Nicotinamide adenine dinucleotide (NAD+) is the substrate used for the introduction of the ubiquitous and highly dynamic PTM in which either one or multiple adenosine diphosphate ribose (ADPr)... Show moreNicotinamide adenine dinucleotide (NAD+) is the substrate used for the introduction of the ubiquitous and highly dynamic PTM in which either one or multiple adenosine diphosphate ribose (ADPr) moieties are covalently attached to a nucleophilic side chain of an specific amino acid in the target protein to regulate cellular pathways including adipogenesis, DNA damage repair and gene expression. A significant fraction of the nucleophilic amino acid functionalities, most recently histidine and tyrosine, have been identified as ADPr-acceptor sites. In this thesis, new methodologies have been developed to synthesize peptide fragments carrying an ADPr modification to investigate ADP-ribosylation on histidine. Show less
The endocannabinoid receptors CB1R and CB2R are involved in a plethora of processes, and consequently are involved in many pathological conditions. Their wide distribution makes the CBRs both an... Show moreThe endocannabinoid receptors CB1R and CB2R are involved in a plethora of processes, and consequently are involved in many pathological conditions. Their wide distribution makes the CBRs both an interesting therapeutic target and hard to study. Additional chemical tools are required to study and understand the function and mechanism of CB1R and CB2R. This thesis describes the development of several such tools to improve our insight in the (pathological) roles of the receptors in order to develop novel and improved therapeutics. First evaluation of three dimensional ligand-CB2R complexes made and analysed with Cryo-EM are described. Hotspots that potentially generate selectivity between CB1R and CB2R are evaluated with point-mutations in vitro. Consequently describes the development of the first tools, two-step bifunctional probes based on LEI-121 and LEI 102, is described. As two-step probes are not compatible with every assay, the toolbox is expanded with a one-step fluorescent probe. Briefly touching upon CB1R, ligands were designed with negatively charged phosphonium groups that are potentially selective for mtCB1R. Show less
Diacylglycerol lipases (DAGLα and DAGLβ) are responsible for the biosynthesis of the endocannabinoid 2-arachidonoylglycerol (2-AG) in the brain and peripheral tissues. Selective DAGLβ inhibitors... Show moreDiacylglycerol lipases (DAGLα and DAGLβ) are responsible for the biosynthesis of the endocannabinoid 2-arachidonoylglycerol (2-AG) in the brain and peripheral tissues. Selective DAGLβ inhibitors have been proposed as a potential treatment for inflammatory diseases with reduced potential for central nervous system (CNS) mediated side effects, but they are currently lacking. To develop DAGLβ selective inhibitors, a fluorescent biochemical assay was optimized and applied in a high-throughput screening (HTS) for DAGLβ. During the HTS, eight hits classified into four distinct chemotypes were identified. Subsequent structure-activity relationship (SAR) studies, focusing on hit 1 and its modifications, revealed a specific group as the modification hotspot crucial for achieving selectivity towards DAGLβ. Through an extensive SAR investigation, focusing on modifying this group, the first-in-class DAGLβ selective inhibitors, LEI-130 and LEI-131, were discovered. Following their discovery, LEI-130 and LEI-131 underwent comprehensive in vitro and in situ profiling studies. These investigations confirmed that LEI-130 and LEI-131 are selective and noncompetitive inhibitors of DAGLβ, effectively reducing inflammation. Show less
This thesis introduces the concept of "physics-based inverse design", working on the notion that the physical driving forces governing functionality are inherently encoded in independently... Show moreThis thesis introduces the concept of "physics-based inverse design", working on the notion that the physical driving forces governing functionality are inherently encoded in independently parameterized energy functions, which can be resolved through the use of inverse design strategies.The thesis describes the development of EVO-MD, a Python-based implementation of the physics-based inverse design concept. EVO-MD is capable of automatically setting-up, performing, and analyzing molecular dynamics simulations, allowing for the evolutionary optimization of complex and dynamic features in peptides. Examples of such applications include the optimization of lipid composition and curvature sensors, and the development of peptides with antiviral properties. Show less
