Evaluation and ranking of enzyme designs

TitleEvaluation and ranking of enzyme designs
Publication TypeJournal Article
Year of Publication2010
AuthorsKiss, G., Röthlisberger D., Baker D., & Houk K. N.
JournalProtein science
Volume19
Issue9
Pagination1760-73
Date Published2010 Sep
ISSN1469-896X
KeywordsCollaborative Publication
Abstract

In 2008, a successful computational design procedure was reported that yielded active enzyme catalysts for the Kemp elimination. Here, we studied these proteins together with a set of previously unpublished inactive designs to determine the sources of activity or lack thereof, and to predict which of the designed structures are most likely to be catalytic. Methods that range from quantum mechanics (QM) on truncated model systems to the treatment of the full protein with ONIOM QM/MM and AMBER molecular dynamics (MD) were explored. The most effective procedure involved molecular dynamics, and a general MD protocol was established. Substantial deviations from the ideal catalytic geometries were observed for a number of designs. Penetration of water into the catalytic site and insufficient residue-packing around the active site are the main factors that can cause enzyme designs to be inactive. Where in the past, computational evaluations of designed enzymes were too time-extensive for practical considerations, it has now become feasible to rank and refine candidates computationally prior to and in conjunction with experimentation, thus markedly increasing the efficiency of the enzyme design process.

DOI10.1002/pro.462
Alternate JournalProtein Sci.
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