Free-Energy Landscape of RNA Hairpins Constructed via Dihedral Angle Principal Component Analysis

Riccardi, Laura; Nguyen, Phuong H.; Stock, Gerhard

doi:10.1021/jp9076036

Cited by 61 publications

(89 citation statements)

References 78 publications

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“…The methodology stresses on the large dimensionality of the model essential for timescale separation. 17 Similar ideas arise from our multiscale analysis developed in Sec. III and other papers.…”

Section: Introductionmentioning

confidence: 71%

“…In this way, they capture key pathways for structural transitions and associated energy barriers. Earlier choices for OP-like variables include principal component analysis (PCA) modes to identify collective behaviors in macromolecular systems, [13][14][15] dihedral angles, 16,17 curvilinear coordinates to characterize macromolecular folding and coiling, 18 bead models wherein a peptide or nucleotide is represented by a bead which interacts with others via a phenomenological force, and spatial coarse-grained models. [19][20][21] These approaches suffer from one or more of the following difficulties: (1) characteristic variables are not slowly varying in time; (2) macromolecular twist is not readily accounted for; (3) their internal dynamics, and hence inelasticity of their collisions is neglected; and (4) the forces involved must be calibrated for most new applications.…”

Section: Introductionmentioning

confidence: 99%

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Order parameters for macromolecules: Application to multiscale simulation

Singharoy

Cheluvaraja

Ortoleva

2011

The Journal of Chemical Physics

175

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Order parameters (OPs) characterizing the nanoscale features of macromolecules are presented. They are generated in a general fashion so that they do not need to be redesigned with each new application. They evolve on time scales much longer than 10 −14 s typical for individual atomic collisions/vibrations. The list of OPs can be automatically increased, and completeness can be determined via a correlation analysis. They serve as the basis of a multiscale analysis that starts with the N-atom Liouville equation and yields rigorous Smoluchowski/Langevin equations of stochastic OP dynamics. Such OPs and the multiscale analysis imply computational algorithms that we demonstrate in an application to ribonucleic acid structural dynamics for 50 ns.

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Section: Introductionmentioning

confidence: 71%

Section: Introductionmentioning

confidence: 99%

Order parameters for macromolecules: Application to multiscale simulation

Singharoy

Cheluvaraja

Ortoleva

2011

The Journal of Chemical Physics

175

View full text Add to dashboard Cite

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“…As an alternative determination of the folded free-energy landscape, we performed a principal component analysis of the dihedral angles (dPCA) (30,31) of the configurational ensembles in the lowest temperatures. The first two principal components provided an optimal separation of conformations and effectively described the entire free-energy ensemble in six general configurations (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Additional corrections will be necessary in future modifications to the AMBER force field. Characterizing the free-energy landscapes of RNA tetraloops has long been a goal for RNA molecular simulations and has been the subject of multiple studies on different loop systems using a variety of molecular dynamics techniques (25,26,31,42,49,50). In this study, we have determined that the free-energy landscape of an RNA tetraloop can be rigorously characterized through extensive REMD simulations and that analysis of multiple global and internal degrees of freedom can describe a plethora of configurations associated with these landscapes.…”

Section: Discussionmentioning

confidence: 99%

“…To characterize the different minima of the folding free-energy landscape and identify the barriers between native and nonnative tetraloop configurations, we use dPCA (30,31) of RNA-specific backbone and sugar nucleobase dihedral angles (α, β, γ, δ, e, ζ, and χ). Individual peaks are analyzed with the aforementioned clustering methods, and the first centroid is used to identify individual basins.…”

Section: Methodsmentioning

confidence: 99%

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Free-energy landscape of a hyperstable RNA tetraloop

Miner

Chen

Garcı́a

2016

Proc. Natl. Acad. Sci. U.S.A.