In the current global context, there is a pressing need to address sustainable energy supplies to safeguard our Planet and its ecosystems. The choices made by human society have a significant... Show moreIn the current global context, there is a pressing need to address sustainable energy supplies to safeguard our Planet and its ecosystems. The choices made by human society have a significant impact on genetic evolution and climate. To ensure a better future for all, it is crucial to exercise foresight, foster collaboration across various sectors, and reach agreements based on fair and ethical principles. Science plays a pivotal role in advancing energy conversion, offering the potential for significant scientific breakthroughs that contribute to the protection and respect of our World. Specifically, the development of solar-to-fuel devices holds promise for achieving this transition to green energy. This Ph.D. dissertation centers on the development and functionalization of 2D membranes and materials, which constitute integral components of these conversion devices. The optimization of functionalized 2D materials necessitates a comprehensive computational design approach. This involves the adoption of a multiscale computational framework for the thorough design of these materials and the precise prediction and understanding of molecular processes, encompassing molecular self-assembly, ion transport, and catalytic surface reactions. Show less
The research presented in this thesis explores the chemotherapeutic potential of metal-based compounds as chemotherapy agents, with an initial focus on the synthesis and DNA interaction studies of... Show moreThe research presented in this thesis explores the chemotherapeutic potential of metal-based compounds as chemotherapy agents, with an initial focus on the synthesis and DNA interaction studies of platinum and palladium compounds utilizing the [Pt(bapbpy)]2+ scaffold. The study identifies intercalation as the primary mechanism of action for these complexes. Furthermore, it provides a detailed structure-activity relationship analysis, highlighting the critical role of the complex's protonation state in influencing its biological activity and efficacy. Subsequently, the study delves into photoactivated chemotherapy (PACT) using ruthenium (II) complexes, where light activation of ruthenium complexes enables targeted drug delivery to tumor cells, thereby reducing adverse effects. This research emphasizes the development of ruthenium-based compounds that can photorelease a DNA repair inhibitor, specifically targeting the RAD51 protein, essential for Homologous Recombination (HR). By disrupting the DNA repair mechanisms in cancer cells, this approach seeks to enhance the cytotoxicity of the therapy and address drug resistance. Show less
The research aims to explore the evolutionary adaptability of enzymes and the impact of temperature on protein evolution pathways, using M. tuberculosis β-lactamase BlaC as the object of study.... Show moreThe research aims to explore the evolutionary adaptability of enzymes and the impact of temperature on protein evolution pathways, using M. tuberculosis β-lactamase BlaC as the object of study. Enzymes inherently embody a delicate balance between activity and stability, and the acquisition of new enzymatic functions is often accompanied by trade-offs, such as decreased stability or reduction of the original activity. Probing evolutionary adaptability of BlaC with laboratory evolution in combination with structural characterization can provide information about the mechanisms of rapid adaptations observed for β-lactamases in the clinic. The role of temperature as a conventional selection pressure in such evolutionary adaptation is unclear. The cooperative nature of enzyme unfolding over a narrow temperature trajectory raises the question whether evolution at temperatures well below the melting point is influenced by temperature. The approach used in this work to answer these questions is by simulating evolution under different selection pressures and characterize the variant enzymes in terms of activity, structure, dynamics and melting temperature. The research makes clear how enzyme kinetics and dynamics vary with different selection pressures and maps the evolutionary path that enzymes may take. The underlying structural mechanisms are established to provide a rationale for the observed effects. Show less
