HR MAS 1H NMR and chemometrics as useful tool to assess the geographical origin of cocoa beans - Comparison with HR 1H NMR.

Chocolate and cocoa-based products are among the goods with higher added value. A current trend of the cocoa market is to offer to the consumers high quality cocoa products, namely mono-origin cocoa. However, a reliable analytical method able to trace the geographical origin of cocoa is lacking. In this work we tested the capability of HR MAS 1H NMR combined with chemometrics to assess the geographical origins of 60 fermented and dried cocoa beans of 23 different cocoa producing countries from the three major crop-growing areas (Africa, Central/South America, Asia/Oceania). Metabolic profiling was determined by HR MAS 1H NMR directly on cocoa powder after the method optimization. The same samples were also subjected to extraction and analysis with HR 1H NMR. HR MAS 1H NMR, as 1H NMR analysis, allowed the simultaneous detection of amino acids, polyalcohols, organic acids, sugars, methylxanthines, catechins. Moreover, HR MAS allows the detection of lipids, not present in the aqueous extract utilized for 1H NMR. The data set obtained is therefore representative of all classes of cocoa compounds. Untargeted HR MAS 1H NMR and 1H NMR datasets were utilized as fingerprint of the samples and elaborated with multivariate statistical methods. A targeted quantitative approach of selected metabolites was possible only with HR 1H NMR data, because HR MAS 1H NMR does not give reliable quantitative results. All the approaches adopted showed a discrimination of the cocoa origins. HR MAS presents the advantages to obtain a very rapid picture of the samples, comprising both lipophilic and hydrophilic components, avoiding any sample manipulation.

Fluorescence excimer formation imaging: a new technique to investigate association to cells and membrane behavior of glycolipids.

A new fluorescence ratio imaging technique aiming to monitor the lateral distribution of pyrene-labeled lipids in the membranes through visualization of the excimer/monomer (E/M) intensity ratio, has been set up, studying the association of a fluorescent derivative of GM1 ganglioside (pyreneGM1) to rat cerebellar granule cells in culture. The imaging results show that the mean E/M ratio value, under experimental conditions leading to the association of pyreneGM1 with the plasma membrane, is significantly higher in neuritic processes than in cell bodies and, moreover, locally distributed in patches. Fluorescence antisotropy imaging of the fluorescent probe TMA-DPH (trimethylaminodiphenylhexatriene) shows the presence of domains having different fluidity and that the average fluidity is higher in cell bodies than in neuritic processes. Additional experiments using TMA-DPH as a marker of fluid-phase pinocytosis, suggest that the rate of endocytosis is comparable in the two regions of the cell. Taken together, on the one hand these data indicate that the fluorescent ganglioside is present in a more clustered state at the level of neuritic processes than in cell bodies and locally distributed in patches of different size and enrichment. On the other hand, they point out the potentiality of the excimer formation imaging technique to study membrane behavior and dynamics of pyrene-labeled lipids, with a particular insight into their aggregative properties.

Formation of a cytosolic ganglioside-protein complex following administration of photoreactive ganglioside GM1 to human fibroblasts in culture.

A GM 1 ganglioside derivative bearing a photoreactive nitrophenyl azide group and tritium labeled at the acetyl group of N-acetylneuraminic acid, has been administered to cultured human fibroblasts. With photolabeling experiments we found that a portion of the ganglioside in the cell cytosol was associated with a soluble protein of about 30 kDa.

Three dimensional structure of GD1b and GD1b-monolactone gangliosides in dimethylsulphoxide: a nuclear Overhauser effect investigation supported by molecular dynamics calculations.

