@phdthesis{Wolski2011, author = {Wolski, Stefanie Carola}, title = {Structural and functional characterization of nucleotide excision repair proteins}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-67183}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {XPD is a 5'-3' helicase of the superfamily 2. As part of the transcription factor IIH it functions in transcription initiation and nucleotide excision repair. This work focus on the role of XPD in nucleotide excision repair. NER is a DNA repair pathway unique for its broad substrate range. In placental mammals NER is the only repair mechanism able to remove lesions induced by UV-light. NER can be divided into four different steps that are conserved between pro- and eukaryotes. Step 1 consists of the initial damage recognition, during step 2 the putative damage is verified, in step 3 the verified damage is excised and in the 4th and final step the resulting gap in the DNA is refilled. XPD was shown to be involved in the damage verification step. It was possible to solve the first apo XPD structure by a MAD approach using only the endogenous iron from the iron sulfur cluster. Based on the apo XPD structure several questions arise: where is DNA bound? Where is DNA separated? How is damage verification achieved? What is the role of the FeS cluster? These questions were addressed in this work. Hypothesis driven structure based functional mutagenesis was employed and combined with detailed biochemical characterization of the variants. The variants were analyzed by thermal unfolding studies to exclude the possibility that the overall stability could be affected by the point mutation. DNA binding assays, ATPase assays and helicase assays were performed to delineate amino acid residues important for DNA binding, helicase activity and damage recognition. A structure of XPD containing a four base pair DNA fragment was solved by molecular replacement. This structure displays the polarity of the translocated strand with respect to the helicase framework. Moreover the properties of the FeS cluster were studied by electron paramagnetic resonance to get insights into the role of the FeS cluster. Furthermore XPD from Ferroplasma acidarmanus was investigated since it was shown that it is stalled at CPD containing lesions. The data provide the first detailed insight into the translocation mechanism of a SF2B helicase and reveal how polarity is achieved. This provides a basis for further anlayses understanding the combined action of the helicase and the 4Fe4S cluster to accomplish damage verification within the NER cascade.}, subject = {DNS-Reparatur}, language = {en} } @phdthesis{Roth2011, author = {Roth, Heide Marie}, title = {Nucleotide Excision Repair: From Recognition to Incision of damaged DNA}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-57098}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {The Nucleotide Excision Repair (NER) pathway is able to remove a vast diversity of structurally unrelated DNA lesions and is the only repair mechanism in humans responsible for the excision of UV induced DNA damages. The NER mechanism raises two fundamental questions: 1) How is DNA damage recognition achieved discriminating damaged from non damaged DNA? 2) How is DNA incision regulated preventing endonucleases to cleave DNA non specifically but induce and ensure dual incision of damaged DNA? Thus, the aim of this work was to investigate the mechanisms leading from recognition to incision of damaged DNA. To decipher the underlying process of damage recognition in a prokaryotic model system, the intention of the first part of this work was to co crystallize the helicase UvrB form Bacillus caldotenax together with a DNA substrate comprising a fluorescein adducted thymine as an NER substrate. Incision assays were performed to address the question whether UvrB in complex with the endonuclease UvrC is able to specifically incise damaged DNA employing DNA substrates with unpaired regions at different positions with respect to the DNA lesion. The results presented here indicate that the formation of a