Structure-activity relationship study of hydroxyethylamine isostere and P1' site structure of peptide mimetic BACE1 inhibitors.

An aromatic substituent has been introduced into a known hydroxyethylamine (HEA)-type BACE1 inhibitor containing the superior substrate sequence to enhance inhibitory activity. The HEA-type isosteres bearing different hydroxyl group and methyl group configurations were prepared through a branched synthesis approach using intra- and inter-molecular epoxide opening reactions. The effect of their configuration was evaluated, showing that an R-configuration improved the inhibitory activity, while introduction of a methyl group on the isostere decreased the activity. Based on the non-substituted isostere with an R-configuration, 21 derivatives containing various substituents at the P1' site were synthesized. Our evaluation of the derivatives showed that the structure of the P1' site had a clear effect on activity, and highly potent inhibitor 40g, which showed sub-micromolar activity against recombinant BACE1 (rBACE1), was identified. The docking simulation of 40g with rBACE1 suggested that a carboxymethyl group at the para-position of the P1' benzene ring interacted with Lys285 in the S1' pocket.

Improvement of windowed type environmental-cell transmission electron microscope for in situ observation of gas-solid interactions.

We have developed an improved, windowed type environmental-cell (E-cell) transmission electron microscope (TEM) for in situ observation of gas-solid interactions, such as catalytic reactions at atmospheric pressure. Our E-cell TEM includes a compact E-cell specimen holder with mechanical stability, resulting in smoother introduction of the desired gases compared with previous E-cell TEMs. In addition, the gas control unit was simplified by omitting the pressure control function of the TEM pre-evacuation chamber. This simplification was due to the successful development of remarkably tough thin carbon films as the window material. These films, with a thickness of <10 nm, were found to withstand pressure differences >2 atm. Appropriate arrangement of the specimen position inside the E-cell provided quantitatively analyzable TEM images, with no disturbances caused by the windowed films. As an application, we used this E-cell TEM to observe the dynamic shape change in a catalytic gold nanoparticle supported on TiO(2) during the oxidation of CO gas.