Real‐Time Atomistic Description of DNA Unfolding

Pérez, Alberto; Orozco, Modesto

doi:10.1002/ange.201000593

Cited by 13 publications

(16 citation statements)

References 20 publications

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“…24 Experiments and theory have shown that this oligonucleotide folds on a (multi)microsecond time scale 25−27 in water, and should unfold on a similar time scale in a denaturant solvent such as pyridine. 22 The small size of the system accelerates calculations, favors sampling, and reduces memory effects, which might be very important for longer oligonucleotides. Previous studies have demonstrated the ability of current force field and MD protocols to simulate this structure properly in a variety of environments.…”

Section: Methodsmentioning

confidence: 99%

Structure and Properties of DNA in Apolar Solvents

et al. 2014

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The study of nucleic acids in low-polarity environments paves the way for novel biotechnological applications of DNA. Here, we use a repertoire of atomistic molecular simulation tools to study the nature of DNA when placed in a highly apolar environment and when transferred from aqueous to apolar solvent. Our results show that DNA becomes stiffer in apolar solvents and suggest that highly negatively charged states, which are the most prevalent in water, are strongly disfavored in apolar solvents and neutral states with conformations not far from the aqueous ones are the dominant forms. Transfer from water to an apolar solvent such as CCl4 is unlikely to occur, but our results suggest that if forced, the DNA would migrate surrounded by a small shell of water (the higher the DNA charge, the larger the number of water molecules in this shell). Even the neutral form (predicted to be the dominant one in apolar solvents) would surround itself by a small number of highly stable water molecules when moved from water to a highly apolar environment. Neutralization of DNA charges seems a crucial requirement for transfer of DNA to apolar media, and the most likely mechanism to achieve good transfer properties.

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Section: Methodsmentioning

confidence: 99%

Structure and Properties of DNA in Apolar Solvents

et al. 2014

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“…Because of the long timescales involved in the structure formation process of nucleic acids the reverse process of unfolding stable structures has been studied using MD simulations at elevated temperatures . The increased simulation temperature can significantly accelerate conformational transitions and shifts relative free energies of conformational states and can lower free energy barriers.…”

Section: Computational Approaches For Structure Prediction Of Rnamentioning

confidence: 99%

“…Similar to unfolding of proteins, the study of the unfolding process of nucleic acids can also give insights into putative intermediate states of the folding process. The method has been used extensively to study the coupled dissociation and unfolding of a DNA duplex dodecamer and the unfolding of nucleic acid hairpin structures . Alternatively, unfolding can be induced by applying an external force on the molecule to disrupt a key interaction that stabilizes the 3D conformation.…”

Section: Computational Approaches For Structure Prediction Of Rnamentioning

confidence: 99%

Theoretical studies of nucleic acids folding

Kara

Zacharias²

2013

WIREs Comput Mol Sci

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The mechanism of how RNA and DNA molecules fold into defined threedimensional (3D) structures is still not well understood. Molecular simulation approaches are increasingly being used to study structure formation processes of nucleic acids and to understand the driving forces for folding. It is possible to use molecular dynamics (MD) simulations based on a classical force field to follow the dynamics of nucleic acids at atomic resolution and high time resolution and including surrounding solvent molecules and ions explicitly. Recent studies indicate that it is possible to investigate folding of small motifs such as hairpin structures using MD simulations. However, this approach is still limited by the currently accessible time scales and force field accuracy. Advanced sampling methods such as the replica-exchange MD (REMD) approach allow significant enhancement of conformational sampling of nucleic acids and could help to systematically study structure formation processes and to refine force fields. In case of large RNAs or RNA containing macromolecular structures, coarse-grained representations can help to overcome current computational limitations. In combination with experimentally derived constraints and predicted secondary structure, several approaches have been developed to fold RNA molecules into possible 3D structures. Such structural model can often be helpful to plan experiments or to interpret experimental results. C 2013 John Wiley & Sons, Ltd.

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“…In the view of the complexity of problems related to the DNA physics, computer modeling has always played an important role in bridging the gap between the bulk experiments and molecular‐level understanding. The currently available all atom (AA) force fields have significantly evolved since their inception in the 1980s21,22 and are now able to reproduce a diverse set of subtle structural fluctuations that take place from pico‐ to microsecond timescales 23–27…”

Section: Introductionmentioning

confidence: 99%

Recent successes in coarse‐grained modeling of DNA

Potoyan

Savelyev

Papoian

2012

WIREs Comput Mol Sci

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The growing interest in the DNA-based mesoscale systems of biological and nonbiological nature has encouraged the computational molecular science community to develop coarse-grained (CG) representationsof the DNA that will be simple enough to permit exhaustive simulations in a reasonable amount of time, yet complex enough to capture the essential physics at play. In the recent years, there have been some major developments in the DNA coarse-graining area and several fairly sophisticated models are now available that faithfully reproduce key mechanical and chemical properties of the double-and single-stranded DNA. However, there are still many challenges, which limit the applicability of the present models, and much has to be done yet to develop more reliable schemes which would have a predictive power beyond the target domain of the intrinsic parametrization. A development of robust, controllable, and transferrable CG DNA force fields will provide an invaluable tool for gaining physical insights into the molecular nature of complex DNA-based nanoscale entities such as the chromatin, virus capsids, and DNA nanocomposites. In the present contribution, we provide an overview of the recent developments in the DNA coarse-graining field. Our aim is to review the existing CG models of the double-stranded DNA, where a small selection of models, which we believe provide avenues for promising future development, are discussed in some detail. C 2012 John Wiley & Sons, Ltd. tour length of DNA in a micrometer-sized nucleus of a eukaryotic cell is of the order of 1 m. 14 The physical basis and the biological implications of the nearly million-fold compression of the highly charged and relatively stiff macromolecule are currently actively investigated. In vivo, DNA is packed into chromatin fibers in complexation with positively charged proteins, called histones. Despite structural condensation and packing, the chromatin organization allows retrieval of the desired portions of DNA in a timely manner for processing and manipulation. 11,15 Developing a more complete physical picture of DNA in isolation as well when complexed with various proteins is needed for making further progress in uncovering the principles of genetic regulation in biology.Recently, a great interest has also emerged in the nonbiological applications of the DNA, namely, the design of the DNA-based nanoscale materials. 16 Through the pioneering works of Seeman and coworkers on DNA nanoassembly, the programmable design of the DNA nanomaterials

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Real‐Time Atomistic Description of DNA Unfolding

Cited by 13 publications

References 20 publications

Structure and Properties of DNA in Apolar Solvents

Structure and Properties of DNA in Apolar Solvents

Theoretical studies of nucleic acids folding

Recent successes in coarse‐grained modeling of DNA

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