@phdthesis{Goetz2018,
  author    = {G{\"o}tz, Silvia},
  title     = {Zuo1 - ein neues G-Quadruplex-bindendes Protein in \(Saccharomyces\) \(cerevisiae\)},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-152158},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2018},
  abstract  = {G-Quadruplex (G4)-Strukturen sind sehr stabile und polymorphe DNA und RNA Sekund{\"a}rstrukturen mit einem konservierten Guanin-reichen Sequenzmotiv (G4-Motiv). Sie bestehen aus {\"u}bereinander gestapelten planaren G-Quartetts, in denen je vier Guanine durch Wasserstoffbr{\"u}ckenbindungen zusammengehalten werden. Da G4-Motive in Eukaryoten an bestimmten Stellen im Genom angereichert vorkommen, wird angenommen, dass die Funktion von G4-Strukturen darin besteht, biologische Prozesse positiv oder negativ zu regulieren. Aufgrund der hohen thermodynamischen Stabilit{\"a}t von G4 Strukturen ist davon auszugehen, dass Proteine in die Faltung, Stabilisierung und Entfaltung dieser Nukleins{\"a}ure-Strukturen regulatorisch involviert sind. Bis heute wurden viele Proteine in der Literatur beschrieben, die G4-Strukturen entwinden k{\"o}nnen. Jedoch konnten bisher nur wenige Proteine identifiziert werden, die in vivo die Faltung f{\"o}rdern oder G4-Strukturen stabilisieren. Durch Yeast One-Hybrid (Y1H)-Screenings habe ich Zuo1 als neues G4 bindendes Protein identifiziert. In vitro Analysen best{\"a}tigten diese Interaktion und es stellte sich heraus, dass Zuo1 G4-Strukturen stabilisiert. {\"U}bereinstimmend mit den in vitro Daten konnte gezeigt werden, dass Zuo1 signifikant an G4-Motive im Genom von Saccharomyces ceresivisiae bindet. Genomweit {\"u}berlappen G4-Motive, an die Zuo1 bindet, mit Stellen, an denen die DNA Replikation zum Stillstand kommt und vermehrt DNA Sch{\"a}den vorkommen. Diese Ergebnisse legen nahe, dass Zuo1 eine Funktion w{\"a}hrend der DNA Reparatur oder in Zusammenhang mit dem Vorankommen der DNA Replikationsgabel hat, indem G4-Strukturen stabilisiert werden. Diese Hypothese wird außerdem durch genetische Experimente gest{\"u}tzt, wonach in Abwesenheit von Zuo1 die Genominstabilit{\"a}t zunimmt. Aufgrund dieser Daten war es m{\"o}glich ein Model zu entwickeln, bei dem Zuo1 w{\"a}hrend der S-Phase G4-Strukturen bindet und stabilisiert wodurch die DNA Replikation blockiert wird. Diese Interaktion findet neben Stellen schadhafter DNA statt und unterst{\"u}tzt somit DNA Reparatur-Prozesse wie beispielsweise die Nukleotidexzisionsreparatur. Als weiteres potentielles G4-bindendes Protein wurde Slx9 in Y1H-Screenings identifiziert. In vitro Experimente zeigten zwar, dass Slx9 mit h{\"o}herer Affinit{\"a}t an G4-Strukturen bindet im Vergleich zu anderen getesteten DNA Konformationen, jedoch wurde in S. cerevisiae genomweit keine signifikante Bindung an G4-Motive festgestellt.},
  subject      = {Saccharomyces cerevisiae},
  language  = {de}
}
@phdthesis{Wanzek2016,
  author    = {Wanzek, Katharina},
  title     = {The investigation of the function of repair proteins at G-quadruplex structures in \(Saccharomyces\) \(cerevisiae\) revealed that Mms1 promotes genome stability},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-142547},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2016},
  abstract  = {G-quadruplex structures are highly stable alternative DNA structures that can, when not properly regulated, impede replication fork progression and cause genome instability (Castillo Bosch et al, 2014; Crabbe et al, 2004; Koole et al, 2014; Kruisselbrink et al, 2008; London et al, 2008; Lopes et al, 2011; Paeschke et al, 2013; Paeschke et al, 2011; Piazza et al, 2015; Piazza et al, 2010; Piazza et al, 2012; Ribeyre et al, 2009; Sabouri et al, 2014; Sarkies et al, 2012; Sarkies et al, 2010; Schiavone et al, 2014; Wu \& Spies, 2016; Zimmer et al, 2016). The aim of this thesis was to identify novel G-quadruplex interacting proteins in Saccharomyces cerevisiae and to unravel their regulatory function at these structures to maintain genome integrity. Mms1 and Rtt101 were identified as G-quadruplex binding proteins in vitro via a pull-down experiment with subsequent mass spectrometry analysis. Rtt101, Mms1 and Mms22, which are all components of an ubiquitin ligase (Rtt101Mms1/Mms22), are important for the progression of the replication fork following fork stalling (Luke et al, 2006; Vaisica et al, 2011; Zaidi et al, 2008). The in vivo binding of endogenously tagged Mms1 to its target regions was analyzed genome-wide using chromatin-immunoprecipitation followed by deep-sequencing. Interestingly, Mms1 bound independently of Mms22 and Rtt101 to G-rich regions that have the potential to form G-quadruplex structures. In vitro, formation of G-quadruplex structures could be shown for the G-rich regions Mms1 bound to. This binding was observed throughout the cell cycle. Furthermore, the deletion of MMS1 caused replication fork stalling as evidenced by increased association of DNA Polymerase 2 at Mms1 dependent sites. A gross chromosomal rearrangement assay revealed that deletion of MMS1 results in a significantly increased genome instability at G-quadruplex motifs compared to G-rich or non-G-rich regions. Additionally, binding of the helicase Pif1, which unwinds G4 structures in vitro (Paeschke et al, 2013; Ribeyre et al, 2009; Sanders, 2010; Wallgren et al, 2016), to Mms1 binding sites was reduced in mms1 cells. The data presented in this thesis, together with published data, suggests a novel mechanistic model in which Mms1 binds to G-quadruplex structures and enables Pif1 association. This allows for replication fork progression and genome integrity.},
