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The post-transcriptional modification of the canonical nucleoside uridine into its rotational isomer pseudouridine occurs in non-coding as well as coding RNA and is the most abundant post-transcriptional modification in all kingdoms of life. While the occurrence of pseudouridine has been linked to the enhancement of stability and the codon-anticodon interaction in tRNAs, enhancement of the translation efficiency in rRNAs, regulatory functions in spliceosomal snRNA and nonsense codon suppression in mRNA, its exact role in many RNAs is still ambiguous. The uridine to pseudouridine isomerization can either be catalyzed by one of various standalone pseudouridylases or it can be performed in an RNA-guided manner by H/ACA ribonucleoproteins. In eukaryotes, the guide RNA always adapts a conserved bipartite, double-hairpin conformation. Each hairpin contains an internal RNA-loop motif, which can recruit a specific substrate RNA via base pairing. The catalytically active RNP is formed by the interactions of the guide RNA with four proteins. While Cbf5 forms the catalytically active center, Nop10 and Nhp2 perform auxiliary functions and Gar1 is involved in substrate turnover. Up until now, most structural knowledge about H/ACA RNPs has been derived from archaeal complexes, while the exact structure-function-relationships between RNA and proteins in eukaryotic RNPs is still ambiguous. While archaeal H/ACA RNPs share many similarities with eukaryotic RNPs and act as good model system, there are also many differences between them like eukaryotic specific protein domains as well as the overall bipartite complex structure, dictated by the snoRNA. Investigating pseudouridylation by eukaryotic H/ACA RNPs opens up a broad area of research and helps to gain a better understanding of this enzyme class – especially since malfunction of H/ACA RNPs has been linked to the genetic disease Dyskeratosis congenita as well as several types of cancer.
The main goal of this thesis was to gain new insights into the RNA/protein interactions in the eukaryotic snR81 H/ACA snoRNP from Saccharomyces cerevisiae on a structural as well as dynamical level. In the first part of this thesis, the main goal was to in vitro prepare a functionally active snR81 H/ACA RNP. The guiding snoRNA was prepared by in vitro transcription and purification, while the Saccharomyces cerevisiae proteins were recombinantly expressed from Escherichia coli. Apart from the full length, bipartite snR81 snoRNP, several sub-complexes of the RNP were reconstituted. Therefore, snoRNA constructs were designed and prepared, which only contained a single hairpin motif of the complex. Furthermore, snoRNA constructs in which the apical hairpin stem was replaced by a stable tetraloop were prepared, to investigate the influence of the apical stem on protein binding and activity. Also, for the eukaryotic proteins, a shortened version of Gar1 (Gar1Δ) was utilized, which lacks the eukaryotic specific RGG domains, that have been characterized as accessory RNA binding motifs. Reconstituted snoRNPs were utilized in catalytic activity assays, monitoring the turnover rate of uridine to pseudouridine. For this purpose, radioactively labeled substrate RNAs were prepared by phosphorylation and splinted ligation of oligonucleotides and were objected to reconstituted H/ACA RNPs under single as well as multiple turnover conditions. In the second part of this thesis, the RNA/protein interactions were dissected via single molecule FRET spectroscopy. Therefore, the snoRNA was labeled with an acceptor fluorophore via NHS ester/amine-reaction. Furthermore, the snoRNA contained a biotin-handle, allowing immobilization of the complex during the experimental time-window of the spectroscopic analysis. Eukaryotic specific protein Nhp2 was labeled with a donor fluorophore via “click” chemistry, which included the chemical synthesis and incorporation by genetic code expansion of non-canonical amino acids. The interactions of Nhp2 with the different snoRNA constructs (standalone-hairpins “H5” and “H3”, as well as hairpins lacking the apical binding motif “H5Δ” and “H3Δ”) were monitored on a single molecule level.
In summary, it was possible to gain new insights into the complex structure and the dynamical behavior of the still sparsely characterized eukaryotic H/ACA RNPs. Especially, new knowledge could be obtained about the hairpin specific behavior on the bipartite RNA complex structure, including the rather ambiguous role of the protein Nhp2 and the contribution of the eukaryotic specific features of Gar1 in their interaction with the guide/substrate RNA.
This dissertation contains two chapters. Each chapter covers a unique topic within RNA sci-ence and is divided in two sub sections, part A and B. Each chapter contains an introduction.
Chapter 1 gives an insight into challenges encountered during sample design and preparation for single molecule Förster energy transfer (smFRET) spectroscopy and offers a solution via a newly establishedestablished workflow to obtain accurate smFRET constructs. Following this workflow, a FRET network could be generated, which allowed a detailed structural dynamics study on H/ACA RNP during catalysis with smFRET spectroscopy. This led to detailed mech-anistic insights into H/ACA RNPs dynamics during catalysis.
Chapter 2 deals with RNA synthetic biology whereby a novel eclectic design strategy for RNA of interest (ROI) release platform is presented, which allows to release a diverse ROI se-quences with single nucleotide precision triggered by an external stimulus. This design strat-egy was used to establish a ROI release system and its powerful performance in in vitro and in vivo applications was shown.
