Michaela Egger scite author profile

Michaela Egger

5Publications

203Citation Statements Received

281Citation Statements Given

How they've been cited

184

How they cite others

267

269

Affiliations

Universität Innsbruck

Publications

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Structural distinctions between NAD+ riboswitch domains 1 and 2 determine differential folding and ligand binding

Chen

Egger

et al. 2020

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Riboswitches are important gene regulatory elements frequently encountered in bacterial mRNAs. The recently discovered nadA riboswitch contains two similar, tandemly arrayed aptamer domains, with the first domain possessing high affinity for nicotinamide adenine dinucleotide (NAD+). The second domain which comprises the ribosomal binding site in a putative regulatory helix, however, has withdrawn from detection of ligand-induced structural modulation thus far, and therefore, the identity of the cognate ligand and the regulation mechanism have remained unclear. Here, we report crystal structures of both riboswitch domains, each bound to NAD+. Furthermore, we demonstrate that ligand binding to domain 2 requires significantly higher concentrations of NAD+ (or ADP retaining analogs) compared to domain 1. Using a fluorescence spectroscopic approach, we further shed light on the structural features which are responsible for the different ligand affinities, and describe the Mg2+-dependent, distinct folding and pre-organization of their binding pockets. Finally, we speculate about possible scenarios for nadA RNA gene regulation as a putative two-concentration sensor module for a time-controlled signal that is primed and stalled by the gene regulation machinery at low ligand concentrations (domain 1), and finally triggers repression of translation as soon as high ligand concentrations are reached in the cell (domain 2).

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Crucial Roles of Two Hydrated Mg²⁺ Ions in Reaction Catalysis of the Pistol Ribozyme

Teplova

Falschlunger²,

Krasheninina³

et al. 2020

Angew Chem Int Ed

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Pistol ribozymes constitute anew class of small selfcleaving RNAs.Crystal structures have been solved, providing three-dimensional snapshots along the reaction coordinate of pistol phosphodiester cleavage,c orresponding to the precatalytic state,avanadate mimic of the transition state,a nd the product. The results led to the proposed underlying chemical mechanism. Importantly,ahydrated Mg 2+ ion remains innersphere-coordinated to N7 of G33 in all three states,a nd is consistent with its likely role as acid in general acid base catalysis (d and b catalysis). Strikingly,t he new structures shed light on as econd hydrated Mg 2+ ion that approaches the scissile phosphate from its binding site in the pre-cleavage state to reacho ut for water-mediated hydrogen bonding in the cyclophosphate product. The major role of the second Mg 2+ ion appears to be the stabilization of product conformation. This study delivers amechanistic understanding of ribozyme-catalyzed backbone cleavage.

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Insights into xanthine riboswitch structure and metal ion-mediated ligand recognition

Egger

Chen

et al. 2021

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Riboswitches are conserved functional domains in mRNA that mostly exist in bacteria. They regulate gene expression in response to varying concentrations of metabolites or metal ions. Recently, the NMT1 RNA motif has been identified to selectively bind xanthine and uric acid, respectively, both are involved in the metabolic pathway of purine degradation. Here, we report a crystal structure of this RNA bound to xanthine. Overall, the riboswitch exhibits a rod-like, continuously stacked fold composed of three stems and two internal junctions. The binding-pocket is determined by the highly conserved junctional sequence J1 between stem P1 and P2a, and engages a long-distance Watson–Crick base pair to junction J2. Xanthine inserts between a G–U pair from the major groove side and is sandwiched between base triples. Strikingly, a Mg2+ ion is inner-sphere coordinated to O6 of xanthine and a non-bridging oxygen of a backbone phosphate. Two further hydrated Mg2+ ions participate in extensive interactions between xanthine and the pocket. Our structure model is verified by ligand binding analysis to selected riboswitch mutants using isothermal titration calorimetry, and by fluorescence spectroscopic analysis of RNA folding using 2-aminopurine-modified variants. Together, our study highlights the principles of metal ion-mediated ligand recognition by the xanthine riboswitch.

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Impact of 3-deazapurine nucleobases on RNA properties

Bereiter

Himmelstoß

Renard

et al. 2021

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Deazapurine nucleosides such as 3-deazaadenosine (c3A) are crucial for atomic mutagenesis studies of functional RNAs. They were the key for our current mechanistic understanding of ribosomal peptide bond formation and of phosphodiester cleavage in recently discovered small ribozymes, such as twister and pistol RNAs. Here, we present a comprehensive study on the impact of c3A and the thus far underinvestigated 3-deazaguanosine (c3G) on RNA properties. We found that these nucleosides can decrease thermodynamic stability of base pairing to a significant extent. The effects are much more pronounced for 3-deazapurine nucleosides compared to their constitutional isomers of 7-deazapurine nucleosides (c7G, c7A). We furthermore investigated base pair opening dynamics by solution NMR spectroscopy and revealed significantly enhanced imino proton exchange rates. Additionally, we solved the X-ray structure of a c3A-modified RNA and visualized the hydration pattern of the minor groove. Importantly, the characteristic water molecule that is hydrogen-bonded to the purine N3 atom and always observed in a natural double helix is lacking in the 3-deazapurine-modified counterpart. Both, the findings by NMR and X-ray crystallographic methods hence provide a rationale for the reduced pairing strength. Taken together, our comparative study is a first major step towards a comprehensive understanding of this important class of nucleoside modifications.

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Scaling Catalytic Contributions of Small Self‐Cleaving Ribozymes

et al. 2022

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Nucleolytic ribozymes utilize general acid-base catalysis to perform phosphodiester cleavage. In most ribozyme classes, a conserved active site guanosine is positioned to act as general base, thereby activating the 2'-OH group to attack the scissile phosphate (γ-catalysis). Here, we present an atomic mutagenesis study for the pistol ribozyme class. Strikingly, "general base knockout" by replacement of the guanine N1 atom by carbon results in only 2.7-fold decreased rate. Therefore, the common view that γ-catalysis critically depends on the N1 moiety becomes challenged. For pistol ribozymes we found that γ-catalysis is subordinate in overall catalysis, made up by two other catalytic factors (α and δ). Our approach allows scaling of the different catalytic contributions (α, β, γ, δ) with unprecedented precision and paves the way for a thorough mechanistic understanding of nucleolytic ribozymes with active site guanines.

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Michaela Egger

Structural distinctions between NAD+ riboswitch domains 1 and 2 determine differential folding and ligand binding

Crucial Roles of Two Hydrated Mg²⁺ Ions in Reaction Catalysis of the Pistol Ribozyme

Insights into xanthine riboswitch structure and metal ion-mediated ligand recognition

Impact of 3-deazapurine nucleobases on RNA properties

Scaling Catalytic Contributions of Small Self‐Cleaving Ribozymes

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Michaela Egger

Structural distinctions between NAD+ riboswitch domains 1 and 2 determine differential folding and ligand binding

Crucial Roles of Two Hydrated Mg2+ Ions in Reaction Catalysis of the Pistol Ribozyme

Insights into xanthine riboswitch structure and metal ion-mediated ligand recognition

Impact of 3-deazapurine nucleobases on RNA properties

Scaling Catalytic Contributions of Small Self‐Cleaving Ribozymes

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Product

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Crucial Roles of Two Hydrated Mg²⁺ Ions in Reaction Catalysis of the Pistol Ribozyme