The effect of high pressure on crystal structure topology

Wood, Peter Andrew

January 2008

This thesis describes the effects of the application of high pressure to single crystals of small organic compounds. A range of different structural analysis techniques have been used with the emphasis on whole molecule interactions rather than atom-atom contacts. A study of the effect of pressure on the crystal structure of salicylaldoxime showed that the size of a pseudo-macrocyclic cavity within the structure is tuneable by compression. This cavity determines the reactivity of salicylaldoxime as a ligand, when deprotonated it is known to preferentially bind Cu 2+ ions over other cations in a bis(salicylaldoximato) complex due to the compatibility between the cavity size and the ionic radius of Cu 2+. Further compression studies on a range of substituted salicylaldoximes with different ambient cavity sizes showed that the application of pressure consistently decreases the cavity size across the whole series. Variation of substituent and the pressure yields cavities which span the covalent radii of many of the 1st transition series metal dications. This should allow the selectivity of metal extraction to be tuned using pressure. Computational studies of lattice energies and conformational energies in the compression studies of L-serine and 3-aza-bicyclo(3.3.1)nonane-2,4-dione have shown that significant molecular distortions can occur during compression of a crystal structure below 10 GPa. L-serine shows different conformations between phases with an energy difference of 40 kJ mol-1, whereas the conformation of 3-aza-bicyclo(3.3.1)nonane-2,4-dione is seen to distort within the same phase. Analysis of a database of compression studies using Hirshfeld surfaces has highlighted the fact that all different types of intermolecular interaction have a lower limit for compression, at least in the pressure regime below 10 GPa. These studies, along with theoretical calculations, have suggested a lower distance limit for H…H contacts of 1.7 A. This is potentially very useful for prediction of the effects of compression as H…H contacts are almost universal across small organic crystal structures.

547.13

Structural Chemistry ; Crystallography

Targeting the mevalonate pathway for pharmacological intervention

Tsoumpra, Maria

January 2011

Farnesyl pyrophosphate synthase (FPPS) is a key branch point enzyme in the mevalonate pathway and the main molecular target of nitrogen-containing bisphosphonates (N-BPs), potent inhibitors of osteoclastic activity and the leading drug of choice for conditions characterized by excessive bone resorption. The main aim of this thesis is to investigate the interaction of N-BPs with FPPS in order to gain further insights into the mechanism of drug inhibition. Kinetic and crystallographic studies following site-directed mutagenesis of FPPS reveal key residues involved in stabilization of carbocation intermediate, substrate binding and formation of a tight enzyme-inhibitor complex. The aromatic ring of Tyr204 is involved in N-BP binding but not in the catalytic mechanism, where the hydroxyl moiety plays an important role. Lys200 is implicated in regulation of substrate binding, product specificity and enzyme isomerization which leads to a tight binding inhibition. Phe239 is considered important for the FPPS C-terminal switch which stabilizes substrate binding and promotes the inhibitor induced isomerized state. The highly conserved Arg112, Asp103 and Asp107 are pivotal for catalysis. Successful purification of the full length of Rab geranylgeranyl transferase (RGGT) complex downstream of the FPPS in the mevalonate pathway was achieved and may lead to co-crystallization with BP analogues and identification of the putative site of drug binding. Investigation of the in vitro effect of N-BPs on osteoclastogenesis suggest a correlation with FPPS inhibition kinetics for the most potent N-BPs but indicate an alternative mechanism of the disruption of bone resorption by alendronate. Together these results highlight the importance of the multiple interactions of N-BPs with side-chain residues of FPPS which dictate their strength of binding and advance the understanding of their pharmacophore effect.

615.1