Kinetic study on the reaction of sodium nitrite with neurotransmitters secreted in the stomach

Kinetic study on the reaction of sodium nitrite with neurotransmitters secreted in the stomach

Nitroso-compounds are potentially mutagenic and carcinogenic compounds due to their ability to alkylate DNA bases. One of the most common sources of human exposure to nitroso-compounds is their formation in the acidic environment of the stomach by the reaction between electron-rich molecules present...

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Bibliographic Details
Published in:Scientific reports Vol. 13; no. 1; p. 15713
Main Authors: González-Jiménez, Mario, García-Santos, M. Pilar, Bermejo Tesón, Blanca, Fuentes de Arriba, Ángel L., Arenas Valgañón, Jorge, Calle, Emilio, Casado, Julio
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 21-09-2023
Nature Publishing Group
Nature Portfolio
Subjects:
639/638/440/950
639/638/92
Biological research
Dopamine
Humanities and Social Sciences
Ionic strength
multidisciplinary
Nitrites
Nitrosation
Reaction mechanisms
Science
Science (multidisciplinary)
Serotonin
Sodium
Sodium nitrite
Spectroscopy
Stomach
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Summary:Nitroso-compounds are potentially mutagenic and carcinogenic compounds due to their ability to alkylate DNA bases. One of the most common sources of human exposure to nitroso-compounds is their formation in the acidic environment of the stomach by the reaction between electron-rich molecules present in the lumen and sodium nitrite ingested in the diet. To date, the formation of nitroso-compounds by the reaction of nitrite with food components has been investigated in depth, but little attention has been paid to substances secreted in the stomach, such as dopamine or serotonin, whose reaction products with nitrite have proven mutagenic properties. In this article, we present a kinetic study with UV–visible spectroscopy of the nitrosation reactions of both molecules, as well as of L-tyrosine, the amino-acid precursor of dopamine. We determined the kinetic parameters and reaction mechanisms for the reactions, studying the influence of the reactants concentration, pH, temperature, and ionic strength on the reaction rate. In all cases, the favoured reaction product was a stable nitroso-compound. Serotonin, the molecule whose product was the most mutagenic, underwent two consecutive nitrosation reactions. These findings suggest that additional biological research is needed to understand how this reaction alters the function of these neurotransmitters as well as the potentially toxic effects they may have once nitrosated.
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ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-023-42759-x