Protein glycosylation has profound implications in a wide range of molecular and biological processes occurring in cancer, where specific changes in the glycan structures have shown to be... Show moreProtein glycosylation has profound implications in a wide range of molecular and biological processes occurring in cancer, where specific changes in the glycan structures have shown to be associated with the development and progression of the disease paving the way for the development of new clinical biomarkers as well as providing specific targets for therapeutic intervention, patient stratification and personalized medicine. Protein glycosylation is also critical for the development of biopharmaceuticals, as even minor shifts in manufacturing procedures can substantially impact the bioactivity, safety, and efficacy of therapeutic proteins. Although a variety of mass spectrometric and chromatographic methods are available for the identification and characterization of glycans from complex sample mixtures, the lack of standardized protocols across platforms often results in inconsistent results, making data integration and comparison challenging. Furthermore, most of the current technology for the study of intact glycans would not be suitable for the rapid analysis of large sample sets, mainly due to limitations in sample throughput. The scope of this thesis is to establish standardized, high-throughput glycomics technologies for the quantitative analysis of protein N- and O-glycosylation and improve current methodologies in order to facilitate the characterization of intact oligosaccharides from in vitro established model systems. Show less
Analytical assay development, particularly pertaining to glycomics, is an exciting amalgam of biology, chemistry and engineering. Besides academic research in natural and medical sciences,... Show moreAnalytical assay development, particularly pertaining to glycomics, is an exciting amalgam of biology, chemistry and engineering. Besides academic research in natural and medical sciences, glycomics assays have immense importance in industrial applications such as in quality control and quality assurance of glycoproteins. An up-coming industrial and clinical application is the high-throughput glycan profiling of clinical samples, such as plasma, for identifying disease associations. These glycomics assays are often based on chromatographic and mass spectrometric instrumentation. Thus, they create a requirement of instrumentation infrastructure as well as technical skills which are both not always readily available. This creates a demand in industry for the development of glycomics assays that have a low infrastructure cost as well as minimal training requirements and that are user-friendly. With these objectives in focus, this thesis develops novel exoglycosidase-based high-throughput glycomics assays for use in industrial glycan profiling. In doing so, this thesis also contributes to the development of potential products, such as glycomics kits. Show less
The challenge of achieving fast quantification in metabolomics is the presence of severe matrix effects during the MS analysis of complex samples. Complex samples also result in challenges during... Show moreThe challenge of achieving fast quantification in metabolomics is the presence of severe matrix effects during the MS analysis of complex samples. Complex samples also result in challenges during metabolite identification as complex MS/MS spectra and peak overlap in 1H NMR complicate structure elucidation. The goal of this thesis is to tackle these challenges by the development and application of innovative fractionation approaches and state-of-the-art MS and NMR analyses. Show less
This dissertation describes the development of glyco-bioinformatics tools that facilitate the high-throughput data processing of glycomics and glycoproteomics experiments, specifically for both... Show moreThis dissertation describes the development of glyco-bioinformatics tools that facilitate the high-throughput data processing of glycomics and glycoproteomics experiments, specifically for both MALDI-TOF-MS (Chapter 2) and LC-ESI-MS (Chapter 3). The developed methods also provide various quality control parameters that assist the researcher in curating both the measured spectra and quantified analytes, thereby providing high-quality data in a high-throughput manner.The tools that were developed within this thesis have been used to identify the influence of glycosylation on trypsin efficacy of Immunoglobulin G (Chapter 3) and two biological cohorts. Specifically, to investigate the serum N-glycosylation during and after pregnancy (Chapter 5) and to identify the differences in the N-glycosylation between maternal and fetal serum and IgG (Chapter 6). Show less
