 Terrence G. OasAssociate Professor of Biochemistry and ChemistryProtein folding; structure-function relationships of proteins; multidimensional NMR structure determination of macromolecules. Contact InformationOffice Number: (919) 684-4363 Fax: (919) 681-8862 e-mail oas@duke.edu Lab Location Room 230 Nanaline Duke Mailing Address Department of Biochemistry 230C Nanaline Duke Building Box 3711, DUMC Durham, NC 27710 Education
Research InterestsOur laboratory is primarily interested in the mechanisms of protein folding. We use nuclear magnetic resonance (NMR) and other types of spectroscopy to study the solution structure, stability and folding reactions of small protein models. In the past few years, our work has primarily focused on a monomeric form of the DNA-binding protein, λ repressor. This protein (λ6-85) is a stable, native protein that folds in a two-state fashion, i.e. only two states, fully denatured or fully native are populated under all conditions. Using a dynamic NMR method, we have shown that λ6-85 folds in less than 300 msec and a hyperstable mutant form (G46A,G48A) folds in 15 msec under physiological conditions. Both the wild type and mutant forms unfold very rapidly with a native state lifetime of only 30 milliseconds. Thus, under physiological conditions, the N-terminal domain samples the unfolded state 30 times per second. Clearly, for this protein and a growing number of other rapidly folding and unfolding proteins, folding is more than a once-in-a-lifetime process, it happens millions of times during the lifetime of the protein in the cell. We have developed a quantitative and predictive model for the folding mechanism of λ6-85 based on diffusion-collision theory. This model correctly predicts the folding rates of several λ6-85 variants that we have characterized experimentally and we are in the process of testing and refining the model with other variants. The mechanism of λ6-85 folding envisioned by the model involves a large ensemble of pathways by which the five native helices form transiently, diffuse and collide to form native inter-helical contacts. We are also interested in the dynamic properties of native proteins in solution. We study the motions of proteins over the picosecond to millisecond time scale using a variety of NMR-based experiments including 15N relaxation studies, amide hydrogen exchange rates and dynamic NMR. With these results we hope to gain a better understanding of the dynamic behavior of proteins in solution and the role of these dynamics in function. Most recently, we have begun to characterize the folding of the protein subunit of Bacillus subtilis Ribonuclease P, are ribonulceoprotein that catalyzes the cleavage of precursor tRNAs to their mature form. Purified B. subtilis P protein is unfolded under physiological conditions but can be refolded by the addition of small molecule ligands at micromolar concentrations. This tightly coupled folding and binding may play an important role in the assembly of the protein-RNA complex that forms the active RNase P holoenzyme. We are in the process of characterizing the ligand selectivity, binding affinities and energetics and kinetics of P protein binding and folding. Selected Publications1. G.G. Hammes, Y.C. Chang, T.G. Oas (2009). Conformational Selection or Induced Fit: A Flux Description of Reaction Mechanism. Proc Natl Acad Sci 106, 13737-41. More… 2. S.C. Schmidler, J.E. Lucas, T.G. Oas (2007). Statistical estimation of statistical mechanical models: helix-coil theory and peptide helicity prediction. J Comput Biol 14, 1287-310. More… 3. C.H. Henkels, Y.C. Chang, S.I. Chamberlin, T.G. Oas (2007). Dynamics of backbone conformational heterogeneity in Bacillus subtilis ribonuclease P protein. Biochemistry 46, 15062-75. More… 4. P. Chugha, T.G. Oas (2007). Backbone dynamics of the monomeric λ repressor denatured state ensemble under nondenaturing conditions. Biochemistry 46, 1141-51. More… 5. A. Valiaev, D.W. Lim, T.G. Oas, A. Chilkoti, S. Zauscher (2007). Force-induced prolyl cis-trans isomerization in elastin-like polypeptides. J Am Chem Soc, 129, 6491-7. More… 6. K.N. Nobles, Z. Guan, K. Xiao, T.G. Oas, R.J. Lefkowitz (2007). The active conformation of beta -arrestin1: Direct evidence for the phosphate sensor in the N-domain and conformational differences in the active states of beta -arrestins1 and 2. J Biol Chem 282, 21370-81. More… 7. P. Arora, G.G. Hammes, T.G. Oas (2006). Folding mechanism of a multiple independently folding domain protein: Double B domain of protein A. Biochemistry 45, 12312-12324. More… 8. C.H. Henkels, T.G. Oas (2006). Ligation-state hydrogen exchange: Coupled binding and folding equilibria in ribonuclease P protein. J Am Chem Soc 128, 7772-81. More… 9. P. Chugha, H.J. Sage, T.G. Oas (2006). Methionine oxidation of monomeric λ repressor: The denatured state ensemble under nondenaturing conditions. Protein Sci 15, 533-42. More… 10. V.J. Hilser, B. García-Moreno E., T.G. Oas, G. Kapp and S.T. Whitten (2005). A statistical thermodynamic model of the protein ensemble. Chemical Rev., 106, 1545-58. More… 11. S. Ghaemmaghami and T.G. Oas (2001). Quantitative protein stability measurement in vivo. Nature Struct. Biol. 8: 879-82. More… 12. S. Ghaemmaghami, M.C. Fitzgerald and T.G. Oas (2000) A quantitative, high-throughput screen for protein stability, Proc. Nat. Acad. Sci., 97, 8296-8301. More… 13. R.E. Burton, J.K. Myers and T.G. Oas (1998). Protein folding dynamics: Quantitative comparison between theory and experiment. Biochemistry37: 5337-5343. More… 14. R.E. Burton, G.S. Huang, M.A. Daugherty, T.L. Calderone, and T.G. Oas (1997). The energy landscape of a fast-folding protein mapped by Ala-Gly substitutions. Nature Structural Biology 4, 305-310 More… 15. G.S. Huang and T.G. Oas (1995). Sub-millisecond folding of monomeric l repressor. Proc. Nat. Acad. Sci., 92, 6878-6882. More… |
|