This dissertation contains two chapters. Each chapter covers a unique topic within RNA science and is divided in two sub sections, part A and B. Each chapter contains an introduction.
Chapter 1 gives an insight into challenges encountered during sample design and preparation for single molecule Förster energy transfer (smFRET) spectroscopy and offers a solution via a newly establishedestablished workflow to obtain accurate smFRET constructs. Following this workflow, a FRET network could be generated, which allowed a detailed structural dynamics study on H/ACA RNP during catalysis with smFRET spectroscopy. This led to detailed mechanistic insights into H/ACA RNPs dynamics during catalysis.
Chapter 2 deals with RNA synthetic biology whereby a novel eclectic design strategy for RNA of interest (ROI) release platform is presented, which allows to release a diverse ROI sequences with single nucleotide precision triggered by an external stimulus. This design strategy was used to establish a ROI release system and its powerful performance in in vitro and in vivo applications was shown.
N6-methyladenosine (m6A) is the most abundant and well understood modification in eukaryotic mRNA and was first identified in polyadenylated parts of the mRNA.The distinct distribution of m6A in the transcriptome with special enrichment in long internal exons, 39UTRs and around stop codons was uncovered by early biochemical work and later on antibody based sequencing techniques. The so called m6A writer, reader and eraser machinery is responsible for the dynamic and with that regulatory nature of the m6A modification. As m6A writer, the human N6-methyltransferase complex (MTC) cotranscriptionally methylates the central adenine within a RRACH (preferably GGACU) sequence context to form m6A in the nascent RNA chain.9–15 The catalytic core of the complex is formed by the two proteins METTL3 and METTL14, with the active site located in the methyltransferase domain (MTD) of METTL3.16–18 The DPPW motif near the methyl donor S-adenosylmethionine (SAM) binding site in this MTD was postulated to bind the target adenine during catalysis. Moreover, a positively charged groove in the METTL3-METTL14 interface, the C-terminal RGG domain in METTL14 and the zinc finger motifs in METTL3 were identified as important domains for RNA binding. However, to date there are no full-length or substrate-RNA-bound structures of the catalytic METTL3-METTL14 complex.
In addition, a set of accessory proteins assembles to the METTL3-METTL14 heterodimer to form the full MTC, mediated by WTAP that firmly binds to the N-terminal leader helix in METTL3.20 WTAP was shown to locate the whole complex to the nuclear speckles and can modulate m6A deposition to specific sites in the RNA. Moreover, WTAP acts as binding platform for other accessory proteins including VIRMA, RBM15, ZC3H13 and HAKAI that are mostly identified to mediate position specific methylation. For example, RBM15 was shown to mediates region-selective methylation in a WTAP dependent manner, directing specificity towards U-rich sequences.
The observed specificity of the methyltransferase complex to methylate only site specific DRACH sequenced is still poorly understood. Some possible modulators like the role of the accessory proteins are under investigation, however, the structural context of the RNA methylation sites or a structural preference of the complex have been mainly neglected so far. Moreover, the structural dynamics of this methylation process still remain elusive. This thesis contributes to the afore-mentioned aspects by analysis of the methylation process regarding RNA structure sensitivity with enzymatic activity assays and its dynamic nature by implementing a smFRET approach.
We hypothesized the target RNA secondary structure to be an additional important modulator of methylation efficiency, based on the RNA binding elements of the complex (positively charged binding groove, zinc finger domain, RGG domain) and the supposed target adenine binding in the active site. Here, we postulated the possibility for a flipped-out adenine to be of special relevance, which is closely related to the local stability of the target adenine containing structure. Moreover, efficient binding of the protein complex to the RNA should require the ability to anchor the RNA on both sides of the target sequence.
H/ACA-RNPs are involved in RNA guided pseudouridylation of rRNAs and snRNAs. In this thesis I reconstituted active and labeled archaeal as well as eukaryotic H/ACA-RNPs and studied the structural dynamics of complex assembly and pseudouridine formation. Single molecule FRET spectroscopy was used as method of analysis to study structure, assembly and dynamics of these important complexes.
Die vorliegende Dissertation mit dem Titel “Structural dynamics of eukaryotic H/ACA RNPs from Saccharomyces cerevisiae & Structural dynamics of the Guanidine-II riboswitch from Escherichia coli” besteht aus zwei Projekten. Das erste Projekt befasst sich mit den eukaryotischen H/ACA Ribonukleoproteinen (RNP) aus der Hefe. Diese können sequenzspezifisch in der RNA ein Uridin Nukleotid in das Rotationsisomer Pseudouridin (Ψ) umwandeln. Die H/ACA RNPs bestehen aus einer Leit-RNA und vier Proteinen, der katalytisch aktiven Pseudouridylase Cbf5, Nhp2, Gar1 und Nop10. Die Leit-RNA besteht in Eukaryoten konserviert aus zwei Haarnadelstrukturen, die von einem H-Box oder ACA-Box Sequenzmotiv gefolgt sind. In jeder dieser Haarnadeln befindet sich ein ungepaarter Bereich, die sogenannte Pseudouridylierungstasche, wo durch komplementäre Basenpaarung die Ziel-RNA gebunden wird. Fehlerhafte H/ACA RNPs können beim Menschen zu schweren Krankheiten wie verschiedenen Krebsarten oder dem Knochenmarksversagen Dyskeratosis congenita führen, aber sie bieten auch Möglichkeiten zum Einsatz als Therapiemethode. In dieser Arbeit wurde hauptsächlich der zweiteilige Aufbau der H/ACA RNPs untersucht.
