Structural Basis for the Resistance of Tay-Sachs Ganglioside GM2 to Enzymatic Degradation*

Yu-Teh LiDagger §, Su-Chen LiDagger , Akira Hasegawa, Hideharu Ishida, Makoto Kiso, Anna Bernardiparallel , Paola Brocca**, Laura Raimondiparallel , and Sandro Sonnino**

From the Dagger  Department of Biochemistry, Tulane University School of Medicine, New Orleans, Louisiana 70112, the  Department of Bio-Organic Chemistry, Gifu University, Gifu 501-11, Japan, the parallel  Department of Organic and Industrial Chemistry, University of Milan, Via Venezian 21, 20133 Milano, Italy, and the ** Department of Medical Chemistry and Biochemistry, University of Milan, Via Fratelli Cervi 93, 20090 Segrate (Mi), Italy

    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

To understand the reason why, in the absence of GM2 activator protein, the GalNAc and the NeuAc in GM2 (GalNAcbeta 1right-arrow4(NeuAcalpha 2right-arrow3)Galbeta 1right-arrow4Glcbeta 1-1'Cer) are refractory to beta -hexosaminidase A and sialidase, respectively, we have recently synthesized a linkage analogue of GM2 named 6'GM2 (GalNAcbeta 1right-arrow6(NeuAcalpha 2right-arrow3)Galbeta 1right-arrow4Glcbeta 1-1'Cer). While GM2 has GalNAcbeta 1right-arrow4Gal linkage, 6'-GM2 has GalNAcbeta 1right-arrow6Gal linkage (Ishida, H., Ito, Y., Tanahashi, E., Li, Y.-T., Kiso, M., and Hasegawa, A. (1997) Carbohydr. Res. 302, 223-227). We have studied the enzymatic susceptibilities of GM2 and 6'GM2, as well as that of the oligosaccharides derived from GM2, asialo-GM2 (GalNAcbeta 1right-arrow4Galbeta 1right-arrow 4Glcbeta 1-1'Cer) and 6'GM2. In addition, the conformational properties of both GM2 and 6'GM2 were analyzed using NMR spectroscopy and molecular mechanics computation. In sharp contrast to GM2, the GalNAc and the Neu5Ac of 6'GM2 were readily hydrolyzed by beta -hexosaminidase A and sialidase, respectively, without GM2 activator. Among the oligosaccharides derived from GM2, asialo-GM2, and 6'GM2, only the oligosaccharide from GM2 was resistant to beta -hexosaminidase A. Conformational analyses revealed that while GM2 has a compact and rigid oligosaccharide head group, 6'GM2 has an open spatial arrangement of the sugar units, with the GalNAc and the Neu5Ac freely accessible to external interactions. These results strongly indicate that the resistance of GM2 to enzymatic hydrolysis is because of the specific rigid conformation of the GM2 oligosaccharide.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
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Tay-Sachs disease is caused by the impaired catabolism of ganglioside GM21 (GalNAcbeta 1right-arrow4(Neu5Acalpha 2right-arrow3)Galbeta 1right-arrow4GlcCer). It has been shown that the terminal GalNAc in GM2 is resistant to beta -hexosaminidase A (Hex A), and that a specific protein cofactor, GM2 activator, is required to assist the hydrolysis (1-4). The disease, therefore, can be caused by the deficiency of either Hex A (5-7) or GM2 activator protein (8-10). The reason for the resistance of GM2 to Hex A is still an enigma.

We have shown that, in addition to the GalNAc, the enzymatic hydrolysis of the Neu5Ac in GM2 also requires GM2 activator protein (11). In GM2, both the GalNAc and the Neu5Ac are linked to the Gal to form GalNAcbeta 1right-arrow4(Neu5Acalpha 2right-arrow3)-Galbeta -, a branched trisaccharide (GM2-epitope). We have rationalized that the resistance of the GalNAc and the Neu5Ac in GM2 to enzymatic hydrolysis may be because of the specific rigid structural conformation of the GM2-epitope and that GM2 activator may interact with the GM2-epitope to make the GalNAc and the Neu5Ac accessible to Hex A and sialidase, respectively (11). To show that this is the case, we have recently synthesized a GM2 analog, 6'GM2 (GalNAcbeta 1right-arrow6(Neu5Acalpha 2right-arrow3)-Galbeta 1right-arrow4GlcCer), in which the GalNAc is linked beta 1right-arrow6 to the Gal (12). Here, we report that, in sharp contrast to GM2, the GalNAc and the Neu5Ac in 6'GM2 were readily hydrolyzed by Hex A and clostridial sialidase, respectively, independent of GM2 activator protein. NMR analysis and molecular mechanics computation revealed that the trisaccharide head group of 6'GM2 is much more flexible than that of GM2. Our results provide the structural basis for the resistance of the GalNAc and the Neu5Ac in GM2 to enzymatic degradation.

