Research Interests
Membrane proteins, Protein structure and function, Proteomics, Transporters
Research Focus Teams
COVID-19, Cancer, Cardiovascular, Addiction, Tuberculosis
Departments
Biochemistry and Molecular Biology
Contact
Email: fduong [at] mail.ubc.ca
Office Phone: 604–822–5975
Office number: 5407
Publications
Lab Website
University of Marseilles, France, 1990, BSc
University of Marseilles, France, 1994, PhD
Dartmouth Medical School, USA, 1998, Postdoctoral Fellow
CNRS-University of Paris-Sud, France, 2004,
Principle Investigator
Solubilization of membrane proteins with the Peptidisc
Membrane proteins represent ~60% of medical drug targets and encompass 1/5th of the human proteome; yet these proteins are vastly under-represented in structure and interaction databases. This discrepancy is due to biochemical and biophysical studies requiring proteins in a water-soluble state, while membrane proteins are naturally sequestered in a hydrophobic lipid environment. In order to render membrane proteins into a soluble state, that is amenable for their study, researchers generally use detergents to extract and purify these proteins. However, these surfactants have many undesired effects on protein structure, function and downstream analysis.
Work from our group and others has focused on developing nanotechnology-based reconstitution systems to try replacing the natural lipid bilayer while maintaining water-solubility. These membrane mimetics, either protein-based scaffolds or synthetic polymers, have been around for a decade, yet their utilities did not reach the expected potential due to the optimization and adaptation required for each membrane protein system. Recently, our laboratory developed a “one-size-fits-all” formulation known as the Peptidisc— the Peptidisc is made by multiple copies of an amphipathic peptide that spontaneously associate around transmembrane domains of proteins upon removal of detergent. The peptide number adapts spontaneously to fit the size and shape of the protein, allowing for minimal reconstitution optimization.
Structural Characterization by CryoEM
By making membrane proteins soluble, and retaining their native state, structural characterization becomes possible. Utilizing cryo-electron microscopy, high-resolution structural data of membrane proteins can be obtained. Our work with cryo-EM focuses on isolating and structurally characterizing novel membrane protein complexes.
Antibody Generation by Animal Immunization
Injection of membrane proteins into animals with detergent causes aggregation and loss of relevant native protein structure for antibody generation. Hence, by using the Peptidisc to stabilize proteins in their native form, we can inject soluble membrane proteins into animals. This results in antibodies that recognize the protein of interest in its native form, upon injection of the complex.
Antibody Generation by Phage Display
Membrane proteins in the Peptidisc allows for the native form of a protein to be presented to a phage display library. Therefore the interactions found will be more useful, as non-native forms of the protein are excluded, and the library sorting can give biologically relevant binders faster.
Downstream Binding Characterization
As membrane proteins constitute a disproportionate fraction of drug targets, the characterization of drug interactions with target protein is very important. Because the Peptidisc holds membrane proteins in its native, functional state, the binding characteristics of substrates, as well as drugs, of the target protein can be assessed. This allows for effective and reliable Kd calculations, on and off rates, binding sites, and protein stability.