Hydrolysis of the Urethane Bond Catalyzed by Pseudomonas sp. MIS38 Lipase: A QM/MM Mechanistic Insight

Luís M.C. Teixeira; Pedro Paiva; Martin B. Johansen; Andreas Sommerfeldt; Allan R. Petersen; Laura Rotilio; Alexander Sandahl; J. Preben Morth; Peter Westh; Daniel E. Otzen; Pedro A. Fernandes; Maria J. Ramos

doi:10.1021/acscatal.5c03228

Hydrolysis of the Urethane Bond Catalyzed by Pseudomonas sp. MIS38 Lipase: A QM/MM Mechanistic Insight

Luís M.C. Teixeira
, Pedro Paiva
, Martin B. Johansen
, Andreas Sommerfeldt
, Allan R. Petersen
, Laura Rotilio
, Alexander Sandahl
, J. Preben Morth
, Peter Westh
, Daniel E. Otzen
, Pedro A. Fernandes
, Maria J. Ramos^*

^*Corresponding author for this work

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

1 Citation (Scopus)

Abstract

Plastic accumulation has become a major global concern due to the lack of efficient and environmentally friendly strategies to manage the end-of-life of these materials. Among the most used families of plastics is polyurethane (PU), which is valued for its versatility and low production cost. A promising strategy to address the end-of-life challenges of PU is employing efficient PU-degrading enzymes. Notably, an extracellular lipase from the I.3 family originating from Pseudomonas sp. MIS38 has shown significant promise in this regard. In this study, we investigated the enzyme’s capability to hydrolyze a PU fragment. Employing QM/MM computational methodologies, we studied the hydrolysis mechanism of MIS38 lipase and found it to follow the prototypical serine esterase mechanism involving acylation and deacylation stages. The rate-limiting step occurred between the formation of the acyl-enzyme intermediate and the formation of the second tetrahedral intermediate. The Gibbs activation barrier for this step was 19.67 kcal·mol^–1, confirming the lipase’s potential to biodegrade PU efficiently. More importantly, we observed that the enzyme preferentially cleaved the C–N bond instead of the C–O bond. This preference was due to the arrangement of the active site and the substrate, which made C–N the more favorable cleavable site. Furthermore, we find that the C–O group is not a suitable cleavable bond due to steric hindrances. This study suggests that the mechanism of urethane bond hydrolysis is more complex than currently assumed because bond cleavage is context-dependent and may differ depending on the enzyme and the substrate.

Original language	English
Journal	ACS Catalysis
Volume	15
Pages (from-to)	14728-14740
Number of pages	13
ISSN	2155-5435
DOIs	https://doi.org/10.1021/acscatal.5c03228
Publication status	Published - 2025

Keywords

catalysis
enzyme
hydrolase
lipase
plastic
polyurethane
PURase
QM/MM

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@article{1caf422c067d4eb2bf816376fe0adddc,

title = "Hydrolysis of the Urethane Bond Catalyzed by Pseudomonas sp. MIS38 Lipase: A QM/MM Mechanistic Insight",

abstract = "Plastic accumulation has become a major global concern due to the lack of efficient and environmentally friendly strategies to manage the end-of-life of these materials. Among the most used families of plastics is polyurethane (PU), which is valued for its versatility and low production cost. A promising strategy to address the end-of-life challenges of PU is employing efficient PU-degrading enzymes. Notably, an extracellular lipase from the I.3 family originating from Pseudomonas sp. MIS38 has shown significant promise in this regard. In this study, we investigated the enzyme{\textquoteright}s capability to hydrolyze a PU fragment. Employing QM/MM computational methodologies, we studied the hydrolysis mechanism of MIS38 lipase and found it to follow the prototypical serine esterase mechanism involving acylation and deacylation stages. The rate-limiting step occurred between the formation of the acyl-enzyme intermediate and the formation of the second tetrahedral intermediate. The Gibbs activation barrier for this step was 19.67 kcal·mol–1, confirming the lipase{\textquoteright}s potential to biodegrade PU efficiently. More importantly, we observed that the enzyme preferentially cleaved the C–N bond instead of the C–O bond. This preference was due to the arrangement of the active site and the substrate, which made C–N the more favorable cleavable site. Furthermore, we find that the C–O group is not a suitable cleavable bond due to steric hindrances. This study suggests that the mechanism of urethane bond hydrolysis is more complex than currently assumed because bond cleavage is context-dependent and may differ depending on the enzyme and the substrate.",

keywords = "catalysis, enzyme, hydrolase, lipase, plastic, polyurethane, PURase, QM/MM",

