FireProt: Energy- and Evolution-Based Computational Design of Thermostable Multiple-Point Mutants.
2015
There is great interest in increasing proteins’ stability to
enhance their utility as biocatalysts, therapeutics,
diagnostics and nanomaterials. Directed evolution is a
powerful, but experimentally strenuous approach. Computational
methods offer attractive alternatives. However, due to the
limited reliability of predictions and potentially antagonistic
effects of substitutions, only single-point mutations are
usually predicted in silico, experimentally verified and then
recombined in multiple-point mutants. Thus, substantial
screening is still required. Here we present FireProt, a robust
computational strategy for predicting highly stable
multiple-point mutants that combines energy- and
evolution-based approaches with smart filtering to identify
additive stabilizing mutations. FireProt’s reliability and
applicability was demonstrated by validating its predictions
against 656 mutations from the ProTherm database. We
demonstrate that thermostability of the model enzymes
haloalkane dehalogenase DhaA and gama-hexachlorocyclohexane
dehydrochlorinase LinA can be substantially increased (Tm =
24°C and 21°C) by constructing and characterizing only a
handful of multiple-point mutants. FireProt can be applied to
any protein for which a tertiary structure and homologous
sequences are available, and will facilitate the rapid
development of robust proteins for biomedical and
biotechnological applications.
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