A comparative study on the conformational features of the oligosaccharide moiety of GD1b and GD1b lactone gangliosides, in dimethylsulphoxide, has been carried out by nuclear Overhauser effect investigation; the experimental interresidue contacts have been used for restrained molecular mechanics and dynamics calculations. For GD1b, the tetrasaccharide beta-GalNAc-(1----4)-[alpha-Neu5Ac-(2 ----8)-alpha-Neu5Ac-(2----3)]-beta-Gal has a circular arrangement leaving a highly hydrophobic region with seven hydrogens pointing towards the center. At one side of this region the three electron rich groups GalNAc--NH, external Neu5Ac--OH4 and internal Neu5Ac--COO- are grouped together; at the other side five polar groups (four hydroxy groups and the external Neu5Ac carboxylate) define a large annular hydrophilic region. The external Neu5Ac is close to the external Gal residue, and the external Neu5Ac--COO- is within van der Waals contact with the inner Neu5Ac-OH9 group. The beta-Gal-(1----3)-beta-GalNAc glycosidic linkage shows a high degree of freedom. For GD1b-L, the trisaccharide beta-GalNAc-(1----4)-[alpha-Neu5Ac-(2----3)]-beta-Gal is disposed to forming rigid partially circular arrangement showing strong interresidue contacts between the inner Neu5Ac-H8 and both GalNAc-H1 and GalNAc-H5. The conformation of the lactone ring is the boat 9(A),2(B)B. The lactonization of the disialosyl residue induces a strong variation of the preexisting torsional glycosidic angles phi and psi, leaving the external Neu5Ac far from the external Gal. In both GD1b and GD1b lactone gangliosides, the conformation of the sialic acid side chain is the same as that of the free sialic acid in which the H7 is trans to H8 and gauche to H6, thus indicating that the presence of glycosidic and/or ester linkages does not affect the conformational properties of sialic acid. Both GD1b and GD1b lactone containing sialic acid carboxylate anion(s) or undissociated carboxyl group(s) show the same three dimensional structure, indicating that the presence of charges does not affect the intrinsic conformational features of gangliosides.

Aggregative properties of gangliosides in solution.

The aggregative properties of gangliosides in diluted aqueous solutions are discussed on the basis of simple and well-established thermodynamic concepts. Theoretical assumptions are compared with experimental data obtained, mainly by scattering techniques, on GM3, GM2, GM1, GD1a, GalNAc-GD1a, GD1b, GD1b lactone and GT1b gangliosides, all containing ceramide portions of similar composition, and on GM1 molecular species containing different well-defined ceramide structures. We also report on mixed aggregates with amphiphilic compounds and on the ganglioside aggregate-soluble protein interaction effects which give rise to very stable lipoproteic complexes of well-defined ganglioside-protein composition.

Aggregation properties of GD1b, II3Neu5Ac2GgOse4Cer, and of GD1b-lactone, II3[alpha-Neu5Ac-(2----8, 1----9)-alpha-Neu5Ac]GgOse4Cer, in aqueous solution.

The relevance of the presence of an inner ester in the oligosaccharide chain on the aggregative properties of gangliosides is investigated. Micellar molecular weight and hydrodynamic radius of natural GD1b and of semisynthetic GD1b-lactone are measured by the laser light scattering technique. The presence of the lactone ring causes an increase of 36% for the molecular weight and 16% for the hydrodynamic radius. Measurements on mixtures of GD1b and GD1b-lactone show that mixed micelles are formed with microdomain structure. The results are interpreted in terms of the geometrical packing model for the aggregation of amphiphilic molecules and are correlated to membrane processes.

Aggregation properties of GM3 ganglioside (II3Neu5AcLacCer) in aqueous solutions.

The aggregative properties of highly pure GM3 ganglioside in aqueous solution have been studied by static and dynamic laser light scattering measurements and fluorescence spectroscopy experiments performed by the use of a GM3 derivative containing the pyrene group at the end of the fatty acid moiety. GM3 ganglioside spontaneously aggregates as unilamellar vesicles, down to a concentration of 1.25 x 10(-8) M, showing molecular weight and hydrodynamic radius ranging from 15,000 to 30,000 kDa and from 350 to 470 A, respectively. GM3 vesicles are stable with dilution and can be stored at room temperature for some weeks without appreciable change.

Semisynthetic preparation of N-glycolylneuraminic acid containing GM1 ganglioside: chemical characterization, physico-chemical properties and some biochemical features.

