Ion mobility mass spectrometry of saponin ions

Rationale Saponins are natural compounds presenting a high structural diversity whose structural characterization remains extremely challenging. Ideally, saponin structures are best established using nuclear magnetic resonance experiments conducted on isolated molecules. However, saponins are also i...

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Bibliographic Details
Published in:Rapid communications in mass spectrometry 2019-07, Vol.33 (S2), p.22-33
Main Authors: Decroo, Corentin, Colson, Emmanuel, Lemaur, Vincent, Caulier, Guillaume, De Winter, Julien, Cabrera‐Barjas, Gustavo, Cornil, Jérôme, Flammang, Patrick, Gerbaux, Pascal
Format: Article
Language:English
Subjects:
Cations
Computer simulation
Ionic mobility
Ions
Isomers
Liquid chromatography
Mass spectrometry
Molecular dynamics
NMR
Nuclear magnetic resonance
Phase separation
Positive ions
Saponins
Scientific imaging
Spectroscopy
Structural analysis
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Summary:Rationale Saponins are natural compounds presenting a high structural diversity whose structural characterization remains extremely challenging. Ideally, saponin structures are best established using nuclear magnetic resonance experiments conducted on isolated molecules. However, saponins are also increasingly characterized using tandem mass spectrometry (MS/MS) coupled with liquid chromatography, even if collision‐induced dissociation (CID) experiments are often quite limited in accurately determining the saponin structure. Methods We consider here ion mobility mass spectrometry (IMMS) as an orthogonal tool for the structural characterization of saponin isomers by comparing the experimental collisional cross sections (CCSs) of saponin ions with theoretical CCSs for candidate ion structures. Indeed, state‐of‐the‐art theoretical calculations perfectly complement the experimental results, allowing the ion structures to be deciphered at the molecular level. Results We demonstrate that ion mobility can contribute to the structural characterization of saponins because different saponin ions present significantly distinct CCSs. Depending on the nature of the cation (in the positive ion mode), the differences in CCSs can also be exacerbated, optimizing the gas‐phase separation. When associated with molecular dynamics simulations, the CCS data can be used to describe the interactions between the cations, i.e. H+, Na+ and K+, and the saponin molecules at a molecular level. Conclusions Our work contributes to resolve the relationship between the primary and secondary structures of saponin ions. However, it is obvious that the structural diversity and complexity of the saponins cannot be definitively unraveled by measuring a single numerical value, here the CCS. Consequently, the structural characterization of unknown saponins will be difficult to achieve based on IMMS alone. Nevertheless, we demonstrated that monodesmosidic and bidesmosidic saponins can be distinguished via IMMS.
ISSN:0951-4198
1097-0231
DOI:10.1002/rcm.8193