The crystal structures of 3-O-benzyl-1,2-O-iso-propyl-idene-5-O-methane-sulfonyl-6-O-tri-phenyl-methyl-α-d-gluco-furan-ose and its azide displacement product.

The effect of different leaving groups on the substitution versus elimination outcomes with C-5 d-glucose derivatives was investigated. The stereochemical configurations of 3-O-benzyl-1,2-O-iso-propyl-idene-5-O-methane-sulfonyl-6-O-tri-phenyl-methyl-α-d-gluco-furan-ose, C36H38O8S (3) [systematic name: 1-[(3aR,5R,6S,6aR)-6-benz-yloxy-2,2-di-methyl-tetra-hydro-furo[2,3-d][1,3]dioxol-5-yl)-2-(trit-yloxy)ethyl methane-sulfonate], a stable inter-mediate, and 5-azido-3-O-benzyl-5-de-oxy-1,2-O-iso-propyl-idene-6-O-tri-phenyl-methyl-ß-l-ido-furan-ose, C35H35N3O5 (4) [systematic name: (3aR,5S,6S,6aR)-5-[1-azido-2-(trit-yloxy)eth-yl]-6-benz-yloxy-2,2-di-methyl-tetra-hydro-furo[2,3-d][1,3]dioxole], a substitution product, were examined and the inversion of configuration for the azido group on C-5 in 4 was confirmed. The absolute structures of the mol-ecules in the crystals of both compounds were confirmed by resonant scattering. In the crystal of 3, neighbouring mol-ecules are linked by C-H⋯O hydrogen bonds, forming chains along the b-axis direction. The chains are linked by C-H⋯π inter-actions, forming layers parallel to the ab plane. In the crystal of 4, mol-ecules are also linked by C-H⋯O hydrogen bonds, forming this time helices along the a-axis direction. The helices are linked by a number of C-H⋯π inter-actions, forming a supra-molecular framework.

Back to (non-)Basics: An Update on Neutral and Charge-Balanced Glycosidase Inhibitors.

Glycosidases have important anti-cancer, anti-viral and anti-diabetic properties. This review covers the literature in the past 15 years since our initial review in this journal on "neutral" glycosidase inhibitors lacking a basic nitrogen found in iminosugars and azasugars or inhibitors that are neutral by virtue of being "charge-balanced" (zwitterionic). These structurally diverse inhibitors include lactones, lactams, epoxides such as cyclophellitol, and sulfonium ion derivatives of the natural product salacinol. Synthetic efforts toward cyclophillitol, salicinol and derivatives are also highlighted. Importantly, certain metals can inhibit glycosidases and care must be taken to remove residual catalysts from synthetic material to be tested against these enzymes.

Identification of electric-field-dependent steps in the Na(+),K(+)-pump cycle.

The charge-transporting activity of the Na(+),K(+)-ATPase depends on its surrounding electric field. To isolate which steps of the enzyme's reaction cycle involve charge movement, we have investigated the response of the voltage-sensitive fluorescent probe RH421 to interaction of the protein with BTEA (benzyltriethylammonium), which binds from the extracellular medium to the Na(+),K(+)-ATPase's transport sites in competition with Na(+) and K(+), but is not occluded within the protein. We find that only the occludable ions Na(+), K(+), Rb(+), and Cs(+) cause a drop in RH421 fluorescence. We conclude that RH421 detects intramembrane electric field strength changes arising from charge transport associated with conformational changes occluding the transported ions within the protein, not the electric fields of the bound ions themselves. This appears at first to conflict with electrophysiological studies suggesting extracellular Na(+) or K(+) binding in a high field access channel is a major electrogenic reaction of the Na(+),K(+)-ATPase. All results can be explained consistently if ion occlusion involves local deformations in the lipid membrane surrounding the protein occurring simultaneously with conformational changes necessary for ion occlusion. The most likely origin of the RH421 fluorescence response is a change in membrane dipole potential caused by membrane deformation.