Involvement of water in host-guest interactions.

As predicted by inhibition studies the X-ray crystal structure of the complex formed between the tetrasaccharide alpha-L-Fuc(1----2)-beta-D-Gal(1----3) [alpha-L-Fuc-(1----4)]-beta-D-GlcNAc- OMe (Leb-OMe) and the lectin IV of Griffonia simplicifolia (GS-IV) shows three hydroxyl groups (referred to as the polar key) hydrogen bonded within the combining site and flanked by hydrophobic surfaces. Apart from OH-6 of the beta-D-GlcNAc unit, the six other hydroxyl groups reside at or near the periphery of the combining site. Linear enthalpy-entropy compensation is observed for complex formation with monodeoxy and other derivatives of Leb-OMe involving one of these six hydroxyl groups. Decreases in both the thermodynamic parameters (- delta H 0 and - delta S 0) are largest when a hydroxyl group is in contact with water at the periphery of the combining site. The experimental evidence indicates that the binding reactions involve very similar if not identical changes in the conformations of both the lectin and the ligands; it is therefore proposed that the enthalpy-entropy compensations arise because water molecules hydrogen bonded to the amphiphilic surfaces of the unbound oligosaccharide and the protein are more mobile (higher entropy content) and less strongly hydrogen bonded than are water molecules in bulk solution. Monte Carlo simulations of the hydration of Leb-OMe appear to support this idea. In accordance with this proposal the association of complementary amphiphilic molecular surfaces from aqueous solution is driven by the release of the water molecules from both non-polar and polar regions of the amphiphiles to form stronger hydrogen bonds in bulk water. In the case of highly amphiphilic molecules such as the oligosaccharide Leb-OMe the negative contributions to entropy change dominate positive contributions that may arise from hydrophobic effects. The GS-IV(Leb-OMe)2 complex is stabilized by the hydrogen-bonding networks involving an asparate, an asparagine and a serine residue within the combining site and the above-mentioned key hydroxyl groups. Improved packing of the molecules may also be involved.

The conformational analysis of substance P analogs using high-field NMR techniques.

High-field nuclear magnetic resonance measurements were carried out on substance P fragments SP4-11' [pGlu5]-SP5-11 and [pGlu6]SP6-11 both at 400 and at 500 MHz. A spectral simulation was carried out on two of these peptides and the coupling constants were interpreted in terms of the conformations. The JNH-CHa coupling constants are all approximately 8 Hz, with the exception of glycine, indicating no preferred conformation for the backbone. For the amino acids other than p-Glu, a comparison of the coupling constant data suggests the same relative rotamer populations for the side chains. Proton longitudinal relaxation time data were measured for all three peptides and support the above conclusions.

The detailed conformational study of a leukotriene antagonist, FPL-55712, using high-field nuclear magnetic resonance spectroscopy.

High-field proton magnetic resonance measurements at 400 MHz and 600 MHz allowed the evaluation of the preferred conformations of a leukotriene antagonist, FPL-55712. The experiments involved an analysis of proton-proton coupling constants, longitudinal relaxation time data and nuclear Overhauser effect experiments. The NMR parameters confirm the conformational features expected from X-ray and microwave data for related substances, such as rotational freedom about C14-C15 and C15-C16, synperiplanar arrangements for C7-C8-O-C14 and C16-O-C17-C18 and segmental motion in the propyl side chains.