Elucidating the Role of Topological Constraint on the Structure of Overstretched DNA Using Fluorescence Polarization Microscopy

Adam S. Backer; Graeme A. King; Andreas S. Biebricher; Jack W. Shepherd; Agnes Noy; Mark C. Leake; Iddo Heller; Gijs J.L. Wuite; Erwin J.G. Peterman

doi:10.1021/acs.jpcb.1c02708

Elucidating the Role of Topological Constraint on the Structure of Overstretched DNA Using Fluorescence Polarization Microscopy

Adam S. Backer^*
, Graeme A. King
, Andreas S. Biebricher
, Jack W. Shepherd
, Agnes Noy
, Mark C. Leake
, Iddo Heller
, Gijs J.L. Wuite
, Erwin J.G. Peterman

^*Corresponding author for this work

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

Abstract

The combination of DNA force spectroscopy and polarization microscopy of fluorescent DNA intercalator dyes can provide valuable insights into the structure of DNA under tension. These techniques have previously been used to characterize S-DNA - an elongated DNA conformation that forms when DNA overstretches at forces ≥ 65 pN. In this way, it was deduced that the base pairs of S-DNA are highly inclined, relative to those in relaxed (B-form) DNA. However, it is unclear whether and how topological constraints on the DNA may influence the base-pair inclinations under tension. Here, we apply polarization microscopy to investigate the impact of DNA pulling geometry, torsional constraint, and negative supercoiling on the orientations of intercalated dyes during overstretching. In contrast to earlier predictions, the pulling geometry (namely, whether the DNA molecule is stretched via opposite strands or the same strand) is found to have little influence. However, torsional constraint leads to a substantial reduction in intercalator tilting in overstretched DNA, particularly in AT-rich sequences. Surprisingly, the extent of intercalator tilting is similarly reduced when the DNA molecule is negatively supercoiled up to a critical supercoiling density (corresponding to ∼70% reduction in the linking number). We attribute these observations to the presence of P-DNA (an overwound DNA conformation). Our results suggest that intercalated DNA preferentially flanks regions of P-DNA rather than those of S-DNA and also substantiate previous suggestions that P-DNA forms predominantly in AT-rich sequences.

Original language	English
Pages (from-to)	8351-8361
Number of pages	11
Journal	Journal of Physical Chemistry B
Volume	125
Issue number	30
Early online date	26 Jul 2021
DOIs	https://doi.org/10.1021/acs.jpcb.1c02708
Publication status	Published - 5 Aug 2021

Bibliographical note

Funding Information:
Data appearing in this manuscript were collected, while A.S.Ba. was an employee of Sandia National Laboratories. A.S.Ba. acknowledges the support from the Laboratory Directed Research and Development program and the Harry S. Truman Fellowship at Sandia. This work was supported by a Chemical Sciences Top grant from the Netherlands Organization for Scientific Research (NWO) (G.J.L.W. and E.J.G.P. and G.A.K.). I.H. acknowledges research funding from an NWO VIDI award. M.C.L. acknowledges the Leverhulme Trust, U.K. (RPG-2017-340 and RPG-2019-156) and the Engineering and Physical Sciences Research Council, U.K. ( EPSRC, EP/N027639/1) (A.N. and M.C.L.), with computational time secured on JADE via the U.K. High-End Computing Consortium for Biomolecular Simulation, HECBioSim (EP/R029407/1) (A.N.) and on the Cambridge Tier-2 system capital grant (EP/P020259/1) (A.N.). We also thank Tier 3 High-Performance Computing (HPC) facilities at the University of York, U.K. (Viking cluster) for additional computational resources.

Publisher Copyright:
© 2021 The Authors. Published by American Chemical Society.