author = "Teixeira, \{Lu{\'i}s M.C.\} and Pedro Paiva and Johansen, \{Martin B.\} and Andreas Sommerfeldt and Petersen, \{Allan R.\} and Laura Rotilio and Alexander Sandahl and Morth, \{J. Preben\} and Peter Westh and Otzen, \{Daniel E.\} and Fernandes, \{Pedro A.\} and Ramos, \{Maria J.\}",

note = "Publisher Copyright: {\textcopyright} 2025 American Chemical Society",

year = "2025",

doi = "10.1021/acscatal.5c03228",

language = "English",

volume = "15",

pages = "14728--14740",

journal = "ACS Catalysis",

issn = "2155-5435",

publisher = "American Chemical Society",

}

TY - JOUR

T1 - Hydrolysis of the Urethane Bond Catalyzed by Pseudomonas sp. MIS38 Lipase

T2 - A QM/MM Mechanistic Insight

AU - Teixeira, Luís M.C.

AU - Paiva, Pedro

AU - Johansen, Martin B.

AU - Sommerfeldt, Andreas

AU - Petersen, Allan R.

AU - Rotilio, Laura

AU - Sandahl, Alexander

AU - Morth, J. Preben

AU - Westh, Peter

AU - Otzen, Daniel E.

AU - Fernandes, Pedro A.

AU - Ramos, Maria J.

PY - 2025

Y1 - 2025

N2 - Plastic accumulation has become a major global concern due to the lack of efficient and environmentally friendly strategies to manage the end-of-life of these materials. Among the most used families of plastics is polyurethane (PU), which is valued for its versatility and low production cost. A promising strategy to address the end-of-life challenges of PU is employing efficient PU-degrading enzymes. Notably, an extracellular lipase from the I.3 family originating from Pseudomonas sp. MIS38 has shown significant promise in this regard. In this study, we investigated the enzyme’s capability to hydrolyze a PU fragment. Employing QM/MM computational methodologies, we studied the hydrolysis mechanism of MIS38 lipase and found it to follow the prototypical serine esterase mechanism involving acylation and deacylation stages. The rate-limiting step occurred between the formation of the acyl-enzyme intermediate and the formation of the second tetrahedral intermediate. The Gibbs activation barrier for this step was 19.67 kcal·mol–1, confirming the lipase’s potential to biodegrade PU efficiently. More importantly, we observed that the enzyme preferentially cleaved the C–N bond instead of the C–O bond. This preference was due to the arrangement of the active site and the substrate, which made C–N the more favorable cleavable site. Furthermore, we find that the C–O group is not a suitable cleavable bond due to steric hindrances. This study suggests that the mechanism of urethane bond hydrolysis is more complex than currently assumed because bond cleavage is context-dependent and may differ depending on the enzyme and the substrate.

AB - Plastic accumulation has become a major global concern due to the lack of efficient and environmentally friendly strategies to manage the end-of-life of these materials. Among the most used families of plastics is polyurethane (PU), which is valued for its versatility and low production cost. A promising strategy to address the end-of-life challenges of PU is employing efficient PU-degrading enzymes. Notably, an extracellular lipase from the I.3 family originating from Pseudomonas sp. MIS38 has shown significant promise in this regard. In this study, we investigated the enzyme’s capability to hydrolyze a PU fragment. Employing QM/MM computational methodologies, we studied the hydrolysis mechanism of MIS38 lipase and found it to follow the prototypical serine esterase mechanism involving acylation and deacylation stages. The rate-limiting step occurred between the formation of the acyl-enzyme intermediate and the formation of the second tetrahedral intermediate. The Gibbs activation barrier for this step was 19.67 kcal·mol–1, confirming the lipase’s potential to biodegrade PU efficiently. More importantly, we observed that the enzyme preferentially cleaved the C–N bond instead of the C–O bond. This preference was due to the arrangement of the active site and the substrate, which made C–N the more favorable cleavable site. Furthermore, we find that the C–O group is not a suitable cleavable bond due to steric hindrances. This study suggests that the mechanism of urethane bond hydrolysis is more complex than currently assumed because bond cleavage is context-dependent and may differ depending on the enzyme and the substrate.

KW - catalysis

KW - enzyme

KW - hydrolase

KW - lipase

KW - plastic

KW - polyurethane

KW - PURase

KW - QM/MM

UR - https://www.scopus.com/pages/publications/105013485495

U2 - 10.1021/acscatal.5c03228

DO - 10.1021/acscatal.5c03228

M3 - Journal article

AN - SCOPUS:105013485495

SN - 2155-5435

VL - 15

SP - 14728

EP - 14740

JO - ACS Catalysis

JF - ACS Catalysis

ER -

Hydrolysis of the Urethane Bond Catalyzed by Pseudomonas sp. MIS38 Lipase: A QM/MM Mechanistic Insight

Abstract

Keywords

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