Oligomerization and Nitration of the Grass Pollen Allergen Phl P 5 by Ozone, Nitrogen Dioxide, and Peroxynitrite: Reaction Products, Kinetics, and Health Effects

Overview

Journal Int J Mol Sci

Publisher MDPI

Specialties Biochemistry
Chemistry
Molecular Biology

Date 2021 Jul 24

PMID 34299235

Citations 9

Authors

Anna T Backes

Kathrin Reinmuth-Selzle

Anna Lena Leifke

Kira Ziegler

Carola S Krevert

Georg Tscheuschner

Kurt Lucas

Michael G Weller

Thomas Berkemeier

Ulrich Poschl

Janine Frohlich-Nowoisky

Affiliations

Soon will be listed here.

Abstract

The allergenic and inflammatory potential of proteins can be enhanced by chemical modification upon exposure to atmospheric or physiological oxidants. The molecular mechanisms and kinetics of such modifications, however, have not yet been fully resolved. We investigated the oligomerization and nitration of the grass pollen allergen Phl p 5 by ozone (O), nitrogen dioxide (NO), and peroxynitrite (ONOO). Within several hours of exposure to atmospherically relevant concentration levels of O and NO, up to 50% of Phl p 5 were converted into protein oligomers, likely by formation of dityrosine cross-links. Assuming that tyrosine residues are the preferential site of nitration, up to 10% of the 12 tyrosine residues per protein monomer were nitrated. For the reaction with peroxynitrite, the largest oligomer mass fractions (up to 50%) were found for equimolar concentrations of peroxynitrite over tyrosine residues. With excess peroxynitrite, the nitration degrees increased up to 40% whereas the oligomer mass fractions decreased to 20%. Our results suggest that protein oligomerization and nitration are competing processes, which is consistent with a two-step mechanism involving a reactive oxygen intermediate (ROI), as observed for other proteins. The modified proteins can promote pro-inflammatory cellular signaling that may contribute to chronic inflammation and allergies in response to air pollution.

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