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Materials-- GM2 was isolated from the brain of a Tay-Sachs patient according to the published method (13). Asialo-GM2 (GA2) was prepared from GM2 by mild acid hydrolysis (14). Hex A (33.3 units/mg) from human liver was prepared according to our previous report (1). 6'GM2 was chemically synthesized (12). The oligosaccharides OM2, 6'OM2, and OA2 were prepared by the removal of ceramide moieties from GM2, 6'GM2, and GA2 using ceramide glycanase (15). The following were obtained from commercial sources: precoated silica gel-60 TLC plates, Merck (Darmstadt, Germany); GM3, Matreya; sialyllactose, lactose, type X clostridial sialidase, (CD3)2SO, and D2O, Sigma; and Chelex-100 resin, Bio-Rad.

Enzymatic Hydrolysis-- For enzymatic hydrolysis of the GalNAc from glycolipids or from the oligosaccharides derived from glycolipids, each reaction mixture contained 8 nmol of the substrate and the specified amount of Hex A, as indicated in each figure, in 100 µl of 10 mM sodium acetate buffer, pH 4.6. Incubations were carried out at 37 °C for the preset time. For hydrolysis of the Neu5Ac from the glycolipids, 8 nmol of GM2 or 6'GM2 was incubated with 10 units of clostridial sialidase in the presence or absence of 5 µg of GM2 activator protein (11) in 100 µl of 20 mM sodium acetate buffer, pH 5.5. Incubation was carried out at 37 °C for 16 h.

TLC Analysis-- After incubation, each reaction mixture was evaporated to dryness and analyzed by silica gel-60 thin layer chromatography. The solvent system used for developing the glycolipids was chloroform/methanol/water (60:35:8) and that for the oligosaccharides was n-butyl alcohol/acetic acid/water (2:1:1). The plate was sprayed with the diphenylamine reagent (16) and heated at 110 °C for 15 min to reveal oligosaccharides and glycoconjugates. Quantitative results on the % hydrolysis of substrates were obtained from the scanning of the TLC plates using Scan Jet 2C/ADF scanner (Hewlett Packard) and the NIH Image 1.41 program.

NMR Sample Preparation-- Five mg of 6'GM2 were dried under vacuum and were dissolved in 0.5 ml of (CD3)2SO or (CD3)2SO/D2O (20:1) under a stream of nitrogen. To overcome signal broadening of OH groups, such as the Neu5Ac OH8, Gal OH2, and GalNAc OH6, the sample was passed through a Chelex-100 column (0.5 × 2.5 cm, pH 6) before analysis. This procedure allowed the detection of the Neu5Ac OH8 proton as a typical sharp signal at low fields (6.15 ppm), but caused the loss of other OH signals. To complete the assignment, about 4 mg of 6'GM2 in 2 ml of water was dialyzed against 2 mM EDTA, followed by water, and then passed through a Chelex-100 column at pH 7.0. This treatment furnished the GalNAc OH6 and Gal OH2 resonance at 5.16 and 4.35 ppm, respectively, while it caused the loss of the previously assigned OH2 of Glc.

NMR Spectroscopy-- 1H-NMR and 13C-NMR spectra were obtained at 500 and 125 MHz, respectively, on a Bruker AM500 spectrometer and analyzed on a X32 Bruker satellite station equipped with standard Bruker UXNMR software. 1H-1H and 1H-13C two-dimensional spectra were acquired as 2048 × 512 and 2048 × 256 matrices, respectively, with 64 scans per t1 point and processed after zero filling in F1 dimension and appropriate window function multiplication. Proton inter- and intra-residual contacts were evaluated by NOE experiments in the rotating frame ROESY (17) with a spin lock pulse strength of 2.6 kH applied at one end of the spectrum to avoid scalar transfer (18, 19). Temperature was varied in the range of 305-323 K and mixing time between 100-200 ms. The experiments were conducted on both the D2O-exchanged and not-exchanged samples as well as the samples before and after the treatments. Cross-peak volumes were transformed into proton-proton distances r, under the hypothesis of the 1/r6 NOE dependence and using internal calibration on Glc, Gal, GalNAc H1/H3, and H1/H5 distances, and on Glc H1/H2 when accessible. Distances from four experiments were averaged to give the reported values. To achieve reliable comparisons between the oligosaccharide structure of 6'GM2 and GM2, parallel NMR analyses were conducted on GM2 and 6'GM2.