This work describes the use of click-to-release chemistry to get spatiotemporal control over immunocytokine activity. Until now, immunocytokines (cytokines coupled to a tumor-targeting-moiety)... Show moreThis work describes the use of click-to-release chemistry to get spatiotemporal control over immunocytokine activity. Until now, immunocytokines (cytokines coupled to a tumor-targeting-moiety) remained active throughout the body, being able to bind their respective receptors, causing mild to severe side-effects in cancer patients. Attempts have been made to improve the specific action of these immunocytokines, but these solutions remained very cytokine-specific and toxicity was not reduced significantly. Click-to-release chemistry allows us to inactivate a cytokine by blocking its free amines, present in lysines. This prevents the cytokine, IL-1β and TNF-α in particular, from binding its receptor. Removal of the blocking agent using a tetrazine restores the native amine and for IL-1β also its activity. By coupling the blocked cytokine to a targeting moiety allows for transport to the target, the tumor(-environment) upon which the unblocking or decaging can take place. This blocking-unblocking or caging-decaging was assessed using various cell-based assay. This technique can provide new opportunities in the immunocytokine field, as it is not cytokine-specific, and thereby opportunities in cancer therapy development. Show less
In this thesis, we consider various (electro)chemical phenomena at surfaces and nanoparticles and their underlying atomistic processes, which we studied using first-principles methods such as... Show moreIn this thesis, we consider various (electro)chemical phenomena at surfaces and nanoparticles and their underlying atomistic processes, which we studied using first-principles methods such as density functional theory. These phenomena range from CO2 reduction to C2 and C3 species, through solvation of adsorbates on various surface features of late transition metals, to the impact of graphene on hydrogen evolution reaction, cathodic corrosion and surface oxidation of Pt. With our thermodynamic and kinetic calculations, we provide explanations for experimental observations by unraveling underlying phenomena, support novel computational methods and techniques, and propose new atomic structures that explain prior findings and provide inroads into future electrocatalytic research. Show less
Global healthcare is on the verge of an antibiotic availability crisis as bacteria have evolved resistance to nearly all known antibacterials. Identifying new antibiotics that operate via novel... Show moreGlobal healthcare is on the verge of an antibiotic availability crisis as bacteria have evolved resistance to nearly all known antibacterials. Identifying new antibiotics that operate via novel modes-of-action is therefore of high priority.This thesis contains two drug discovery projects, originating from a antibacterial screen of a compound library. In both projects chemical hits are first structurally optimized, after which their mode-of-action is determined.The first project entails optimizing a hit with potency against MRSA into a submicromolar active antibiotic. By using a chemical proteomics approach, the targets of this compound were elucidated, along with the targets that are most important in its antibacterial activity.The second project concerns Gram-negative bacteria, where a hit molecule is optimized into the conformationally restricted LEI-800. The target of LEI-800 is found to be DNA gyrase, a common antibiotic target. However, it is that LEI-800 inhibits DNA gyrase differently, and more potently, than the status quo. Show less
This thesis focuses on the application of lipid-based nanomedicine in drug delivery, including small molecular antitumor drugs and biomacromolecules including mRNA, and evaluates their biological... Show moreThis thesis focuses on the application of lipid-based nanomedicine in drug delivery, including small molecular antitumor drugs and biomacromolecules including mRNA, and evaluates their biological performance. We have modified liposomes and LNPs with fusogenic coiled-coil peptides to enhance the drug/mRNA delivery efficiency (Chapter 2-4), and also investigated how the lipid composition of LNPs influences the immune response (Chapter 5). Show less
To design the ideal water oxidation catalyst, understanding of the catalytic mechanism and decomposition pathways is essential. The aim of the research described in this thesis is to provide... Show moreTo design the ideal water oxidation catalyst, understanding of the catalytic mechanism and decomposition pathways is essential. The aim of the research described in this thesis is to provide mechanistic insight on the water oxidation reaction catalyzed by homogeneous electrocatalysts and topostulate design criteria for the ideal water oxidation catalyst. Show less
