32 research outputs found
N-Glycosylation of LRP6 by B3GnT2 Promotes Wnt/β-Catenin Signalling
Reception of Wnt signals by cells is predominantly mediated by Frizzled receptors in conjunction with a co-receptor, the latter being LRP6 or LRP5 for the Wnt/β-catenin signalling pathway. It is important that cells maintain precise control of receptor activation events in order to properly regulate Wnt/β-catenin signalling as aberrant signalling can result in disease in humans. Phosphorylation of the intracellular domain (ICD) of LRP6 is well known to regulate Wntβ-catenin signalling; however, less is known for regulatory post-translational modification events within the extracellular domain (ECD). Using a cell culture-based expression screen for functional regulators of LRP6, we identified a glycosyltransferase, B3GnT2-like, from a teleost fish (medaka) cDNA library, that modifies LRP6 and regulates Wnt/β-catenin signalling. We provide both gain-of-function and loss-of-function evidence that the single human homolog, B3GnT2, promotes extension of polylactosamine chains at multiple N-glycans on LRP6, thereby enhancing trafficking of LRP6 to the plasma membrane and promoting Wnt/β-catenin signalling. Our findings further highlight the importance of LRP6 as a regulatory hub in Wnt signalling and provide one of the few examples of how a specific glycosyltransferase appears to selectively target a signalling pathway component to alter cellular signalling events
Acute phase inflammation is characterized by rapid changes in plasma/peritoneal fluid N-glycosylation in mice.
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This article is open access.Murine zymosan-induced peritonitis is a widely used model for studying the molecular and cellular events responsible for the initiation, persistence and/or resolution of inflammation. Among these events, it is becoming increasingly evident that changes in glycosylation of proteins, especially in the plasma and at the site of inflammation, play an important role in the inflammatory response. Using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS)-based glycosylation profiling, we investigated the qualitative and quantitative effect of zymosan-induced peritonitis on N-glycosylation in mouse plasma and peritoneal fluid. Our results show that both N-glycomes exhibit highly similar glycosylation patterns, consisting mainly of diantennary and triantennary complex type N-glycans with high levels (>95 %) of galactosylation and sialylation (mostly NeuGc) and a medium degree of core fucosylation (30 %). Moreover, MS/MS structural analysis, assisted by linkage-specific derivatization of sialic acids, revealed the presence of O-acetylated sialic acids as well as disialylated antennae ("branching sialylation") characterized by the presence of α2-6-linked NeuGc on the GlcNAc of the NeuGcα2-3-Galβ1-3-GlcNAc terminal motif. A significant decrease of (core) fucosylation together with an increase of both α2-3-linked NeuGc and "branching sialylation" were observed in N-glycomes of mice challenged with zymosan, but not in control mice injected with PBS. Importantly, substantial changes in glycosylation were already observed 12 h after induction of peritonitis, thereby demonstrating an unexpected velocity of the biological mechanisms involved.Dutch Arthritis Association (Reumafonds)
LLP-24
Innovative Medicines Initiative Joint Undertaking (IMI JU)/
115142-2
Netherlands Genomic Initiative/93511033
info:eu-repo/grantAgreement/EC/FP7/278535info:eu-repo/grantAgreement/EC/FP7/27853
Anti-D monoclonal antibodies from 23 human and rodent cell lines display diverse IgG Fc-glycosylation profiles that determine their clinical efficacy.