  subject      = {Quadruplex-DNS},
  language  = {en}
}
@phdthesis{Sauer2019,
  author    = {Sauer, Markus},
  title     = {DHX36 function in RNA G-quadruplex-mediated posttranscriptional gene regulation},
  doi       = {10.25972/OPUS-18395},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-183954},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2019},
  abstract  = {The expression of genetic information into proteins is a key aspect of life. The efficient and exact regulation of this process is essential for the cell to produce the correct amounts of these effector molecules to a given situation. For this purpose, eukaryotic cells have developed many different levels of transcriptional and posttranscriptional gene regulation. These mechanisms themselves heavily rely on interactions of proteins with associated nucleic acids. In the case of posttranscriptional gene regulation an orchestrated interplay between RNA-binding proteins, messenger RNAs (mRNA), and non-coding RNAs is compulsory to achieve this important function. A pivotal factor hereby are RNA secondary structures. One of the most stable and diverse representatives is the G-quadruplex structure (G4) implicated in many cellular mechanisms, such as mRNA processing and translation. In protein biosynthesis, G4s often act as obstacles but can also assist in this process. However, their presence has to be tightly regulated, a task which is often fulfilled by helicases. One of the best characterized G4-resolving factors is the DEAH-box protein DHX36. The in vitro function of this helicase is extensively described and individual reports aimed to address diverse cellular functions as well. Nevertheless, a comprehensive and systems-wide study on the function of this specific helicase was missing, so far. The here-presented doctoral thesis provides a detailed view on the global cellular function of DHX36. The binding sites of this helicase were defined in a transcriptome-wide manner, a consensus binding motif was deviated, and RNA targets as well as the effect this helicase exerts on them were examined. In human embryonic kidney cells, DHX36 is a mainly cytoplasmic protein preferentially binding to G-rich and G4-forming sequence motifs on more than 4,500 mRNAs. Loss of DHX36 leads to increased target mRNA levels whereas ribosome occupancy on and protein output of these transcripts are reduced. Furthermore, DHX36 knockout leads to higher RNA G4 levels and concomitant stress reactions in the cell. I hypothesize that, upon loss of this helicase, translationally-incompetent structured DHX36 target mRNAs, prone to localize in stress granules, accumulate in the cell. The cell reacts with basal stress to avoid cytotoxic effects produced by these mis-regulated and structured transcripts.},
  subject      = {RNS},
  language  = {en}
}
@phdthesis{Iltzsche2017,
  author    = {Iltzsche, Fabian},
  title     = {The Role of DREAM/MMB-mediated mitotic gene expression downstream of mutated K-Ras in lung cancer},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-154108},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2017},
  abstract  = {The evolutionary conserved Myb-MuvB (MMB) multiprotein complex has an essential role in transcriptional activation of mitotic genes. MMB target genes as well as the MMB associated transcription factor B-Myb and FoxM1 are highly expressed in a range of different cancer types. The elevated expression of these genes correlates with an advanced tumor state and a poor prognosis. This suggests that MMB could contribute to tumorigenesis by mediating overexpression of mitotic genes. Although MMB has been extensively characterized biochemically, the requirement for MMB to tumorigenesis in vivo remains largely unknown and has not been tested directly so far. In this study, conditional knockout of the MMB core member Lin9 inhibits tumor formation in vivo in a mouse model of lung cancer driven by oncogenic K-Ras and loss of p53. The incomplete recombination observed within tumors points towards an enormous selection pressure against the complete loss of Lin9. RNA interference (RNAi)-mediated depletion of Lin9 or the MMB associated subunit B-Myb provides evidence that MMB is required for the expression of mitotic genes in lung cancer cells. Moreover, it was demonstrated that proliferation of lung cancer cells strongly depends on MMB. Furthermore, in this study, the relationship of MMB to the p53 tumor suppressor was investigated in a primary lung cancer cell line with restorable p53 function. Expression analysis revealed that mitotic genes are downregulated after p53 re-expression. Moreover, activation of p53 induces formation of the repressive DREAM complex and results in enrichment of DREAM at mitotic gene promoters. Conversely, MMB is displaced at these promoters. Based on these findings the following model is proposed: In p53-negative cells, mitogenic stimuli foster the switch from DREAM to MMB. Thus, mitotic genes are overexpressed and may promote chromosomal instability and tumorigenesis. This study provides evidence that MMB contributes to the upregulation of G2/M phase-specific genes in p53-negative cells and suggests that inhibition of MMB (or its target genes) might be a strategy for treatment of lung cancer.},
  subject      = {Nicht-kleinzelliges Bronchialkarzinom (NSCLC)},
  language  = {en}
}