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The mucin O-glycan sialyl Tn antigen (sTn, Neu5Acα2-6GalNAcα1-O-Ser/Thr) is an antigen associated with different types of cancers, often linked with a higher risk of metastasis and poor prognosis. Despite efforts to develop anti-sTn antibodies with high specificity for diagnostics and immunotherapy, challenges in eliciting high-affinity antibodies for glycan structures have limited their effectiveness, leading to low titers and short protection durations. Experimental structural insights into anti-sTn antibody specificity are lacking, hindering their optimization for cancer cell recognition. In this study, we used a comprehensive structural approach, combining X-ray crystallography, NMR spectroscopy, computational methods, glycan/glycopeptide microarrays, and biophysical techniques, to thoroughly investigate the molecular basis of sTn recognition by L2A5, a novel preclinical anti-sTn monoclonal antibody (mAb). Our data unequivocally show that the L2A5 fragment antigen-binding (Fab) specifically binds to core sTn moieties. NMR and X-ray structural data suggest a similar binding mode for the complexes formed by the sTn moiety linked to Ser or Thr and the L2A5 Fab. The sugar moieties are similarly oriented in the paratope of mAb, with the Neu5Ac moiety establishing key interactions with the receptor and the GalNAc moiety providing additional contacts. Furthermore, L2A5 exhibits fine specificity toward cancer-related MUC1 and MUC4 mucin-derived sTn glycopeptides, which might contribute to its selective targeting against tumor cells. This newfound knowledge holds promise for the rational improvement and potential application of this anti-sTn antibody in diagnosis and targeted therapy against sTn expressing cancers such as breast, colorectal, and bladder cancer, improving patient care.

In the last decade, it was discovered that protein mucin-type O-glycosylation and O-GlcNAcylation modify Tyr residues besides the well explored Thr and Ser amino acids. Several glycoproteomic studies have identified α-GalNAc-O-Tyr modifications, and studies propose that β-GlcNAc-O-Tyr also exists as a new group of posttranslational modifications (PTMs). Specific bacterial toxins have further been identified to modify host GTPases with α-GlcNAc-O-Tyr to promote bacterial virulence. Despite being identified on numerous proteins, the biological roles, biosynthesis and expression of GalNAc- and GlcNAc-O-Tyr modifications are poorly understood. A major obstacle is the lack of tools to specifically detect and identify proteins containing these modifications. With this in mind, we prepared vaccine constructs and raised antibodies to enable selective detection of proteins carrying these new PTMs. The obtained polyclonal antibody sera were evaluated using ELISA and glycopeptide microarrays and were found to be highly selective for GlcNAc- and GalNAc-O-Tyr glycopeptides over the corresponding Ser- and Thr-modifications. For microarray analysis, synthetic GlcNAc- and GalNAc-O-Tyr Fmoc-amino acids were prepared and applied in Fmoc-SPPS to obtain an extensive O-glycopeptide library. After affinity purification, the antibodies were applied in western blot analysis and showed specific detection of α-GlcNAc-O-Tyr modified RhoA GTPase.

Mucin glycoproteins are essential components of the mucosal barrier, which protects the host from pathogens. Throughout evolution, bacteria have developed strategies to modulate and penetrate this barrier, and cause virulence by interacting with mucin O-glycans at the epithelial cell-surface. O-fucosylated glycan epitopes on mucins are key ligands of many bacterial lectins. Here, a chemoenzymatic synthesis strategy is described to prepare a library of fucosylated mucin core glycopeptides to enable studies of mucin-interacting and fucose-binding bacterial lectins. Glycan cores with biologically important Lewis and H-antigens were prepared decorating the peptide backbone at different sites and densities. The fucosylated mucin glycopeptides were applied in microarray binding studies to explore the importance of glycan core and peptide backbone presentation of these antigens in binding interactions with the P. aeruginosa lectin LecB and the C. difficile toxin A.

Mucin expression and glycosylation patterns on cancer cells differ markedly from healthy cells. Mucin 1 (MUC1) is overexpressed in several solid tumors and presents high levels of aberrant, truncated O-glycans (e.g., Tn antigen). Dendritic cells (DCs) express lectins that bind to these tumor-associated carbohydrate antigens (TACAs) to modulate immune responses. Selectively targeting these receptors with synthetic TACAs is a promising strategy to develop anticancer vaccines and to overcome TACA tolerance. In this work, we prepared, via a solid phase peptide synthesis approach, a modular tripartite vaccine candidate, incorporating a high-affinity glycocluster based on a tetraphenylethylene scaffold, to target the macrophage galactose-type lectin (MGL) on antigen presenting cells. MGL is a C-type lectin receptor that binds Tn antigens and can route them to human leukocyte antigen class II or I, making it an attractive target for anticancer vaccines. Conjugation of the glycocluster to a library of MUC1 glycopeptides bearing the Tn antigen is shown to promote uptake and recognition of the TACA by DCs via MGL. In vivo testing revealed that immunization with the newly designed vaccine construct bearing the GalNAc glycocluster induced a higher titer of anti-Tn-MUC1 antibodies compared to the TACAs alone. Additionally, the antibodies obtained bind a library of tumor-associated saccharide structures on MUC1 and MUC1-positive breast cancer cells. Conjugation of a high-affinity ligand for MGL to tumor-associated MUC1 glycopeptide antigens has a synergistic impact on antibody production.