Anti-D immunoglobulin (Anti-D Ig) prophylaxis prevents haemolytic disease of the fetus and newborn. Monoclonal IgG anti-Ds (mAb-Ds) would enable unlimited supplies but have differed in efficacy in FcγRIIIa-mediated ADCC assays and clinical trials. Structural variations of the oligosaccharide chains of mAb-Ds are hypothesised to be responsible. Quantitative data on 12 Fc-glycosylation features of 23 mAb-Ds (12 clones, 5 produced from multiple cell lines) and one blood donor-derived anti-D Ig were obtained by HPLC and mass spectrometry using 3 methods. Glycosylation of mAb-Ds from human B-lymphoblastoid cell lines (B) was similar to anti-D Ig although fucosylation varied, affecting ADCC activity. In vivo, two B mAb-Ds with 77-81% fucosylation cleared red cells and prevented D-immunisation but less effectively than anti-D Ig. High fucosylation (>89%) of mouse-human heterohybridoma (HH) and Chinese hamster ovary (CHO) mAb-Ds blocked ADCC and clearance. Rat YB2/0 mAb-Ds with 60%) together with lower fucosylation (<60%) as safe features of mAb-Ds for mediating rapid red cell clearance at low doses, to enable effective, inexpensive prophylaxis
Assessment of IgG-Fc glycosylation from individual RhD-specific B cell clones reveals regulation at clonal rather than clonotypic level
The type and strength of effector functions mediated by immunoglobulin G (IgG) antibodies rely on the subclass and the composition of the N297 glycan. Glycosylation analysis of both bulk and antigen-specific human IgG has revealed a marked diversity of the glycosylation signatures, including highly dynamic patterns as well as long-term stability of profiles, yet information on how individual B cell clones would contribute to this diversity has hitherto been lacking. Here, we assessed whether clonally related B cells share N297 glycosylation patterns of their secreted IgG. We differentiated single antigen-specific peripheral IgG+ memory B cells into antibody-secreting cells and analysed Fc glycosylation of secreted IgG. Furthermore, we sequenced the variable region of their heavy chain, which allowed the grouping of the clones into clonotypes. We found highly diverse glycosylation patterns of culture-derived IgG, which, to some degree, mimicked the glycosylation of plasma IgG. Each B cell clone secreted IgG with a mixture of different Fc glycosylation patterns. The majority of clones produced fully fucosylated IgG. B cells producing afucosylated IgG were scattered across different clonotypes. In contrast, the remaining glycosylation traits were, in general, more uniform. These results indicate IgG-Fc fucosylation to be regulated at the single-clone level, whereas the regulation of other glycosylation traits most likely occurs at a clonotypic or systemic level. The discrepancies between plasma IgG and culture-derived IgG, could be caused by the origin of the B cells analysed, clonal dominance or factors from the culture system, which need to be addressed in future studies
Dissecting Total Plasma and Protein-Specific Glycosylation Profiles in Congenital Disorders of Glycosylation
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Murine Plasma <i>N</i>‑Glycosylation Traits Associated with Sex and Strain
Glycosylation is
an abundant and important protein modification
with large influence on the properties and interactions of glycoconjugates.
Human plasma <i>N</i>-glycosylation has been the subject
of frequent investigation, revealing strong associations with physiological
and pathological conditions. Less well-characterized is the plasma <i>N</i>-glycosylation of the mouse, the most commonly used animal
model for studying human diseases, particularly with regard to differences
between strains and sexes. For this reason, we used MALDI-TOF(/TOF)-MS(/MS)
assisted by linkage-specific derivatization of the sialic acids to
comparatively analyze the plasma <i>N</i>-glycosylation
of both male and female mice originating from BALB/c, CD57BL/6, CD-1,
and Swiss Webster strains. The combined use of this analytical method
and the recently developed data processing software named MassyTools
allowed the relative quantification of the <i>N</i>-glycan
species within plasma, the distinction between α2,3- and α2,6-linked <i>N</i>-glycolylneuraminic acids (due to respective lactonization
and ethyl esterification), the detection of sialic acid <i>O</i>-acetylation, as well as the characterization of branching sialylation
(Neu5Gcα2,3-Hex-[Neu5Gcα2,6-]HexNAc). When analyzing the
glycosylation according to mouse sex, we found that female mice present
a considerably higher degree of core fucosylation (2–4-fold
depending on the strain), galactosylation, α2,6-linked sialylation,
and larger high-mannose type glycan species compared with their male
counterparts. Male mice, on the contrary, showed on average higher
α2,3-linked sialylation, branching sialylation, and putative
bisection. These differences together with sialic acid acetylation
proved to be strain-specific as well. Interestingly, the outbred strains
CD-1 and Swiss Webster displayed considerably larger interindividual
variation than inbred strains BALB/c and CD57BL/6, suggesting a strong
hereditable component of the observed plasma <i>N</i>-glycome
Murine Plasma <i>N</i>‑Glycosylation Traits Associated with Sex and Strain
Glycosylation is
an abundant and important protein modification
with large influence on the properties and interactions of glycoconjugates.
