@phdthesis{Dindar2014, author = {Dindar, G{\"u}lcin}, title = {Molecular basis for product-specificity of DOT1 methyltransferases in Trypanosoma brucei}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-102524}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {Post-translational histone modifications (PTMs) such as methylation of lysine residues influence chromatin structure and function. PTMs are involved in different cellular processes such as DNA replication, transcription and cell differentiation. Deregulations of PTM patterns are responsible for a variety of human diseases including acute leukemia. DOT1 enzymes are highly conserved histone methyltransferases that are responsible for methylation of lysine 79 on histone H3 (H3K79). Most eukaryotes contain one single DOT1 enzyme, whereas African trypanosomes have two homologues, DOT1A and DOT1B, which methylate H3K76 (H3K76 is homologous to H3K79 in other organisms). DOT1A is essential and mediates mono- and di-methylations, whereas DOT1B additionally catalyzes tri-methylation of H3K76. However, a mechanistic understanding how these different enzymatic activities are achieved is lacking. This thesis exploits the fact that trypanosomes possess two DOT1 enzymes with different catalytic properties to understand the molecular basis for the differential product-specificity of DOT1 enzymes. A trypanosomal nucleosome reconstitution system was established to analyze methyltransferase activity under defined in vitro conditions. Homology modeling allowed the identification of critical residues within and outside the catalytic center that modulate product-specificity. Exchange of these residues transferred the product-specificity from one enzyme to the other and revealed regulatory domains adjacent to the catalytic center. This work provides the first evidence that few specific residues in DOT1 enzymes are crucial to catalyze methyl-state-specific reactions. These results have also consequences for the functional understanding of homologous enzymes in other eukaryotes.}, subject = {Histon-Methyltransferase}, language = {en} } @phdthesis{Eisenhuth2021, author = {Eisenhuth, Nicole Juliana}, title = {Novel and conserved roles of the histone methyltransferase DOT1B in trypanosomatid parasites}, doi = {10.25972/OPUS-21993}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-219936}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {The family of trypanosomatid parasites, including the human pathogens Trypanosoma brucei and Leishmania, has evolved sophisticated strategies to survive in harmful host environments. While Leishmania generate a safe niche inside the host's macrophages, Trypanosoma brucei lives extracellularly in the mammalian bloodstream, where it is constantly exposed to the attack of the immune system. Trypanosoma brucei ensures its survival by periodically changing its protective surface coat in a process known as antigenic variation. The surface coat is composed of one species of 'variant surface glycoprotein' (VSG). Even though the genome possesses a large repertoire of different VSG isoforms, only one is ever expressed at a time from one out of the 15 specialized subtelomeric 'expression sites' (ES). Switching the coat can be accomplished either by a recombination-based exchange of the actively-expressed VSG with a silent VSG, or by a transcriptional switch to a previously silent ES. The conserved histone methyltransferase DOT1B methylates histone H3 on lysine 76 and is involved in ES regulation in T. brucei. DOT1B ensures accurate transcriptional silencing of the inactive ES VSGs and influences the kinetics of a transcriptional switch. The molecular machinery that enables DOT1B to execute these regulatory functions at the ES is still elusive, however. To learn more about DOT1B-mediated regulatory processes, I wanted to identify DOT1B-associated proteins. Using two complementary approaches, specifically affinity purification and proximity-dependent biotin identification (BioID), I identified several novel DOT1B-interacting candidates. To validate these data, I carried out reciprocal co-immunoprecipitations with the most promising candidates. An interaction of DOT1B with the Ribonuclease H2 protein complex, which has never been described before in any other organism, was confirmed. Trypanosomal Ribonuclease H2 maintains genome integrity by resolving RNA-DNA hybrids, structures that if not properly processed might initiate antigenic variation. I then investigated DOT1B's contribution to this novel route to antigenic variation. Remarkably, DOT1B depletion caused an increased RNA-DNA hybrid abundance, accumulation of DNA damage, and increased VSG switching. Deregulation of VSGs from throughout the silent repertoire was observed, indicating that recombination-based switching events occurred. Encouragingly, the pattern of deregulated VSGs was similar to that seen in Ribonuclease H2-depleted cells. Together these data support the hypothesis that both proteins act together in modulating RNA-DNA hybrids to contribute to the tightly-regulated process of antigenic variation. The transmission of trypanosomatid parasites to mammalian hosts is facilitated by insect vectors. Parasites need to adapt to the extremely different environments encountered during transmission. To ensure their survival, they differentiate into various specialized forms adapted to each tissue microenvironment. Besides antigenic variation, DOT1B additionally affects the developmental differentiation from the mammalian-infective to the insect stage of Trypanosoma brucei. However, substantially less is known about the influence of chromatin-associated proteins such as DOT1B on survival and adaptation strategies of related Leishmania parasites. To elucidate whether DOT1B's functions are conserved in Leishmania, phenotypes after gene deletion were analyzed. As in Trypanosoma brucei, generation of a gene deletion mutant demonstrated that DOT1B is