Single-molecule transition-state analysis of RNA folding

Bokinsky, Gregory; Rueda, David; Misra, Vinod K.; Rhodes, M.; Gordus, Andrew; Babcock, Hazen P.; Walter, Nils G.; Zhuang, Xiaowei

doi:10.1073/pnas.1133280100

Cited by 201 publications

(301 citation statements)

References 52 publications

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“…6B). In support of this model, the formation of a compact intermediate that possesses native tertiary interactions (i.e., correctly oriented helices) is a key step during folding of large RNAs such as ribozymes (Bokinsky et al 2003;Buchmueller and Weeks 2003;Pyle et al 2007;Behrouzi et al 2012). The role of L3 very early in 60S subunit assembly is consistent with this compaction.…”

Section: Discussionsupporting

confidence: 52%

A hierarchical model for assembly of eukaryotic 60S ribosomal subunit domains

et al. 2014

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Despite having high-resolution structures for eukaryotic large ribosomal subunits, it remained unclear how these ribonucleoprotein complexes are constructed in living cells. Nevertheless, knowing where ribosomal proteins interact with ribosomal RNA (rRNA) provides a strategic platform to investigate the connection between spatial and temporal aspects of 60S subunit biogenesis. We previously found that the function of individual yeast large subunit ribosomal proteins (RPLs) in precursor rRNA (pre-rRNA) processing correlates with their location in the structure of mature 60S subunits. This observation suggested that there is an order by which 60S subunits are formed. To test this model, we used proteomic approaches to assay changes in the levels of ribosomal proteins and assembly factors in preribosomes when RPLs functioning in early, middle, and late steps of pre-60S assembly are depleted. Our results demonstrate that structural domains of eukaryotic 60S ribosomal subunits are formed in a hierarchical fashion. Assembly begins at the convex solvent side, followed by the polypeptide exit tunnel, the intersubunit side, and finally the central protuberance. This model provides an initial paradigm for the sequential assembly of eukaryotic 60S subunits. Our results reveal striking differences and similarities between assembly of bacterial and eukaryotic large ribosomal subunits, providing insights into how these RNA-protein particles evolved.

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Section: Discussionsupporting

confidence: 52%

A hierarchical model for assembly of eukaryotic 60S ribosomal subunit domains

et al. 2014

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confidence: 99%

“…However, NLPB approaches require high-resolution structural data, consider only electrostatic effects, and treat the structure of the RNA as if it were static, as opposed to the dynamic ensemble of conformations that is probably more typical for RNAs in solution. NLPB treatments are therefore most powerful as interpretive aids paired with data from other techniques, as demonstrated in recent studies employing fluorescently labeled helical junctions along with NLPB calculations to investigate junction folding and dynamics (13,16).In this study, we use ITC (17) to determine thermodynamic parameters for the folding of the hammerhead ribozyme (18), a three-way RNA helical junction. Recently, Lilley and coworkers reported ITC-measured values for Mg 2+ -binding and coupled folding of the hammerhead ribozyme and two folding mutants (19).…”

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confidence: 99%

Entropy-Driven Folding of an RNA Helical Junction: An Isothermal Titration Calorimetric Analysis of the Hammerhead Ribozyme

2004

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Helical junctions are extremely common motifs in naturally occurring RNAs, but little is known about the thermodynamics that drive their folding. Studies of junction folding face several challenges: non-two-state folding behavior, superposition of secondary and tertiary structural energetics, and drastically opposing enthalpic and entropic contributions to folding. Here we describe a thermodynamic dissection of the folding of the hammerhead ribozyme, a three-way RNA helical junction, by using isothermal titration calorimetry of bimolecular RNA constructs. By using this method, we show that tertiary folding of the hammerhead core occurs with a highly unfavorable enthalpy change, and is therefore entropically driven. Furthermore, the enthalpies and heat capacities of core folding are the same whether supported by monovalent or divalent ions. These properties appear to be general to the core sequence of bimolecular hammerhead constructs. We present a model for the ion-induced folding of the hammerhead core that is similar to those advanced for the folding of much larger RNAs, involving ion-induced collapse to a structured, non-native state accompanied by rearrangement of core residues to produce the native fold. In agreement with previous enzymological and structural studies, our thermodynamic data suggest that the hammerhead structure is stabilized in vitro predominantly by diffusely bound ions. Our approach addresses several significant challenges that accompany the study of junction folding, and should prove useful in defining the thermodynamic determinants of stability in these important RNA motifs.RNA helical junctions, single-stranded loops flanked by multiple double helices, are pervasive in known and predicted RNA structures. Helical junctions appear in a broad range of functional RNAs (1,2), including small and large ribozymes, mRNA untranslated regions, riboregulatory RNAs, snRNAs, and rRNAs. Alone or in complex with proteins, junctions may serve as the major tertiary structural elements of small RNAs or as critical elements in organizing much larger architectures. Despite their prominence, little is known about the forces that drive the folding of RNA helical junctions. Pairwise coaxial stacking and ion-dependent folding have emerged as common themes in junction architecture, but the exact role of central, looped regions and the energetics of the folding process are still unclear. As a result, there are currently no general principles of helical junction folding dependable enough for use in predicting RNA tertiary structure, much less in predicting the impact of solution conditions or bound ligands on junction stabilities. † This work was supported by IU, the IU Department of Chemistry, grants from the NIH (GM-065430 to A.L.F. and T32-GM07757 to IU/P.J.M.), the NSF (CHE-9909407 to A.L.F.) and an HHMI/Capstone award to J.C.T. Andrew Feig is a Cottrell Scholar of Research Corporation.*To whom correspondence should be addressed:Andrew L. Feig, Department of Chemistry, Indiana University, 800 E. Kirk...

