Hyperstretching DNA

K. Schakenraad; A.S. Biebricher; M. Sebregts; B. ten Bensel; E.J.G. Peterman; G.J.L. Wuite; I. Heller; C. Storm; P.A.M. van der Schoot

doi:10.1038/s41467-017-02396-1

Hyperstretching DNA

K. Schakenraad
, A.S. Biebricher
, M. Sebregts
, B. ten Bensel
, E.J.G. Peterman
, G.J.L. Wuite
, I. Heller
, C. Storm
, P.A.M. van der Schoot

Research output: Contribution to journal › Article › Academic › peer-review

25 Citations (Scopus)

139 Downloads (Pure)

Abstract

The three-dimensional structure of DNA is highly susceptible to changes by mechanical and biochemical cues in vivo and in vitro. In particular, large increases in base pair spacing compared to regular B-DNA are effected by mechanical (over)stretching and by intercalation of compounds that are widely used in biophysical/chemical assays and drug treatments. We present single-molecule experiments and a three-state statistical mechanical model that provide a quantitative understanding of the interplay between B-DNA, overstretched DNA and intercalated DNA. The predictions of this model include a hitherto unconfirmed hyperstretched state, twice the length of B-DNA. Our force-fluorescence experiments confirm this hyperstretched state and reveal its sequence dependence. These results pin down the physical principles that govern DNA mechanics under the influence of tension and biochemical reactions. A predictive understanding of the possibilities and limitations of DNA extension can guide refined exploitation of DNA in, e.g., programmable soft materials and DNA origami applications.

Original language	English
Article number	2197
Number of pages	7
Journal	Nature Communications
Volume	8
Issue number	2197
DOIs	https://doi.org/10.1038/s41467-017-02396-1
Publication status	Published - 1 Dec 2017

Keywords

Base Sequence/genetics
Benzoxazoles/chemistry
Biomechanical Phenomena/genetics
DNA/chemistry
Elasticity
Fluorescence
Models, Molecular
Nucleic Acid Conformation
Quinolinium Compounds/chemistry
Single Molecule Imaging/methods

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title = "Hyperstretching DNA",

abstract = "The three-dimensional structure of DNA is highly susceptible to changes by mechanical and biochemical cues in vivo and in vitro. In particular, large increases in base pair spacing compared to regular B-DNA are effected by mechanical (over)stretching and by intercalation of compounds that are widely used in biophysical/chemical assays and drug treatments. We present single-molecule experiments and a three-state statistical mechanical model that provide a quantitative understanding of the interplay between B-DNA, overstretched DNA and intercalated DNA. The predictions of this model include a hitherto unconfirmed hyperstretched state, twice the length of B-DNA. Our force-fluorescence experiments confirm this hyperstretched state and reveal its sequence dependence. These results pin down the physical principles that govern DNA mechanics under the influence of tension and biochemical reactions. A predictive understanding of the possibilities and limitations of DNA extension can guide refined exploitation of DNA in, e.g., programmable soft materials and DNA origami applications.",

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AU - Schakenraad, K.

AU - Biebricher, A.S.

AU - Sebregts, M.

AU - ten Bensel, B.

AU - Peterman, E.J.G.

AU - Wuite, G.J.L.

AU - Heller, I.

AU - Storm, C.

AU - van der Schoot, P.A.M.

PY - 2017/12/1

Y1 - 2017/12/1

N2 - The three-dimensional structure of DNA is highly susceptible to changes by mechanical and biochemical cues in vivo and in vitro. In particular, large increases in base pair spacing compared to regular B-DNA are effected by mechanical (over)stretching and by intercalation of compounds that are widely used in biophysical/chemical assays and drug treatments. We present single-molecule experiments and a three-state statistical mechanical model that provide a quantitative understanding of the interplay between B-DNA, overstretched DNA and intercalated DNA. The predictions of this model include a hitherto unconfirmed hyperstretched state, twice the length of B-DNA. Our force-fluorescence experiments confirm this hyperstretched state and reveal its sequence dependence. These results pin down the physical principles that govern DNA mechanics under the influence of tension and biochemical reactions. A predictive understanding of the possibilities and limitations of DNA extension can guide refined exploitation of DNA in, e.g., programmable soft materials and DNA origami applications.

AB - The three-dimensional structure of DNA is highly susceptible to changes by mechanical and biochemical cues in vivo and in vitro. In particular, large increases in base pair spacing compared to regular B-DNA are effected by mechanical (over)stretching and by intercalation of compounds that are widely used in biophysical/chemical assays and drug treatments. We present single-molecule experiments and a three-state statistical mechanical model that provide a quantitative understanding of the interplay between B-DNA, overstretched DNA and intercalated DNA. The predictions of this model include a hitherto unconfirmed hyperstretched state, twice the length of B-DNA. Our force-fluorescence experiments confirm this hyperstretched state and reveal its sequence dependence. These results pin down the physical principles that govern DNA mechanics under the influence of tension and biochemical reactions. A predictive understanding of the possibilities and limitations of DNA extension can guide refined exploitation of DNA in, e.g., programmable soft materials and DNA origami applications.

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KW - Benzoxazoles/chemistry

KW - Biomechanical Phenomena/genetics

KW - DNA/chemistry

KW - Elasticity

KW - Fluorescence

KW - Models, Molecular

KW - Nucleic Acid Conformation

KW - Quinolinium Compounds/chemistry

KW - Single Molecule Imaging/methods

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VL - 8

JO - Nature Communications

JF - Nature Communications

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ER -

Hyperstretching DNA

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