@phdthesis{Zachary2021,
  author    = {Zachary, Marie},
  title     = {Functional characterization of small non-coding RNAs of \(Neisseria\) \(gonorrhoeae\)},
  doi       = {10.25972/OPUS-24582},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-245826},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {During infection, bacteria need to adapt to a changing environment and have to endure various stress conditions. Small non-coding RNAs are considered as important regulators of bacterial gene expression and so allow quick adaptations by altering expression of specific target genes. Regulation of gene expression in the human-restricted pathogen Neisseria gonorrhoeae, the causative agent of the sexually transmitted disease gonorrhoea, is only poorly understood. The present study aims a better understanding of gene regulation in N. gonorrhoeae by studying small non-coding RNAs. The discovery of antisense RNAs for all opa genes led to the hypothesis of asRNA-mediated degradation of out-of-frame opa transcripts. Analysis of asRNA expression revealed a very low abundance of the transcripts and inclusion of another phase-variable gene in the study indicates that the asRNAs are not involved in degradation of out-of-frame transcripts. This doctoral thesis focuses on the analysis of trans-acting sRNAs. The sibling sRNAs NgncR_162 and NgncR_163 were discovered as post-transcriptional regulators altering expression of genes involved in metabolic processes, amino acid uptake and transcriptional regulation. A more detailed analysis by in silico and transcriptomic approaches showed that the sRNAs regulate a broad variety of genes coding for proteins of central metabolism, amino acid biosynthesis and degradation and several transport processes. Expression levels of the sibling sRNAs depend on the growth phase of the bacteria and on the growth medium. This indicates that NgncR_162 and NgncR_163 are involved in the adaptation of the gonococcal metabolism to specific growth conditions. This work further initiates characterisation of the sRNA NgncR_237. An in silico analysis showed details on sequence conservation and a possible secondary structure. A combination of in silico target prediction and differential RNA sequencing resulted in the identification of several target genes involved in type IV pilus biogenesis and DNA recombination. However, it was not successful to find induction conditions for sRNA expression. Interestingly, a possible sibling sRNA could be identified that shares the target interaction sequence with NgncR_237 and could therefore target the same mRNAs. In conclusion, this thesis provides further insights in gene regulation by non-coding RNAs in N. gonorrhoeae by analysing two pairs of sibling sRNAs modulating bacterial metabolism or possibly type IV pilus biogenesis.},
  subject      = {Neisseria gonorrhoeae},
  language  = {en}
}
@phdthesis{Pernitzsch2021,
  author    = {Pernitzsch, Sandy Ramona},
  title     = {Functional Characterization of the abundant and conserved small regulatory RNA RepG in Helicobacter pylori},
  doi       = {10.25972/OPUS-12268},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-122686},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {Bacterial small non-coding RNAs (sRNAs) play fundamental roles in controlling and finetuning gene expression in a wide variety of cellular processes, including stress responses, environmental signaling and virulence in pathogens. Despite the identification of hundreds of sRNA candidates in diverse bacteria by genomics approaches, the mechanisms and regulatory capabilities of these posttranscriptional regulators have most intensively been studied in Gram-negative Gammaproteobacteria such as Escherichia coli and Salmonella. So far, almost nothing is known about sRNA-mediated regulation (riboregulation) in Epsilonproteobacteria, including the major human pathogen Helicobacter pylori. H. pylori was even thought to be deficient for riboregulation as none of the sRNAs known from enterobacteria are conserved in Helicobacter and since it lacks the major RNA chaperone Hfq, which is crucial for sRNA function as well as stability in many bacteria. Nonetheless, more than 60 cis- and trans-acting sRNA candidates were recently identified in H. pylori by a global RNA sequencing approach, indicating that this pathogen, in principle, has the capability to use riboregulation for its gene expression control. However, the functions and underlying mechanisms of H. pylori sRNAs remained unclear. This thesis focused on the first functional characterization and target gene identification of a trans-acting sRNA, RepG (Regulator of polymeric G-repeats), in H. pylori. Using in-vitro and in-vivo approaches, RepG was shown to directly base-pair with its C/Urich terminator loop to a variable homopolymeric G-repeat in the 5' untranslated region (UTR) of the tlpB mRNA, thereby regulating expression of the chemotaxis receptor TlpB. While the RepG sRNA is highly conserved, the length of the G-repeat in the tlpB mRNA leader varies among different H. pylori isolates, resulting in a strain-specific tlpB regulation. The modification of the number of guanines within the G-stretch in H. pylori strain 26695 demonstrated that the length of the homopolymeric G-repeat determines the outcome