I have recently moved to the National Institutes of Health; please see my new website here:
http://www2.niddk.nih.gov/NIDDKLabs/IntramuralFaculty/BestRobert.htm
My research is concerned with the dynamics of large biomolecules, in particular with protein dynamics, folding and binding. Through the impressive achievements of structural biology, much has been learnt about the function of proteins by solving the structures of their stable states (e.g. active, inactive conformations). Studying the dynamics and mechanism of transitions between these states is still a major challenge for both experiment and simulation, yet is equally important for understanding function. I develop novel methods for studying macromolecular dynamics and apply them to biologically interesting systems, using a combination of simulation and theory appropriate for addressing each question.
For example, we have devised algorithms for enhanced sampling of the “rare events” in simulations, which constitute the reactive portions of the trajectory; by designing good “reaction coordinates”, we are able to describe the progress of the reaction (mechanism) quantitatively. To study larger systems or longer time scales, we are developing coarse-grained models with reduced complexity. We have also devised improvements to all-atom simulation models, towards the goal of more accurately simulating protein folding and the mechanism of coupled folding and binding. We work closely with experimental collaborators, either by using theory to help in interpreting experiments or experimental data to refine simulation methodology. We have used coarse-grained models to help interpret single molecule protein folding experiments based on fluorescence resonance energy transfer or atomic force microscopy and all-atom models to interpret NMR dynamics experiments.
Selected Publications
Force mode atomic force microscopy as a tool for protein folding studies
RB Best, DJ Brockwell, JL Toca-Herrera, AW Blake, DA Smith, SE Radford, J Clarke - Analytica Chimica Acta (
2003)
479, 87
(DOI:
10.1016/S0003-2670(02)01572-6)
Combining protein engineering and dynamic force microscopy to examine protein folding landscapes
J Clarke, RB Best, SF Fowler, A Steward, JL Toca-Herrera, PM Williams, KS Martin, E Paci - BIOPHYSICAL JOURNAL (2003) 84, 308A
Mechanical unfolding of a titin Ig domain: Structure of unfolding intermediate revealed by combining AFM, molecular dynamics simulations, NMR and protein engineering
SB Fowler, RB Best, JLT Herrera, TJ Rutherford, A Steward, E Paci, M Karplus, J Clarke - Journal of Molecular Biology (
2002)
322, 841
(DOI:
10.1016/S0022-2836(02)00805-7)
A simple method for probing the mechanical unfolding pathway of proteins in detail
RB Best, SB Fowler, JL Toca-Herrera, J Clarke - Proceedings of the National Academy of Sciences (
2002)
99, 12143
(DOI:
10.1073/pnas.192351899)
What can atomic force microscopy tell us about protein folding?
RB Best, J Clarke - Chemical Communications (
2002), 183
(DOI:
10.1039/b108159b)
What can atomic force microscopy tell us about protein folding?
RB Best, J Clarke - Chemical communications (Cambridge, England) (2002), 183
Can non-mechanical proteins withstand force? Stretching barnase by atomic force microscopy and molecular dynamics simulation
RB Best, B Li, A Steward, V Daggett, J Clarke - Biophysical Journal (
2001)
81, 2344
(DOI:
10.1016/S0006-3495(01)75881-X)
Extending AFM to globular proteins: A general method for constructing multidomain repeats applied to proteins without any structural function.
RB Best, A Steward, S Fowler, J Clarke - ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY (2001) 221, U345
Funding
Further Funding Information
