Sequencing glycans is demanding due to their structural diversity. Compared to mammalian glycans, bacterial glycans pose a steeper challenge because they are constructed from a larger pool of monosaccharide building blocks, including pyranose andf uranose isomers. Though mammalian glycans incorporate only the pyranose form of galactose (Galp), many pathogens, including Mycobacterium tuberculosis and Klebsiella pneumoniae, contain galactofuranose (Galf) residues in their cell envelope. Thus, glycan sequencing would benefit from methods to distinguish between pyranose and furanose isomers of different anomeric configurations. We used infrared multiple photon dissociation (IRMPD) spectroscopy with mass spectrometry (MS-IR) to differentiate between pyranose-and furanose-linked galactose residues. These targets pose a challenge for MS-IR because the saccharides lack basic groups, and galactofuranose residues are highly flexible. We postulated cationic groups that could complex through hydrogen bonding would offer a solution. Here, we present the first MS-IR analysis of hexose ammonium adducts. We compared their IR fingerprints with those of lithium adducts. We determined the diagnostic MS-IR signatures of the α-and β-anomers of galactose in furanose and pyranose forms. We also showed these signatures could be applied to disaccharides to assign galactose ring size. Our findings highlight the utility of MS-IR for analyzing the unique substructures that occur in bacterial glycans.
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Infrared vibrational spectroscopy in the gas phase has emerged as a powerful tool to determine complex molecular structures with high precision. Among the different approaches IRMPD (InfraRed Multiple Photon Dissociation),...
Nature
offers a huge diversity of glycosidic derivatives. Amongst numerous structural
modulations, the nature of the ring size of hexosides may induce significant
differences on both biological and physicochemical properties of the
glycoconjugate of interest. On this assumption, we expect that small
disaccharides bearing either a furanosyl entity or a pyranosyl residue would
give a specific signature, even in the gas phase. On the basis of the scope of
mass spectrometry, two analytical techniques to register those signatures were
considered, i.e. the ion-mobility (IM) and the infra-red multiple photon
dissociation (IRMPD), in order to build up cross-linked databases. D-Galactose
occurs in natural products in both tautomeric forms and presents all possible
regioisomers when linked to D-mannose. Consequently, the four reducing Gal<i>f</i>-Man<i>p</i>
disaccharides as well as the four Gal<i>p</i>-Man<i>p</i> counterparts were firstly synthesized
according to a highly convergent approach, and IM-MS and IRMPD-MS data were
secondly collected. Both techniques used afforded signatures, specific to the
nature of the connectivity between the two glycosyl entities.
Fucose is a ubiquitous monosaccharide associated to major classes of glycans. A main obstacle to the sequencing of fucosylated glycans is the migration of fucose, which leads to misinterpretations in mass spectrometry analysis. Here, using ion vibrational spectroscopy, we resolve the structure of fucosylated fragments of Lewis and blood group H antigen trisaccharides and we unveil the position and linkage of the fucose after migration. Our findings demonstrate that the structure of fragment ions resulting from fucose migration can be characterized. Additionally, we report a new type of fucose migration, which does not feature any change of mass and therefore had not been previously reported: it consists of a local migration where the fucose changes its position remaining on the initial residue. Our approach allows the characterization of glycans, an essential step to interpret glycomics data, as well as to understand underlying processes at play in mass spectrometry.
O-acetylations are functional modifications which can be found on different hydroxyl groups of glycans and which contribute to the fine tuning of their biological activity. Localizing the acetyl modifications is...
Carbohydrates are ubiquitous in nature but are among the least conserved biomolecules in life. These biopolymers pose a particular challenge to analytical chemists because of their high diversity and structural heterogeneity. In addition, they contain many isomerisms that complicate their structural characterization, notably by mass spectrometry. The tautomerism of the constitutive subunits is of particular interest. A given cyclized monosaccharide unit can take two forms: a most common 6membered ring (pyranose, p) and a more flexible 5-membered ring (furanose, f). The tautomers impact the biological properties of polysaccharides, resulting in interesting properties of the derived oligosaccharides. From an analytical point of view, the impact of tautomerism on the gas-phase behavior of ions has scarcely been described in the literature. In this work, we study the behavior of Galf-containing oligosaccharides, ionized as [M+Li] + species, under collisional dissociation (CID) conditions using high-resolution and multistage ion mobility (IMS) on a Cyclic IMS platform. In the first part of this work, we studied whether disaccharidic fragments released from Galf-containing (Gal) 1 (Man) 2 trisaccharides (and their Galp counterpart) would match the corresponding disaccharide standards, and�despite the fragments generally being a good match�we showed the possibility of Galf migrations and other unidentified alterations in the IMS profile. Next, we expanded on these unknown features using multistage IMS and molecular dynamics, unveiling the contributions of additional gas-phase conformers in the profile of fragments from a Galf-containing trisaccharide compared with the corresponding disaccharides.
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