of posttranscriptional control (repression or activation) of tlpB by RepG. This lengthdependent targeting of a simple sequence repeat by a trans-acting sRNA represents a new twist in sRNA-mediated regulation and a novel mechanism of gene expression control, since it uniquely links phase variation by simple sequence repeats to posttranscriptional regulation. In almost all sequenced H. pylori strains, tlpB is encoded in a two gene operon upstream of HP0102, a gene of previously unknown function. This study provided evidence that HP0102 encodes a glycosyltransferase involved in LPS O-chain and Lewis x antigen production. Accordingly, this glycosyltransferase was shown to be essential for mice colonization by H. pylori. The coordinated posttranscriptional regulation of the tlpB-HP0102 operon by antisense base-pairing of RepG to the phase-variable G-repeat in the 5' UTR of the tlpB mRNA allows for a gradual, rather than ON/OFF, control of HP0102 expression, thereby affecting LPS biosynthesis in H. pylori. This fine-tuning of O-chain and Lewis x antigen expression modulates H. pylori antibiotics sensitivity and thus, might be advantageous for Helicobacter colonization and persistence. Whole transcriptome analysis based on microarray and RNA sequencing was used to identify additional RepG target mRNAs and uncover the physiological role of this riboregulator in H. pylori. Altogether, repG deletion affected expression of more than 40 target gene candidates involved various cellular processes, including membrane transport and adhesion, LPS modification, amino acid metabolism, oxidative and nitrosative stress, and nucleic acid modification. The presence of homopolymeric G-repeats/G-rich sequences in almost all target mRNA candidates indicated that RepG hijacks a conserved motif to recognize and regulate multiple target mRNAs in H. pylori. Overall, this study demonstrates that H. pylori employs riboregulation in stress response and virulence control. In addition, this thesis has successfully established Helicobacter as a new model organism for investigating general concepts of gene expression control by Hfq-independent sRNAs and sRNAs in bacterial pathogens.},
  subject      = {Small RNA},
  language  = {en}
}
@phdthesis{Aydinli2021,
  author    = {Aydinli, Muharrem},
  title     = {Software unterst{\"u}tzte Analyse von regulatorischen Elementen in Promotoren mittels AIModules},
  doi       = {10.25972/OPUS-24802},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-248025},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {Die Regulation der Genexpression steht am Anfang vieler zellbiologischer Prozesse wie beispielsweise dem Zellwachstum oder der Differenzierung. Gene werden an Promotoren transkribiert, wobei ein Promotor selbst aus vielen logischen Einheiten aufgebaut ist, den Transkriptionsfaktorbindestellen (TFBSs). Diese k{\"o}nnen sehr nah beieinander liegen, aber auch weit entfernt voneinander sein. Sie werden spezifisch von Transkriptionsfaktoren (TFs) gebunden, die die Transkritptionsrate z.B. verst{\"a}rken (Enhancer) oder schw{\"a}chen (Silencer) k{\"o}nnen. Zwei oder mehr dieser TFBSs mit bestimmtem Abstand werden als "Module" zusammengefasst, die {\"u}ber Spezies hinweg konserviert sein k{\"o}nnen. Typischerweise findet man Module in Zellen mit einem Zellkern. Spezies mit gemeinsamen Modulen k{\"o}nnen ein Hinweis auf die gemeinsame phylogenetische Abstammung darstellen, aber auch gemeinsame Funktionsmechanismen von TFs {\"u}ber Gene hinweg aufdecken. Heutzutage sind verschiedene Anwendungen verf{\"u}gbar, mit denen nach TFBSs in DNA gesucht werden kann. Zum Zeitpunkt des Verfassens dieser Arbeit sind aber nur zwei kommerzielle Produkte bekannt, die nicht nur TFBSs, sondern auch Module erkennen. Deshalb stellen wir hier die freie und quelloffene L{\"o}sung "AIModules" vor, die diese L{\"u}cke f{\"u}llt und einen Webservice zur Verf{\"u}gung stellt, der es erlaubt nach TFBSs sowie nach Modulen auf DNA- und auf RNA-Abschnitten zu suchen. F{\"u}r die Motivesuche werden entweder Matrizen aus der Jaspar Datenbank oder Matrizen vom Anwender verwendet. Dar{\"u}berhinaus zeigen wir, dass unser Tool f{\"u}r die TF Suche nur Sekunden ben{\"o}tigt, wohingegen conTraV3 mindestens eine Stunde f{\"u}r dieselbe Analyse braucht. Zus{\"a}tzlich kann der Anwender bei unserem Tool den Grad der Konserviertheit f{\"u}r TFs mit angeben und wir zeigen, dass wir mit unserer L{\"o}sung, die die Jaspar Datenbank heranzieht, mehr Module finden, als ein kommerziell verf{\"u}gbares Produkt. Weiterhin kann mit unserer L{\"o}sung auch auf RNA-Sequenzen nach regulatorischen Motiven gesucht werden, wenn der Anwender die daf{\"u}r n{\"o}tigen Matrizen liefert. Wir zeigen dies am Beispiel von Polyadenylierungsstellen. Zusammenfassend stellen wir ein Werkzeug vor, das erstens frei und quelloffen ist und zweitens entweder auf Servern ver{\"o}ffentlicht werden kann oder On-Site auf einem Notebook l{\"a}uft. Unser Tool erlaubt es Promotoren zu analysieren und nach konservierten Modulen sowie TFBSs in Genfamilien sowie nach regulatorischen Elementen in mRNA wie z.B. Polyadenylierungsstellen oder andere regulatorische Elemente wie beispielsweise Enhancern oder Silencern in genomischer DNA zu suchen.},
  subject      = {Genregulation},
  language  = {de}
}