All living organisms are made out of cells, which serve as the fundamental units of life. Protein molecules, comprised of amino acids, carry out diverse functions across various cellular... Show moreAll living organisms are made out of cells, which serve as the fundamental units of life. Protein molecules, comprised of amino acids, carry out diverse functions across various cellular compartments. Proteins are tightly controlled in their synthesis, folding, localization and degradation to ensure proper functioning. Dysregulation of protein control mechanisms within the cell can lead to cellular dysfunction, disease or eventually cell death. Post-translational modifications (PTMs) are the addition of a chemical group to an existing protein to regulate its function, localization, stability or interaction. In this thesis we will dive deeper into PTMs SUMO and ubiquitin, with the aim to understand the biochemistry of these proteins in different aspects of cellular function and human pathophysiology. An interesting aspect of the conjugation process lies in its reversibility, which is governed by specific proteases known as SENPs in the case of SUMO. However, only SENP6 and SENP7 have the ability to depolymerize SUMO2/3 chains by an insertion in their conserved catalytic domains. We delve into the promising horizon that lies ahead of a small yet profoundly impactful post-translational modifying protein. Despite its modest size, this protein wields a significant influence on fundamental cellular processes Show less
There is a need for alternative methods to replace, reduce and refine (3R) animal experimentation. Combining experimental data from high-throughput in vitro studies with in silico modeling is a... Show moreThere is a need for alternative methods to replace, reduce and refine (3R) animal experimentation. Combining experimental data from high-throughput in vitro studies with in silico modeling is a promising approach to unravel the effect of chemicals on living cells and to gain a better understanding of the processes leading to adverse effects. Exposure to chemicals can activate various stress response pathways that limit the amount of cellular damage, help cells to recover or orchestrate irreversible cell fates such as apoptosis. In this thesis, we use experimental data and current knowledge on stress pathway activation and cell fate to create different types of computational models. With these models, we mathematically describe intracellular protein signaling cascades activated upon exposure to various compounds and their link to cell fate. In this way, we integrate molecular-level biological processes to cell-level phenomena such as cell cycle progression, senescence and necrosis, and generate new hypotheses about the mechanisms underlying adversity. Show less
Temviriyanukul, P.; Hees-Stuivenberg, S. van; Delbos, F.; Jacobs, H.; Wind, N. de; Jansen, J.G. 2012
