Strategies for RNA Resonance Assignment by 13C/15N- and 1H-Detected Solid-State NMR Spectroscopy

Magic angle spinning (MAS) solid-state NMR (ssNMR) is an established tool that can be applied to non-soluble or non-crystalline biomolecules of any size or complexity. The ssNMR method advances rapidly due to technical improvements and the development of advanced isotope labeling schemes. While ssNMR has shown significant progress in structural studies of proteins, the number of RNA studies remains limited due to ssNMR methodology that is still underdeveloped. Resonance assignment is the most critical and limiting step in the structure determination protocol that defines the feasibility of NMR studies. In this review, we summarize the recent progress in RNA resonance assignment methods and approaches for secondary structure determination by ssNMR. We critically discuss advantages and limitations of conventional 13C- and 15N-detected experiments and novel 1H-detected methods, identify optimal regimes for RNA studies by ssNMR, and provide our view on future ssNMR studies of RNA in large RNP complexes

Solution structure of a let-7 miRNA:lin-41 mRNA complex from C. elegans

let-7 microRNA (miRNA) regulates heterochronic genes in developmental timing of the nematode Caenorhabditis elegans. Binding of miRNA to messenger RNA (mRNA) and structural features of the complex are crucial for gene silencing. We herein present the NMR solution structure of a model mimicking the interaction of let-7 miRNA with its complementary site (LCS 2) in the 3′ untranslated region (3′-UTR) of the lin-41 mRNA. A structural study was performed by NMR spectroscopy using NOE restraints, torsion angle restraints and residual dipolar couplings. The 33-nt RNA construct folds into a stem–loop structure that features two stem regions which are separated by an asymmetric internal loop. One of the stems comprises a GU wobble base pair, which does not alter its overall A-form RNA conformation. The asymmetric internal loop adopts a single, well-defined structure in which three uracils form a base triple, while two adenines form a base pair. The 3D structure of the construct gives insight into the structural aspects of interactions between let-7 miRNA and lin-41 mRNA

Ion selectivity of the NaK channel investigated by solid-state NMR

Ionenkanäle sind für die zelluläre Homöostase und die elektrische Aktivität in höheren Eukaryoten essentiell. Die vorliegende Arbeit widmet sich dem nichtselektiven Kanal NaK und seinen kaliumselektiven Mutanten. Die Bedeutung von Ionenkanälen wird in Kapitel 1 speziell für die kationenselektive Ionenkanal-Superfamilie diskutiert. Darin werden verschiedene Vertreter dieser Superfamilie untersucht und ihre Strukturen und Ionenselektivität analysiert. In Kapitel 2 wird gezeigt, dass NaK zwei unterschiedliche Selektivitätsfilterkonformationen aufweist, die entweder durch Na+- oder K+-Ionen stabilisiert sind. Unter Verwendung von Festkörper-NMR Spektroskopie und molekulardynamischen Simulationen wurden zwei Ionenleitungswege entdeckt. In Kapitel 3 wurde eine Kristallstruktur von NaK ermittelt, welche die vorhergesagte und für den Seiteneintrittsmechanismus essentielle seitliche Ionenbindungsstelle bestätigt. Die zwei Untereinheiten in der asymmetrischen Einheit zeigen die dynamische Natur der unteren Teile der Transmembranhelices sowie duale Konformationen für die Reste im Selektivitätsfilter. Im Gegensatz zu NaK sind die kaliumselektiven Mutanten ionensensitiver, wie in Kapitel 4 gezeigt: Unter Na+-Bedingungen verliert der gesamte Selektivitätsfilter in den kaliumselektiven Mutanten seine Stabilität. Die stärkere Verbindung zwischen Selektivitätsfilter und der Porenhelix in den kaliumselektiven Mutanten ermöglicht keine nichtselektive Ionenleitung. Unter Verwendung von protonendetektierter Festkörper-NMR wurde die Wechselwirkung zwischen Wassermolekülen und der kaliumselektiven Mutante NaK2K charakterisiert und präsentiert in Kapitel 5. Es wurde gezeigt, dass der Selektivitätsfilter von NaK2K unter physiologischen Bedingungen wasserfrei ist. Diese Ergebnisse werden in Kapitel 6 im Ganzen betrachtet und die verbleibenden Fragen werden erörtert, außerdem wird ein kurzer Ausblick auf die zukünftige Forschung zum Thema Ionenselektivität im NaK-Kanal gegeben.Ion channels are essential to cellular homeostasis and electrical activity in higher eukaryotes. This thesis discusses the non-selective channel NaK and its potassium-selective mutants. The importance of ion channels is discussed in chapter 1 with a special focus on the tetrameric cation-selective ion channel superfamily. Various members of this superfamily are explored and their structures and ion selectivity are analysed. NaK is shown to have two distinct selectivity filter conformations that are stabilized by either Na+ or K+ ions in chapter 2. Using solid-state NMR spectroscopy and molecular dynamics simulations, two ion conduction pathways were discovered. In chapter 3 a crystal structure of NaK was determined that confirms the previously predicted side-entry ion binding site, essential to the side-entry pathway. The two subunits in the asymmetric unit display the dynamical nature of the lower parts of the transmembrane helices as well as dual conformations for residues in the selectivity filter. In contrast to NaK the potassium-selective mutants are more ion sensitive as shown in chapter 4. The entire selectivity filter loses its stability under Na+ conditions for the potassium-selective mutants. The stronger connection of the selectivity filter and the pore helix in the potassium-selective mutants does not allow for non-selective ion conduction. Using proton-detected ssNMR, the interaction between water molecules and the potassium-selective mutant NaK2K was characterized and this is presented in chapter 5. The selectivity filter of NaK2K was shown to be free of water under physiological conditions. These results get put in perspective and the questions which remain are discussed in chapter 6. A short outlook on future research for the topic of ion selectivity in the NaK channel is given

