NEGATIVE ION MASS SPECTROMETRY FOR THE ANALYSIS OF <i>N</i>‐LINKED GLYCANS

Harvey, David J.

doi:10.1002/mas.21622

Cited by 36 publications

(41 citation statements)

References 432 publications

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“…Due to their instability, these can be easily lost in MSI steps, which decreases their detection [50,51]. This can be circumvented by fragmentation of derivatised glycans to increase sialic acid stabilisation [50,86,87], which can be addressed by the new instrumentation's advances. Nonetheless, following the results acquired by HILIC-UPLC, it seems that the abundance of sialic acids in the brain is overall reduced.…”

Section: Discussionmentioning

confidence: 99%

Complete spatial characterisation of N-glycosylation upon striatal neuroinflammation in the rodent brain

Rebelo

Gubinelli

Roost

et al. 2021

J Neuroinflammation

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Background Neuroinflammation is an underlying pathology of all neurological conditions, the understanding of which is still being comprehended. A specific molecular pathway that has been overlooked in neuroinflammation is glycosylation (i.e., post-translational addition of glycans to the protein structure). N-glycosylation is a specific type of glycosylation with a cardinal role in the central nervous system (CNS), which is highlighted by congenital glycosylation diseases that result in neuropathological symptoms such as epilepsy and mental retardation. Changes in N-glycosylation can ultimately affect glycoproteins’ functions, which will have an impact on cell machinery. Therefore, characterisation of N-glycosylation alterations in a neuroinflammatory scenario can provide a potential target for future therapies. Methods With that aim, the unilateral intrastriatal injection of lipopolysaccharide (LPS) in the adult rat brain was used as a model of neuroinflammation. In vivo and post-mortem, quantitative and spatial characterisation of both neuroinflammation and N-glycome was performed at 1-week post-injection of LPS. These aspects were investigated through a multifaceted approach based on positron emission tomography (PET), quantitative histology, reverse transcription-quantitative polymerase chain reaction (RT-qPCR), liquid chromatography and matrix-assisted laser desorption ionisation mass spectrometry imaging (MALDI-MSI). Results In the brain region showing LPS-induced neuroinflammation, a significant decrease in the abundance of sialylated and core fucosylated structures was seen (approximately 7.5% and 8.5%, respectively), whereas oligomannose N-glycans were significantly increased (13.5%). This was confirmed by MALDI-MSI, which provided a high-resolution spatial distribution of N-glycans, allowing precise comparison between normal and diseased brain hemispheres. Conclusions Together, our data show for the first time the complete profiling of N-glycomic changes in a well-characterised animal model of neuroinflammation. These data represent a pioneering step to identify critical targets that may modulate neuroinflammation in neurodegenerative diseases.

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Section: Discussionmentioning

confidence: 99%

Complete spatial characterisation of N-glycosylation upon striatal neuroinflammation in the rodent brain

Rebelo

Gubinelli

Roost

et al. 2021

J Neuroinflammation

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“…The vast majority of PGC LC-MS analyses use negative ion mode because of the improved detection of sialylated N-glycans and associated isomers (Nguyen-Khuong et al, 2018;Harvey, 2020). We previously utilized capillary negative ion PGC LC-MS to characterize N-glycan changes in ovarian cancer progression and found complex bi-antennary N-glycans to be unique markers for disease progression in late-stage ovarian cancer tissue (Briggs et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

In-House Packed Porous Graphitic Carbon Columns for Liquid Chromatography-Mass Spectrometry Analysis of N-Glycans

