Cells constitute the tissues of our body and are responsible for producing various changes in response to different situations. For instance, the repair of damaged DNA. DNA resides within the cell... Show moreCells constitute the tissues of our body and are responsible for producing various changes in response to different situations. For instance, the repair of damaged DNA. DNA resides within the cell nucleus and can be transcribed and translated into proteins, which play vital roles in numerous cellular processes. The cell relies on modifying existing proteins to carry out essential functions. These modifications can involve the conjugation of small molecules such as Ubiquitin (Ub) or Small Ubiquitin-like Modifiers (SUMOs), leading to protein degradation, conformational changes or intracellular relocation of critical proteins. The conjugation of these small molecules involves a well-orchestrated sequence of enzymatic activities performed by dedicated enzymes: E1 (activating), E2 (conjugating) and E3 (ligase). Among these, the E3 ligase enzymes hold significant importance as they confer substrate specificity.In this thesis, we have developed an advanced Mass-Spectrometry technology called TULIP2 (Targets for Ubiquitin Ligases Identified by Proteomics 2), which facilitates the identification of Ubiquitination targets for specific E3 ligases of interest. Using this technology, we have investigated the BRCA1-BARD1 E3 ligase and explore the in vivo role of the E2 UBE2D3. Furthermore, we have adapted the TULIP2 technology to create the SUMO Activated Target Traps (SATTs), enabling the identification of an E3-specific SUMO proteome. Show less
All cellular organisms contain genomic DNA which provides the instructions for their correct development and functioning. Damage to this DNA may interfere with critical cellular processes such as... Show moreAll cellular organisms contain genomic DNA which provides the instructions for their correct development and functioning. Damage to this DNA may interfere with critical cellular processes such as transcription and replication and has the potential to drive mutagenesis. In turn, this may underlie inherited disorders and accelerate progression of diseases such as cancer and neurodegenerative disorders. The protection of cells and organisms against these devastating effects of DNA damage relies on the DNA damage response (DDR), which comprises a complex network of signaling and repair pathways that coordinate the sensing, signaling and repair of DNA lesions while accommodating suitable adjustments in for instance chromatin structure and cell cycle progression. Not only does the DDR dictate the appropriate repair pathway for several types of DNA damage, including DNA double-strand breaks (DSB), it also modulates replication fork surveillance mechanisms in response to DNA replication stress (RS). While many core proteins have been studied in detail, the full repertoire of factors involved in these pathways remains unknown. Clearly, extending our knowledge on regulators of the DDR will contribute to our understanding of the development, and possibly the treatment, of the numerous disorders that are associated with defects in the DDR. The research described in this thesis has successfully identified and characterized novel factors in DSB repair and the RS response. Show less
This thesis aims to gain a better understanding of NER, to elucidate new molecular mechanisms and proteins that orchestrate how DNA repair is carried out on genomic DNA that is tightly packed in... Show moreThis thesis aims to gain a better understanding of NER, to elucidate new molecular mechanisms and proteins that orchestrate how DNA repair is carried out on genomic DNA that is tightly packed in chromatin inside the living cell. It is important to obtain a better clinical picture of how inherited defects in DNA repair genes shapes phenotypes in patients with DNA repair-deficiency disorders. Show less
Cells in the human body have to deal with DNA damage daily, either caused by external or internal sources. The DDR is particularly strong in stem cells. Since these cells have a long life span and... Show moreCells in the human body have to deal with DNA damage daily, either caused by external or internal sources. The DDR is particularly strong in stem cells. Since these cells have a long life span and are essential for tissue homeostasis, tolerance to damaged DNA would lead to accumulation of mutations and malignant transformation. In addition, accumulation of damaged DNA would lead to loss of the stem cell pool and contribute to aging. In this thesis I investigated the role of the DNA damage response in the context of stem cells as well as cancer cells, from the response to different DNA damaging agents, to the importance of the interaction with the extracellular matrix in combination with the presence of oncogenes. In order to acquire a complete picture of the DNA damage response in mES cells, and therefore elucidate novel pathways involved in this particular response, we combined OMICS techniques such as Functional Genomics, Transcriptomics and Phosphoprotoemics, that once overlapped, allowed us to find novel pathways that where not previously described to be involved in the DNA damage response. Show less