Supramolecular polymers are class of materials that are formed by non-covalent interactions such as hydrogen bonding, π-π interactions, electrostatic interactions and the hydrophobic effect. The... Show moreSupramolecular polymers are class of materials that are formed by non-covalent interactions such as hydrogen bonding, π-π interactions, electrostatic interactions and the hydrophobic effect. The design and development of supramolecular polymers in aqueous solution gained a particular attention for the wide variety of applications in the biomedical field. In water, the self-assembly of well-defined nanostructures is mainly determined by the combination of hydrophobic effect with hydrogen bonding interactions in the monomer design. When squaramide-based monomer self-assemble, the formation of stable nanostructures in water is determined by the formation of directional hydrogen bonds which are strengthened by the partial aromatic character of the squaramide. In this thesis, the self-assembly properties of a panel of squaramide-based monomers is examined in aqueous solution through modulating the monomer chemical structure, co-assembly and introduction of light responsive chemistries. Show less
Ice, the solid state of water, plays an important role on our planet as well as the entire universe.Despite the fact that an individual water molecule has a very simple structure, its chemical... Show moreIce, the solid state of water, plays an important role on our planet as well as the entire universe.Despite the fact that an individual water molecule has a very simple structure, its chemical bonding in the solid phase can be surprisingly complex.Nowadays, atomistic computational models allow to describing and understanding these properties in a way that has not been possible for a long time.Chemical interactional potentials are at the heart of these atomistic models.In increasing order of complexity, these potentials range from simple pair potentials over polarizable force fields up to density functional theory (DFT).It is an ongoing scientific challenge is to improve and test these potentials.This thesis attempts to provide some answers to the following research questions:(i) How important is the contribution of zero-point energy to thermodynamical properties of ice phases?(ii) How accurately do available interaction potentials allow to model (small) differences between H2O and D2O ices related to nuclear quantum effects?(iii) Do interaction potentials need to be improved when nuclear quantum effects in ice are taken into account? Show less
Het proefschrift omschrijft de chemische synthese van fenolische glycolipiden van verschillende mycobacteriën met het doel om deze te kunnen gebruiken voor immunologisch onderzoek.
Glycoside hydrolases (glycosidases/GHs) are widely abundant enzymes in all kingdoms of life and are important biocatalysts that catalyze the hydrolysis of glycosidic linkages in oligo... Show moreGlycoside hydrolases (glycosidases/GHs) are widely abundant enzymes in all kingdoms of life and are important biocatalysts that catalyze the hydrolysis of glycosidic linkages in oligo/polysaccharides, glycoproteins and glycolipids with tremendous efficiency. Abnormal glycosidase activity is intimately associated with a variety of human diseases. Overexpression of heparanase, for example, is implicated in almost all cancers examined, and correlates with increased tumor size, tumor angiogenesis, enhanced metastasis and poor prognosis. Specific inhibitors of glycosidases are of great value, not only because they can serve as useful biological tools to study the catalytic machinery, mechanism and itinerary of target enzymes by crystal structure analysis of (covalent) inhibitor-enzyme complexes, but also because they may act as starting points for the development of therapeutic drugs for the treatment of glycosidase-mediated diseases. Additionally, covalent mechanism-based inhibitors have been used as scaffolds for the development of activity-based probes (ABPs) which allow profiling of glycosidases in complex biological systems. The research described in this dissertation focus on the development and biochemical evaluation of covalent inhibitors and ABPs for retaining endo- and exo-glycosidases including starch-degrading enzymes and human lysosomal β-glucocerebrosidase (GBA), as well as the synthesis of a panel of uronic acid-type 1-N-iminosugars as potential competitive heparanase inhibitors. Show less
The spindle-assembly checkpoint (SAC) is a safety mechanism which secures accurate chromosome segregation during mitosis. BUB1, a serine/threonine kinase, is one of the proteins involved in this... Show moreThe spindle-assembly checkpoint (SAC) is a safety mechanism which secures accurate chromosome segregation during mitosis. BUB1, a serine/threonine kinase, is one of the proteins involved in this checkpoint and its inhibition is thought to have therapeutic potential for the treatment of cancer. Although the exact role of BUB1 in the SAC remains controversial, inhibition of its kinase function has previously been shown to reduce tumor size in mouse xenograft models when combined with paclitaxel. The research described in this thesis aimed to develop novel BUB1 kinase inhibitors for which high-throughput screening was used as starting point for drug discovery. Medicinal chemistry efforts were performed to improve potency after which the obtained inhibitors were further evaluated in cellular assays. In addition, the development of a cellular BUB1 target engagement assay is described. Hit optimization led to the discovery of two lead compounds with good physicochemical properties, subnanomolar affinity for BUB1, good cellular BUB1 target engagement, acceptable selectivity over other kinases and a favorable in vitro ADME profile. Show less
