Synthesis of chiral pentacyclo-undecane ligands and their use in the enantioselective alkylation of benzaldehyde with diethylzinc
The synthesis of a new class chiral cage annulated bidentate ligands is reported. The ability of the chiral amino alcohols to catalyse the enantioselective addition of diethyl zinc to benzaldehyde was investigated. The cage annulated amino alcohols have C1 symmetry and showed poor to good enantioselectivity with high chemical yields. The system could be utilised as a versatile probe into the reaction mechanism. The synthesis of a new class of chiral pentacycloundecane cage annulated bidentate ligands is reported. This class of ligands can be used in many reactions that are catalysed by amino alcohol ligands. The ability of the chiral ligands to asymmetrically catalyse the reaction between diethylzinc and benzaldehyde was investigated. The cage annulated bidentate ligands have C1 symmetry and showed poor to good enantioselectivity with high yields compared to previous systems reported using other amino alcohol ligands. An important conclusion from the results is that both ligands should be involved in the mechanism as the bidentate ligands gives much improved enantioselectivity when compared with a single chiral source molecule. This system could be utilised as a versatile probe for examining the reaction mechanism.
Boyle, Grant A.,Govender, Thavendran,Kruger, Hendrik G.,Maguire, Glenn E.M.
p. 2661 - 2666
(2007/10/03)
Remote binding energy in antibody catalysis: Studies of a catalytically unoptimized specificity pocket
Binding interactions remote from the hydrolytic reaction center have been probed with substrate and phosphonate transition state analogues to understand how these types of interactions are used to promote catalysis in the 17E8 system. We find that the hapten-generated recogniton pocket in 17E8 has properties that are analogous to those of specificity pockets in enzymes. We have also found that there are specific requirements to form catalytically productive interactions between the side chain and the recognition pocket including conformation, size, and geometry. An additional requirement includes favorable simultaneous interactions between the side chain and binding pocket along with favorable interactions with the oxyanion hole. The 17E8 side chain recognition pocket seems to be less catalytically efficient than analogous pockets in enzymatic systems. The apparent binding energy gained from the methylene-pocket interactions in the 17E8 system is significantly smaller than those observed in natural enzymes. Furthermore, 17E8 does not use specific interactions in the recognition pocket to significantly affect catalytic turnover (kcat) which is thought to be a trait of an unoptimized catalyst. Analysis of the crystal structure of the 17E8·hapten complex has allowed for the identification of differences between the active sites of 17E8 and several proteases. The identified differences give insight to the sources of the inefficient use of binding energy.
Wade, Herschel,Scanlan, Thomas S.
p. 1434 - 1443
(2007/10/03)
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