantly C18-sphingosine, whereas LDN-based species exhibited mostly phytosphingosine derivatives, in addition to C18-sphingosine, indicating that the two classes of glycosphingolipids might be synthesized via different biosynthetic routes. Compared with literature data, adult worm glycosphingolipids with Le(X) epitopes revealed clear structural differences in comparison to corresponding cercarial species which have been shown to exhibit mainly sphinganine bases with 18-21 carbon atoms. Therefore, it may be hypothesized that the divergent structural features of the respective ceramide moieties are responsible for the published observation that only adult worm, but not cercarial glycosphingolipids are able to induce dendritic cell activation skewing the T-cell response toward a Th1 profile.     

Specificity of lung surfactant protein SP-A for both the carbohydrate and the lipid moieties of certain neutral glycolipids.

Binding specificity of the major surfactant protein SP-A from human and dog lung has been investigated. Radiobinding experiments have shown that both proteins bind in a Ca(2+)-dependent manner to galactose, mannose, fucose, and glucose linked to bovine serum albumin. These results are in accord with a previous study in which monosaccharides were linked to agarose (Haagsman, H. P., Hawgood, S., Sargeant, T., Buckley, D., White, R. T., Drickamer, K., and Benson, B. J. (1987) J. Biol. Chem. 262, 13877-13880). Chromatogram overlays in conjunction with in situ liquid secondary ion mass spectrometry (TLC-LSIMS) of several purified glycosphingolipids and neoglycolipids as well as binding assays with glycolipids immobilized on plastic wells, demonstrate recognition of galactose (human and dog SP-A), glucose, and lactose (human SP-A) in association with specific lipids. In addition, the occurrence of several neutral and acidic glycosphingolipids in human and rat extracellular surfactants and rat alveolar type II cells is described. Selected components among the neutral glycolipids are bound by radiolabeled human SP-A; these are identified by TLC-LSIMS as predominantly ceramide mono- and disaccharides (human surfactant) and ceramide tri- and tetrasaccharides (rat surfactant and type II cells). A recombinant carbohydrate recognition domain (CRD) of human SP-A inhibits the binding of human SP-A to galactosyl ceramide and to galactose- and mannose-bovine serum albumin, indicating that the CRD is directly involved in the binding of SP-A to these ligands. These results provide evidence for a novel type of binding specificity for proteins that have Ca(2+)-dependent CRDs and raise the possibility that glycosphingolipids are endogenous ligands for SP-A.     

Glycosphingolipid specificity of the human sulfatide activator protein

The interaction of the sulfatide activator protein with different glycosphingolipids have been studied in detail. The following findings were made. 1. The sulfatide activator protein forms water-soluble complexes with sulfatides [Fischer, G. and Jatzkewitz, H. (1977) Hoppe-Seyler's Z. Physiol. Chem. 356, 6588-6591] and various other glycospingolipids. 2. In the absence of degrading enzymes the activator protein acts in vitro as a glycosphingolipid transfer protein, transporting glycosphingolipids from donor to acceptor liposomes. Lipids having less than three hexoses, e.g. galactosylceramide, sulfatide and ganglioside GM3 were transferred at very slow rates, whereas complex lipids such as gangliosides GM2, GM1 and GD1a were transferred much faster than the former. The transfer rate increased with increasing length of the carbohydrate chain of the lipid molecules. 3. Both the acyl residue in the ceramide moiety and the nature of the carbohydrate chain are significant for recognition of the glycosphingolipids by the sulfatide activator protein. Apparently, both residues serve as an anchor and the longer they are the better they are recognized by the protein. 4. In the absence of activator protein, degradation rates of sulfatide derivatives by arylsulfatase A, and of ganglioside GM1 derivatives by beta-galactosidase, increase with decreasing length of acyl residues in their hydrophobic ceramide moiety. Addition of activator protein stimulates the degradation of only those GM1 and sulfatide derivatives that have long-chain fatty acids in their hydrophobic ceramide anchor.     

Proton nuclear magnetic resonance analysis of anomeric structure of glycosphingolipids. Blood group ABH-active substances.

High resolution nuclear magnetic resonance spectra of permethylated and permethylated-reduced (LiAlH₄) derivatives were recorded in chloroform solution for the following glycosphingolipids with known structure: lactotriaosylceramide, neolactotetraosylceramide (paragloboside), two blood group H-active pentaglycosylceramides (type 1 and type 2 saccharide chains, respectively), a B-active hexaglycosylceramide, an A-active hexaglycosylceramide, and an A-active octaglycosylceramide. Good quality and resolution allow a clear-cut diagnosis of α-anomeric protons of Fuc, Gal, and GalNAc, and in most cases of all β protons. Upon reduction there is a strong deshielding effect on H-1 of Gal of Galβ1 → 3GlcNAc but not on Gal of Galβ1 → 4GlcNAc. It is therefore possible to differentiate type 1 and type 2 chains by this method, a structural difference of importance for serological specificity. Nuclear magnetic resonance spectroscopy may therefore provide conclusive information on the anomeric structure of the immunodeterminant of blood group-active glycolipids using the same derivatives as for sequence analysis by mass spectrometry.