N-Glycolylneuraminic acid containing GM1, GM1(NeuGc), was prepared by semisynthetic procedure. The procedure makes use of GM1 ganglioside deacetylated at the level of sialic acid residue (deAc-GM1) and of 1,3-dioxalan-2,4-dione. DeAc-GM1 is prepared from GM1 by alkaline hydrolysis in the presence of tetramethylammonium hydroxide and the glycolylating compound by reaction of glycolic acid with phosgene in dioxane, followed by cyclization under vacuum. Mass spectrometric and nuclear magnetic resonance spectroscopy analyses clearly indicated the presence, in the neosynthesized ganglioside of a glycolic group in the sialic acid residue. Laser-light scattering measurements show that GM1(NeuGc) aggregates in aqueous media being present in solution as micelles with a molecular weight of 576,000 and a hydrodynamic radius of 62.4 A as determined at 25 degrees C. GM1(NeuGc) promotes neurite outgrowth in N-2a cells to a similar degree as GM1(NeuAc), but shows different behaviour under treatment with sialidase from Arthrobacter ureafaciens.

A new chemical procedure for the preparation of gangliosides carrying fluorescent or paramagnetic probes on the lipid moiety.

A new chemical procedure is described for preparing labelled GM1 molecular species, carrying as acyl moiety pyrene-decanoic acid, 5-doxyl-stearic acid and 16-doxyl-stearic acid. It makes use of a mixed anhydride formed by ethylchloroformate and the labelled acyl chain, as the reagent for N-acylation of a deacetylated, deacylated GM1 ganglioside, which is prepared by alkaline hydrolysis of natural GM1. The reaction performed with a unitary GM1 derivative/mixed anhydride molar ratio, occurs with a yield of above 40%. The labelled deacetylated GM1 molecular species are then N-acetylated by means of acetic anhydride with quantitative yield. The chemical process of insertion of labelled fatty acid and reconstitution of GM1 ganglioside has been confirmed by GLC-MS and NMR analyses. Fluorescence and electron spin resonance experiments indicate that the labelled gangliosides behave similarly to natural GM1, in both the aggregation properties and the capability to be transferred from micelles to vesicular dispersions of phospholipids.

New chemical trends in ganglioside research.

A report is given of recent progress in the methodology for isolation of gangliosides from natural sources, for the preparation of molecular species of gangliosides homogeneous in both the oligosaccharide and ceramide portions of the molecule, for chemical manipulation and derivatization of gangliosides, and for the preparation of gangliosides radiolabelled in different parts of the molecule. Particular emphasis has been given to: high performance liquid chromatographic procedures capable to separate gangliosides on the basis of their oligosaccharide or ceramide moieties and yielding completely homogeneous compounds, that is gangliosides with a single oligosaccharide, a single long chain base and a single fatty acid; two-dimensional thin-layer chromatographic procedures, provided with a fully computerized quantification system, particularly suitable to identifying gangliosides containing alkali-labile linkages, including ganglioside lactones; chemical procedures of high yield for reducing gangliosides at the double bond of long chain base, for selective removal of the fatty acyl moiety and replacement with a novel fatty acid, and for the synthesis of ganglioside lactones; chemical procedures for inserting fluorescent, paramagnetic or photoreactive probes at the fatty acyl part of the ganglioside molecule; procedures for chemical isotopic radiolabelling of gangliosides at the level of sialic acid acetyl group and at the fatty acid moiety. Examples are provided evidencing the significance and potential use of a variety of ganglioside derivatives in the study of ganglioside metabolism and functional implications.

Aggregation properties of semisynthetic GM1 ganglioside (II3Neu5AcGgOse4Cer) containing an acetyl group as acyl moiety.

The aggregative properties of GM1 ganglioside containing an acetyl group as acyl moiety [GM1(acetyl)] in aqueous solution have been studied by static and dynamic light scattering measurements and surface tension experiments. GM1 (acetyl) spontaneously aggregates as small micelles showing a hydrodynamic radius and molecular weight of 34 A and 102 kDa, respectively, down to a concentration of 2.0 x 10(-5) M.