Computational Methods-- All calculations were performed using the MacroModel/Batchmin package (20) (version 5.5) on an O2 SGI workstation and the AMBER* sugar force field (21) augmented by modified neglect of diatomic differential overlap (MNDO)-derived parameters for the anomeric torsion of sialic acid (22). To simplify the computational problem, all calculations on 6'GM2 were run on the methyl derivatives. The calculations were carried out using the generalized born/surface area (GB/SA) water solvation model (23) of MacroModel. This model treats the solvent as an analytical continuum starting near the van der Waals surface of the solute and uses a dielectric constant of 78 for the bulk water and 1 for the molecule. Extended nonbonded cut-off distances were used. Thus, all calculations were run with a van der Waals cut-off of 8.0 Å and an electrostatic cut-off of 20.0 Å.

The conformational searches were carried out using the pseudo systematic variant (SUMM) (24) of the Monte Carlo (MC)/energy minimization procedure (25). The search proceeded by a pseudo systematical alteration of the torsion angles of a starting structure (a minimum energy conformation), thus, a new geometry was generated and energy minimized. This process produced a new minimum energy conformation, which in turn was tested for duplication with previously found conformations. The procedure, therefore, alternated random changes of coordinates (MC), which allowed wide sampling of the potential energy surface, and energy minimization. This MC/energy minimization procedure has been proven to be among the most effective methods for finding nearly all conformations of flexible molecules with low energy. All the anomeric torsion phi, phiC and psi , the C5-C6 omega  torsion, the side chain C6-C7 and C8-C9 torsion of the Neu5Ac residue, and the C-N bonds were used as explicit MC variables.

Energy minimization was performed using the Truncated Newton Conjugate Gradient (TNCG) procedure (26) and was terminated either after 200 iterations or when the energy gradient RMS fell below 0.1 kJ/mol Å. All conformers that differed from the global minimum energy conformation by no more than 50 kJ/mol were saved, and comparison was made only on the heavy atoms to avoid duplicate conformations. Thus, only the global minimum for each conformer was retained, independent of the OH conformations. After addition of explicit H atoms on the sugars, they were further subjected to energy minimization to reduce the energy gradient RMS to 0.01 kJ/mol Å. Fifty four conformers with minimum energy that differed from the global minimum energy conformation by no more than 10 kJ/mol were found. Among them, 15 were contained within 4 kJ/mol and 37 within 8 kJ/mol from the global minimum.

    RESULTS AND DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
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Hydrolysis of GM2 and 6'GM2 by Hex A and Clostridial Sialidase-- The enzymatic susceptibilities of GM2 and 6'GM2 were examined, and the results are shown in Fig. 1. While the GalNAcbeta 1right-arrow4(Neu5Acalpha 2right-arrow3)Galbeta - in GM2 is resistant to Hex A (Fig. 1A, a), the GalNAcbeta 1right-arrow6(Neu5Acalpha 2right-arrow3)Galbeta - in 6'GM2 is readily hydrolyzed by Hex A without the assistance of GM2 activator protein (Fig. 1A, b). We subsequently examined the susceptibility of the Neu5Ac in 6'GM2 to clostridial sialidase, and the result is shown in Fig. 1B. The hydrolysis of the Neu5Ac in GM2 by clostridial sialidase required the assistance of GM2 activator, whereas the Neu5Ac in 6'GM2 could be readily hydrolyzed by clostridial sialidase in the absence of GM2 activator protein. These results clearly indicate that the mutation of the GalNAc linkage in GM2 from GalNAcbeta 1right-arrow4Gal to GalNAcbeta 1right-arrow6Gal affects not only the enzymatic susceptibility of the GalNAc but also that of the Neu5Ac which is linked to C3 of the Gal in both gangliosides.


