Double-stranded RNA under force and torque: Similarities to and striking differences from double-stranded DNA

Lipfert, Jan; Skinner, Gary M.; Keegstra, Johannes M.; Hensgens, Toivo; Jager, Tessa; Dulin, David; Köber, Mariana; Yu, Zhongbo; Donkers, Serge; Chou, Fang‐Chieh; Das, Rhiju; Dekker, Nynke H.

doi:10.1073/pnas.1407197111

Cited by 170 publications

(292 citation statements)

References 58 publications

Supporting

Mentioning

258

Contrasting

Order By: Relevance

“…Direct evidence of the interplay between mechanical stress and biological activity has been provided via single-molecule experiments (13,14). Indeed, techniques such as optical and magnetic tweezers (1,13,14) have emerged as essential tools in the characterization of the mechanical properties of dsDNA (1) and, most recently, dsRNA (5,6,15).…”

mentioning

confidence: 99%

“…The analysis of single-molecule force extension data with a continuum mechanics approach, the so-called elastic rod model (17,18), reveals two particularly striking results: the threefold softer stretching response of dsRNA compared with dsDNA (6) and the opposite sign of the twist-stretch coupling (2,3,5,19). Ad hoc model extensions, such as the addition of an outer helical wire (2), and several models at the base-pair level (5,20) have been proposed to rationalize some of these results.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Understanding the mechanical response of double-stranded DNA and RNA under constant stretching forces using all-atom molecular dynamics

Marín-González

Vilhena

Pérez

et al. 2017

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

152

View full text Add to dashboard Cite

Multiple biological processes involve the stretching of nucleic acids (NAs). Stretching forces induce local changes in the molecule structure, inhibiting or promoting the binding of proteins, which ultimately affects their functionality. Understanding how a force induces changes in the structure of NAs at the atomic level is a challenge. Here, we use all-atom, microsecond-long molecular dynamics to simulate the structure of dsDNA and dsRNA subjected to stretching forces up to 20 pN. We determine all of the elastic constants of dsDNA and dsRNA and provide an explanation for three striking differences in the mechanical response of these two molecules: the threefold softer stretching constant obtained for dsRNA, the opposite twist-stretch coupling, and its nontrivial force dependence. The lower dsRNA stretching resistance is linked to its more open structure, whereas the opposite twist-stretch coupling of both molecules is due to the very different evolution of molecules' interstrand distance with the stretching force. A reduction of this distance leads to overwinding in dsDNA. In contrast, dsRNA is not able to reduce its interstrand distance and can only elongate by unwinding. Interstrand distance is directly correlated with the slide base-pair parameter and its different behavior in dsDNA and dsRNA traced down to changes in the sugar pucker angle of these NAs.

show abstract

mentioning

confidence: 99%

mentioning

confidence: 99%

Understanding the mechanical response of double-stranded DNA and RNA under constant stretching forces using all-atom molecular dynamics

Marín-González

Vilhena

Pérez

et al. 2017

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

152

View full text Add to dashboard Cite

show abstract

“…The slope of the hat curves, about 40 nm per turn, can significantly increase at low stretching force [80,81]. The critical level of DNA supercoiling required to extrude the plectoneme increases with increasing tension.…”

Section: Twisting Dna With Magnetic Tweezersmentioning

confidence: 99%

“…Production of labeled RNA molecules has been achieved with the help of in vitro transcription [52,81]. To this end, dsDNA templates were constructed that give rise to complementary RNA strands with unique leader sequences to facilitate further cloning.…”

Section: Custom Dna Substratesmentioning

confidence: 99%

See 1 more Smart Citation

A Guide to Magnetic Tweezers and Their Applications

Sarkar

Rybenkov

2016

Front. Phys.

View full text Add to dashboard Cite

Magnetic force spectroscopy is a rapidly developing single molecule technique that has found numerous applications at the interface of physics and biology. Since the invention of the first magnetic tweezers, a number of modifications to the approach have helped to relieve the limitations of the original design while amplifying its strengths. Inventive molecular biology solutions further advanced the technique by expanding its possible applications. In its present form, the method can be applied to both single molecules and live cells without resorting to intense irradiation, can be easily multiplexed, accommodates multiple DNAs, displays impressive resolution, and allows a remarkable ease in the stretching and twisting of macromolecules. In this review, we describe the architecture of magnetic tweezers, key requirements for experimental design and analysis of data, and outline several applications of the method that illustrate its versatility.

show abstract

All I's on the RADAR: role of ADAR in gene regulation

Shevchenko

Morris

2018

FEBS Letters

View full text Add to dashboard Cite

Adenosine to inosine (A-to-I) editing is the most abundant form of RNA modification in mammalian cells, which is catalyzed by adenosine deaminase acting on the double-stranded RNA (ADAR) protein family. A-to-I editing is currently known to be involved in the regulation of the immune system, RNA splicing, protein recoding, microRNA biogenesis, and formation of heterochromatin. Editing occurs within regions of double-stranded RNA, particularly within inverted Alu repeats, and is associated with many diseases including cancer, neurological disorders, and metabolic syndromes. However, the significance of RNA editing in a large portion of the transcriptome remains unknown. Here, we review the current knowledge about the prevalence and function of A-to-I editing by the ADAR protein family, focusing on its role in the regulation of gene expression. Furthermore, RNA editing-independent regulation of cellular processes by ADAR and the putative role(s) of this process in gene regulation will be discussed.

show abstract

Double-stranded RNA under force and torque: Similarities to and striking differences from double-stranded DNA

Cited by 170 publications

References 58 publications

Understanding the mechanical response of double-stranded DNA and RNA under constant stretching forces using all-atom molecular dynamics

Understanding the mechanical response of double-stranded DNA and RNA under constant stretching forces using all-atom molecular dynamics

A Guide to Magnetic Tweezers and Their Applications

All I's on the RADAR: role of ADAR in gene regulation

Contact Info

Product

Resources

About