Nanomechanical measurements of the sequence-dependent folding landscapes of single nucleic acid hairpins

Woodside, Michael T.; Behnke-Parks, William M.; Larizadeh, Kevan; Travers, Kevin; Herschlag, Daniel; Block, Steven M.

doi:10.1073/pnas.0511048103

Cited by 427 publications

(624 citation statements)

References 58 publications

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“…4.4A shows the first type of unfolding behavior, termed "Type 1" in which the A24G mutant unfolds in a single step at some force, F, but upon relaxation (red curve) refolds event at a lower force than the unfolding force. This behavior had not been observed for the wild-type BWYV pseudoknot or the mutants stretched up to this point (see Chapter 3), but the behavior has been observed for RNA hairpins and pseudoknot structures (26,28,51,106). It signifies that the refolding kinetics is slower than the pulling rate, but that we may be approaching an equilibrium state were the stretching performed slightly slower (perhaps 1-2 pN/s slower).…”

Section: Stretching Of An A24g Mutant Pseudoknotmentioning

confidence: 87%

Mechanical Unfolding of the Beet Western Yellow Virus −1 Frameshift Signal

et al. 2011

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Section: Stretching Of An A24g Mutant Pseudoknotmentioning

confidence: 87%

Mechanical Unfolding of the Beet Western Yellow Virus −1 Frameshift Signal

et al. 2011

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“…This approach has answered one of the most fundamental questions in nucleic acid structure formation, providing direct evidence for the long-held nucleation model for duplex involving formation of 2-3 base pairs prior to rapid formation of the remainder of the duplex [107]. Further, it has been shown that force unfolding data can be deconstructed into a complete energy landscape [108].…”

Section: Rna: Present and Futurementioning

confidence: 99%

Unwinding RNA's secrets: advances in the biology, physics, and modeling of complex RNAs

Chu

Herschlag

2008

Current Opinion in Structural Biology

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SummaryThe rapid development of our understanding of the diverse biological roles fulfilled by non-coding RNA has motivated interest in the basic macromolecular behavior, structure, and function of RNA. We focus on two areas in the behavior of complex RNAs. First, we present advances in the understanding of how RNA folding is accomplished in vivo by presenting a mechanism for the action of DEAD-box proteins. Members of this family are intimately associated with almost all cellular processes involving RNA, mediating RNA structural rearrangements and chaperoning their folding. Next, we focus on advances in understanding and characterizing the basic biophysical forces that govern the folding of complex RNAs. Ultimately we expect that a confluence and synergy between these approaches will lead to profound understanding of RNA and its biology.The explosion in our knowledge about noncoding RNA (ncRNA) -RNA that is not translated into protein -has expanded interest in RNA beyond the traditional RNA community. Diverse ncRNAs include the recently-discovered riboswitches, whose novel gene-regulation function is induced by the binding of small metabolites [1]; most of the so-called "Human Accelerated Regions" (HAR) of the human genome, whose recent evolution may be linked to the emergence of the human brain [2]; and many ncRNAs of unknown function [3]. These discoveries underscore the need to understand the fundamental macromolecular behavior of RNA, its structure and dynamics, and how these RNAs are handled and exploited in biology.Study of catalytic RNAs, which allow detection of correct folding via activity measurements, has established basic thermodynamic and kinetic properties of RNA folding. Large catalytic RNAs such as the group I intron from Tetrahymena thermophila and the RNase P RNA from Bacillus subtilis fold at vastly different rates under different conditions upon addition of Mg 2+ and have been shown to fold via multiple parallel pathways, in which different molecules follow different routes with different rates and intermediates, to a common final folded structure [4,5]. These observations support the common view that RNAs traverse rugged energy landscapes as they fold [6,7]. However, little is known about the true shape of these

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“…Woodside et al recently measured the thermodynamics and kinetics of 20 different DNA hairpins with different stem lengths, G·C content and loop sizes (Woodside et al 2006). Their work illustrates how folding free energies and rate constants critically depend on the sequences and structures of the hairpins.…”

Section: Kinetics Of Unfolding-mentioning

confidence: 99%

Determination of thermodynamics and kinetics of RNA reactions by force

Tinoco

Bustamante

2006

Quart. Rev. Biophys.

106

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Single-molecule methods have made it possible to apply force to an individual RNA molecule. Two beads are attached to the RNA; one is on a micropipette, the other is in a laser trap. The force on the RNA and the distance between the beads are measured. Force can change the equilibrium and the rate of any reaction in which the product has a different extension from the reactant. This review describes use of laser tweezers to measure thermodynamics and kinetics of unfolding/refolding RNA. For a reversible reaction the work directly provides the free energy; for irreversible reactions the free energy is obtained from the distribution of work values. The rate constants for the folding and unfolding reactions can be measured by several methods. The effect of pulling rate on the distribution of force-unfolding values leads to rate constants for unfolding. Hopping of the RNA between folded and unfolded states at constant force provides both unfolding and folding rates. Force-jumps and force-drops, similar to the temperature jump method, provide direct measurement of reaction rates over a wide range of forces. The advantages of applying force and using single-molecule methods are discussed. These methods, for example, allow reactions to be studied in non-denaturing solvents at physiological temperatures; they also simplify analysis of kinetic mechanisms because only one intermediate at a time is present. Unfolding of RNA in biological cells by helicases, or ribosomes, has similarities to unfolding by force.

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Nanomechanical measurements of the sequence-dependent folding landscapes of single nucleic acid hairpins

Cited by 427 publications

References 58 publications

Mechanical Unfolding of the Beet Western Yellow Virus −1 Frameshift Signal

Mechanical Unfolding of the Beet Western Yellow Virus −1 Frameshift Signal

Unwinding RNA's secrets: advances in the biology, physics, and modeling of complex RNAs

Determination of thermodynamics and kinetics of RNA reactions by force

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