The studies presented in the work show the potential of the integrative use of biophysical data in defining the structural basis of protein interactions. Even if the results obtained hold a... Show moreThe studies presented in the work show the potential of the integrative use of biophysical data in defining the structural basis of protein interactions. Even if the results obtained hold a degree of ambiguity, this approach allows to iteratively refine and validate the model and interpret its meaning for the molecular basis of protein function. Often all three points at the same time. This dynamic nature makes the use of structural models in the design of therapeutic compounds especially useful since the inhibition of a certain protein function might not require a structure to be accurate down to the last atom but rather highlight key interactions or structural features that can be addressed in context of small molecule or peptide inhibitors. Presented are the use of strucutral biochemistry techniques to investigate the mechanism of how the ubiquitine ligase PSIP1 obtains its target specificity. Furthermore, another epigenetic effector protein PSIP1 is investigated with the aim to develop a workflow for the design of potential peptide-based inhibitors. Show less
In human cells, a meter-long DNA is condensed inside a micrometer-sized cell nucleus. Simultaneously, the genetic code must remain accessible for its replication and transcription to functional... Show moreIn human cells, a meter-long DNA is condensed inside a micrometer-sized cell nucleus. Simultaneously, the genetic code must remain accessible for its replication and transcription to functional proteins. Such plasticity of the genome is maintained by dynamic folding and unfolding of DNA-protein spools called nucleosomes. It is unclear, however, how this process is controlled when multiple nucleosomes stack on top of each other and form compact chromatin fibers. This is particularly important since nucleosomes are rarely present in isolation inside a densely packed cell nucleus. Therefore, the aim of this thesis was to increase the understanding of the chromatin fiber structure and its dynamics. Knowing these details would provide many new insights into the mechanisms of gene expression (epigenetic regulation) which, upon malfunction, may cause severe diseases. The presented work consists of an experimental approach involving the application of single-molecule force spectroscopy, and makes use of theoretical modelling based on statistical mechanics. By using magnetic tweezers, we stretched and twisted individual chromatin fibers reconstituted in vitro in order to unfold its nucleosomes. These studies show that folding of nucleosomes into chromatin fibers opens up a plethora of regulatory pathways for controlling the level of DNA organization in cells. Show less