et al. 2021

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Protein glycosylation is a common post-translational modification that modulates biological processes such as the immune response and protein trafficking. Altered glycosylation profiles are associated with cancer and inflammatory diseases, as well as impacting the efficacy of therapeutic monoclonal antibodies. Consisting of oligosaccharides attached to asparagine residues, enzymatically released N-linked glycans are analytically challenging due to the diversity of isomeric structures that exist. A commonly used technique for quantitative N-glycan analysis is liquid chromatography-mass spectrometry (LC-MS), which performs glycan separation and characterization. Although many reversed and normal stationary phases have been utilized for the separation of N-glycans, porous graphitic carbon (PGC) chromatography has become desirable because of its higher resolving capability, but is difficult to implement in a robust and reproducible manner. Herein, we demonstrate the analytical properties of a 15 cm fused silica capillary (75 µm i.d., 360 µm o.d.) packed in-house with Hypercarb PGC (3 µm) coupled to an Agilent 6550 Q-TOF mass spectrometer for N-glycan analysis in positive ion mode. In repeatability and intermediate precision measurements conducted on released N-glycans from a glycoprotein standard mixture, the majority of N-glycans reported low coefficients of variation with respect to retention times (≤4.2%) and peak areas (≤14.4%). N-glycans released from complex samples were also examined by PGC LC-MS. A total of 120 N-glycan structural and compositional isomers were obtained from formalin-fixed paraffin-embedded ovarian cancer tissue sections. Finally, a comparison between early- and late-stage formalin-fixed paraffin-embedded ovarian cancer tissues revealed qualitative changes in the α2,3- and α2,6-sialic acid linkage of a fucosylated bi-antennary complex N-glycan. Although the α2,3-linkage was predominant in late-stage ovarian cancer, the alternate α2,6-linkage was more prevalent in early-stage ovarian cancer. This study establishes the utility of in-house packed PGC columns for the robust and reproducible LC-MS analysis of N-glycans.

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“…Cell pellets were homogenized, and (glyco-)proteins were adsorbed to PVDF membrane, followed by enzymatic N-glycan release, reduction, and analysis by porous graphitized carbon nanoLC-MS nanoelectrospray ion trap MS/MS (AmazonSpeed ion trap; Bruker Daltonics) using a nanoBooster. Tandem mass spectra were manually assigned following the collision-induced glycan fragmentation rules for negative-mode MS summarized in a recent review article (77). Glycan tandem mass spectra including those of the doublycharged ion at m/z 901.34 were extracted from the raw LC-MS/MS data.…”

Section: Mass Spectrometry Analysis Of Cho-lec2 N-glycansmentioning

confidence: 99%

Human Gb3/CD77 synthase produces P1 glycotope-capped N-glycans, which mediate Shiga toxin 1 but not Shiga toxin 2 cell entry

Szymczak-Kulus

Weidler

Bereznicka

et al. 2021

Journal of Biological Chemistry

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The human Gb3/CD77 synthase, encoded by the A4GALT gene, is an unusually promiscuous glycosyltransferase. It synthesizes the Galα1→4Gal linkage on two different glycosphingolipids (GSLs), producing globotriaosylceramide (Gb3, CD77, P k ) and the P1 antigen. Gb3 is the major receptor for Shiga toxins (Stxs) produced by enterohemorrhagic Escherichia coli . A single amino acid substitution (p.Q211E) ramps up the enzyme’s promiscuity, rendering it able to attach Gal both to another Gal residue and to GalNAc, giving rise to NOR1 and NOR2 GSLs. Human Gb3/CD77 synthase was long believed to transfer Gal only to GSL acceptors, therefore its GSL products were, by default, considered the only human Stx receptors. Here, using soluble, recombinant human Gb3/CD77 synthase and p.Q211E mutein, we demonstrate that both enzymes can synthesize the P1 glycotope (terminal Galα1→4Galβ1→4GlcNAc-R) on a complex type N-glycan and a synthetic N-glycoprotein (saposin D). Moreover, by transfection of CHO-Lec2 cells with vectors encoding human Gb3/CD77 synthase and its p.Q211E mutein, we demonstrate that both enzymes produce P1 glycotopes on N-glycoproteins, with the mutein exhibiting elevated activity. These P1-terminated N-glycoproteins are recognized by Stx1 but not Stx2 B subunits. Finally, cytotoxicity assays show that Stx1 can use P1 N-glycoproteins produced in CHO-Lec2 cells as functional receptors. We conclude that Stx1 can recognize and use P1 N-glycoproteins in addition to its canonical GSL receptors to enter and kill the cells, while Stx2 can use GSLs only. Collectively, these results may have important implications for our understanding of the Shiga toxin pathology.

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NEGATIVE ION MASS SPECTROMETRY FOR THE ANALYSIS OF N‐LINKED GLYCANS

Cited by 36 publications

References 432 publications

Complete spatial characterisation of N-glycosylation upon striatal neuroinflammation in the rodent brain

Complete spatial characterisation of N-glycosylation upon striatal neuroinflammation in the rodent brain

In-House Packed Porous Graphitic Carbon Columns for Liquid Chromatography-Mass Spectrometry Analysis of N-Glycans

Human Gb3/CD77 synthase produces P1 glycotope-capped N-glycans, which mediate Shiga toxin 1 but not Shiga toxin 2 cell entry

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