Synthesis and aggregative properties of GM1 ganglioside (IV3Neu5AcGgOse4Cer) containing D-(+)-2-hydroxystearic acid.

GM1 ganglioside containing a hydroxylated fatty acid moiety, GM1(OH), was synthesized starting from lyso-GM1 and D-(+)-2-hydroxystearic acid. The aggregative, geometrical and distribution properties of GM1(OH) were compared with those of stearic acid containing GM1 ganglioside; laser light scattering measurements, differential scanning calorimetry and fluorescence spectroscopy were used. GM1 and GM1(OH) are present in solution as micelles with a hydrodynamic radius of 58.7 and 60.0 A, and molecular mass of 470 and 570 kDa, respectively. The surface area occupied by the monomer of GM1(OH) at the lipid-water interface of the aggregate was calculated to be 117 A2, which is 3 A2 lower than that determined for GM1. Proton NMR analyses of GM1 and GM1(OH) suggest different three-dimensional structures at the ganglioside lipid-water interface. Both GM1(OH) and GM1 inserted into dipalmitoylphosphatidylcholine (DPPC) vesicles undergo segregation phenomena, with the formation of ganglioside-enriched microdomains, but GM1(OH) shows a higher degree of dispersion in the DPPC matrix and exerts a lower rigidifying effect than does GM1.

The structural basis for the susceptibility of gangliosides to enzymatic degradation.

The conformational properties of GM2, GalNacbeta-4(Neu5Acalpha-3) Galbeta-4Glcbeta-1Cer have been compared to those of 6'-GM2, in which the linkage between the GalNAc and Gal was altered from GalNacbeta-4Galbeta- to GalNacbeta-6Galbeta-, and to those of GD1a, Neu5Acalpha-3Galbeta-3GalNAcbeta-4(Neu5Acalpha-3 )Galbeta-4Glcbeta-1Cer, and GalNAc-GD1a. Our results revealed that unlike the compact and rigid oligosaccharide head group found in GM2, where the Neu5Ac and the GalNAc residues interact, the sugar chain of 6'-GM2 is in an open spatial arrangement, with the Neu5Ac no longer interacting with GalNAc, freely accessible to external interactions. The structure of GD1a can be regarded as that of GM2 with an extension of the terminal Neu5Acalpha-3Galbeta-disaccharide. The inner portion of GD1a is that of GM2 comprising the very rigid GalNAc-[Neu5Ac-]Gal trisaccharide. The terminal Neu5Ac-Gal linkage is flexible and fluctuates between two limiting conformations. In GalNAc-GD1a the outer sialic acid gains conformational rigidity due to the presence of the outer GalNAc in position 4 of galactose. This ganglioside has two 'core' GalNAc-[Neu5Ac-]Gal trisaccharide linked in tandem.

Synthesis, structure, and conformation of the dilactone derivative of GD1b ganglioside.

Treatment of DG1b, beta-Gal-(1----3)-beta-GalNAc-(1---- 4)-[alpha-Neu5Ac-(2----8)-alpha-Neu5Ac-(2---- 3)]-beta-Gal-(1----4)-beta-Glc-(1----1)-Cer, with dicyclohexylcarbodi-imide in anhydrous methyl sulfoxide affords 95-98% of GD1b-dilactone. The carboxyl groups of the two sialic acid units are involved in ester linkages, as proved by ammoniolysis and reduction which gave derivatives containing the amide of sialic acid and N-acetylneuraminulose, respectively. 1H-N.m.r. spectroscopy showed that the lactone rings involved position 9 of the inner sialic acid and position 2 of the inner galactose and that the disialosyl chain is extended toward the -beta-Gal-(1 ----4)-beta-Glc- portion of the ganglioside moiety.

Synthesis and structural characterization of the dilactone derivative of GD1a ganglioside.

