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The mechanism behind the oxidase activity of cellulose-active AA10 lytic polysaccharide monooxygenases

Wieduwilt, Erna K. ; Hagemann, Marlisa M. LU ; Ryde, Ulf LU orcid and Hedegård, Erik D. LU (2025) In Inorganic Chemistry Frontiers 12(18). p.5344-5359
Abstract

Lytic polysaccharide monooxygenases (LPMOs) are copper enzymes that boost the degradation of different polysaccharides and play important roles in the sustainable production of biofuels, in human and plant pathogens, and potentially also in plastic degradation. Their activity depends on a co-substrate, where recent results show that hydrogen peroxide is the preferred co-substrate. Under typical experimental conditions, no hydrogen peroxide is added and it is instead produced in situ by LPMOs themselves, which could be the rate-limiting step. Previous theoretical investigations of the oxidase reaction have been highly inhomogeneous and focused on different aspects of LPMO reactivity. In this paper, we systematically investigate how LPMOs... (More)

Lytic polysaccharide monooxygenases (LPMOs) are copper enzymes that boost the degradation of different polysaccharides and play important roles in the sustainable production of biofuels, in human and plant pathogens, and potentially also in plastic degradation. Their activity depends on a co-substrate, where recent results show that hydrogen peroxide is the preferred co-substrate. Under typical experimental conditions, no hydrogen peroxide is added and it is instead produced in situ by LPMOs themselves, which could be the rate-limiting step. Previous theoretical investigations of the oxidase reaction have been highly inhomogeneous and focused on different aspects of LPMO reactivity. In this paper, we systematically investigate how LPMOs generate hydrogen peroxide using accurate quantum mechanics/molecular mechanics (QM/MM) hybrid methods with extended QM regions. We find that the reaction of the reduced LPMO active site with O2 yields a superoxide coordinated to Cu(ii), from which [Cu(ii)−OOH]+ can be formed via a proton-coupled electron transfer, using a second-coordination-sphere histidine as the proton donor. Either OOH dissociates from this species (while abstracting a proton from a water molecule) or [Cu(ii)−OOH]+ reacts in a second protonation from the second-sphere histidine, yielding [Cu(ii) − H2O2]2+, followed by dissociation of H2O2. Energetically, all three oxygen species can dissociate into solution, but the dissociation of H2O2 from the Cu(ii) active site is the most favorable while the dissociation of O2˙ is least favorable.

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organization
publishing date
type
Contribution to journal
publication status
published
subject
in
Inorganic Chemistry Frontiers
volume
12
issue
18
pages
16 pages
publisher
Royal Society of Chemistry
external identifiers
  • scopus:105004388897
ISSN
2052-1553
DOI
10.1039/d5qi00796h
language
English
LU publication?
yes
id
9f6a6005-b13d-4785-ad16-e0b43300dae1
date added to LUP
2025-09-18 12:43:06
date last changed
2025-09-18 12:43:44
@article{9f6a6005-b13d-4785-ad16-e0b43300dae1,
  abstract     = {{<p>Lytic polysaccharide monooxygenases (LPMOs) are copper enzymes that boost the degradation of different polysaccharides and play important roles in the sustainable production of biofuels, in human and plant pathogens, and potentially also in plastic degradation. Their activity depends on a co-substrate, where recent results show that hydrogen peroxide is the preferred co-substrate. Under typical experimental conditions, no hydrogen peroxide is added and it is instead produced in situ by LPMOs themselves, which could be the rate-limiting step. Previous theoretical investigations of the oxidase reaction have been highly inhomogeneous and focused on different aspects of LPMO reactivity. In this paper, we systematically investigate how LPMOs generate hydrogen peroxide using accurate quantum mechanics/molecular mechanics (QM/MM) hybrid methods with extended QM regions. We find that the reaction of the reduced LPMO active site with O<sub>2</sub> yields a superoxide coordinated to Cu(ii), from which [Cu(ii)−OOH<sup>−</sup>]<sup>+</sup> can be formed via a proton-coupled electron transfer, using a second-coordination-sphere histidine as the proton donor. Either OOH<sup>−</sup> dissociates from this species (while abstracting a proton from a water molecule) or [Cu(ii)−OOH<sup>−</sup>]<sup>+</sup> reacts in a second protonation from the second-sphere histidine, yielding [Cu(ii) − H<sub>2</sub>O<sub>2</sub>]<sup>2+</sup>, followed by dissociation of H<sub>2</sub>O<sub>2</sub>. Energetically, all three oxygen species can dissociate into solution, but the dissociation of H<sub>2</sub>O<sub>2</sub> from the Cu(ii) active site is the most favorable while the dissociation of O<sub>2</sub>˙<sup>−</sup> is least favorable.</p>}},
  author       = {{Wieduwilt, Erna K. and Hagemann, Marlisa M. and Ryde, Ulf and Hedegård, Erik D.}},
  issn         = {{2052-1553}},
  language     = {{eng}},
  number       = {{18}},
  pages        = {{5344--5359}},
  publisher    = {{Royal Society of Chemistry}},
  series       = {{Inorganic Chemistry Frontiers}},
  title        = {{The mechanism behind the oxidase activity of cellulose-active AA10 lytic polysaccharide monooxygenases}},
  url          = {{http://dx.doi.org/10.1039/d5qi00796h}},
  doi          = {{10.1039/d5qi00796h}},
  volume       = {{12}},
  year         = {{2025}},
}