Twist-diameter coupling drives DNA twist changes with salt and temperature

Chen Zhang; Fujia Tian; Ying Lu; Bing Yuan; Zhi-Jie Tan; Xing-Hua Zhang; Liang Dai

doi:10.1126/sciadv.abn1384

Twist-diameter coupling drives DNA twist changes with salt and temperature

Chen Zhang (Co-first Author), Fujia Tian (Co-first Author), Ying Lu, Bing Yuan, Zhi-Jie Tan, Xing-Hua Zhang^*, Liang Dai^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

23 Citations (Scopus)

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Abstract

DNA deformations upon environmental changes, e.g., salt and temperature, play crucial roles in many biological processes and material applications. Here, our magnetic tweezers experiments observed that the increase in NaCl, KCl, or RbCl concentration leads to substantial DNA overwinding. Our simulations and theoretical calculation quantitatively explain the salt-induced twist change through the mechanism: More salt enhances the screening of interstrand electrostatic repulsion and hence reduces DNA diameter, which is transduced to twist increase through twist-diameter coupling. We determined that the coupling constant is 4.5 ± 0.8 k_BT/(degrees nm) for one base pair. The coupling comes from the restraint of the contour length of DNA backbone. On the basis of this coupling constant and diameter-dependent DNA conformational entropy, we predict the temperature dependence of DNA twist Δωbp/ΔT ≈ -0.01 degree/°C, which agrees with our and previous experimental results. Our analysis suggests that twist-diameter coupling is a common driving force for salt- and temperature-induced DNA twist changes.

Original language	English
Article number	eabn1384
Number of pages	7
Journal	Science Advances
Volume	8
Issue number	12
Online published	23 Mar 2022
DOIs	https://doi.org/10.1126/sciadv.abn1384
Publication status	Published - 25 Mar 2022

Funding

We are grateful to the financial support from the National Natural Science Foundation of China (nos. 12074294, 21973080, and 32100991), the Research Grants Council of Hong Kong (no. 21302520), and the Super Computing Center of Wuhan University.

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This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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title = "Twist-diameter coupling drives DNA twist changes with salt and temperature",

abstract = "DNA deformations upon environmental changes, e.g., salt and temperature, play crucial roles in many biological processes and material applications. Here, our magnetic tweezers experiments observed that the increase in NaCl, KCl, or RbCl concentration leads to substantial DNA overwinding. Our simulations and theoretical calculation quantitatively explain the salt-induced twist change through the mechanism: More salt enhances the screening of interstrand electrostatic repulsion and hence reduces DNA diameter, which is transduced to twist increase through twist-diameter coupling. We determined that the coupling constant is 4.5 ± 0.8 kBT/(degrees nm) for one base pair. The coupling comes from the restraint of the contour length of DNA backbone. On the basis of this coupling constant and diameter-dependent DNA conformational entropy, we predict the temperature dependence of DNA twist Δωbp/ΔT ≈ -0.01 degree/°C, which agrees with our and previous experimental results. Our analysis suggests that twist-diameter coupling is a common driving force for salt- and temperature-induced DNA twist changes.",

author = "Chen Zhang and Fujia Tian and Ying Lu and Bing Yuan and Zhi-Jie Tan and Xing-Hua Zhang and Liang Dai",

year = "2022",

month = mar,

day = "25",

doi = "10.1126/sciadv.abn1384",

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volume = "8",

journal = "Science Advances",

issn = "2375-2548",

publisher = "American Association for the Advancement of Science",

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TY - JOUR

T1 - Twist-diameter coupling drives DNA twist changes with salt and temperature

AU - Zhang, Chen

AU - Tian, Fujia

AU - Lu, Ying

AU - Yuan, Bing

AU - Tan, Zhi-Jie

AU - Zhang, Xing-Hua

AU - Dai, Liang

PY - 2022/3/25

Y1 - 2022/3/25

N2 - DNA deformations upon environmental changes, e.g., salt and temperature, play crucial roles in many biological processes and material applications. Here, our magnetic tweezers experiments observed that the increase in NaCl, KCl, or RbCl concentration leads to substantial DNA overwinding. Our simulations and theoretical calculation quantitatively explain the salt-induced twist change through the mechanism: More salt enhances the screening of interstrand electrostatic repulsion and hence reduces DNA diameter, which is transduced to twist increase through twist-diameter coupling. We determined that the coupling constant is 4.5 ± 0.8 kBT/(degrees nm) for one base pair. The coupling comes from the restraint of the contour length of DNA backbone. On the basis of this coupling constant and diameter-dependent DNA conformational entropy, we predict the temperature dependence of DNA twist Δωbp/ΔT ≈ -0.01 degree/°C, which agrees with our and previous experimental results. Our analysis suggests that twist-diameter coupling is a common driving force for salt- and temperature-induced DNA twist changes.

AB - DNA deformations upon environmental changes, e.g., salt and temperature, play crucial roles in many biological processes and material applications. Here, our magnetic tweezers experiments observed that the increase in NaCl, KCl, or RbCl concentration leads to substantial DNA overwinding. Our simulations and theoretical calculation quantitatively explain the salt-induced twist change through the mechanism: More salt enhances the screening of interstrand electrostatic repulsion and hence reduces DNA diameter, which is transduced to twist increase through twist-diameter coupling. We determined that the coupling constant is 4.5 ± 0.8 kBT/(degrees nm) for one base pair. The coupling comes from the restraint of the contour length of DNA backbone. On the basis of this coupling constant and diameter-dependent DNA conformational entropy, we predict the temperature dependence of DNA twist Δωbp/ΔT ≈ -0.01 degree/°C, which agrees with our and previous experimental results. Our analysis suggests that twist-diameter coupling is a common driving force for salt- and temperature-induced DNA twist changes.

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DO - 10.1126/sciadv.abn1384

M3 - RGC 21 - Publication in refereed journal

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SN - 2375-2548

VL - 8

JO - Science Advances

JF - Science Advances

IS - 12

M1 - eabn1384

ER -

Twist-diameter coupling drives DNA twist changes with salt and temperature

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ECS: Controlling Knots in Simple Polymer Models and its Applications to DNA and Protein Knots

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Twist-diameter coupling drives DNA twist changes with salt and temperature

Abstract

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Publisher's Copyright Statement

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ECS: Controlling Knots in Simple Polymer Models and its Applications to DNA and Protein Knots

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