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Fig. 1.   Thin layer chromatograms showing the susceptibility of the GalNAc and the Neu5Ac in GM2 and 6'GM2 to enzymatic hydrolysis. A, hydrolysis of the GalNAc from GM2 and 6'GM2. Hex, Hex A; h, hour; m, minute; 6'M2, 6'GM2. For the hydrolysis of GM2, 0.25 unit of Hex A was used. For the hydrolysis of 6'GM2, only 0.06 unit of Hex A was used because this ganglioside was completely hydrolyzed by 0.25 unit of Hex A in less than 5 min. B, hydrolysis of the NeuAc from GM2 and 6'GM2. CS, clostridial sialidase; Act, GM2 activator protein. Detailed conditions are described under "Experimental Procedures."

The quantitative comparison on the hydrolyses of GM2 and 6'GM2 by human Hex A in the presence or absence of GM2 activator protein is presented in Table I. Under our assay conditions, GM2 was not hydrolyzed by Hex A in the absence of GM2 activator. The resistance of GM2 to Hex A has been widely recognized. However, in the presence of the activator protein, GM2 became susceptible to Hex A. In contrast, 6'GM2 was readily hydrolyzed by Hex A without GM2 activator protein. To obtain a comparable level of the hydrolysis for both substrates, it was necessary to use only 0.06 units of Hex A for 6'GM2 hydrolysis and 0.25 units of the enzyme for GM2 hydrolysis (see Table I). This suggests that 6'GM2 is a better substrate for Hex A. Moreover, in the presence of the activator protein, the hydrolysis of 6'GM2 increased only 5-10%. These results indicate that GM2 activator protein does not stimulate the two substrates equally. Thus, GM2 activator protein has a specific stimulatory effect on the hydrolysis of GM2 by Hex A. 

                              
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Table I
Hydrolysis of GM2 and 6'GM2 by human Hex A in the presence of GM2 activator
Each assay contained 8 nmol of GM2 or 6'GM2 with or without 1 µg of GM2 activator in 100 µl of 10 mM sodium acetate buffer, pH 4.6. For the hydrolysis of GM2, 0.25 unit of Hex A was used. For the hydrolysis of 6'GM2, 0.06 unit of Hex A was used. The mixtures were incubated at 37 °C for a preset time as indicated, and the percent hydrolysis of the substrate was determined from the TLC plate using a Scan Jet 2C/ADF scanner (Hewlett-Packard).

Susceptibility of the Oligosaccharides Derived from GM2, 6'GM2, and GA2 to Hex A-- To eliminate any possible influence by the ceramide moiety of the glycolipids on the enzymatic hydrolysis of the GalNAc residue, the ceramide residue was removed from the glycolipids, GM2, 6'GM2 and GA2, to yield the oligosaccharides OM2, 6'OM2 and OA2, respectively. As shown in Fig. 2, both 6'OM2 and OA2 were readily hydrolyzed by Hex A alone. In contrast, OM2 was completely resistant to Hex A. Similarly, the Neu5Ac of 6'OM2, but not that of OM2, was susceptible to clostridial sialidase (results not shown). Inclusion of GM2 activator protein in the reaction mixture did not alter the above results because this activator protein requires the lipid moiety of the substrate to exert its stimulatory activity. These results further support that the resistance of GM2 to Hex A and clostridial sialidase is because of the rigid carbohydrate structure of GM2-epitope.


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Fig. 2.   Thin layer chromatogram showing the susceptibility of the GalNAc in OM2, OA2, and 6'OM2 to enzymatic hydrolysis. OM2, OA2, and 6'OM2 are the oligosaccharides derived from GM2, GA2, and 6'GM2, respectively. For each incubation, 0.1 unit of Hex A was used. SL, sialyl lactose; Hex, Hex A; h, hour; Lac, lactose. Detailed conditions are described under "Experimental Procedures."

Conformational Analysis of GM2 and 6'GM2-- To understand the conformation/function relationship of GM2 and 6'GM2, we have also investigated the conformational properties of these two gangliosides by high resolution NMR spectroscopy and molecular mechanics computation, applying an MC conformational search. As shown in Fig. 3A, the pattern of interresidual NOE interactions detected on GM2 is consistent with a single prevalent spatial arrangement of the GalNAcbeta 1right-arrow4(Neu5Acalpha 2right-arrow3)Gal- trisaccharide. In particular, because of the interaction of the GalNAc with the Neu5Ac residue (Fig. 3A), the GalNAc-Gal bond shows a limited flexibility. Such a conformational restriction is confirmed by the MC calculation (Figs. 4 and 6A) and is in agreement with the previous results on the conformation of GM2-oligosaccharide (27).