The interactions between bacterial lectins and carbohydrates on the host cell surface can mediate bacterial adhesion, invasion, and immune evasion. Multivalency plays a key role in these binding events. However, additional molecular mechanisms greatly impact multivalent binding recognition. To develop specific and effective bacterial inhibitors, a deeper understanding of the complex underlying mechanisms of bacterial adhesion processes is necessary. By interfering with bacterial adhesion, synthetic multivalent glycoconjugates do not only have the potential to improve or replace antibiotic treatments, but also represent useful tools to study carbohydrate-pathogen interactions. In this review, we highlight a few recent advances in the synthesis and application of synthetic glycan-based scaffolds to uncover the nature of glycan-bacteria interactions and to design efficient bacterial inhibitors.

Sialyl-Tn (STn or sialyl-Thomsen-nouveau) is a carbohydrate antigen expressed by more than 80% of human carcinomas. We here report a strategy for ratiometric STn detection and dual-color cancer cell labeling, particularly, by molecularly imprinted polymers (MIPs). Imprinting was based on spectroscopic studies of a urea-containing green-fluorescent monomer 1 and STn-Thr-Na (sodium salt of Neu5Acα2-6GalNAcα-O-Thr). A few-nanometer-thin green-fluorescent polymer shell, in which STn-Thr-Na was imprinted with 1, other comonomers, and a cross-linker, was synthesized from the surface of red-emissive carbon nanodot (R-CND)-doped silica nanoparticles, resulting in dual fluorescent STn-MIPs. Dual-color labeling of cancer cells was achieved since both red and green emissions were detected in two separate channels of the microscope and an improved accuracy was obtained in comparison with single-signal MIPs. The flow cytometric cell analysis showed that the binding of STn-MIPs was significantly higher (p < 0.001) than that of non-imprinted polymer (NIP) control particles within the same cell line, allowing to distinguish populations. Based on the modularity of the luminescent core-fluorescent MIP shell architecture, the concept can be transferred in a straightforward manner to other target analytes.

Glycosylation is the most abundant form of post-translational modification (PTM). Recently, O-glycosylation attracted much attention in the glycoproteomic field due to its association with various diseases, such as pathogenic infections and cancer. However, glycoproteomic analysis of O-linked glycosylation is highly challenging due its structural diversity and complexity. New and efficient methods need to be developed to obtain a better understanding of the biological functions of O-glycans. In the presented thesis, glycopeptide microarrays were used as tools to explore the role of mucin type O-glycosylation in cancer, bacterial adhesion processes and galectin recognition on a molecular level, and to get insights into a new group of tyrosine O-glycosylation. A better understanding of these carbohydrate-protein interactions on a molecular level could facilitate the development of glycomimetic inhibitors to fight bacterial infections or block glycan binding proteins involved in cancer progression, or improve the design of novel carbohydrate-based cancer vaccines.

In the first part of this work, tools were developed to elucidate the role of a novel group of PTMs, where N-acetylhexosamine (HexNAc = α-GalNAc, α- or β-GlcNAc) was found to modify the hydroxyl group of tyrosine. Synthetic glycopeptides carrying this new modification, as well as glycopeptide microarray libraries were prepared to evaluate the abilities of plant lectins (carbohydrate-binding proteins) to detect HexNAc-O-Tyr modifications. These lectins are commonly used in glycoproteomic work flows to detect and enrich glycopeptides and -proteins. Additionally, HexNAc-O-Tyr-specific rabbit antibodies were raised and immunologically analyzed by enzyme-linked immunosorbent assays, western blot and microarray binding studies.

