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Despite the well-known importance of ribonucleic acids (RNA) in cell biology, it is astounding to realize the pace at which new fundamental functions of RNAs have been discovered. One of the fundamental reasons for the multitude of functions of RNA is the property of RNA to adopt different conformations or folds. The primary sequence of RNA, a linear polymer built from four different repetition units, can fold into alternate secondary structure motifs which in turn form alternate long-range interactions in complex tertiary structures. Ligands such as metal ions or small molecular weight metabolites and also proteins or peptides can bind to RNA and induce the changes in tertiary conformation. For example, in the cell, RNA participates in gene regulation in the form of riboswitches. Riboswitches are found in untranslated regions of messenger RNA (mRNA) and adopt alternate conformations depending on the presence or absence of specific metabolites. If a metabolite is present above a specific concentration, it induces a conformational change in the respective riboswitch by binding and thereby alters gene expression. Another example is the RNA thermometer which participates in the cell translational mechanism by a similar strategy. Translation initiation requires the binding of RNA thermometers to the ribosome. The ribosome binding region is located in the 5’ untranslated region of mRNA. At low temperatures this region is prevented from binding to the ribosome by forming basepairs. At higher temperatures, these basepairs dissociate allowing ribosome binding and subsequent translation. Therefore, the characterization and delineation of the kinetics and pathway of RNA folding is important to understand the function of RNA and is an important contribution to fundamentally understand RNA’s role in the cell. RNA conformational transitions occur over a wide range of timescales. Depending on the timescale, various biophysical techniques are used to study RNA conformational transitions. In these biophysical studies, achieving good structural and temporal resolution constitute frequently encountered challenges or limitations. For example, single molecule FRET spectroscopy provides high temporal resolution in the milliseconds at high sensitivity but lacks atomic resolution. Recent advances in the field of Nuclear Magnetic Resonance (NMR) spectroscopy have enabled the elucidation of tertiary folding events to be characterized with atomic resolution. This thesis involves the use of NMR spectroscopy to characterize the folding of RNA molecules. Kinetics experiments require rapid initiation of the kinetics followed by monitoring of the reaction. In this thesis, two different folding initiation techniques have been applied and coupled to the subsequent detection of RNA folding using NMR spectroscopy, namely, photocaging and rapid mixing. The method of photocaging is well established (Kuhn and Schwalbe, 2000) and builds on the following principle: A photolabile moiety is attached to a molecule that prevents a specific interaction. Upon irradiation of the molecule with the photolabile group using laser light at a specific wave length, at which the molecule of interest is not absorbing, the protecting group is released. In our group, together with the group of S. Pitsch, ETH Lausanne, we could "cage" RNA at its equilibrium state by a photolabile molecule (similar work has been carried out in the group of A. Heckel). Rapid and traceless release of the photolabile precursor compound by a laser pulse releases the RNA to fold into its native state; the build-up of the native state of the RNA is monitored by NMR signals that are uniquely characteristic for the native state of the RNA. By optically coupling a laser source to an NMR magnet, the above procedure can take place in situ and the kinetics recorded by NMR. Several different molecules can be caged: The photocage can be attached to RNA. Then, a modified photolabile nucleotide can be placed at strategic positions of a target RNA whose folding properties is to be studied. The photocage can also be attached to a ligand: if folding is dependent on ligand binding then the ligand can be modified to carry a photosensitive unit whose degradation allows binding to RNA. In this thesis, an alternative method for photocaging is introduced. Here, metal ions essential for folding of the RNA are photocaged using the photolabile chelating agent Dimethyl-nitrophen (DMN). Photolysis of DMNr releases the metal ion, thereby RNA folding is initiated. In the rapid-mixing technique, one of (several) components required for proper folding of the RNA is rapidly injected into an NMR sample in situ by the use of a pneumatic injection device. ...