Conformational Analysis of C-Disaccharides using Molecular Mechanics Calculations

ABSTRACT Relaxed-residue energy maps based on the MM3 force field were computed for the methyl glycosides of eight C-linked D-glucosyl disaccharides: the two-bond axial-equatorial linked disaccharides β-kojibioside [(1→2)α–], β-nigeroside [(1→3)α–] and β-maltose [(1→4)α–], the two-bond equatorial-equatorial linked disaccharides β-sophoroside [(1→2)β–], β–laminarabioside [(1→3)β-], β–cellobioside [(1→4)β–] and the three-bond-linked (1→6) disacharides C-isomaltoside and C-gentiobioside. Optimized structures were calculated on a 20° grid spacing of the torsional angles about the C-glycosidic bonds and the final isoenergy surfaces were based on 11664 conformations, for the two-bond-linked disaccharides and 69984 conformations for the three-bond-linked disaccharides. Boltzmann-weighted 3J coupling constants were calculated and compared to the experimental values. They are satisfactory except for maltose where hydrogen bonds cause an over-estimation of the energy differences between the conformers. The energy maps are similar to maps of the corresponding O-disaccharides, but there are differences in the locations and the relative energies of the minima. The preferred conformations of the C-glycosidic bonds are as if they were conforming to the exo-anomeric effect but are closer to staggered conformations than shown by the MM3 results for the O-linkages.

[1]  Kjeld Rasmussen,et al.  A comparison and chemometric analysis of several molecular mechanics force fields and parameter sets applied to carbohydrates , 1998 .

[2]  M. Martín-Pastor,et al.  Experimental Evidence of Conformational Differences between C-Glycosides and O-Glycosides in Solution and in the Protein-Bound State: The C-Lactose/O-Lactose Case , 1996 .

[3]  M. Martín-Pastor,et al.  Experimental and theoretical evidences of conformational flexibility of C-glycosides. NMR analysis and molecular mechanics calculations of C-lactose and its O-analogue , 1995 .

[4]  A. French,et al.  AB INITIO-MIA AND MOLECULAR MECHANICS STUDIES OF THE DISTORTED SUCROSE LINKAGE OF RAFFINOSE , 1994 .

[5]  A. French,et al.  Relaxed‐residue conformational mapping of the three linkage bonds of isomaltose and gentiobiose with MM3(92) , 1994, Biopolymers.

[6]  A. French,et al.  Conformational analysis of the anomeric forms of sophorose, laminarabiose, and cellobiose using MM3. , 1992, Carbohydrate research.

[7]  A. French,et al.  Conformational analysis of the anomeric forms of kojibiose, nigerose, and maltose using MM3. , 1992, Carbohydrate research.

[8]  Y. Kishi,et al.  Preferred conformation of C-glycosides. 7. Preferred conformation of carbon analogs of isomaltose and gentiobiose , 1991 .

[9]  Alfred D. French,et al.  Computer modeling of carbohydrate molecules , 1990 .

[10]  S. Pérez,et al.  Conformational features of C-glycosyl compounds: crystal structure and molecular modelling of "methyl C-gentiobioside". , 1990, Carbohydrate research.

[11]  Norman L. Allinger,et al.  Molecular mechanics. The MM3 force field for hydrocarbons. 1 , 1989 .

[12]  Yukishige Ito,et al.  Synthesis of saccharides and related polyhydroxylated natural products. 4. .alpha.-D- and .beta.-D-C-Glycopyranosides (2,6-dialkyl-substituted tetrahydropyrans) , 1982 .

[13]  K. Kumagai,et al.  Nojirimycin, a new antibiotic. II. Isolation, characterization and biological activity. , 1967, The Journal of antibiotics.

[14]  F. D. Leeuw,et al.  The relationship between proton-proton NMR coupling constants and substituent electronegativities—I : An empirical generalization of the karplus equation , 1980 .

[15]  M. Karplus Contact Electron‐Spin Coupling of Nuclear Magnetic Moments , 1959 .