In the second part of the presented thesis, synthetic mucin glycopeptide microarray libraries were prepared and employed to explore carbohydrate-protein interactions of galectins, bacterial lectins and tumor specific antibodies. Mucin glycoproteins are part of the mucus barrier that protects the host against invading pathogens. However, bacteria and viruses have co-evolved with the human host and have developed strategies to promote virulence, for example by adhering to glycans on the host cell-surface. To combat bacterial infections, their virulence and pathogenicity must be understood on a molecular level. In this work, mucin glycopeptides were enzymatically modified with different fucose motifs and used to determine the fine binding specificities of fucose-recognizing lectins LecB from Pseudomonas aeruginosa and the Clostridium difficile toxin A. Furthermore, a synthesis strategy was developed to generate simplified mucin core glycopeptides that could be used as scaffolds to enzymatically generate LacdiNAc modified glycopeptides. They could be used in microarray binding studies to evaluate the glycan binding preferences of various proteins, including the Helicobacter pylori lectin LabA and human galectins, which play roles in cancer development and progression. Aberrant glycosylation of mucin glycoproteins has been associated with various types of cancer. Tumor specific carbohydrate antigens on mucins represent attractive antigenic targets for the development of effective anti-cancer vaccines. In this work, antibodies induced by tumor-associated MUC1 glycopeptide-bacteriophage Qβ vaccine conjugates were immunologically analyzed using MUC1 glycopeptide microarray libraries.

MUC1 glycopeptides are attractive antigens for anti-cancer vaccine development. One potential drawback in using the native MUC1 glycopeptide for vaccine design is the instability of theO-glycosyl linkage between the glycan and the peptide backbone to glycosidase. To overcome this challenge, a MUC1 glycopeptide mimic has been synthesized with the galactose-galactosamine disaccharide linked with threonine (Thomsen-Friedenreich or Tf antigen) through an unnatural β-glycosyl bond. The resulting MUC1-β-Tf had a much-enhanced stability toward a glycosidase capable of cleaving the glycan from the corresponding MUC1 glycopeptide with the natural α-Tf linkage. The MUC1-β-Tf was subsequently conjugated with a powerful carrier bacteriophage Qβ. The conjugate induced high levels of IgG antibodies in clinically relevant human MUC1 transgenic mice, which cross-recognized not only the natural MUC1-α-Tf glycopeptide but also MUC1 expressing tumor cells, supporting the notion that a simple switch of the stereochemistry of the glycan/peptide linkage can be a strategy for anti-cancer vaccine epitope design for glycopeptides.

The initial contact of pathogens with host cells is usually mediated by their adhesion to glycan structures present on the cell surface in order to enable infection. Furthermore, glycans play important roles in the modulation of the host immune responses to infection. Understanding the carbohydrate-pathogen interactions are of importance for the development of novel and efficient strategies to either prevent, or interfere with pathogenic infection. Synthetic glycopeptides and mimetics thereof are capable of imitating the multivalent display of carbohydrates at the cell surface, which have become an important objective of research over the last decade. Glycopeptide based constructs may function as vaccines or anti-adhesive agents that interfere with the ability of pathogens to adhere to the host cell glycans and thus possess the potential to improve or replace treatments that suffer from resistance. Additionally, synthetic glycopeptides are used as tools for epitope mapping of antibodies directed against structures present on various pathogens and have become important to improve serodiagnostic methods and to develop novel epitope-based vaccines. This review will provide an overview of the most recent advances in the synthesis and application of glycopeptides and glycopeptide mimetics exhibiting a peptide-like backbone in glycobiology.

Mucin-1 (MUC1) is a highly attractive antigenic target for anticancer vaccines. Naturally existing MUC1 can contain multiple types of O-linked glycans, including the Thomsen–Friedenreich (Tf) antigen and the Sialyl Thomsen-nouveau (STn) antigen. In order to target these antigens as potential anticancer vaccines, MUC1 glycopeptides SAPDT*RPAP (T* is the glycosylation site) bearing the Tf and the STn antigen, respectively, have been synthesized. The bacteriophage Qβ carrier is a powerful carrier for antigen delivery. The conjugates of MUC1-Tf and -STn glycopeptides with Qβ were utilized to immunize immune-tolerant human MUC1 transgenic (MUC1.Tg) mice, which elicited superior levels of anti-MUC1 IgG antibodies with titers reaching over 2 million units. The IgG antibodies recognized a wide range of MUC1 glycopeptides bearing diverse glycans. Antibodies induced by Qβ-MUC1-Tf showed strongest binding, with MUC1-expressing melanoma B16-MUC1 cells, and effectively killed these cells in vitro. Vaccination with Qβ-MUC1-Tf first followed by tumor challenge in a lung metastasis model showed significant reductions of the number of tumor foci in the lungs of immunized mice as compared to those in control mice. This was the first time that a MUC1-Tf-based vaccine has shown in vivo efficacy in a tumor model. As such, Qβ-MUC1 glycopeptide conjugates have great potential as anticancer vaccines.