not essential for the cell viability in vitro. DOT1B deletion was accompanied with a loss of histone H3 lysine 73 trimethylation (the lysine homologous to trypanosomal H3K76), indicating that Leishmania DOT1B is also solely responsible for catalyzing this post-translational modification. As in T. brucei, dimethylation could only be observed during mitosis/cytokinesis, while trimethylation was detectable throughout the cell cycle in wild-type cells. In contrast to the trypanosome DOT1B, LmxDOT1B was not essential for differentiation in vitro. However, preliminary data indicate that the enzyme is required for effective macrophage infection. In conclusion, this study demonstrated that the identification of protein networks and the characterization of protein functions of orthologous proteins from related parasites are effective tools to improve our understanding of the parasite survival strategies. Such insights are a necessary step on the road to developing better treatments for the devastating diseases they cause.}, subject = {Trypanosoma brucei}, language = {en} } @phdthesis{FetivaMora2023, author = {Fetiva Mora, Maria Camila}, title = {Changes in chromatin accessibility by oncogenic YAP and its relevance for regulation of cell cycle gene expression and cell migration}, doi = {10.25972/OPUS-30291}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-302910}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {Various types of cancer involve aberrant cell cycle regulation. Among the pathways responsible for tumor growth, the YAP oncogene, a key downstream effector of the Hippo pathway, is responsible for oncogenic processes including cell proliferation, and metastasis by controlling the expression of cell cycle genes. In turn, the MMB multiprotein complex (which is formed when B-MYB binds to the MuvB core) is a master regulator of mitotic gene expression, which has also been associated with cancer. Previously, our laboratory identified a novel crosstalk between the MMB-complex and YAP. By binding to enhancers of MMB target genes and promoting B-MYB binding to promoters, YAP and MMB co-regulate a set of mitotic and cytokinetic target genes which promote cell proliferation. This doctoral thesis addresses the mechanisms of YAP and MMB mediated transcription, and it characterizes the role of YAP regulated enhancers in transcription of cell cycle genes. The results reported in this thesis indicate that expression of constitutively active, oncogenic YAP5SA leads to widespread changes in chromatin accessibility in untransformed human MCF10A cells. ATAC-seq identified that newly accessible and active regions include YAP-bound enhancers, while the MMB-bound promoters were found to be already accessible and remain open during YAP induction. By means of CRISPR-interference (CRISPRi) and chromatin immuniprecipitation (ChIP), we identified a role of YAP-bound enhancers in recruitment of CDK7 to MMB-regulated promoters and in RNA Pol II driven transcriptional initiation and elongation of G2/M genes. Moreover, by interfering with the YAP-B-MYB protein interaction, we can show that binding of YAP to B-MYB is also critical for the initiation of transcription at MMB-regulated genes. Unexpectedly, overexpression of YAP5SA also leads to less accessible chromatin regions or chromatin closing. Motif analysis revealed that the newly closed regions contain binding motifs for the p53 family of transcription factors. Interestingly, chromatin closing by YAP is linked to the reduced expression and loss of chromatin-binding of the p53 family member Np63. Furthermore, I demonstrate that downregulation of Np63 following expression of YAP is a key step in driving cellular migration. Together, the findings of this thesis provide insights into the role of YAP in the chromatin changes that contribute to the oncogenic activities of YAP. The overexpression of YAP5SA not only leads to the opening of chromatin at YAP-bound enhancers which together with the MMB complex stimulate the expression of G2/M genes, but also promotes the closing of chromatin at ∆Np63 -bound regions in order to lead to cell migration.}, subject = {Chromatin}, language = {en} } @phdthesis{Kraus2021, author = {Kraus, Amelie Johanna}, title = {H2A.Z - a molecular guardian of RNA polymerase II transcription in African trypanosomes}, doi = {10.25972/OPUS-25056}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-250568}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {In eukaryotes, the enormously long DNA molecules need to be packaged together with histone proteins into nucleosomes and further into compact chromatin structures to fit it into the nucleus. This nuclear organisation interferes with all phases of transcription that require the polymerase to bind to DNA. During transcription - the process in which the hereditary information stored in DNA is transferred to many transportable RNA molecules - nucleosomes form a physical obstacle for polymerase progression. Thus, transcription is usually accompanied by processes mediating nucleosome destabilisation, including post-translational histone modifications (PTMs) or exchange of canonical histones by their variant forms. To the best of our knowledge, acetylation of histones has the highest capability to induce chromatin opening. The lysine modification can destabilise histone-DNA interactions within a nucleosome and can serve as a binding site for various chromatin remodelers that can modify the nucleosome composition. For example, H4 acetylation can impede chromatin folding and can stimulate the exchange of canonical H2A histone by its variant form H2A.Z at transcription start sites (TSSs) in many eukaryotes, including humans. As histone H4, H2A.Z can be post-translationally acetylated and as acetylated H4, acetylated H2A.Z is enriched at TSSs suggested to be critical for transcription. However, thus far, it has been difficult to study the cause and consequence of H2A.Z