Dafür wurden zunächst die einzelnen Komponenten hergestellt werden. Cbf5, Nop10 und Gar1 wurden zusammen heterolog in E. coli exprimiert und gereinigt. Außerdem wurden mehrere Deletionsvarianten von Gar1 hergestellt. Zusätzlich wurde die Leit-RNA unmarkiert über T7 Transkription synthetisiert, sowie sechs verschiedene FRET-Konstrukte mit verschiedenen Markierungschemas der Fluorophore Cy3 und Cy5 über DNA-geschiente Ligation. Anschließend wurde über Größenausschlusschromatographie und radioaktiven Aktivitätsassays geprüft, dass sich die aktiven H/ACA RNPs in vitro aus den einzelnen Komponenten rekonstituieren lassen.
In smFRET Experimenten wurden einzelne Haarnadelstrukturen mit dem zweiteiligen Komplexen verglichen. Dabei konnte gezeigt werden, dass die H3 Haarnadel durch die Anwesenheit von H5 dynamischer und heterogener wurde, während H5 überwiegend unbeeinflusst war. Außerdem konnte die dreidimensionale Orientierung der Haarnadelstrukturen in verschiedenen Assemblierungsschritten mittels smFRET untersucht werden. Hier deutete sich an, dass in Abwesenheit von Proteinen beide Haarnadeln eher entgegengesetzt stehen als in einer parallelen Konformation. Cbf5 scheint den Linker zwischen den Beiden auszustrecken bzw. zu orientieren und die Haarnadelstrukturen etwas gegeneinander zu neigen. Ein Zusammenspiel von Nhp2 und Gar1 war nötig um die oberen Bereiche der Haarnadeln zusammenzuziehen. Es konnte auch ein Modell für den vollen H/ACA RNP vorgeschlagen werden. Im kompletten Komplex könnte das Zusammenziehen der Haarnadelstrukturen durch Nhp2 und Gar1 mit dem Effekt von Cbf5 konkurrieren und könnte hauptsächlich den oberen Bereich von H3 betreffen. Zum Schluss wurde das Zusammenspiel von Gar1 und Nhp2 auf eine Abhängigkeit von den RGG Domänen von Gar1 hin untersucht. Hier besteht möglicherweise eine Hierarchie, die eine Kooperativität von den N- und C-terminalen Domänen benötigt.
Das zweite Projekt befasst sich mit dem Guanidin-II Riboschalter aus E. coli. Der Riboschalter kann das toxische Molekül Guanidinium (Gdm+) spezifisch in seiner Aptamerdomäne binden und dadurch die Genexpression von Proteinen zur Detoxifizierung von Gdm+ aktivieren. Der Riboschalter besteht aus zwei Haarnadelstrukturen, mit einer Schleife, die aus der Sequenz ACGR besteht, wobei R ein Purin ist. In einem vorgeschlagenen Modell soll die Ribosomenbindestelle (Shine-Dalgarno Sequenz) in Abwesenheit von Ligand mit dem Linker komplementär Basenpaaren und so die Translation verhindern. Mit Ligand würde sich dann eine Schleifen-Schleifen Interaktion mit den beiden CG Basen ausbilden, wodurch die Anti-Shine-Dalgarno Sequenz nicht mehr zugänglich wäre. Bisherige Studien arbeiteten zumeist nur mit der Aptamerdomäne, den einzelnen Haarnadeln oder noch kleineren Elementen. In dieser Arbeit wurden die Strukturdynamiken von verschiedenen Längen, auch mit der Expressionsplatform, untersucht. Außerdem wurden verschiedene Mutationen analysiert und die Effekte auf den Riboschalter in seiner natürlichen Umgebung in E. coli.
Zunächst mussten insgesamt 24 FRET-Konstrukte hergestellt werden, die sich in Länge, Markierungsschema und Mutationen unterschieden. Hierfür wurde DNA-geschiente Ligation verwendet. Dank der verschiedenen Fluorophorpositionen konnte ein konformationelles Modell für die Aptamerdomäne vorgeschlagen werden. In diesem Modell könnte in Abwesenheit von Ionen das Aptamer offen vorliegen. Durch Mg2+ würde sich bereits eine lockere Schleifen-Schleifen Interaktion ausbilden. Zusätzlich deuten die Ergebnisse auf eine neue Konformation hin, der stabilisierten Schleifen-Schleifen Interaktion, bei der der Linker zusätzlich mit den Haarnadelstrukturen interagiert, beispielswese mit den Purinen an der vierten Schleifenposition...