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Shuffling Active Site Substate Populations Affects Catalytic Activity : The Case of Glucose Oxidase

Petrović, Dušan ; Frank, David ; Kamerlin, Shina Caroline Lynn LU orcid ; Hoffmann, Kurt and Strodel, Birgit (2017) In ACS Catalysis 7(9). p.6188-6197
Abstract

Glucose oxidase has wide applications in the pharmaceutical, chemical, and food industries. Many recent studies have enhanced key properties of this enzyme using directed evolution, yet without being able to reveal why these mutations are actually beneficial. This work presents a synergistic combination of experimental and computational methods, indicating how mutations, even when distant from the active site, positively affect glucose oxidase catalysis. We have determined the crystal structures of glucose oxidase mutants containing molecular oxygen in the active site. The catalytically important His516 residue has been previously shown to be flexible in the wild-type enzyme. The molecular dynamics simulations performed in this work... (More)

Glucose oxidase has wide applications in the pharmaceutical, chemical, and food industries. Many recent studies have enhanced key properties of this enzyme using directed evolution, yet without being able to reveal why these mutations are actually beneficial. This work presents a synergistic combination of experimental and computational methods, indicating how mutations, even when distant from the active site, positively affect glucose oxidase catalysis. We have determined the crystal structures of glucose oxidase mutants containing molecular oxygen in the active site. The catalytically important His516 residue has been previously shown to be flexible in the wild-type enzyme. The molecular dynamics simulations performed in this work allow us to quantify this floppiness, revealing that His516 exists in two states: catalytic and noncatalytic. The relative populations of these two substates are almost identical in the wild-type enzyme, with His516 readily shuffling between them. In the glucose oxidase mutants, on the other hand, the mutations enrich the catalytic His516 conformation and reduce the flexibility of this residue, leading to an enhancement in their catalytic efficiency. This study stresses the benefit of active site preorganization with respect to enzyme conversion rates by reducing molecular reorientation needs. We further suggest that the computational approach based on Hamiltonian replica exchange molecular dynamics, used in this study, may be a general approach to screening in silico for improved enzyme variants involving flexible catalytic residues.

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author
; ; ; and
publishing date
type
Contribution to journal
publication status
published
in
ACS Catalysis
volume
7
issue
9
pages
10 pages
publisher
The American Chemical Society (ACS)
external identifiers
  • scopus:85029103375
  • pmid:29291138
ISSN
2155-5435
DOI
10.1021/acscatal.7b01575
language
English
LU publication?
no
id
3ef657d0-96bf-49f8-8161-8e411ffde05e
date added to LUP
2025-01-11 21:19:23
date last changed
2025-06-16 04:39:38
@article{3ef657d0-96bf-49f8-8161-8e411ffde05e,
  abstract     = {{<p>Glucose oxidase has wide applications in the pharmaceutical, chemical, and food industries. Many recent studies have enhanced key properties of this enzyme using directed evolution, yet without being able to reveal why these mutations are actually beneficial. This work presents a synergistic combination of experimental and computational methods, indicating how mutations, even when distant from the active site, positively affect glucose oxidase catalysis. We have determined the crystal structures of glucose oxidase mutants containing molecular oxygen in the active site. The catalytically important His516 residue has been previously shown to be flexible in the wild-type enzyme. The molecular dynamics simulations performed in this work allow us to quantify this floppiness, revealing that His516 exists in two states: catalytic and noncatalytic. The relative populations of these two substates are almost identical in the wild-type enzyme, with His516 readily shuffling between them. In the glucose oxidase mutants, on the other hand, the mutations enrich the catalytic His516 conformation and reduce the flexibility of this residue, leading to an enhancement in their catalytic efficiency. This study stresses the benefit of active site preorganization with respect to enzyme conversion rates by reducing molecular reorientation needs. We further suggest that the computational approach based on Hamiltonian replica exchange molecular dynamics, used in this study, may be a general approach to screening in silico for improved enzyme variants involving flexible catalytic residues.</p>}},
  author       = {{Petrović, Dušan and Frank, David and Kamerlin, Shina Caroline Lynn and Hoffmann, Kurt and Strodel, Birgit}},
  issn         = {{2155-5435}},
  language     = {{eng}},
  month        = {{09}},
  number       = {{9}},
  pages        = {{6188--6197}},
  publisher    = {{The American Chemical Society (ACS)}},
  series       = {{ACS Catalysis}},
  title        = {{Shuffling Active Site Substate Populations Affects Catalytic Activity : The Case of Glucose Oxidase}},
  url          = {{http://dx.doi.org/10.1021/acscatal.7b01575}},
  doi          = {{10.1021/acscatal.7b01575}},
  volume       = {{7}},
  year         = {{2017}},
}