acetylation. Even though, genome-wide chromatin profiling studies such as ChIP-seq have already revealed the genomic localisation of many histone PTMs and variant proteins, they can only be used to study individual chromatin marks and not to identify all factors important for establishing a distinct chromatin structure. This would require a comprehensive understanding of all marks associated to a specific genomic locus. However, thus far, such analyses of locus-specific chromatin have only been successful for repetitive regions, such as telomeres. In my doctoral thesis, I used the unicellular parasite Trypanosoma brucei as a model system for chromatin biology and took advantage of its chromatin landscape with TSSs comprising already 7\% of the total T. brucei genome (humans: 0.00000156\%). Atypical for a eukaryote, the protein-coding genes are arranged in long polycistronic transcription units (PTUs). Each PTU is controlled by its own ~10 kb-wide TSS, that lies upstream of the PTU. As observed in other eukaryotes, TSSs are enriched with nucleosomes containing acetylated histones and the histone variant H2A.Z. This is why I used T. brucei to particularly investigate the TSS-specific chromatin structures and to identify factors involved in H2A.Z deposition and transcription regulation in eukaryotes. To this end, I established an approach for locus-specific chromatin isolation that would allow me to identify the TSSs- and non-TSS-specific chromatin marks. Later, combining the approach with a method for quantifying lysine-specific histone acetylation levels, I found H2A.Z and H4 acetylation enriched in TSSs-nucleosomes and mediated by the histone acetyltransferases HAT1 and HAT2. Depletion of HAT2 reduced the levels of TSS-specific H4 acetylation, affected targeted H2A.Z deposition and shifted the sites of transcription initiation. Whereas HAT1 depletion had only a minor effect on H2A.Z deposition, it had a strong effect on H2A.Z acetylation and transcription levels. My findings demonstrate a clear link between histone acetylation, H2A.Z deposition and transcription initiation in the early diverged unicellular parasite T. brucei, which was thus far not possible to determine in other eukaryotes. Overall, my study highlights the usefulness of T. brucei as a model system for studying chromatin biology. My findings allow the conclusion that H2A.Z regardless of its modification state defines sites of transcription initiation, whereas H2A.Z acetylation is essential co-factor for transcription initiation. Altogether, my data suggest that TSS-specific chromatin establishment is one of the earliest developed mechanisms to control transcription initiation in eukaryotes.}, subject = {Chromatin}, language = {en} } @phdthesis{Wedel2018, author = {Wedel, Carolin}, title = {The impact of DNA sequence and chromatin on transcription in \(Trypanosoma\) \(brucei\)}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-173438}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2018}, abstract = {For cellular viability, transcription is a fundamental process. Hereby, the DNA plays the most elemental and highly versatile role. It has long been known that promoters contain conserved and often well-defined motifs, which dictate the site of transcription initiation by providing binding sites for regulatory proteins. However, research within the last decade revealed that it is promoters lacking conserved promoter motifs and transcribing constitutively expressed genes that constitute the majority of promoters in eukaryotes. While the process of transcription initiation is well studied, whether defined DNA sequence motifs are required for the transcription of constitutively expressed genes in eukaryotes remains unknown. In the highly divergent protozoan parasite Trypanosoma brucei, most of the proteincoding genes are organized in large polycistronic transcription units. The genes within one polycistronic transcription unit are generally unrelated and transcribed by a common transcription start site for which no RNA polymerase II promoter motifs have been identified so far. Thus, it is assumed that transcription initiation is not regulated but how transcription is initiated in T. brucei is not known. This study aimed to investigate the requirement of DNA sequence motifs and chromatin structures for transcription initiation in an organism lacking transcriptional regulation. To this end, I performed a systematic analysis to investigate the dependence of transcription initiation on the DNA sequence. I was able to identify GT-rich promoter elements required for directional transcription initiation and targeted deposition of the histone variant H2A.Z, a conserved component during transcription initiation. Furthermore, nucleosome positioning data in this work provide evidence that sites of transcription initiation are rather characterized by broad regions of open and more accessible chromatin than narrow nucleosome depleted regions as it is the case in other eukaryotes. These findings highlight the importance of chromatin during transcription initiation. Polycistronic RNA in T. brucei is separated by adding an independently transcribed miniexon during trans-splicing. The data in this work suggest that nucleosome occupancy plays an important role during RNA maturation by slowing down the progressing polymerase and thereby facilitating the choice of the proper splice site during trans-splicing. Overall, this work investigated the role of the DNA sequence during transcription initiation and nucleosome positioning in a highly divergent eukaryote. Furthermore, the findings shed light on the conservation of the requirement of DNA motifs during transcription initiation and the regulatory potential of chromatin during RNA maturation. The findings improve the understanding of gene expression regulation in T. brucei, a eukaryotic parasite lacking transcriptional Regulation.}, subject = {Transkription}, language = {en} }