Rapid and Bifunctional Chemoselective Metabolome Analysis of Liver Disease Plasma Using the Reagent 4‐Nitrophenyl‐2H‐azirine

Author:

Lin Weifeng1ORCID,Gerullat Lars1,Braadland Peder R.2ORCID,Fournier Anaïs1,Hov Johannes R.2ORCID,Globisch Daniel1ORCID

Affiliation:

1. Department of Chemistry— BMC Science for Life Laboratory Uppsala University Box 576 SE-75123 Uppsala Sweden

2. Norwegian PSC Research Center at Department of Transplantation Medicine Research Institute of Internal Medicine Oslo University Hospital and University of Oslo 0424 Oslo Norway

Abstract

AbstractPrimary sclerosing cholangitis (PSC) is a chronic inflammatory disease of the bile ducts that has been associated with diverse metabolic carboxylic acids. Mass spectrometric techniques are the method of choice for their analysis. However, the broad investigation of this metabolite class remains challenging. Derivatization of carboxylic acids represents a strategy to overcome these limitations but available methods suffer from diverse analytical challenges. Herein, we have designed a novel strategy introducing 4‐nitrophenyl‐2H‐azirine as a new chemoselective moiety for the first time for carboxylic acid metabolites. This moiety was selected as it rapidly forms a stable amide bond and also generates a new ketone, which can be analyzed by our recently developed quant‐SCHEMA method specific for carbonyl metabolites. Optimization of this new method revealed a high reproducibility and robustness, which was utilized to validate 102 metabolic carboxylic acids using authentic synthetic standard conjugates in human plasma samples including nine metabolites that were newly detected. Using this sequential analysis of the carbonyl‐ and carboxylic acid‐metabolomes revealed alterations of the ketogenesis pathway, which demonstrates the vast benefit of our unique methodology. We anticipate that the developed azirine moiety with rapid functional group transformation will find broad application in diverse chemical biology research fields.

Funder

Vetenskapsrådet

Science for Life Laboratory

Cancerfonden

H2020 European Research Council

Helse Sør-Øst RHF

Publisher

Wiley

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