Protein resonance assignment by BSH‐CP‐based 3D solid‐state NMR experiments: A practical guide

Solid-state NMR (ssNMR) spectroscopy has evolved into a powerful method to obtain structural information and to study the dynamics of proteins at atomic resolution and under physiological conditions. The method is especially well suited to investigate insoluble and noncrystalline proteins that cannot be investigated easily by X-ray crystallography or solution NMR. To allow for detailed analysis of ssNMR data, the assignment of resonances to the protein atoms is essential. For this purpose, a set of three-dimensional (3D) spectra needs to be acquired. Band-selective homo-nuclear cross-polarization (BSH-CP) is an effective method for magnetization transfer between carbonyl carbon (CO) and alpha carbon (CA) atoms, which is an important transfer step in multidimensional ssNMR experiments. This tutorial describes the detailed procedure for the chemical shift assignment of the backbone atoms of 13C–15N-labeled proteins by BSH-CP-based 13C-detected ssNMR experiments. A set of six 3D experiments is used for unambiguous assignment of the protein backbone as well as certain side-chain resonances. The tutorial especially addresses scientists with little experience in the field of ssNMR and provides all the necessary information for protein assignment in an efficient, time-saving approach.European Research Council http://dx.doi.org/10.13039/501100000781Max Planck Society http://dx.doi.org/10.13039/501100004189Leibniz‐Forschungsinstitut für Molekulare PharmakologiePeer Reviewe

13C-direct detected NMR experiments for the sequential J-based resonance assignment of RNA oligonucleotides

We present here a set of 13C-direct detected NMR experiments to facilitate the resonance assignment of RNA oligonucleotides. Three experiments have been developed: (1) the (H)CC-TOCSY-experiment utilizing a virtual decoupling scheme to assign the intraresidual ribose 13C-spins, (2) the (H)CPC-experiment that correlates each phosphorus with the C4′ nuclei of adjacent nucleotides via J(C,P) couplings and (3) the (H)CPC-CCH-TOCSY-experiment that correlates the phosphorus nuclei with the respective C1′,H1′ ribose signals. The experiments were applied to two RNA hairpin structures. The current set of 13C-direct detected experiments allows direct and unambiguous assignment of the majority of the hetero nuclei and the identification of the individual ribose moieties following their sequential assignment. Thus, 13C-direct detected NMR methods constitute useful complements to the conventional 1H-detected approach for the resonance assignment of oligonucleotides that is often hindered by the limited chemical shift dispersion. The developed methods can also be applied to large deuterated RNAs