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Fig. 3.   The ROESY interaction maps. Two-dimensional ROESY sections are shown for GM2 (A) and 6'GM2 (B), composed by three regions of the two-dimensional maps: the GalNAc-H1 (III-H1), the Neu5Ac-OH8 (A-OH8), and the GalNAc-NH(III-NH) regions. I, Glc; II, Gal; III, GalNAc; A, Neu5Ac. The interactions critical for the definition of the oligosaccharide conformation are marked. Note the loss of the GalNAc/Neu5Ac interactions in 6'GM2.


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Fig. 4.   The phi, psi  maps of the GalNAc-Gal glycosidic bond. The lowest energy conformations within 8 kJ/mol from the global minimum of the MC conformational searches performed on the methyl derivatives of the oligosaccharides of GM2 (GalNAcbeta 1right-arrow4(Neu5Acalpha 2right-arrow3)Galbeta 1right-arrow4Glcbeta OMe) and 6'-GM2 (GalNAcbeta 1right-arrow6(Neu5Acalpha 2right-arrow3)Galbeta 1right-arrow4Glcbeta OMe) are shown. Glycosidic angles phi, psi  maps of GM2 (open circle ) and 6'GM2 () are defined as follows: for GM2, phi = GalNAcH1-GalNAcC1-O1-GalC4, psi  = GalNAcC1-O1-GalC4-GalH4; for 6'GM2, phi = GalNAcH1-GalNAcC1-O1-GalC6, psi  = GalNAcC1-O1-GalC6-GalC5. The GalNAc-Gal glycosidic bond of GM2 appears to populate a single well at phi, psi  30°, 20°, which is in agreement with the experimental data shown in Fig. 3. In contrast, a marked flexibility is observed around the GalNAc-Gal glycosidic bond of 6'GM2. The GalNAc anomeric torsion phi appears to be well defined around 45°, but the Gal C6-O6 bond is freely switching from the two conformations at psi  -90° (global minimum shown in Fig. 6B) and psi  +70° (1.2 kJ/mol above the global minimum shown in Fig. 6C). Another conformer of the Gal C6-O6 bond which has energy higher than 8 kJ/mol appears around psi  +180°.

In sharp contrast, a considerable spatial flexibility is found for the GalNAc residue of 6'GM2. As shown in Fig. 3B, the NOE interactions across the GalNAcbeta 1right-arrow6Gal linkage of 6'GM2 consist uniquely of the contacts between the anomeric proton of the GalNAc and the two protons on the C6 of the Gal; the intensities of the two interactions are almost equal. Another important interresidual interaction detected on the GalNAc of 6'GM2 is between the GalNAc-NH and the Glc-OH3 (Fig. 3B). Fig. 5 shows that these three contacts cannot be achieved simultaneously in a single conformation. The MC analysis suggests that they arise from the average of two conformations of the GalNAcbeta 1right-arrow6Gal linkage at phi, psi  45°, -90°, and 45°, +70° (Fig. 4). Fig. 5 also shows how the psi  -90° conformers give rise to the GalNAcNH-GlcOH3 and GalNAcH1-GalH6' contacts, whereas the psi  +70° conformers generate the GalNAcH1-GalH6 cross-peaks. The distances calculated by Boltzmann averaging (28) of the MC conformations in Fig. 5 agree well with the experimental data (see legend to Fig. 5). The interresidual interactions between the Neu5Ac and the Gal protons in 6'GM2 are centered on the side chain of the Neu5Ac, showing the contacts of Neu5Ac-H8 and -OH8 with Gal-H3 (Fig. 3B). These contacts are not detected in the trisaccharide GalNAcbeta 1right-arrow4(Neu5Acalpha 2right-arrow3)Gal- of GM2, or in the same trisaccharide found in GM1, GD1a, and GalNAc-GD1a (17, 27, 29-31). The conformations of these gangliosides are highly restrained at the Neu5Ac-Gal glycosidic bond in an antiperiplanar conformation with the side chain of the Neu5Ac interacting with the GalNAc residue. This is not the case for 6'GM2. The interactions of Neu5Ac-H8 and -OH8 with GalH3 in 6'GM2 suggest that the most populated conformation of the Neu5Ac-Gal bond in this ganglioside is a gauche conformation. The MC calculations corroborate and strengthen the results of NMR analyses and also enable comparison of the lowest energy conformations of the oligosaccharide moieties of GM2 (Fig. 6A) and 6'GM2 (Fig. 6, B and C).


