Identification of a Chimera Mass Spectrum of Isomeric Lipid A Species Using Negative Ion Tandem Mass Spectrometry.
Ágnes DörnyeiAnikó KilárViktor SándorPublished in: Toxins (2024)
The toxic nature of bacterial endotoxins is affected by the structural details of lipid A, including the variety and position of acyl chains and phosphate group(s) on its diglucosamine backbone. Negative-ion mode tandem mass spectrometry is a primary method for the structure elucidation of lipid A, used independently or in combination with separation techniques. However, it is challenging to accurately characterize constitutional isomers of lipid A extracts by direct mass spectrometry, as the elemental composition and molecular mass of these molecules are identical. Thus, their simultaneous fragmentation leads to a composite, so-called chimera mass spectrum. The present study focuses on the phosphopositional isomers of the classical monophosphorylated, hexaacylated Escherichia coli -type lipid A. Collision-induced dissociation (CID) was performed in an HPLC-ESI-QTOF system. Energy-resolved mass spectrometry (ERMS) was applied to uncover the distinct fragmentation profiles of the phosphorylation isomers. A fragmentation strategy applying multi-levels of collision energy has been proposed and applied to reveal sample complexity, whether it contains only a 4'-phosphorylated species or a mixture of 1- and 4'-phosphorylated variants. This comparative fragmentation study of isomeric lipid A species demonstrates the high potential of ERMS-derived information for the successful discrimination of co-ionized phosphorylation isomers of hexaacylated lipid A.
Keyphrases
- tandem mass spectrometry
- liquid chromatography
- mass spectrometry
- high performance liquid chromatography
- ultra high performance liquid chromatography
- gas chromatography
- fatty acid
- simultaneous determination
- escherichia coli
- ms ms
- high resolution
- high resolution mass spectrometry
- gene expression
- oxidative stress
- pseudomonas aeruginosa
- genome wide
- single molecule
- multidrug resistant
- diabetic rats
- protein kinase
- drug induced
- klebsiella pneumoniae