Elucidation of the Cation−π Interaction in Small-Molecule Asymmetric Catalysis

Lin, Song

14 October 2013

The cation&ndash;&pi; interaction has been long-established to play an important role in molecular recognition, supramolecular chemistry, and molecular biology. In contrast, its potential application in small-molecule catalysis, especially as a selectivity-determining factor in asymmetric synthesis has been overlooked until very recently. This dissertation begins with an extensive literature review on the state-of-the-art research on the application of cation&ndash;&pi; interactions in non-enzymatic catalysis of organic and organometallic transformations. The research in this field has been largely inspired and guided by the related biosynthetic systems incorporating the same type of interactions.</p> / Chemistry and Chemical Biology

Organic chemistry

anion binding

asymmetric catalysis

cation-pi interaction

episulfonium ion

polycyclization

thiourea

Experimental and Computational Studies in Bioorganic and Synthetic Organic Chemistry

Lam, Polo Chun Hung

13 December 2004

Cationâ Ï interaction is an important determinant in protein structure and function. Among the three proteinogenic aromatic amino acids, tryptophan (Trp) is the strongest cationâ Ï donor. We reported the asymmetric syntheses of tryptophan regioisomers in which the amino acid side chain is attached at different position of the indole moiety. These new tryptophan regioisomers can effect a different mode of cationâ Ï interaction. In nature, dramatic increases in binding affinity can be achieved through multivalent binding. Following a fragmentation-dimerization approach, we synthesized Taxol-based dimer in which the baccatin III core of Taxol is coupled with flexible PEG linker. However, microtubule assembly assay suggested that these new dimers are not capable of effecting bivalent binding to the Taxol binding sites in microtubules. Memory of chirality (MOC) is an emerging theme in asymmetric synthesis in which the dynamic chirality of the reactive intermediate "memorizes" the static chirality of the reactant. Using dynamic 1D and 2D NMR and density functional theory (DFT) methods, we studied the MOC effect of 1,4-benzodiazepin-2-ones. Reconstruction of the reaction pathway using DFT calculations supported our proposed contra steric, retention of configuration mechanism. / Ph. D.

Memory of Chirality

Microtubules

Dynamic Chirality

Density Functional Theory

Dynamic NMR

Cation-Pi Interaction

Amino Acids

Asymmetric Synthesis

PEG

Taxol

Paclitaxel

Multivalent Binding

Tryptophan