Possible mechanisms contributing to oxidative inactivation of activated protein C: molecular dynamics study

Activated protein C (APC) is a serine protease, an effector enzyme of the natural anticoagulant pathway. APC is approved for treatment of severe sepsis characterized by the increased concentrations of H(2)O(2) and hypochlorite. We found that treatment of APC with these oxidants markedly inhibits the...

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Bibliographic Details
Published inThrombosis and haemostasis Vol. 100; no. 1; p. 18
Main Authors Nalian, Armen, Iakhiaev, Alexei V
Format Journal Article
LanguageEnglish
Published Germany 01.07.2008
Subjects
Allosteric Regulation
Aspartic Acid - chemistry
Binding Sites
Computer Simulation
Cyanogen Bromide - chemistry
Enzyme Activation
Enzyme Stability
Histidine - chemistry
Humans
Hydrogen Bonding
Hydrogen Peroxide - chemistry
Hydrogen Peroxide - metabolism
Hypochlorous Acid - chemistry
Hypochlorous Acid - metabolism
Methionine - chemistry
Models, Molecular
Oxidants - chemistry
Oxidants - metabolism
Oxidation-Reduction
Protein Binding
Protein C - chemistry
Protein C - metabolism
Protein Conformation
Recombinant Proteins - chemistry
Recombinant Proteins - metabolism
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Summary:Activated protein C (APC) is a serine protease, an effector enzyme of the natural anticoagulant pathway. APC is approved for treatment of severe sepsis characterized by the increased concentrations of H(2)O(2) and hypochlorite. We found that treatment of APC with these oxidants markedly inhibits the cleavage of the APC-specific chromogenic substrate, suggesting that oxidants can induce changes in the structure of the active site of APC. Resistance of oxidant-treated APC to chemical digestion with cyanogen bromide (CNBr) implies that methionine oxidation can at least in part be responsible for inhibition of APC. Since methionine residues, the main targets of oxidants in APC, are not included in the active site, we hypothesize that oxidation induces allosteric changes in the architecture of the catalytic triad of APC. Using molecular dynamics (MD) simulations we found that methionine oxidation alters the distance between cSer195Ogamma and cHis57Nepsilon2 atoms placing them in positions unfavorable for the catalysis. At the same time, neither distances between Calpha atoms of the catalytic triad cAsp102-cHis57-cSer195, nor the overall structure of APC changed significantly after oxidation of the methionine residues. Disruption of the H-bond between Ndelta1 of cHis57 and carboxyl group of cAsp102, which can take place during the hypochlorite-induced modification of cHis57, dramatically changed the architecture of the catalytic triad in oxidized APC. This mechanism could contribute to APC inactivation by hypochlorite concurrently with methionine oxidation. These are novel findings, which describe potentially pathophysiologically relevant changes in the functional stability of APC exposed to the oxidative stress.
ISSN:0340-6245
DOI:10.1160/TH07-12-0750