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Fig. 5.   The distances of GalNAc-H1/Gal-H6, GalNAc-H1/Gal-H6', and GalNAc-NH/Glc-OH3 in the conformations for 6'GM2. The three distances are shown on a single three-axis graph. Points in the graph correspond to the distances obtained from the MC lowest energy conformations within 8 kJ/mol from the global minimum. Point correspondence to the GalNAc-Gal bond psi  -90° and psi  70° conformations of Fig. 4 is also highlighted. The figure shows the incompatibility of those distances with a single GalNAc-Gal preferred conformation. The experimentally derived distances of the three contacts are 2.8, 3.0, and 3.4 Å, respectively. The threshold for the detection of NOE interactions is 4 Å. GalNAc-NH/Glc-OH3 (z axis) for the points corresponding to the psi  -90° conformations of the GalNAc-Gal bond is <4 Å (Fig. 4). They represent conformations with the distances of GalNAc-H1/Gal-H6' that are shorter than that of GalNAc-H1/Gal-H6. The Boltzmann mediated distances (2.5, 2.7, and 3.3 Å, respectively) obtained by the MC calculation are in good agreement with the experimental values.


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Fig. 6.   The spatial arrangements of the oligosaccharide moieties in GM2 (A) and 6'GM2 (B and C). Representative conformers are shown for GM2 and 6'GM2 as calculated by molecular mechanics. Conformers are taken from the lowest energy conformations within 8 kJ/mol. The computational results were validated by comparing the calculated distances with the experimental (NOE-derived) values. The calculated distances were obtained as r = < ri-6> -1/6 where < ri-6> is the Boltzmann average of ri-6 of the individual conformations within 10 kJ/mol from the global minimum. The GalNAcbeta 1right-arrow4(Neu5Acalpha 2right-arrow3)Galbeta 1- trisaccharide of GM2 shows one preferred spatial arrangement which is defined by a number of experimentally detected interactions (arrows). The GalNAcbeta 1right-arrow6(Neu5Acalpha 2right-arrow3)Galbeta 1- of 6'GM2, on the contrary, shows a fairly "opened" spatial arrangement, with the GalNAc-Gal bond sampling the two conformations as shown in Fig. 4. The conversion of GM2 to 6'GM2 dramatically alters the spatial disposition of the Neu5Ac residue because of the loss of its interactions with the GalNAc that exists in the very compact GalNAcbeta 1right-arrow4(Neu5Acalpha 2right-arrow3)Galbeta 1- trisaccharide structure of GM2. The significantly more populated conformation found in GM2 is at phi,psi -160°, -25°, whereas in 6'GM2 the lower energy is at phi,psi -70°, +10° (gauche conformation).

The conformational studies of 6'GM2 and GM2 reveal that the modification of the GalNAc linkage in GM2 from beta 1right-arrow4Gal to beta 1right-arrow6Gal dramatically alters the dynamics of the sugar chain. The overall effect of this modification is to give the oligosaccharide head group of 6'GM2 an "open" spatial arrangement (Fig. 6, B and C) in which the GalNAc and the Neu5Ac residues are freely accessible to external interactions. Indeed, it has been shown that a flexible ligand has a lower affinity to its receptor than a rigid ligand fitting perfectly to the binding site. However, a flexible ligand with a high degree of mobility can increase the rate of association (32).