Human plasma <i>N</i>-glycosylation has been the subject
of frequent investigation, revealing strong associations with physiological
and pathological conditions. Less well-characterized is the plasma <i>N</i>-glycosylation of the mouse, the most commonly used animal
model for studying human diseases, particularly with regard to differences
between strains and sexes. For this reason, we used MALDI-TOF(/TOF)-MS(/MS)
assisted by linkage-specific derivatization of the sialic acids to
comparatively analyze the plasma <i>N</i>-glycosylation
of both male and female mice originating from BALB/c, CD57BL/6, CD-1,
and Swiss Webster strains. The combined use of this analytical method
and the recently developed data processing software named MassyTools
allowed the relative quantification of the <i>N</i>-glycan
species within plasma, the distinction between α2,3- and α2,6-linked <i>N</i>-glycolylneuraminic acids (due to respective lactonization
and ethyl esterification), the detection of sialic acid <i>O</i>-acetylation, as well as the characterization of branching sialylation
(Neu5Gcα2,3-Hex-[Neu5Gcα2,6-]HexNAc). When analyzing the
glycosylation according to mouse sex, we found that female mice present
a considerably higher degree of core fucosylation (2–4-fold
depending on the strain), galactosylation, α2,6-linked sialylation,
and larger high-mannose type glycan species compared with their male
counterparts. Male mice, on the contrary, showed on average higher
α2,3-linked sialylation, branching sialylation, and putative
bisection. These differences together with sialic acid acetylation
proved to be strain-specific as well. Interestingly, the outbred strains
CD-1 and Swiss Webster displayed considerably larger interindividual
variation than inbred strains BALB/c and CD57BL/6, suggesting a strong
hereditable component of the observed plasma <i>N</i>-glycome
The N-Glycosylation of Mouse Immunoglobulin G (IgG)-Fragment Crystallizable Differs Between IgG Subclasses and Strains
N-linked glycosylation of the fragment crystallizable (Fc)-region of immunoglobulin G (IgG) is known to have a large influence on the activity of the antibody, an effect reported to be IgG subclass specific. This situation applies both to humans and mice. The mouse is often used as experimental animal model to study the effects of Fc-glycosylation on IgG effector functions, and results are not uncommonly translated back to the human situation. However, while human IgG Fc-glycosylation has been extensively characterized in both health and disease, this is not the case for mice. To characterize the glycosylation profile of murine IgG-Fc and in addition evaluate the systematic glycosylation differences between mouse strains, sexes, and IgG subclasses, we used nanoliquid chromatography mass spectrometry (nanoLC-MS(/MS)) to look at the subclass-specific IgG Fc-glycopeptides of male and female mice from the strains BALB/c, C57BL/6, CD-1, and Swiss Webster. The structural analysis revealed the presence of predominantly fucosylated, diantennary glycans, with varying amounts of galactosylation and α2,6-sialylation. In addition, we report glycosylation features not previously reported in an Fc-specific way on murine IgG, including monoantennary, hybrid, and high mannose structures, as well as diantennary structures without a core fucose, with a bisecting N-acetylglucosamine, or with α1,3-galactosylation. Pronounced differences were detected between strains and the IgG subclasses within each strain. Especially the large spread in galactosylation and sialylation levels found between both strains and subclasses may vastly influence IgG effector functions. Mouse strain-based and subclass-specific glycosylation differences should be taken into account when designing and interpreting immunological and glycobiological mouse studies involving IgG effector functions
Site-specific N-and O-glycosylation analysis of atacicept
International audienceThe Fc-fusion protein atacicept is currently under clinical investigation for its biotherapeutic application in autoimmune diseases owing to its ability to bind the two cytokines B-Lymphocyte Stimulator (BLyS) and A PRoliferation-Inducing Ligand (APRIL). Like typical recombinant IgG-based therapeutics, atacicept is a glycoprotein whose glycosylation-related heterogeneity arises from the glycosylation-site localization, site-specific occupation and structural diversity of the attached glycans. Here, we present a first comprehensive site-specific N- and O-glycosylation characterization of atacicept using mass spectrometry-based workflows. First, N- and O-glycosylation sites and their corresponding glycoforms were identified. Second, a relative quantitation of the N-glycosylation site microheterogeneity was achieved by glycopeptide analysis, which was further supported by analysis of the released N-glycans. We confirmed the presence of one N-glycosylation site, carrying 47 glycoforms covering 34 different compositions, next to two hinge region O-glycosylation sites with core 1-type glycans. The relative O-glycan distribution was analyzed based on the de-N-glycosylated intact protein species. Overall, N- and O-glycosylation were consistent between two individual production batches