Funding

Data appearing in this manuscript were collected, while A.S.Ba. was an employee of Sandia National Laboratories. A.S.Ba. acknowledges the support from the Laboratory Directed Research and Development program and the Harry S. Truman Fellowship at Sandia. This work was supported by a Chemical Sciences Top grant from the Netherlands Organization for Scientific Research (NWO) (G.J.L.W. and E.J.G.P. and G.A.K.). I.H. acknowledges research funding from an NWO VIDI award. M.C.L. acknowledges the Leverhulme Trust, U.K. (RPG-2017-340 and RPG-2019-156) and the Engineering and Physical Sciences Research Council, U.K. ( EPSRC, EP/N027639/1) (A.N. and M.C.L.), with computational time secured on JADE via the U.K. High-End Computing Consortium for Biomolecular Simulation, HECBioSim (EP/R029407/1) (A.N.) and on the Cambridge Tier-2 system capital grant (EP/P020259/1) (A.N.). We also thank Tier 3 High-Performance Computing (HPC) facilities at the University of York, U.K. (Viking cluster) for additional computational resources.

Funders	Funder number
Nederlandse Organisatie voor Wetenschappelijk Onderzoek
Laboratory Directed Research and Development
UK Research and Innovation	26534
Engineering and Physical Sciences Research Council	EP/N027639/1, EP/P020259/1, EP/R029407/1
Leverhulme Trust	RPG-2017-340, RPG-2019-156

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@article{393f4bd6ce8849bc83d28e66b15dcd69,

title = "Elucidating the Role of Topological Constraint on the Structure of Overstretched DNA Using Fluorescence Polarization Microscopy",

abstract = "The combination of DNA force spectroscopy and polarization microscopy of fluorescent DNA intercalator dyes can provide valuable insights into the structure of DNA under tension. These techniques have previously been used to characterize S-DNA - an elongated DNA conformation that forms when DNA overstretches at forces ≥ 65 pN. In this way, it was deduced that the base pairs of S-DNA are highly inclined, relative to those in relaxed (B-form) DNA. However, it is unclear whether and how topological constraints on the DNA may influence the base-pair inclinations under tension. Here, we apply polarization microscopy to investigate the impact of DNA pulling geometry, torsional constraint, and negative supercoiling on the orientations of intercalated dyes during overstretching. In contrast to earlier predictions, the pulling geometry (namely, whether the DNA molecule is stretched via opposite strands or the same strand) is found to have little influence. However, torsional constraint leads to a substantial reduction in intercalator tilting in overstretched DNA, particularly in AT-rich sequences. Surprisingly, the extent of intercalator tilting is similarly reduced when the DNA molecule is negatively supercoiled up to a critical supercoiling density (corresponding to ∼70\% reduction in the linking number). We attribute these observations to the presence of P-DNA (an overwound DNA conformation). Our results suggest that intercalated DNA preferentially flanks regions of P-DNA rather than those of S-DNA and also substantiate previous suggestions that P-DNA forms predominantly in AT-rich sequences. ",

author = "Backer, \{Adam S.\} and King, \{Graeme A.\} and Biebricher, \{Andreas S.\} and Shepherd, \{Jack W.\} and Agnes Noy and Leake, \{Mark C.\} and Iddo Heller and Wuite, \{Gijs J.L.\} and Peterman, \{Erwin J.G.\}",

note = "Funding Information: Data appearing in this manuscript were collected, while A.S.Ba. was an employee of Sandia National Laboratories. A.S.Ba. acknowledges the support from the Laboratory Directed Research and Development program and the Harry S. Truman Fellowship at Sandia. This work was supported by a Chemical Sciences Top grant from the Netherlands Organization for Scientific Research (NWO) (G.J.L.W. and E.J.G.P. and G.A.K.). I.H. acknowledges research funding from an NWO VIDI award. M.C.L. acknowledges the Leverhulme Trust, U.K. (RPG-2017-340 and RPG-2019-156) and the Engineering and Physical Sciences Research Council, U.K. ( EPSRC, EP/N027639/1) (A.N. and M.C.L.), with computational time secured on JADE via the U.K. High-End Computing Consortium for Biomolecular Simulation, HECBioSim (EP/R029407/1) (A.N.) and on the Cambridge Tier-2 system capital grant (EP/P020259/1) (A.N.). We also thank Tier 3 High-Performance Computing (HPC) facilities at the University of York, U.K. (Viking cluster) for additional computational resources. Publisher Copyright: {\textcopyright} 2021 The Authors. Published by American Chemical Society.",

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doi = "10.1021/acs.jpcb.1c02708",

language = "English",

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AU - Backer, Adam S.

AU - King, Graeme A.

AU - Biebricher, Andreas S.

AU - Shepherd, Jack W.