The above results clearly show that the specific trisaccharide structure of GM2-epitope in which the GalNAcbeta 1right-arrow4 and the Neu5Acalpha 2right-arrow3 are both linked to the penultimate Gal residue can render the GalNAc and the Neu5Ac resistant to enzymatic hydrolysis. The disruption of this rigid structure by mutating the GalNAcbeta 1right-arrow4Gal linkage to GalNAcbeta 1right-arrow6Gal makes the GalNAc susceptible to Hex A and the Neu5Ac to sialidase. A well known example where the linkage mobility is closely associated with the ganglioside-protein interactions is that of GD1a ganglioside. GD1a is a disialoganglioside whose structure can be regarded as having an extension of the sugar chain of GM2 by adding an extra Neu5Acalpha 2right-arrow3Galbeta - disaccharide to the C3 of the GalNAc. It is widely known that, of the two Neu5Acalpha 2right-arrow3Galbeta - linkages in GD1a, only the external one is susceptible to sialidase. The inner Neu5Acalpha 2right-arrow3Galbeta - linkage of GD1a is part of the trisaccharide in GM2, which is very rigid because of the presence of a "blocking" GalNAc residue. The external Neu5Acalpha 2right-arrow3Galbeta - linkage, absence of the "blocking" GalNAc residue, is more flexible and fluctuates between two limiting conformations (31). Thus, the susceptibility of the Neu5Ac in GD1a to sialidase is associated with the dynamics of the Neu5Acalpha 2right-arrow3Galbeta - linkage.

Although complex carbohydrates have been recognized as information rich molecules, functions expressed by complex carbohydrate chains are still not readily decipherable as those of proteins and nucleic acids. The primary structure of a complex carbohydrate chain includes the sugar sequence, the anomeric configurations of the sugar units, and the linkages of the two adjacent sugar residues. It is not difficult to understand that the anomeric configuration of a sugar residue can profoundly affect physicochemical and biological properties of a sugar chain. However, the effect of a single sugar linkage on the overall physicochemical and biological properties of a sugar chain is still not well appreciated. Our results show that the biological properties of a sugar chain can be expressed through the specific linkage of the sugar chain. Our investigation through chemical mutation of sugar linkages provides an explanation for the resistance of GM2 to enzymatic degradation.

    ACKNOWLEDGEMENTS

We thank Drs. A. D. French, S. J. Landry, and K. Maskos for critical review of the manuscript and helpful discussions.

    FOOTNOTES

* This research was supported by the National Institutes of Health Grant NS 09626 (to Y.-T. L.) and CNR 96.03182.CT04 (to S. S.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ To whom correspondence should be addressed: Dept. of Biochemistry, Tulane University School of Medicine, 1430 Tulane Ave., New Orleans, LA 70112. Tel.: 504-584-2459; Fax: 504-584-2739; E-mail: yli{at}tmcpop.tmc.tulane.edu.