Artificial photosynthesis has recognised potential to produce green and sustainable fuels from earth-abundant resources such as water, carbon dioxide (CO2), and sunlight. In an artificial... Show moreArtificial photosynthesis has recognised potential to produce green and sustainable fuels from earth-abundant resources such as water, carbon dioxide (CO2), and sunlight. In an artificial photosynthetic system, two half-reactions, such as water oxidation and proton reduction or CO2 reduction, have to be combined. To achieve such a system, it is crucial to have: a) efficient light-harvesting by the photosensitiser, b) stable catalysts for the oxidation and the reduction reaction, c) unidirectional proton and electron transport between the oxidation and the reduction site, ideally by a recyclable electron relay, d) efficient charge separation, and e) a strong, photostable membrane that does not leak molecular components. In natural photosynthesis, these requirements are achieved altogether using compartmentalisation, which consists in embedding the key components of the system, i.e. for green plants the oxygen evolving complex, photosystem I and II, and the natural electron relays, around the lipid bilayer of the thylakoid membrane. The use of spherical lipid membranes (such as liposomes) as biological mimics of the thylakoid membrane is a promising approach to confine half-reactions, facilitate charge separation, and avoid charge recombination and other undesired side-reactions. In the research described in this thesis, it was attempted to realise a full artificial photosynthetic system based on liposomes and several of the key intermediate steps were achieved: 1) unidirectional electron transfer across a liposomal membrane from an electron donor encapsulated in the interior of the liposome to an electron acceptor located outside (Chapter 2), and 2) photocatalytic reduction of CO2 (Chapter 3) and of protons (Chapter 4) at the surface of liposomes. Special attention was paid in Chapter 2 and Chapter 5 to the question of the (photo)stability of the membrane and light-induced leakage. Show less
This thesis presents the first synthetic peptides ADP-ribosylated on serine, threonine, tyrosine, arginine and cysteine. Besides synthetic peptides, this thesis discusses the first synthetic route... Show moreThis thesis presents the first synthetic peptides ADP-ribosylated on serine, threonine, tyrosine, arginine and cysteine. Besides synthetic peptides, this thesis discusses the first synthetic route towards ADP-ribosylated nucleic acids. Furthermore, two photoaffinity probes for PARP1 have been developed and assessed in living cells and two activity based probes have been synthesized, designed for CD38. Show less
The redox-conversion reaction of metal-disulfide and metal-thiolate complexes are important, as they may shed light on electron-transfer reactions that often occur in Nature. Despite their... Show moreThe redox-conversion reaction of metal-disulfide and metal-thiolate complexes are important, as they may shed light on electron-transfer reactions that often occur in Nature. Despite their importance, very few examples have been reported. In addition to that, there is a limited understanding of how the coordination environment of the metal ion affects this reaction. In this thesis, our investigation was set based on the ligand-field theory to determine its correlation with the redox-conversion reactions in cobalt-based systems. Our experiments revealed that using an exogenous ligand with a strong ligand-field character may induce the redox conversion from cobalt(II)-disulfide complexes to cobalt(III)-thiolate complexes. Using this knowledge, the possibility of the redox-conversion reaction was also extended from cobalt(II)-diselenide to cobalt(III)-selenolate complexes.Finally, we have come up with several conclusions about the redox-conversion reactions of the cobalt(II)-dichalcogenide complexes. It was revealed that the conversion is affected by the ligand-field strength of the dichalcogenide ligand. The smaller ligand-field strength can be counterbalanced with the introduction of the strong auxiliary ligand. Lastly, the cleanliness of the conversion depends on the magnitude of the overall ligand-field splitting energy of the complex. Show less