Peter J. Tonge, Ph.D. (Professor)

Our laboratory utilizes a variety of spectroscopic techniques, principally vibrational spectroscopy and NMR spectroscopy, to develop precise structure-reactivity correlation's for enzyme-catalyzed reactions. Detailed information is obtained concerning the geometry of the bound substrate, the energy of specific enzyme-substrate contacts and the changes that occur in the electronic structure of the substrate on binding. This approach provides fundamental insight into the mechanism of enzyme catalysis and facilitates the rational design of enzyme inhibitors for use as novel therapeutics.

Electrostatic forces and 'electric fields' play a major role in enzyme-catalyzed reactions. Vibrational spectroscopy enables us to analyze and quantitate alterations in electron density in substrates on binding to enzymes and to quantitate the electric field responsible for the perturbation in electronic structure. Research projects comprise both biological and chemical components, involving techniques such as cloning and overexpression of target enzymes, site directed mutagenesis, enzyme kinetics, substrate synthesis, NMR, Raman and FTIR spectroscopies.