Probing stability, specificity, and modular structure in group I intron RNAs

Wan, Yaqi

03 February 2011

Many functional RNAs are required to fold into specific three-dimensional structures. A fundamental property of RNA is that its secondary structure and even some tertiary contacts are highly stable, which gives rise to independent modular RNA motifs and makes RNAs prone to adopting misfolded intermediates. Consequently, in addition to stabilizing the native structure relative to the unfolded species (defined here as stability), RNAs are faced with the challenge of stabilizing the native structure relative to alternative structures (defined as structural specificity). How RNAs have evolved to overcome these challenges is incompletely understood. Self-splicing group I introns have been used to study RNA structure and folding for decades. Among them, the Tetrahymena intron was the first discovered and has been studied extensively. In this work, we found that a version of the intron that was generated by in vitro selection for enhanced stability also displayed enhanced specificity against a stable misfolded structure that is globally similar to the native state, despite the absence of selective pressure to increase the energy gap between these structures. Further dissection suggests that the increased specificity against misfolding arises from two point mutations, which strengthen a local tertiary contact network that apparently cannot form in the misfolded conformation. Our results suggest that the structural rigidity and intricate networks of contacts inherent to structured RNAs can allow them to evolve exquisite structural specificity without explicit negative selection, even against closely-related alternative structures. To explore further how RNAs gain stability from intricate architectures, we examined a novel group I intron from red algae (Bangia). Biochemical methods and computational modeling suggest that this intron possesses general motifs of group IC1 introns but also forms an atypical tertiary contact, which has been reported previously in other subgroups and helps position the reactive helix at the active site. In the Bangia intron, the partners have been swapped relative to known group I RNAs that include this contact. This result underscores the modular nature of RNA motifs and provides insight into how structured RNAs can arrange helices and contacts in multiple ways to achieve and stabilize functional structures. / text

Group I ribozyme

RNA structure

Structural specificity

RNA folding

Bangia

RNA

Tetrahymena

Introns

Group I introns

A Reduction in Structural Specificity by Polar-to-Hydrophobic Surface Substitutions in the Arc Repressor Protein: A Romance of Three Folds

Stewart, Katie Lynn

January 2013

Most amino acid sequences are predicted to specify a single three-dimensional protein structure. However, the identification of "metamorphic" proteins, which can adopt two folds from a single amino acid sequence, has challenged the one sequence/one structure paradigm. Polar-to-hydrophobic substitutions have been suggested computationally as one mechanism to decrease structural specificity, allowing the population of novel folds. Here, we experimentally investigate the role of polar-to-hydrophobic substitutions on structural specificity in the homodimeric ribbon-helix-helix protein Arc repressor. Previous work showed that a single polar-to-hydrophobic surface substitution in the strand region of Arc repressor (Arc-N11L) populates the wild-type fold and a novel dimeric "switch" fold. In this work, we investigate an Arc repressor variant with the N11L substitution plus two additional polar-to-hydrophobic surface substitutions (Arc-S-VLV). We determine that this sequence folds into at least three structures: both dimer forms present in Arc-N11L, and a novel octamer structure containing higher stability and less helicity than the dimer folds. We are able to isolate and stabilize a core of the S-VLV octamer by limited trypsinolysis and deletion mutagenesis (Arc-VLV 4-44). The shortened construct contains only the octameric structure by removing disordered C-terminal segments nonessential for this fold. A two-dimensional NMR spectrum of VLV 4-44 and subsequent trypsinolysis of this construct suggests that at least two types of subunits comprise the S-VLV octamer: subunits structured from residues 4 to 44 and subunits structured from residues 4 to 31. Crystal trials of trypsinolyzed Arc-VLV 4-44 yielded several leads, suggesting that obtaining a high resolution structure of the S-VLV octamer is possible. Relatedly, we determine that the proline residues flanking the Arc repressor strand act in concert as "gatekeepers" to prevent aggregation in the S-VLV sequence. We also find that three highly hydrophobic surface substitutions in the Arc repressor strand region are necessary and sufficient to promote higher-order oligomer formation. In summation, this work reveals in an experimental context that progressive increases in polar-to-hydrophobic surface substitutions populate increasingly diverse, structurally degenerate folds. These results suggest that "metamorphic" as well as "polymetamorphic" proteins, which adopt numerous folds, are possible outcomes for a single protein sequence.

