To advance our understanding of the histone acylation regulators and the response to DNA replication stress, we employ a variety of genetic screening techniques together with follow-up experiments... Show moreTo advance our understanding of the histone acylation regulators and the response to DNA replication stress, we employ a variety of genetic screening techniques together with follow-up experiments in yeast. By employing Epi-ID, we interrogated a common chromatin locus in the yeast deletion and DaMP collection. This was successful in identifying new histone acetylation and acylation regulators and we describe the crotonyltransferase activities of the ADA and NuA4 complexes. Increased crotonylation levels stimulated gene expression dependent on the activity of the HATs Gcn5 and Esa1, suggesting a role for these enzymes in the crotonylation-dependent transcriptional regulation. Additionally, extensive antibody validation studies revealed that non-acetyl pan-lysine specific acylation antibodies had a severe lack of specificity.To identify new regulators of replication stress, we developed a novel approach called Replication-Identifier (Repli-ID), which we used to investigate the accumulation of replicative polymerase ε near a barcoded origin of replication in mutant yeast collections. We demonstrate that this method is effective for studying DNA polymerase occupancy directly on chromatin and we identify new regulators of DNA replication fork progression/stability.Finally, we identify and characterize the Mediator complex in the replication stress response. We show how Mediator reduces replication stress by preventing R-loop formation. Show less
Epigenetic regulation of gene expression by chromatin modifiers is one of the fundamental cellular processes that allow the different cell types in the body to develop from the totipotent embryonic... Show moreEpigenetic regulation of gene expression by chromatin modifiers is one of the fundamental cellular processes that allow the different cell types in the body to develop from the totipotent embryonic stem cells. However, when this epigenetic control mechanism becomes compromised, such as by mutations in chromatin modifiers, it can lead to the development of disease. An example of such epigenetic disease is facioscapulohumeral muscular dystrophy (FSHD), in which the chromatin structure of the D4Z4 macrosatellite repeat is compromised. The loss of a repressive D4Z4 chromatin structure either by contraction of the repeat to a size of 1-10 D4Z4 units (FSHD1), or by mutations in D4Z4 chromatin repressors such as SMCHD1 (FSHD2), results in inappropriate expression of the DUX4 gene from the repeat in skeletal muscle, which is considered the root cause of FSHD.In FSHD, DUX4 expression causes apoptosis, leading to muscle wasting in the patient. In this thesis, we studied the functionality of SMCHD1, and aimed to understand the DUX4 repressive processes in which SMCHD1 is involved. Furthermore, we gathered information on the different roles that SMCHD1 fulfills, such as X-chromosome inactivation in female cells and telomere maintenance. Show less
Melanoma is the most aggressive and lethal type of skin cancer since it has the ability to spread to other organs in the body making it harder to control the disease.In this thesis, we aim to... Show moreMelanoma is the most aggressive and lethal type of skin cancer since it has the ability to spread to other organs in the body making it harder to control the disease.In this thesis, we aim to explore the degree to which epigenetics play a role in melanoma, namely, inherited and acquired epigenetic alterations in melanoma susceptibility and development. Show less
Cardiovascular disease (CVD) is the collective term for diseases that involve the heart or circulation and CVDs are a major cause of mortality and morbidity worldwide. The aim of thesis was to... Show moreCardiovascular disease (CVD) is the collective term for diseases that involve the heart or circulation and CVDs are a major cause of mortality and morbidity worldwide. The aim of thesis was to investigate the role of inflammation in CVD related cardiac and vascular remodelling, which may lead to potential therapeutic agents. We investigated the therapeutic potential of antibodies directed against phosphorylcholine (PC), an endogenous ligand capable of triggering the innate immune system, which is expressed by apoptotic cells and oxidized LDL, in mouse models for myocardial infarction (MI). We found that treatment with anti-PC antibodies reduces adverse cardiac remodelling after both permanent MI as myocardial ischemia reperfusion (MI-R) injury. Furthermore, we found that treatment with annexin A5 also reduces adverse cardiac remodelling after MI-R injury. Interestingly, both anti-PC as annexin A5 treatment reduced the post MI inflammatory response. Next, we investigated the role of PCAF, an inflammatory related epigenetic factor, in vascular remodelling. We found that PCAF deficiency and treatment with a PCAF inhibitor reduces adverse vascular remodelling. Finally, we investigated the role of microRNAs, small RNA molecules that can affect expression of many different gene simultaneously, in vascular remodelling. We show that inhibition of microRNA-495 reduces adverse vascular remodelling. Show less
