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TSRI Faculty Interests
Nuclear Magnetic Resonance Dickerson, Tobin
develops biochemical technologies for predicting and treating evolving disease such as influenza, hepatitis C, and cancer, high-throughput screening paradigms for protein-ligand agonists/antagonists, combating filarial parasites, and the modulation of botulinum neurotoxin.
Dyson, Helen Jane
uses NMR to study the protein-folding process and to study the nature and behavior of unfolded and partly folded forms of proteins, including prion proteins and several newly-discovered, intrinsically unstructured proteins.
Ghadiri, M.Reza
develops novel methods for the rational design and construction of functional and interesting bioorganic molecules, such as novel antimicrobial agents, catalytic peptides, biosensors, self-replicating systems, and molecular logic gates.
Janda, Kim
Investigates biological catalysts, development of methods for the detection of and protection against chemical/biological warfare agents, combinatorial chemical libraries, synthesis and evaluation of enzyme inhibitors, solid-phase organic synthesis, quorum sensing within bacterial systems, lead discovery and detection strategies for tropical diseases, antibody/peptide phage display libraries, cell-penetrating peptides as therapeutic delivery vehicles, and the application of immunopharmacotherapy in the treatment of drug addiction, cancer and obesity.
Kelly, Jeffery
examines the bioorganic and biophysical chemistry of aberrant conformational changes in proteins associated with misfolding diseases, seeking to develop new approaches for preventing these diseases with purposefully designed small molecules.
Noodleman, Louis
uses quantum chemistry and protein electrostatics to investigate the electronic structures and active site mechanisms of redox metalloproteins, such as respiratory iron-sulfur proteins, the nitrogen fixing nitrogenase enzyme, and the iron-oxo dimer enzymes methane monooxygenase and ribonucleotide reductase.
Otomo, Takanori
studies structure and function of proteins involved in the autophagic pathway.
Rebek Jr., Julius
studies basic questions of molecular recognition, self-assembly, catalysis, and complementarity by designing novel organic molecular nanocapsules and synthetic receptors.
Stevens, Raymond
uses crystallography and biochemistry to probe the structure and function of molecules involved in neurotransmission and neurochemistry, seeking to understand how neuronal cells communicate at the molecular level and to create new molecules that affect neuronal signal transduction and recognition.
Williamson, Jamie
studies the structure and dynamics of RNA molecules and RNA-protein complexes involved in the regulation of gene expression by employing NMR spectroscopy and X-ray crystallography for solving high-resolution three-dimensional structures and examining the mechanism of assembly of multiprotein-RNA complexes.
Wong, Chi-Huey
directs his research towards the development of new chemical-enzymatic strategies for the synthesis of biologically active compounds and chiral intermediates; the design and synthesis of mechanism-based inhibitors of enzymes or receptors; the study of carbohydrate-based biological recognition and its intervention; and the investigation of reaction mechanisms.
Wright, Peter
uses high-resolution, multi-dimensional, hetero-nuclear magnetic resonance (NMR) spectroscopy to study protein dynamics, folding, and recognition, particularly of structures of protein-DNA and protein-protein complexes involved in the regulation of transcription.
Wuthrich, Kurt
develops advanced techniques in nuclear magnetic resonance (NMR) spectroscopy and applies them in protein structural biology and structural genomics projects.
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