Sensing force and charge at the nanoscale with a single-molecule tether

Xuanhui Meng; Philipp Kukura; Sanli Faez

doi:10.1039/d1nr01970h

Sensing force and charge at the nanoscale with a single-molecule tether

Xuanhui Meng, Philipp Kukura^*, Sanli Faez

^*Corresponding author for this work

University of Oxford

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

Abstract

Measuring the electrophoretic mobility of molecules is a powerful experimental approach for investigating biomolecular processes. A frequent challenge in the context of single-particle measurements is throughput, limiting the obtainable statistics. Here, we present a molecular force sensor and charge detector based on parallelised imaging and tracking of tethered double-stranded DNA functionalised with charged nanoparticles interacting with an externally applied electric field. Tracking the position of the tethered particle with simultaneous nanometre precision and microsecond temporal resolution allows us to detect and quantify the electrophoretic force down to the sub-piconewton scale. Furthermore, we demonstrate that this approach is suitable for detecting changes to the particle charge state, as induced by the addition of charged biomolecules or changes to pH. Our approach provides an alternative route to studying structural and charge dynamics at the single molecule level.

Original language	English
Pages (from-to)	12687-12696
Number of pages	10
Journal	Nanoscale
Volume	13
Issue number	29
DOIs	https://doi.org/10.1039/d1nr01970h
Publication status	Published - 7 Aug 2021

Bibliographical note

Funding Information:
P.K. is supported by an ERC Consolidator Grant (Photomass, 819593) and an EPSRC Leadership Fellowship (EP/T03419X/1). S. F. acknowledges support from the Dutch Organisation for Scientific Research (NWO) grant no. 16PR3238.

Funding Information:
We gratefully acknowledge support for this work from a China Scholarship Council–University of Oxford Scholarship (X. M.).

Publisher Copyright:
© 2021 The Royal Society of Chemistry.

Funding

P.K. is supported by an ERC Consolidator Grant (Photomass, 819593) and an EPSRC Leadership Fellowship (EP/T03419X/1). S. F. acknowledges support from the Dutch Organisation for Scientific Research (NWO) grant no. 16PR3238. We gratefully acknowledge support for this work from a China Scholarship Council–University of Oxford Scholarship (X. M.).

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title = "Sensing force and charge at the nanoscale with a single-molecule tether",

abstract = "Measuring the electrophoretic mobility of molecules is a powerful experimental approach for investigating biomolecular processes. A frequent challenge in the context of single-particle measurements is throughput, limiting the obtainable statistics. Here, we present a molecular force sensor and charge detector based on parallelised imaging and tracking of tethered double-stranded DNA functionalised with charged nanoparticles interacting with an externally applied electric field. Tracking the position of the tethered particle with simultaneous nanometre precision and microsecond temporal resolution allows us to detect and quantify the electrophoretic force down to the sub-piconewton scale. Furthermore, we demonstrate that this approach is suitable for detecting changes to the particle charge state, as induced by the addition of charged biomolecules or changes to pH. Our approach provides an alternative route to studying structural and charge dynamics at the single molecule level.",

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AB - Measuring the electrophoretic mobility of molecules is a powerful experimental approach for investigating biomolecular processes. A frequent challenge in the context of single-particle measurements is throughput, limiting the obtainable statistics. Here, we present a molecular force sensor and charge detector based on parallelised imaging and tracking of tethered double-stranded DNA functionalised with charged nanoparticles interacting with an externally applied electric field. Tracking the position of the tethered particle with simultaneous nanometre precision and microsecond temporal resolution allows us to detect and quantify the electrophoretic force down to the sub-piconewton scale. Furthermore, we demonstrate that this approach is suitable for detecting changes to the particle charge state, as induced by the addition of charged biomolecules or changes to pH. Our approach provides an alternative route to studying structural and charge dynamics at the single molecule level.

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Sensing force and charge at the nanoscale with a single-molecule tether

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