Treatment of GD1a [alpha-Neu5Ac-(2----3)-beta-GalNAc-(1----4)-[alpha- Neu5Ac-(2----3)]-beta-Gal-(1----4)-beta-Glc-(1----1)-Cer] with dicyclohexylcarbodi-imide in anhydrous methyl sulfoxide affords 94-98% of GD1a-dilactone. The involvement of the carboxyl groups of the two sialic acid residues in the lactone rings was proved by ammoniolysis and reduction experiments, which gave ganglioside derivatives containing the amide of sialic acid and N-acetylneuraminulose, respectively. 1H-N.m.r. spectroscopy showed that the lactone rings involved position 2 of each galactose residue in the ester linkages.

New trends in ganglioside chemistry.

New methods have been developed for the preparation of highly purified gangliosides, homogeneous in the saccharide, long chain base, and fatty acid moieties and gangliosides carrying different kinds of labelled probes. Gangliosides, homogeneous in the oligosaccharide portion, were prepared by preparative normal phase HPLC on a Lichrosorb-NH-2 column, using a gradient of acetonitrile-phosphate buffer, pH 5.6, as solvent system. Each class of ganglioside (from monosialo- to tetrasialogangliosides) was then submitted to reversed phase HPLC on a preparative RP-8 column, using acetonitrile-5 mM phosphate buffer, pH 7, as solvent system, to obtain gangliosides homogeneous in the long chain base moiety. Gangliosides containing C18 and C20 sphinganine were prepared by catalytic hydrogenation of the corresponding unsaturated gangliosides. GM1 with homogeneous acyl chain was prepared by alkaline hydrolysis in the presence of tetramethylammonium hydroxide (which forms a GM1 deacetylated at the level of sialic acid, and a GM1 deacetylated at the level of sialic acid and deacylated at the level ceramide), followed by re-N-acylation, carried out in the presence of dimethylaminopropyl, ethylcarbodiimide and natural fatty acids, or of mixed anhydride of ethylchloroformate and 14C-stearic acid, and re-N-acetylation performed with acetic anhydride or labelled acetic anhydride. The GM1 derivative, de-acetylated at the level of sialic acid, also produced by alkaline treatment of GM1, was submitted to re-N-acetylation with 14C-acetic anhydride to produce specifically 14C-labelled GM1. Re-N-acylation was carried out a) in the presence of dimethylaminopropyl, ethylcarbodiimide and natural fatty acids, b) with mixed anhydride of ethylchloroformate and 14C-stearic acid. After re-N-acylations, re-N-acetylation was performed with acetic anhydride or labelled acetic anhydride. Gangliosides tritium labelled in the oligosaccharide moiety were prepared by the galactose oxidase/3H NaBH4 method, and gangliosides tritium labelled at carbon-3 of unsaturated long chain bases by the dicyano-dichlorobenzoquinone (DDQ)/3H NaBH4 method.

Influence of primary and secondary structures of oligosaccharide chain on the aggregative and geometrical properties of gangliosides.

The aggregative and geometrical properties of gangliosides have been compared and discussed. It is shown that, due to the steric packing features of gangliosides, significative considerations can be made on the primary and secondary structures of their head group, starting from their cooperative behaviour, supporting NMR direct observations.

Relationship between the regulation of membrane enzyme activities by gangliosides and a possible ganglioside segregation in membrane microdomains.

Laser and neutron scattering experiments showed that in mixed micelles of ganglioside GM2 and GT1b, a membrane mimicking system, the segregation of gangliosides may occur spontaneously. Photolabeling experiments using nitrophenylazide containing ganglioside GM1 proved that gangliosides added to cells in culture enter the cell and bind to its membrane as components of microdomains, which specifically interact with a protein of about 30 kDa. This suggests that ganglioside segregation may be a natural phenomenon. Gangliosides when added to granule cells in culture led to increase in protein phosphorylation, the effect exerted being related to the amount of ganglioside molecules inserted stably into the cell lipid layer and an increase of 0.7% of the cell original ganglioside content promoted an increase of 57% in the incorporation of 32P into cell membrane proteins. From the above results a possible relationship between ganglioside segregation and involvement of ganglioside in enzyme activity control is suggested.