Abstract
Computational design of new active sites has generally proceeded by geometrically defining interactions between the reaction transition state(s) and surrounding side‐chain functional groups which maximize transition‐state stabilization, and then searching for sites in protein scaffolds where the specified side‐chain–transition‐state interactions can be realized. A limitation of this approach is that the interactions between the side chains themselves are not constrained. An extensive connected hydrogen bond network involving the catalytic residues was observed in a designed retroaldolase following directed evolution. Such connected networks could increase catalytic activity by preorganizing active site residues in catalytically competent orientations, and enabling concerted interactions between side chains during catalysis, for example, proton shuffling. We developed a method for designing active sites in which the catalytic side chains, in addition to making interactions with the transition state, are also involved in extensive hydrogen bond networks. Because of the added constraint of hydrogen‐bond connectivity between the catalytic side chains, to find solutions, a wider range of interactions between these side chains and the transition state must be considered. Our new method starts from a ChemDraw‐like two‐dimensional representation of the transition state with hydrogen‐bond donors, acceptors, and covalent interaction sites indicated, and all placements of side‐chain functional groups that make the indicated interactions with the transition state, and are fully connected in a single hydrogen‐bond network are systematically enumerated. The RosettaMatch method can then be used to identify realizations of these fully‐connected active sites in protein scaffolds. The method generates many fully‐connected active site solutions for a set of model reactions that are promising starting points for the design of fully‐preorganized enzyme catalysts.
Highlights
Computational design of new active sites has generally proceeded by geometrically defining interactions between the reaction transition state(s) and surrounding sidechain functional groups which maximize transition-state stabilization, and searching for sites in protein scaffolds where the specified side-chain–transitionstate interactions can be realized
We developed a method for designing active sites in which the catalytic side chains, in addition to making interactions with the transition state, are involved in extensive hydrogen bond networks
RosettaMatch starts from a geometric description of the optimal interaction geometries between side-chain functional groups and the transition state; to find fully-connected active sites it is necessary to allow a wider range of functional-group–transition-state geometries
Summary
Abstract Computational design of new active sites has generally proceeded by geometrically defining interactions between the reaction transition state(s) and surrounding sidechain functional groups which maximize transition-state stabilization, and searching for sites in protein scaffolds where the specified side-chain–transitionstate interactions can be realized. We developed a method for designing active sites in which the catalytic side chains, in addition to making interactions with the transition state, are involved in extensive hydrogen bond networks.
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