@phdthesis{Brosi2021,
  author    = {Brosi, Cornelia},
  title     = {Functional characterization of the TTF complex and its role in neurodevelopmental disorders},
  doi       = {10.25972/OPUS-15778},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-157783},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {The eukaryotic gene expression requires extensive regulations to enable the homeostasis of the cell and to allow dynamic responses due to external stimuli. Although many regulatory mechanisms involve the transcription as the first step of the gene expression, intensive regulation occurs also in the post-transcriptional mRNA metabolism. Thereby, the particular composition of the mRNPs plays a central role as the components associated with the mRNA form a specific "mRNP code" which determines the fate of the mRNA. Many proteins which are involved in this regulation and the mRNA metabolism are affected in diseases and especially neurological disorders often result from an aberrant mRNP code which leads to changes in the regulation and expression of mRNPs. The focus of this work was on a trimeric protein complex which is termed TTF complex based on its subunits TDRD3, TOP3β and FMRP. Biochemical investigations revealed that the three components of the TTF complex are nucleo-cytosolic shuttle proteins which localize in the cytoplasm at the steady-state, associate with mRNPs and are presumably connected to the translation. Upon cellular stress conditions, the TTF components concentrate in stress granules. Thus, the TTF complex is part of the mRNP code, however its target RNAs and function are still completely unknown. Since the loss of functional FMRP results in the fragile X syndrome and TOP3β is associated with schizophrenia and intellectual disability, the TTF complex connects these phenotypically related neuro-psychiatric disorders with each other on a molecular level. Therefore, the aim of this work was to biochemically characterize the TTF complex and to define its function in the mRNA metabolism. In this work, evidence was provided that TDRD3 acts as the central unit of the TTF complex and directly binds to FMRP as well as to TOP3β. Thereby, the interaction of TDRD3 and TOP3β is very stable, whereas FMRP is a dynamic component. Interestingly, the TTF complex is not bound directly to mRNA, but is recruited via the exon junction complex (EJC) to mRNPs. This interaction is mediated by a specific binding motif of TDRD3, the EBM. Upon biochemical and biological investigations, it was possible to identify the interactome of the TTF complex and to define the role in the mRNA metabolism. The data revealed that the TTF complex is mainly associated with "early" mRNPs and is probably involved in the pioneer round of translation. Furthermore, TOP3β was found to bind directly to the ribosome and thus, establishes a connection between the EJC and the translation machinery. A reduction of the TTF components resulted in selective changes in the proteome in cultured cells, whereby individual protein subsets seem to be regulated rather than the global protein expression. Moreover, the enzymatic analysis of TOP3β indicated that TOP3β is a type IA topoisomerase which can catalytically attack not only DNA but also RNA. This aspect is particularly interesting with regard to the connection between early mRNPs and the translation which has been revealed in this work. The data obtained in this work suggest that the TTF complex plays a role in regulating the metabolism of an early mRNP subset possibly in the course of the pioneer round of translation. Until now, the link between an RNA topoisomerase and the mRNA metabolism is thereby unique and thus provides a completely new perspective on the steps in the post-transcriptional gene expression and its regulation.},
  subject      = {Messenger-RNP},
  language  = {en}
}
@phdthesis{Stoll2015,
  author    = {Stoll, Georg},
  title     = {Identification of the mRNA-associated TOP3β- TDRD3-FMRP (TTF) -complex and its implication for neurological disorders},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-111440},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2015},
  abstract  = {The propagation of the genetic information into proteins is mediated by messenger- RNA (mRNA) intermediates. In eukaryotes mRNAs are synthesized by RNA- Polymerase II and subjected to translation after various processing steps. Earlier it was suspected that the regulation of gene expression occurs primarily on the level of transcription. In the meantime it became evident that the contribution of post- transcriptional events is at least equally important. Apart from non-coding RNAs and metabolites, this process is in particular controlled by RNA-binding proteins, which assemble on mRNAs in various combinations to establish the so-called "mRNP- code". In this thesis a so far unknown component of the mRNP-code was identified and characterized. It constitutes a hetero-trimeric complex composed of the Tudor domain-containing protein 3 (TDRD3), the fragile X mental retardation protein (FMRP) and the Topoisomerase III beta (TOP3β) and was termed TTF (TOP3β-TDRD3-FMRP) -complex according to its composition. The presented results also demonstrate that all components of the TTF-complex shuttle between the nucleus and the cytoplasm, but are predominantly located in the latter compartment under steady state conditions. Apart from that, an association of the TTF-complex with fully processed mRNAs, not yet engaged in productive translation, was detected. Hence, the TTF-complex is a component of „early" mRNPs. The defined recruitment of the TTF-complex to these mRNPs is not based on binding to distinct mRNA sequence-elements in cis, but rather on an interaction with the so-called exon junction complex (EJC), which is loaded onto the mRNA during the process of pre-mRNA splicing. In this context TDRD3 functions as an adapter, linking EJC, FMRP and TOP3β on the mRNP. Moreover, preliminary results suggest that epigenetic marks within gene promoter regions predetermine the transfer of the TTF-complex onto its target mRNAs. Besides, the observation that TOP3β is able to catalytically convert RNA-substrates disclosed potential activities of the TTF-complex in mRNA metabolism. In combination with the already known functions of FMRP, this finding primarily suggests that the TTF-complex controls the translation of bound mRNAs. In addition to its role in mRNA metabolism, the TTF-complex is interesting from a human genetics perspective as well. It was demonstrated in collaboration with researchers from Finland and the US that apart from FMRP, which was previously linked to neurocognitive diseases, also TOP3β is associated with neurodevelopmental disorders. Understanding the function of the TTF-complex in mRNA metabolism might hence provide important insight into the etiology of these diseases.},
  subject      = {Messenger-RNS},
  language  = {en}
}