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Computational Evidence for a Water-Assisted Proton-Transfer Mechanism in Uronate Isomerase from Bacillus Halodurans (Bh0493)

Jitonnom, Wijitra ; Oláh, Julianna ; Ryde, Ulf LU orcid and Jitonnom, Jitrayut (2025) In The journal of physical chemistry. B 129(49). p.12675-12684
Abstract

Uronate isomerase (EC 5.3.1.12; URI) catalyzes uronate sugar interconversion, a key step in bacterial metabolism, yet its reaction mechanism remains poorly understood. This study delineates the detailed mechanism for the isomerization of d-glucuronate to d-fructuronate catalyzed by a Zn2+-dependent URI enzyme (from Bacillus halodurans). Using quantum mechanical (QM) cluster calculations, three mechanistic pathways were evaluated, all involving Asp355 as the catalytic base but differing in the proton-shuttle mechanism. The most favorable mechanism features C5 deprotonation of the substrate, followed by a water-mediated 1,2-proton transfer via a stabilized cis-enediol intermediate, with the C2-C5 intramolecular transfer as the... (More)

Uronate isomerase (EC 5.3.1.12; URI) catalyzes uronate sugar interconversion, a key step in bacterial metabolism, yet its reaction mechanism remains poorly understood. This study delineates the detailed mechanism for the isomerization of d-glucuronate to d-fructuronate catalyzed by a Zn2+-dependent URI enzyme (from Bacillus halodurans). Using quantum mechanical (QM) cluster calculations, three mechanistic pathways were evaluated, all involving Asp355 as the catalytic base but differing in the proton-shuttle mechanism. The most favorable mechanism features C5 deprotonation of the substrate, followed by a water-mediated 1,2-proton transfer via a stabilized cis-enediol intermediate, with the C2-C5 intramolecular transfer as the rate-determining step. The calculated activation barrier (17.3 kcal mol- 1) aligns well with experimental data. Alternative pathways involving Tyr50 or a Tyr48-water relay were found to be less favorable due to higher net barriers (26-36 kcal mol- 1). A comparative analysis of d-glucuronate and d-galacturonate revealed that although both proceed through similar steps, d-glucuronate has ∼2 kcal mol- 1 lower overall barrier due to enhanced stabilization of late-stage intermediates. These findings clarify the roles of solvent and active-site residues in URI catalysis and contribute to a broader understanding of proton-transfer mechanisms in Zn2+-dependent enzymes across the amidohydrolase superfamily.

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author
; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
in
The journal of physical chemistry. B
volume
129
issue
49
pages
10 pages
publisher
The American Chemical Society (ACS)
external identifiers
  • pmid:41327824
  • scopus:105024729808
ISSN
1520-5207
DOI
10.1021/acs.jpcb.5c06862
language
English
LU publication?
yes
id
c4fc4adf-a362-4efb-b36f-576f176fdc28
date added to LUP
2026-02-11 15:31:29
date last changed
2026-02-12 03:02:16
@article{c4fc4adf-a362-4efb-b36f-576f176fdc28,
  abstract     = {{<p>Uronate isomerase (EC 5.3.1.12; URI) catalyzes uronate sugar interconversion, a key step in bacterial metabolism, yet its reaction mechanism remains poorly understood. This study delineates the detailed mechanism for the isomerization of d-glucuronate to d-fructuronate catalyzed by a Zn2+-dependent URI enzyme (from Bacillus halodurans). Using quantum mechanical (QM) cluster calculations, three mechanistic pathways were evaluated, all involving Asp355 as the catalytic base but differing in the proton-shuttle mechanism. The most favorable mechanism features C5 deprotonation of the substrate, followed by a water-mediated 1,2-proton transfer via a stabilized cis-enediol intermediate, with the C2-C5 intramolecular transfer as the rate-determining step. The calculated activation barrier (17.3 kcal mol- 1) aligns well with experimental data. Alternative pathways involving Tyr50 or a Tyr48-water relay were found to be less favorable due to higher net barriers (26-36 kcal mol- 1). A comparative analysis of d-glucuronate and d-galacturonate revealed that although both proceed through similar steps, d-glucuronate has ∼2 kcal mol- 1 lower overall barrier due to enhanced stabilization of late-stage intermediates. These findings clarify the roles of solvent and active-site residues in URI catalysis and contribute to a broader understanding of proton-transfer mechanisms in Zn2+-dependent enzymes across the amidohydrolase superfamily.</p>}},
  author       = {{Jitonnom, Wijitra and Oláh, Julianna and Ryde, Ulf and Jitonnom, Jitrayut}},
  issn         = {{1520-5207}},
  language     = {{eng}},
  month        = {{12}},
  number       = {{49}},
  pages        = {{12675--12684}},
  publisher    = {{The American Chemical Society (ACS)}},
  series       = {{The journal of physical chemistry. B}},
  title        = {{Computational Evidence for a Water-Assisted Proton-Transfer Mechanism in Uronate Isomerase from Bacillus Halodurans (Bh0493)}},
  url          = {{http://dx.doi.org/10.1021/acs.jpcb.5c06862}},
  doi          = {{10.1021/acs.jpcb.5c06862}},
  volume       = {{129}},
  year         = {{2025}},
}