fold switching

polar-to-hydrophobic substitutions

polymetamorphic protein

structural degeneracy

structural specificity

Biochemistry

Arc repressor

La free R Méthionine sulfoxyde réductase (fRMsr) de Neisseria meningitidis : Mécanisme, catalyse et spécificité structurale / The Free R Methionine sulfoxide reductase (fRMsr) from Neisseria meningitidis : Mecanism, catalysis and specificity

Libiad, Marouane

12 October 2012

Les Méthionine sulfoxyde réductases (Msr) catalysent la réduction spécifique des méthionine sulfoxydes (Met-O) en méthionines (Met). Elles sont impliquées dans la résistance des cellules à un stress oxydant et dans la virulence des bactéries pathogènes du genre Neisseria. Cette famille d'enzyme se compose de trois classes, les MsrA et B, structuralement distinctes, et présentant une stéréosléctivité respectivement pour l'isomère S et R de la fonction sulfoxyde du substrat. Une troisième classe, découverte récemment, et appelée fRMsr, catalyse la réduction spécifique de la forme libre de l'isomère R de la fonction sulfoxyde. La fRMsr appartient à la famille des domaines GAF, généralement impliqués dans la signalisation cellulaire, et les fRMsr représentent le premier domaine GAF présentant une activité enzymatique. Les études réalisées au cours de ma thèse sur la fRMsr de Neisseria meningitidis ont permis de montrer que : 1) fRMsr de N. meningitidis présente un mécanisme catalytique identique à MsrA/B avec la formation d'au moins un pont disulfure intramoléculaire Cys84-Cys118 réduit par la thiorédoxine (Trx) ; 2) La Cys118 est le résidu catalytique sur lequel l'intermédiaire acide sulfénique doit se former ; 3) L'étape réductase est l'étape cinétiquement déterminante du mécanisme à deux étapes conduisant à la formation du pont disulfure Cys84-Cys118. La combinaison de l'analyse des résultats cinétiques, et de la structure tridimensionnelle de la fRMsr de N. meningitidis en complexe avec le substrat ont permis de montrer : 1) L'existence d'un site de reconnaissance oxyanion impliqué dans la stabilisation de la fonction carboxylate ; 2) Un rôle de la fonction carboxylate du résidu Asp143 dans la catalyse de l'étape réductase ; 3) Le résidu Glu125 est impliqué dans la reconnaissance et/ou le positionnement du substrat Met-O probablement via la stabilisation du groupement NH3+ ; 4) Un rôle du résidu Asp141 dans le positionnement des résidus Asp143 et Glu125 ; 5) le noyau indole du Trp62 est impliqué dans la stabilisation du groupe méthyle-[epsilon] / Methionine sulfoxide reductases (Msr) catalyze the specific reduction of methionine sulfoxides (Met-O) into methionine (Met). They are involved in cell defences against oxidative stress and virulence of pathogenic bacteria of Neisseria genius. This family of enzymes consists of three classes, MsrA and MsrB, structurally-unrelated, Specific for the S and the R epimer of the sulfoxide function of the substrate, respectively. A third class, recently discovered and called fRMsr, selectively reduce the free form of the R epimer of the sulfoxide function. The fRMsr belongs to the family of GAF domains, they are usually involved in cell signaling, and fRMsr represent the first GAF domain to show enzymatic activity. The studies of the Neisseria meningitidis fRMsr have shown that: 1) The Neisseria meningitidis fRMsr have a identical catalytic mechanism to MsrA and MsrB with the formation of at least one intramolecular disulfide bond, Cys84-Cys118 reduced by thioredoxin (Trx) ; 2) The Cys118 is demonstrated to be the catalytic Cys on which a sulfenic acid is formed ; 3) The Reductase step is the rate determining step of the mechanism leading to the formation of the disulfide bond Cys84-Cys118. The combination of the biochemical and kinetics data, and the examination of the 3D structure of the N. meningitidis fRMsr in complex with its substrate shown: 1) an oxyanion hole involved in the accommodation of the carboxylate group ; 2) the carboxylate group of the Asp143 residue involved in the catalysis of step reductase, and 3) The Glu125 residue involved in the recognition and/or positioning of the Met-O probably by the stabilization of the NH3+; 4) the Asp141 residue involved in the positioning of Asp143 and Glu125 residues ; 5) the indole ring of the Trp62 residue involved in stabilizing of the epsilon-methyl group

Méthionine sulfoxyde réductase

FRMsr

Domaine GAF

Mécanisme catalytique

Catalyse

Spécificité structurale

Methionine sulfoxide reductase

FRMsr

GAF domain

Catalytic mechanism

Catalysis

Structural specificity

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