Epistasis arises from shifting the rate-limiting step during enzyme evolution of a β-lactamase
Permanent link
https://hdl.handle.net/10037/35166Date
2024-02-23Type
Journal articleTidsskriftartikkel
Peer reviewed
Author
Frøhlich, Christopher; Bunzel, H. Adrian; Buda, Karol; Mulholland, Adrian J.; van der Kamp, Marc W.; Johnsen, Pål Jarle; Leiros, Hanna-Kirsti S.; Tokuriki, NobuhikoAbstract
Epistasis, the non-additive efect of mutations, can provide combinatorial
improvements to enzyme activity that substantially exceed the gains from
individual mutations. Yet the molecular mechanisms of epistasis remain
elusive, undermining our ability to predict pathogen evolution and engineer
biocatalysts. Here we reveal how directed evolution of a β-lactamase yielded
highly epistatic activity enhancements. Evolution selected four mutations
that increase antibiotic resistance 40-fold, despite their marginal individual
efects (≤2-fold). Synergistic improvements coincided with the introduction
of super-stochiometric burst kinetics, indicating that epistasis is rooted in
the enzyme’s conformational dynamics. Our analysis reveals that epistasis
stemmed from distinct efects of each mutation on the catalytic cycle. The
initial mutation increased protein fexibility and accelerated substrate
binding, which is rate-limiting in the wild-type enzyme. Subsequent
mutations predominantly boosted the chemical steps by fne-tuning
substrate interactions. Our work identifes an overlooked cause for
epistasis: changing the rate-limiting step can result in substantial synergy
that boosts enzyme activity.
Publisher
Springer NatureCitation
Frøhlich, Bunzel, Buda, Mulholland, van der Kamp, Johnsen, Leiros, Tokuriki. Epistasis arises from shifting the rate-limiting step during enzyme evolution of a β-lactamase. Nature Catalysis. 2024Metadata
Show full item recordCollections
Copyright 2024 The Author(s)