specific pre incision complex is independent of the damage sensor UvrA. The preference for 5' bubble substrate suggests that UvrB is able to slide along the DNA favorably in a 5' → 3' direction until it directly encounters a DNA damage on the translocating strand to then recruit the endonuclease UvrC. In the second part of this work, the novel endonuclease Bax1 from Thermoplasma acidophilum was characterized. Due to its close association to archaeal XPB, a potential involvement of Bax1 in archaeal NER has been postulated. Bax1 was shown to be a Mg2+ dependent, structure specific endonuclease incising 3' overhang substrates in the single stranded region close to the ssDNA/dsDNA junction. Site directed mutagenesis of conserved amino acids was employed to identify putative active site residues of Bax1. In complex with the helicase XPB, however, incision activity of Bax1 is altered regarding substrate specificity. The presence of two distinct XPB/Bax1 complexes with different endonuclease activities indicates that XPB regulates Bax1 incision activity providing insights into the physical and functional interactions of XPB and Bax1.}, subject = {DNS-Reparatur}, language = {en} } @phdthesis{Meier2011, author = {Meier, Daniel}, title = {Konservierte transkriptionelle Regulationsmechanismen der Fanconi An{\"a}mie core complex Gene}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-65552}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {Fanconi An{\"a}mie (FA) ist eine autosomal rezessive, im Falle der Untergruppe FA-B X-chromosomale Erbkrankheit, die mit chromosomaler und genomischer Instabilit{\"a}t verbunden ist und sich durch große ph{\"a}notypische und genetische Heterogenit{\"a}t auszeichnet. Symptomatisch sind Knochenmarksversagen, eine Vielfalt angeborener Fehlbildungen, die weit {\"u}berdurchschnittliche Disposition f{\"u}r akute myeloische Leuk{\"a}mie (AML), Plattenepithelkarzinome (SCC) sowie eine zellul{\"a}re Hypersensitivit{\"a}t gegen{\"u}ber DNA Doppelstrangvernetzenden Substanzen. FA wird kompliziert durch ein progressives Knochenmarksversagen. Die FA Proteine sind essentiell f{\"u}r die interstrand crosslink (ICL) repair sowie an anderen DNA Reparatursystemen, beteiligt. Bisher wurden haupts{\"a}chlich Regulationsmechanismen untersucht, die die FA Proteine betreffen. Die Regulation der Transkripte war bisher nahezu unbekannt. In der vorliegenden Arbeit wurde die transkriptionelle Regulation der sogenannten FA core complex Gene untersucht. Dabei handelt es sich um acht Gene, deren Produkte im Falle eines DNA Schadens den ersten Proteinkomplex des FA/BRCA Signalweges bilden. F{\"u}r diese acht Gene wurden in dieser Arbeit die Promotoren identifiziert und ihr Aktivierungspotential charakterisiert. Dabei stellte sich heraus, dass diese ein starkes Potential f{\"u}r die Transkriptionsinitiierung besitzen. Des Weiteren zeigten sich Gemeinsamkeiten in Form von Sequenzmotiven sowie Transkriptionsfaktorbindestellen, die in allen core complex Genen nahezu identisch waren. Durch diese Analysen ergaben sich Hinweise, dass die untersuchten Gene durch Mitglieder des JAK/ STAT (STAT1/4) sowie des TGF-b Signalwegs (SMAD1/4) reguliert werden. Funktionelle Untersuchungen mittels siRNA sowie Fibroblastenzelllinen, die biallelische FANCA Mutationen trugen, best{\"a}tigten diese Verbindungen. So hatte der knockdown der entsprechenden Transkriptionsfaktoren einen reduzierenden Einfluss auf die Transkriptmenge der core complex Gene. FANCA-mutierte Zelllinen weisen reduzierte mRNAs von STAT und SMAD auf. Dar{\"u}ber hinaus fanden sich signifikante {\"A}nderungen der Transkriptmenge in 112 verschiedenen Mitgliedern dieser Signalwege in den FA-A Zellinien. Eines dieser Mitglieder, IRF1, zeigte fast identische Ergebnisse wie sie bei STAT1/4 sowie SMAD1/4 beobachtet werden konnten. Die vorliegende Arbeit tr{\"a}gt dazu bei, die transkriptionelle Regulation der core complex Gene besser zu verstehen. Die auff{\"a}lligen Gemeinsamkeiten ihrer Regulation liefern neue Argumente f{\"u}r eine Koevolution dieser Gene.}, subject = {Fanconi An{\"a}mie}, language = {de} }