AU - Noy, Agnes

AU - Leake, Mark C.

AU - Heller, Iddo

AU - Wuite, Gijs J.L.

AU - Peterman, Erwin J.G.

N1 - Funding Information: Data appearing in this manuscript were collected, while A.S.Ba. was an employee of Sandia National Laboratories. A.S.Ba. acknowledges the support from the Laboratory Directed Research and Development program and the Harry S. Truman Fellowship at Sandia. This work was supported by a Chemical Sciences Top grant from the Netherlands Organization for Scientific Research (NWO) (G.J.L.W. and E.J.G.P. and G.A.K.). I.H. acknowledges research funding from an NWO VIDI award. M.C.L. acknowledges the Leverhulme Trust, U.K. (RPG-2017-340 and RPG-2019-156) and the Engineering and Physical Sciences Research Council, U.K. ( EPSRC, EP/N027639/1) (A.N. and M.C.L.), with computational time secured on JADE via the U.K. High-End Computing Consortium for Biomolecular Simulation, HECBioSim (EP/R029407/1) (A.N.) and on the Cambridge Tier-2 system capital grant (EP/P020259/1) (A.N.). We also thank Tier 3 High-Performance Computing (HPC) facilities at the University of York, U.K. (Viking cluster) for additional computational resources. Publisher Copyright: © 2021 The Authors. Published by American Chemical Society.

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N2 - The combination of DNA force spectroscopy and polarization microscopy of fluorescent DNA intercalator dyes can provide valuable insights into the structure of DNA under tension. These techniques have previously been used to characterize S-DNA - an elongated DNA conformation that forms when DNA overstretches at forces ≥ 65 pN. In this way, it was deduced that the base pairs of S-DNA are highly inclined, relative to those in relaxed (B-form) DNA. However, it is unclear whether and how topological constraints on the DNA may influence the base-pair inclinations under tension. Here, we apply polarization microscopy to investigate the impact of DNA pulling geometry, torsional constraint, and negative supercoiling on the orientations of intercalated dyes during overstretching. In contrast to earlier predictions, the pulling geometry (namely, whether the DNA molecule is stretched via opposite strands or the same strand) is found to have little influence. However, torsional constraint leads to a substantial reduction in intercalator tilting in overstretched DNA, particularly in AT-rich sequences. Surprisingly, the extent of intercalator tilting is similarly reduced when the DNA molecule is negatively supercoiled up to a critical supercoiling density (corresponding to ∼70% reduction in the linking number). We attribute these observations to the presence of P-DNA (an overwound DNA conformation). Our results suggest that intercalated DNA preferentially flanks regions of P-DNA rather than those of S-DNA and also substantiate previous suggestions that P-DNA forms predominantly in AT-rich sequences.

AB - The combination of DNA force spectroscopy and polarization microscopy of fluorescent DNA intercalator dyes can provide valuable insights into the structure of DNA under tension. These techniques have previously been used to characterize S-DNA - an elongated DNA conformation that forms when DNA overstretches at forces ≥ 65 pN. In this way, it was deduced that the base pairs of S-DNA are highly inclined, relative to those in relaxed (B-form) DNA. However, it is unclear whether and how topological constraints on the DNA may influence the base-pair inclinations under tension. Here, we apply polarization microscopy to investigate the impact of DNA pulling geometry, torsional constraint, and negative supercoiling on the orientations of intercalated dyes during overstretching. In contrast to earlier predictions, the pulling geometry (namely, whether the DNA molecule is stretched via opposite strands or the same strand) is found to have little influence. However, torsional constraint leads to a substantial reduction in intercalator tilting in overstretched DNA, particularly in AT-rich sequences. Surprisingly, the extent of intercalator tilting is similarly reduced when the DNA molecule is negatively supercoiled up to a critical supercoiling density (corresponding to ∼70% reduction in the linking number). We attribute these observations to the presence of P-DNA (an overwound DNA conformation). Our results suggest that intercalated DNA preferentially flanks regions of P-DNA rather than those of S-DNA and also substantiate previous suggestions that P-DNA forms predominantly in AT-rich sequences.

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Elucidating the Role of Topological Constraint on the Structure of Overstretched DNA Using Fluorescence Polarization Microscopy

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