Jordan M. Rabus scite author profile

We investigate the fragmentation chemistry of cationized carbohydrates using a combination of tandem mass spectrometry, regioselective labeling, and computational methods. Our model system is D-lactose. Barriers to the fundamental glyosidic bond cleavage reactions, neutral loss pathways, and structurally informative cross-ring cleavages are investigated. The most energetically favorable conformations of cationized D-lactose were found to be similar. In agreement with the literature, larger group I cations result in structures with increased cation coordination number which require greater collision energy to dissociate. In contrast with earlier proposals, the B -Y fragmentation pathways of both protonated and sodium-cationized analytes proceed via protonation of the glycosidic oxygen with concerted glycosidic bond cleavage. Additionally, for the sodiated congeners our calculations support sodiated 1,6-anhydrogalactose B ion structures, unlike the preceding literature. This affects the subsequent propensity of formation and prediction of B /Y branching ratio. The nature of the anomeric center (α/β) affects the relative energies of these processes, but not the overall ranking. Low-energy cross-ring cleavages are observed for the metal-cationized analytes with a retro-aldol mechanism producing the A ion from the sodiated forms. Theory and experiment support the importance of consecutive fragmentation processes, particularly for the protonated congeners at higher collision energies. Graphical Abstract ᅟ.

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Sodium-cationized carbohydrate gas-phase fragmentation chemistry: influence of glycosidic linkage position

Rabus

Abutokaikah

Ross

et al. 2017

Phys. Chem. Chem. Phys.

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We investigate the gas-phase structures and fragmentation chemistry of two isomeric sodium-cationized carbohydrates using combined tandem mass spectrometry, hydrogen/deuterium exchange experiments, and computational methods. Our model systems are the glucose-based disaccharide analytes cellobiose (β-d-glucopyranosyl-(1 → 4)-d-glucose) and gentiobiose (β-d-glucopyranosyl-(1 → 6)-d-glucose). These analytes show substantially different tandem mass spectra. We characterize the rate-determining barriers to both the glycosidic and structurally-informative cross-ring bond cleavages. Sodiated cellobiose produces abundant Y and B peaks. Our deuterium labelling and computational chemistry approach provides evidence for 1,6-anhydroglucose B ion structures rather than the 1,2-anhydroglucose and oxacarbenium ion structures proposed elsewhere. Unlike those earlier proposals, this finding is consistent with the experimentally observed B/Y branching ratios. In contrast to cellobiose, sodiated gentiobiose primarily fragments by cross-ring cleavage to form various A ion types. Fragmentation is facilitated by ring-opening at the reducing end which enables losses of CHO oligomers. Deuterium labelling and theory enables rationalization of these processes. Theory and experiment also support the importance of consecutive fragmentation processes at higher collision energies.

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Fragmentation Pathways of Lithiated Hexose Monosaccharides

Abutokaikah

Frye

Tschampel³

et al. 2018

J. Am. Soc. Mass Spectrom.

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We characterize the primary fragmentation reactions of three isomeric lithiated D-hexose sugars (glucose, galactose, and mannose) utilizing tandem mass spectrometry, regiospecific labeling, and theory. We provide evidence that these three isomers populate similar fragmentation pathways to produce the abundant cross-ring cleavage peaks (A and A). These pathways are highly consistent with the prior literature (Hofmeister et al. J. Am. Chem. Soc. 113, 5964-5970, 1991, Bythell et al. J. Am. Soc. Mass Spectrom. 28, 688-703, 2017, Rabus et al. Phys. Chem. Chem. Phys. 19, 25643-25652, 2017) and the present labeling data. However, the structure-specific energetics and rate-determining steps of these reactions differ as a function of precursor sugar and anomeric configuration. The lowest energy water loss pathways involve loss of the anomeric oxygen to furnish B ions. For glucose and galactose, the lithiated α-anomers generate ketone structures at C2 in a concerted reaction involving a 1,2-migration of the C2-H to the anomeric carbon (C1). In contrast, the β-anomers are predicted to form 1,3-anhydroglucose/galactose B ion structures. Initiation of the water loss reactions from each anomeric configuration requires distinct reactive conformers, resulting in different product ion structures. Inversion of the stereochemistry at C2 has marked consequences. Both lithiated mannose forms expel water to form 1,2-anhydromannose B ions with the newly formed epoxide group above the ring. Additionally, provided water loss is not instantaneous, the α-anomer can also isomerize to generate a ketone structure at C2 in a concerted reaction involving a 1,2-migration of the C2-H to C1. This product is indistinguishable to that from α-glucose. The energetics and interplay of these pathways are discussed. Graphical Abstract ᅟ.

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Fragmentation of Multi-charged Derivatized Lysine Using Nanospray CID Tandem Mass Spectrometry

Huang

Rabus

Bythell

et al. 2019

J. Am. Soc. Mass Spectrom.

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Sequence Ion Structures and Dissociation Chemistry of Deprotonated Sucrose Anions

Bythell

Rabus

Wagoner

et al. 2018

J. Am. Soc. Mass Spectrom.

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Jordan M. Rabus

Cationized Carbohydrate Gas-Phase Fragmentation Chemistry

Sodium-cationized carbohydrate gas-phase fragmentation chemistry: influence of glycosidic linkage position

Fragmentation Pathways of Lithiated Hexose Monosaccharides

Fragmentation of Multi-charged Derivatized Lysine Using Nanospray CID Tandem Mass Spectrometry

Sequence Ion Structures and Dissociation Chemistry of Deprotonated Sucrose Anions

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