Numerous studies have contributed to our current understanding of autoimmune diseases (AIDs), however, pathogenesis of many AIDs can still not be fully explained. Both genetic factors and... Show moreNumerous studies have contributed to our current understanding of autoimmune diseases (AIDs), however, pathogenesis of many AIDs can still not be fully explained. Both genetic factors and environmental factors are involved in the onset of autoimmunity. Which mechanisms explain the contribution of these genetic and environmental factors to disease pathogenesis, and how the different factors interplay remain unanswered key questions. The studies presented in this thesis aimed at identifying and unravelling some of the enigmatic mechanisms in rheumatoid arthritis (RA) and systemic sclerosis (SSc). Show less
In this thesis two diseases that share a common feature of hypomethylation of repetitive DNA are studied: facioscapulohumeral muscular dystrophy (FSHD) and immunodeficiency, centromeric... Show moreIn this thesis two diseases that share a common feature of hypomethylation of repetitive DNA are studied: facioscapulohumeral muscular dystrophy (FSHD) and immunodeficiency, centromeric instability, and facial anomalies (ICF) syndrome. In FSHD there is hypomethylation of the macrosatellite repeat D4Z4 and the associated DUX4 gene, which is caused by a repeat contraction and/or variants in chromatin modifiers essential for a repressive D4Z4 chromatin structure in somatic cells. In ICF there is hypomethylation of centromeric repeats, which is caused by recessive variants in one of four ICF genes, of which two are established chromatin modifiers. In this thesis, the mutation spectrum of FSHD and ICF has been expanded. The SMCHD1 mutation spectrum in FSHD2 has been expanded with the discovery of exonic SMCHD1 variants, intronic SMCHD1 variants, and whole SMCHD1 gene deletions. In addition, we identified heterozygous variants in a new FSHD2 gene, DNMT3B, in two FSHD2 families. For ICF syndrome we expanded the mutation spectrum in the two most common ICF genes, DNMT3B and ZBTB24. Show less
The work presented in this thesis provides important new clues on the neurobiology of juvenile psychopathic traits in clinically antisocial juveniles. The data specifically shows that these... Show moreThe work presented in this thesis provides important new clues on the neurobiology of juvenile psychopathic traits in clinically antisocial juveniles. The data specifically shows that these traits are ostensibly underpinned by highly specific corticolimbic network dysfunctions, in which amygdala subregional networks seem particularly relevant. That data additionally suggests that some of these network dysfunctions and their associated neurocognitive deficits are possibly driven by alterations in the oxytocinergic system. Interestingly, the data also provides preliminary neurobiological support for the scientific utility of using juvenile psychopathic traits to subtype the highly heterogeneous group of clinically antisocial teens. While these data may represent important new steps towards a deeper understanding of clinical youth antisociality, their significance has to be evaluated by replication studies that further explore and validate the findings presented here. Show less
In chapter 2, the pancreas was used as a paradigm to study human organ development and assess the quality of our fetal material. In a descriptive, histochemical study, we investigated how blood... Show moreIn chapter 2, the pancreas was used as a paradigm to study human organ development and assess the quality of our fetal material. In a descriptive, histochemical study, we investigated how blood and lymphatic vascular networks develop and their association with basement membranes and smooth muscle cells between gestational weeks 9 and 22 (W9 and W22). In Chapter 3, 4 and 5, we analyzed a total of 21 fetal organs and maternal endometrium at three time points (W9, W18 and W22) at the transcriptional and epigenetic level, thereby, providing an atlas of human organ development. The rare fetal material also allowed us to investigate the presence of an epigenetic memory from the cell of origin in induced pluripotent stem cells (iPSCs). We generated isogenic iPSC lines from six fetal organs (brain, skin, kidney, muscle, lung and pancreas) in chapter 5. The six iPSC lines had very similar DNA methylation profiles, however, we showed that the two clones derived from the brain harbored 18 hypermethylated and 6 hypomethylated CpGs also found in the fetal brain and we demonstrated that the brain-iPSC clones appeared to have a differentiation bias towards neural derivatives when comparing neural differentiation of the brain- and skin-iPSC clones. Show less
