1. | Molecular design, synthesis and fermentation technology |
Theoretical, computational, synthetic and applied approaches to the design and biosynthesis of molecules used to investigate and/or modify biological systems. |
a) | biocatalysis: the use of whole cells and/or enzymes to effect chemical transformations. Small molecule catalysis: the design of small molecule chiral catalysts with enzyme like activities, synthetic enzymes. |
b) | design of key molecules/intermediates for the manipulation of biosynthesis, metabolism or signal transduction. This would include pharmacaphore discovery, drug design and delivery, investigation into molecular modes of action. |
2. | Structure and dynamics of macromolecules |
Physical and theoretical approaches to understanding structure and function of macromolecules with biotechnological applications. |
a) | structural characterization by mass spectrometry, NMR, EPR, specialized RAMAN, IR and optical spectroscopic techniques. |
b) | spectroscopic and theoretical investigations of macromolecular dynamics. Steady state and time resolved NMR, EPR, and optical absorption and emission spectroscopy. Focus on protein and lipid dynamics, protein and lipid interactions, protein conformational changes associated with enzymatic activity, active site dynamics, redox active enzymes and mechanisms of electron transport. Photoactive enzymes and mechanisms of photochemistry. Computer-based molecular modeling techniques applied to biological molecules. |
1. | Regulation of gene expression |
The characterization and manipulation of genes and factors that influence gene expression in prokaryotes and eukaryotes. | |
2. | Genetic Engineering |
Isolation, analysis, modification and re-introduction of genes into organisms with emphasis on gene expression, protein modification, and protein secretion. |