Abstract
Proteins are dynamic systems, and understanding dynamics is critical for fully understanding protein function. Therefore, the question of whether laboratory engineering has an impact on protein dynamics is of general interest. Here, we demonstrate that two homologous, naturally evolved enzymes with high degrees of structural and functional conservation also exhibit conserved dynamics. Their similar set of slow timescale dynamics is highly restricted, consistent with evolutionary conservation of a functionally important feature. However, we also show that dynamics of a laboratory-engineered chimeric enzyme obtained by recombination of the two homologs exhibits striking difference on the millisecond timescale, despite function and high-resolution crystal structure (1.05 Å) being conserved. The laboratory-engineered chimera is thus functionally tolerant to modified dynamics on the timescale of catalytic turnover. Tolerance to dynamic variation implies that maintenance of native-like protein dynamics may not be required when engineering functional proteins.
Highlights
Maintenance of native-like protein dynamics may not be required for engineering functional proteins
The question of whetherlaboratory engineering has an impact on proteindynamicsis of generalinterest
Wealso show thatdynamics of a laboratory-engineeredchimeric enzyme obtained by recombination of the twohomologsexhibitsstrikingdifference on the millisecondtimescale, despitefunction and highresolutioncrystal structure (1.05 Å) beingconserved
Summary
To cite this version: Sophie M.C. Gobeil, Christopher M. Maintenance of native-like protein dynamics may not be required for engineering functional proteins. Chemistry and Biology, Elsevier, 2014, 21 (10), pp.1330-1340.
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