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Niels Andersen, Professor
Chemistry
(206) 543-7099
andersen@chem.washington.edu
Faculty Website

Research Interests

Research in the Andersen group focuses on both the fundamental thermodynamics and structural features associated with biorecognition phenomena and practical applications in drug and protein design. The primary biophysical tools employed are spectroscopic: NMR determinations of polypeptide structure and dynamics, IR- and fluorescence-monitored T-jump kinetics for folding pathways, CD studies of the melting of secondary and tertiary structure. Drug design efforts are supported by NMR structural data for protein hormones and enzymes for key steps required for the viability of bacteria. Active programs in mutant protein over-expression, peptide synthesis, and combinatorial synthesis of small molecule inhibitor libraries support this effort. Illustrative projects are briefly outlined in the following paragraphs.

The earliest stages of protein folding are studied using a priori designed helices and beta hairpins with specific labeling patterns that allow the definition of the thermodynamics, kinetics, and pathways of structuring using NMR and T-jump methods. These studies have already determined the time scales of helix (200 ns) and hairpin (4 – 10 µs) formation and have established that helix formation, but not sheet formation, occurs too rapidly to contribute during the rapid hydrophobic collapse phase of protein folding. The mechanistic details of secondary structure formation are currently being addressed.

‘Minimalist’ proteins (< 25 residues) that display the diagnostic folding features of much larger native proteins are being designed. These systems should provide an atom-level understanding of the factors that yield stable protein folds and are small enough to allow for computational simulations that can be experimentally tested. To date, fully cooperative folding driven by the hydrophobic effect has been realized with systems as small as 18 residues and fully folded systems with protected amide and hydroxyl protons as small as 8 residues have been designed.

The minimalist protein constructs also provide scaffolds for pharmacophore display for drug discovery. They have significant advantages over random peptide libraries in that the three dimensional display of the binding moieties is certain due to the defined fold. Recent studies have established that designed hairpin bearing aromatic sidechains can inhibit amyloid fibril formation, a key step in many “protein folding diseases”

Potent, selective inhibitors of the LpxC enzyme of Pseudomonas aeruginosa (and other gram negative pathogens) are viewed as a potential medicinals for treating resistant hospital acquired infections and the common infections in the lungs of cystic fibrosis patients. Very potent lead compounds have been prepared using combi-synthesis libraries with design optimization based on bioassays and fluorine NMR assays of the relative affinities of leads to the native enzyme.

 

   

© UW Biological Physics, Structure and Design 2013