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“…FRET at the single molecule level or smFRET is a powerful method to probe dynamic conformational changes and molecular level interactions of biomolecules 29,30 . For example, smFRET studies of the hairpin ribozyme have revealed heterogeneous folding kinetics and have dissected the cleavage and ligation reactions coupled with folding and unfolding reactions 28,[31][32][33] . Here we applied smFRET to the study of the conformational changes and cleavage reactions of a DNAzyme.…”

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confidence: 99%

Dissecting metal ion–dependent folding and catalysis of a single DNAzyme

et al. 2007

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Protein metalloenzymes use various modes for functions where metal-dependent global conformational change is required in some cases, but not in others. In contrast, most ribozymes appear to require a global folding that almost always precedes enzyme reactions. Herein we studied metal-dependent folding and cleavage activity of the 8-17 DNAzyme using single molecule fluorescence resonance energy transfer (FRET). Addition of Zn 2+ and Mg 2+ resulted in a folding step followed by cleavage reaction, suggesting that the DNAzyme may require metaldependent global folding for activation. In the presence of Pb 2+ , however, cleavage reaction occurred without a precedent folding step, suggesting that the DNAzyme may be prearranged to accept Pb 2+ for the activity. This feature may contribute to the remarkably fast Pb 2+ -dependent reaction of the DNAzyme. These results suggest that DNAzymes can use all modes of activation that metalloproteins use.Metal ion-dependent folding can play a critical role in metalloenzyme function. Understanding the relationship between folding and reaction is important in obtaining deeper insight into the enzyme mechanism. For protein metalloenzymes, an active-site metal-dependent global folding precedes enzymatic reaction in some cases while such a folding is not required in others 1 . These different modes of activation may fulfill different functions. For example, a reaction preceded by a folding step may be responsible for an allosteric effect in many enzyme functions, or such a folding step may contribute to the overall reaction. Competing Financial Interests StatementThe authors declare there are no competing financial interests. HHS Public Access Author Manuscript Author ManuscriptAuthor Manuscript Author ManuscriptIn the early 1980s, RNA molecules that can catalyze enzymatic reactions were discovered and named ribozymes 2,3 . This discovery was then followed by demonstrations in the 1990s that DNA can also act as enzymes, termed deoxyribozymes or DNAzymes 4-7 . With only four nucleotides as building blocks versus twenty in proteins, nucleic acid enzymes may need to recruit cofactors to perform some functions. Metal ions are a natural choice and indeed most nucleic acid enzymes require metal ions for function under physiological conditions and therefore, are metalloenzymes. Even though DNAzymes constitute the newest metalloenzyme family, they have already been used in a number of applications such as therapeutic agents 8 , biosensors [9][10][11][12] , and nanomaterials assembly 13 , often because DNAzymes are more stable against hydrolysis and more cost-effective to produce than proteins or ribozymes. A primary example is the 8-17 DNAzyme which cleaves a DNA substrate containing one RNA base at the cleavage site (Fig. 1a) Author Manuscript Author ManuscriptAuthor ManuscriptAuthor Manuscript DNAzyme constructsThe original 8-17 DNAzyme was labeled with a fluorophore (Alexa fluoro 488) and two quenchers (Dabcyl) for bulk cleavage activity assays (Fig. 1a). To carry out the smFRET...

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Single-molecule transition-state analysis of RNA folding

Cited by 201 publications

References 52 publications

A hierarchical model for assembly of eukaryotic 60S ribosomal subunit domains

A hierarchical model for assembly of eukaryotic 60S ribosomal subunit domains

Entropy-Driven Folding of an RNA Helical Junction: An Isothermal Titration Calorimetric Analysis of the Hammerhead Ribozyme

Dissecting metal ion–dependent folding and catalysis of a single DNAzyme

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