    ABBREVIATIONS

The abbreviations used are: GM2, GalNAcbeta 1right-arrow4(NeuAcalpha 2right-arrow3)Galbeta 1right-arrow4Glcbeta 1-1'Cer; 6'GM2, GalNAcbeta 1right-arrow6(NeuAcalpha 2right-arrow3)Galbeta 1right-arrow 4Glcbeta 1-1'Cer; asialo-GM2 (GA2), GalNAcbeta 1right-arrow4Galbeta 1right-arrow4Glcbeta 1-1'Cer; GM3, NeuAcalpha 2right-arrow3Galbeta 1right-arrow4Glcbeta 1-1'Cer; OM2, GalNAcbeta 1right-arrow4(NeuAcalpha 2right-arrow3)Galbeta 1right-arrow4Glc; 6'OM2, GalNAcbeta 1right-arrow6(NeuAcalpha 2right-arrow3)Galbeta 1right-arrow4Glc; OA2, GalNAcbeta 1right-arrow4Galbeta 1right-arrow4Glc; Hex A, beta -N-acetylhexosaminidase A; Lac, lactose; SL, sialyl-lactose; TLC, thin layer chromatography; NOE, nuclear Overhauser effect; MC, Monte Carlo; ROESY, rotating frame nuclear Overhauser enhancement spectroscopy.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
  1. Li, Y.-T., Mazzotta, M. Y., Wan, C.-C., Orth, R., and Li, S.-C. (1973) J. Biol. Chem. 248, 7512-7515[Abstract/Free Full Text]
  2. Hectman, P., and LeBlank, D. (1977) Biochem. J. 167, 693-701[Medline] [Order article via Infotrieve]
  3. Conzelmann, E., and Sandhoff, K. (1979) Hoppe-Seyler's Z. Physiol. Chem. 360, 1837-1849[Medline] [Order article via Infotrieve]
  4. Li, S.-C., Hirabayashi, Y., and Li, Y.-T. (1981) J. Biol. Chem. 256, 6234-6240[Free Full Text]
  5. Hultberg, B. (1969) Lancet 2, 1195[Medline] [Order article via Infotrieve]
  6. Okada, S., and O'Brien, J. S. (1969) Science 165, 698-700[Medline] [Order article via Infotrieve]
  7. Sandhoff, K. (1969) FEBS Lett. 4, 351-354[CrossRef][Medline] [Order article via Infotrieve]
  8. Conzelmann, E., and Sandhoff, K (1978) Proc. Natl. Acad. Sci. U. S. A. 75, 3979-3983[Abstract]
  9. Hechtman, P., Gordon, B. A., and Ng Ying Kin, N. M. K. (1982) Pediatr. Res. 16, 217-222[Abstract]
  10. Hirabayashi, Y., Li, Y.-T., and Li, S.-C. (1983) J. Neurochem. 40, 168-175[Medline] [Order article via Infotrieve]
  11. Wu, Y.-Y., Lockyer, J. M., Sugiyama, E., Pavlova, N. V., Li, Y.-T., and Li, S.-C. (1994) J. Biol. Chem. 269, 16276-16283[Abstract/Free Full Text]
  12. Ishida, H., Ito, Y., Tanahashi, E., Li, Y.-T., Kiso, M., and Hasegawa, A. (1997) Carbohydr. Res. 302, 223-227[CrossRef][Medline] [Order article via Infotrieve]
  13. Svennerholm, L. (1972) Methods Carbohydr. Chem. 6, 464-474
  14. Svennerholm, L., Månsson, J.-E., and Li, Y.-T. (1973) J. Biol. Chem. 248, 740-742[Abstract/Free Full Text]
  15. Zhou, B., Li, S.-C., Laine, R. A., Huang, R. T. C., and Li, Y.-T. (1989) J. Biol. Chem. 264, 12272-12277[Abstract/Free Full Text]
  16. Harris, G., and MacWilliam, I. C. (1954) Chem. Ind. (London) 249
  17. Bax, A., and Davis, D. G. (1985) J. Magn. Reson. 63, 207-213
  18. Acquotti, D., Poppe, L., Dabrowski, J., von der Lieth, C. W., Sonnino, S., and Tettamanti, G. (1990) J. Am. Chem. Soc. 112, 7772-7778
  19. Farmer, B. T., II, and Brown, L. R. (1987) J. Magn. Res. 72, 197-202
  20. Mohamadi, F., Richards, N. G. J., Guida, W. C., Liskamp, R., Lipton, M., Caufield, C., Chang, G., Hendrickson, T., and Still, W. C. (1990) J. Comput. Chem. 11, 440-467
  21. Senderowitz, H., and Still, W. C. (1997) J. Org. Chem. 62, 1427-1438[CrossRef]
  22. Bernardi, A., and Raimondi, L. (1995) J. Org. Chem. 60, 3370-3377
  23. Still, W. C., Tempczyk, A., Hawley, R., and Hendrickson, T. (1990) J. Am. Chem. Soc. 112, 6127-6129
  24. Goodman, J. M., and Still, W. C. (1991) J. Comput. Chem. 12, 1110-1117
  25. Chang, G., Guida, W. C., and Still, W. C. (1989) J. Am. Chem. Soc. 111, 4379-4386
  26. Ponder, J. W., and Richards, F. M. (1987) J. Comput. Chem. 8, 1016-1024
  27. Sabesan, S., Bock, K., and Lemieux, R. (1984) Can. J. Chem. 62, 1034-1045
  28. Rutherford, T. J., Spackman, D. G., Simpson, P. J., and Homans, S. W. (1994) Glycobiology 4, 59-68[Abstract]
  29. Brocca, P., Berthault, P., and Sonnino, S. (1998) Biophys. J. 74, 309-318[Abstract/Free Full Text]
  30. Poppe, L., van Halbeek, H., Acquotti, D., and Sonnino, S. (1994) Biophys. J. 66, 1642-1652[Abstract]
  31. Acquotti, D., Cantu, L., Ragg, E., and Sonnino, S. (1994) Eur. J. Biochem. 225, 271-288[Abstract]
  32. Homans, S. W. (1993) Glycobiology 3, 551-555[Medline] [Order article via Infotrieve]


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