The interaction between tumor and immune cells in the microenvironment plays a key role in oncogenesis. This recognition can be mediated by changes in glycosylation on tumor cells which are sensed... Show moreThe interaction between tumor and immune cells in the microenvironment plays a key role in oncogenesis. This recognition can be mediated by changes in glycosylation on tumor cells which are sensed by lectins, such as the Macrophage Galactose-type Lectin (MGL), expressed on immune cells, resulting in immunosuppressive responses. MGL binding to the Tn-epitope on MUC1 triggers DCs to stimulate T-regulatory responses and tolerance against the tumor, while suppressing T-effector cells responsible for tumor eradication. This undesirable consequence in cancer led to interest in the characterization of targets of MGL. This thesis dealt with the analysis of glycoproteins binding to MGL expressed by different tumor cell models. For this purpose, a robust method to enrich MGL binding proteins, in combination with their mass spectrometry-based identification was established. Because of the high level of the Tn-antigen, due to a Cosmc mutation, the Jurkat cell line was initially used for this purpose (Chapter 2) but a slightly adjusted method was later applied to high- and low-MGL binding CRC cell lines as well (Chapter 3 and 5). These analyses led to the identification of hitherto unknown MGL binders. In Chapter 4, we focused on to the contribution of N-glycan MGL binding glycotopes in CRC cell lines, most probably corresponding to LacdiNAc structures, by implementing overall N-glycan release in our workflows. With this, we were able to show that N-glycoproteins represent a hitherto underestimated group of MGL binding protein in these cell lines. Also several secreted proteins from the CRC cell lines could bind to MGL (Chapter 5), indicating that the interaction with immune cells can also be mediated by this group of proteins. The results from previously published transcriptomics and N-/O-glycomic analyses could not explain the different expression of MGL binding proteins on the CRC cell lines used. For this reason, in Chapter 4, we extended our research with full comparative quantitative proteomics analyses, in an attempt to explain the differences in MGL binding, for example by different levels of MGL binding proteins or proteins involved in glycosylation pathways. Additionally, in Chapter 6, we used such a quantitative proteomics dataset also to test the suitability of a previously suggested mass spectrometry-based method to discriminate O-GalNAc (Tn) versus O-GlcNAc, which led to the first site-specific identification of O-glycosylation of both intracellular and secreted anterior gradient protein 2 (AGR2). Show less