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We report the characterization of the energy landscape and the folding/unfolding thermodynamics of a hyperstable RNA tetraloop obtained through high-performance molecular dynamics simulations at microsecond timescales. Sampling of the configurational landscape is conducted using temperature replica exchange molecular dynamics over three isochores at high, ambient, and negative pressures to determine the thermodynamic stability and the freeenergy landscape of the tetraloop. The simulations reveal reversible folding/unfolding transitions of the tetraloop into the canonical A-RNA conformation and the presence of two alternative configurations, including a left-handed Z-RNA conformation and a compact purine Triplet. Increasing hydrostatic pressure shows a stabilizing effect on the A-RNA conformation and a destabilization of the lefthanded Z-RNA. Our results provide a comprehensive description of the folded free-energy landscape of a hyperstable RNA tetraloop and highlight the significant advances of all-atom molecular dynamics in describing the unbiased folding of a simple RNA secondary structure motif.RNA | free-energy landscape | molecular dynamics | tetraloop | pressure T he stability of a folded RNA molecule depends on a complex set of interactions between the RNA with itself and the surrounding environment. Secondary RNA structures fold by a combination of complimentary base pairing, nucleotide stacking, and screening of the anionic phosphate backbone (1), but these interactions depend heavily on the local solution environment, and the RNA configuration can be either stabilized or destabilized by a number of extrinsic factors, including temperature (2), pressure (3), denaturants, and salt concentration (4). Even in simple RNA duplexes, changes in pressure and ion concentrations have been shown to drive the formation of alternative configurations (5, 6) and change the RNA folded ensemble. Characterizing the effects that these different factors have on the folded free-energy landscape of RNA is crucial for determining the thermodynamic stability of different RNA motifs and the probability of transitions between configurations.Small RNA hairpins have been used as a model system for characterizing RNA folding and stability for decades because of their small size, their ubiquitous presence in many natural systems, and the complexity of their internal interactions (7-11). Hairpins result when a single oligonucleotide strand bends 180°t o form an antiparallel duplex through complementary base pairing. The bent, single-stranded loop region is capable of forming complex hydrogen bond networks (12) or long-range interactions with other RNAs (13). Some of the most thermodynamically stable RNA hairpins form loop regions of 4 nt, called tetraloops (14), which are highly compact, structurally conserved, and typically stabilized by the formation of a network of hydrogen bonds (15) that decrease the loop conformational entropy.These tetraloop structures have been explored through multiple experimental (16-23) and computational...

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A Data‐Driven Accelerated Sampling Method for Searching Functional States of Proteins

Zhu

Yuan

et al. 2019

Advcd Theory and Sims

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Protein exhibits distinct characteristics in different functional states. The lack of structural information for proteins hinders the understanding of their function. Here, a data‐driven accelerated (DA2) sampling method is proposed, which is capable of searching new functional states of protein from a known structure with high efficiency. The key function of DA2 sampling is to drive the conformational change of protein along its intrinsic motion without introducing biased potential/force, where principle component analysis is applied on‐the‐fly to reduce the highly redundant information generated by molecular dynamics simulations. In this work, the capacity and accuracy of DA2 sampling are validated by using alanine dipeptide. This protocol is then applied to search for the closed state of N‐terminal calmodulin (nCaM) from the open one. The identified structure resembles the crystal structure of nCaM in its closed state, with a root‐mean‐square deviation between the two of only 1.8 Å. Interestingly, independent DA2 samplings disclose different open‐to‐closed transition pathways for nCaM, which is likely to have implications for its biological functions. Therefore, DA2 sampling is expected to play important roles in exploring functional states of a broad spectrum of proteins at atomic level that are not easily determined experimentally.

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Free-Energy Landscape of RNA Hairpins Constructed via Dihedral Angle Principal Component Analysis

Cited by 61 publications

References 78 publications

Order parameters for macromolecules: Application to multiscale simulation

Order parameters for macromolecules: Application to multiscale simulation

Free-energy landscape of a hyperstable RNA tetraloop

A Data‐Driven Accelerated Sampling Method for Searching Functional States of Proteins

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