Dissecting the Mechanism of (R)‑3-Hydroxybutyrate
Dehydrogenase by Kinetic Isotope Effects, Protein Crystallography,
and Computational Chemistry
Posted on 2020-12-07 - 13:35
The enzyme (R)-3-hydroxybutyrate
dehydrogenase
(HBDH) catalyzes the enantioselective reduction of 3-oxocarboxylates
to (R)-3-hydroxycarboxylates, the monomeric precursors
of biodegradable polyesters. Despite its application in asymmetric
reduction, which prompted several engineering attempts of this enzyme,
the order of chemical events in the active site, their contributions
to limit the reaction rate, and interactions between the enzyme and
non-native 3-oxocarboxylates have not been explored. Here, a combination
of kinetic isotope effects, protein crystallography, and quantum mechanics/molecular
mechanics (QM/MM) calculations were employed to dissect the HBDH mechanism.
Initial velocity patterns and primary deuterium kinetic isotope effects
establish a steady-state ordered kinetic mechanism for acetoacetate
reduction by a psychrophilic and a mesophilic HBDH, where hydride
transfer is not rate limiting. Primary deuterium kinetic isotope effects
on the reduction of 3-oxovalerate indicate that hydride transfer becomes
more rate limiting with this non-native substrate. Solvent and multiple
deuterium kinetic isotope effects suggest hydride and proton transfers
occur in the same transition state. Crystal structures were solved
for both enzymes complexed to NAD+:acetoacetate and NAD+:3-oxovalerate, illustrating the structural basis for the
stereochemistry of the 3-hydroxycarboxylate products. QM/MM calculations
using the crystal structures
as a starting point predicted a higher activation energy for 3-oxovalerate
reduction catalyzed by the mesophilic HBDH, in agreement with the
higher reaction rate observed experimentally for the psychrophilic
orthologue. Both transition states show concerted, albeit not synchronous,
proton and hydride transfers to 3-oxovalerate. Setting the MM partial
charges to zero results in identical reaction activation energies
with both orthologues, suggesting the difference in activation energy
between the reactions catalyzed by cold- and warm-adapted HBDHs arises
from differential electrostatic stabilization of the transition state.
Mutagenesis and phylogenetic analysis reveal the catalytic importance
of His150 and Asn145 in the respective orthologues.
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Machado, Teresa
F. G.; Purg, Miha; McMahon, Stephen A.; Read, Benjamin J.; Oehler, Verena; Åqvist, Johan; et al. (2020). Dissecting the Mechanism of (R)‑3-Hydroxybutyrate
Dehydrogenase by Kinetic Isotope Effects, Protein Crystallography,
and Computational Chemistry. ACS Publications. Collection. https://doi.org/10.1021/acscatal.0c04736