Unfolding dynamics of proteins under applied force

D. Alastair Smith; David J. Brockwell; Rebecca C. Zinober; Anthony W. Blake; Godfrey S. Beddard; Peter D. Olmsted; Sheena E. Radford; W. T. Coffey; E. Sackmann; B. U. Felderhof; M. Maaloum; S. Titmuss; D. S.F. Crothers; P. Bartlett

doi:10.1098/rsta.2002.1160

Unfolding dynamics of proteins under applied force

D. Alastair Smith, David J. Brockwell, Rebecca C. Zinober, Anthony W. Blake, Godfrey S. Beddard, Peter D. Olmsted, Sheena E. Radford, W. T. Coffey, E. Sackmann, B. U. Felderhof, M. Maaloum, S. Titmuss, D. S.F. Crothers, P. Bartlett

Department of Bioscience

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

15 Scopus citations

Abstract

Understanding the mechanisms of protein folding is a major challenge that is being addressed effectively by collaboration between researchers in the physical and life sciences. Recently, it has become possible to mechanically unfold proteins by pulling on their two termini using local force probes such as the atomic force microscope. Here, we present data from experiments in which synthetic protein polymers designed to mimic naturally occurring polyproteins have been mechanically unfolded. For many years protein folding dynamics have been studied using chemical denaturation, and we therefore firstly discuss our mechanical unfolding data in the context of such experiments and show that the two unfolding mechanisms are not the same, at least for the proteins studied here. We also report unexpected observations that indicate a history effect in the observed unfolding forces of polymeric proteins and explain this in terms of the changing number of domains remaining to unfold and the increasing compliance of the lengthening unstructured polypeptide chain produced each time a domain unfolds.

Original language	English
Pages (from-to)	713-730
Number of pages	18
Journal	Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences
Volume	361
Issue number	1805
DOIs	https://doi.org/10.1098/rsta.2002.1160
State	Published - 15 Apr 2003

Keywords

Atomic force microscope
Force
Mechanical resistance
Mechanical unfolding
Protein folding
Single molecule

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10.1098/rsta.2002.1160

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Alastair Smith, D., Brockwell, D. J., Zinober, R. C., Blake, A. W., Beddard, G. S., Olmsted, P. D., Radford, S. E., Coffey, W. T., Sackmann, E., Felderhof, B. U., Maaloum, M., Titmuss, S., Crothers, D. S. F., & Bartlett, P. (2003). Unfolding dynamics of proteins under applied force. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 361(1805), 713-730. https://doi.org/10.1098/rsta.2002.1160

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title = "Unfolding dynamics of proteins under applied force",

abstract = "Understanding the mechanisms of protein folding is a major challenge that is being addressed effectively by collaboration between researchers in the physical and life sciences. Recently, it has become possible to mechanically unfold proteins by pulling on their two termini using local force probes such as the atomic force microscope. Here, we present data from experiments in which synthetic protein polymers designed to mimic naturally occurring polyproteins have been mechanically unfolded. For many years protein folding dynamics have been studied using chemical denaturation, and we therefore firstly discuss our mechanical unfolding data in the context of such experiments and show that the two unfolding mechanisms are not the same, at least for the proteins studied here. We also report unexpected observations that indicate a history effect in the observed unfolding forces of polymeric proteins and explain this in terms of the changing number of domains remaining to unfold and the increasing compliance of the lengthening unstructured polypeptide chain produced each time a domain unfolds.",

keywords = "Atomic force microscope, Force, Mechanical resistance, Mechanical unfolding, Protein folding, Single molecule",

author = "{Alastair Smith}, D. and Brockwell, {David J.} and Zinober, {Rebecca C.} and Blake, {Anthony W.} and Beddard, {Godfrey S.} and Olmsted, {Peter D.} and Radford, {Sheena E.} and Coffey, {W. T.} and E. Sackmann and Felderhof, {B. U.} and M. Maaloum and S. Titmuss and Crothers, {D. S.F.} and P. Bartlett",

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Alastair Smith, D, Brockwell, DJ, Zinober, RC, Blake, AW, Beddard, GS, Olmsted, PD, Radford, SE, Coffey, WT, Sackmann, E, Felderhof, BU, Maaloum, M, Titmuss, S, Crothers, DSF & Bartlett, P 2003, 'Unfolding dynamics of proteins under applied force', Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, vol. 361, no. 1805, pp. 713-730. https://doi.org/10.1098/rsta.2002.1160

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T1 - Unfolding dynamics of proteins under applied force

AU - Alastair Smith, D.

AU - Brockwell, David J.

AU - Zinober, Rebecca C.

AU - Blake, Anthony W.

AU - Beddard, Godfrey S.

AU - Olmsted, Peter D.

AU - Radford, Sheena E.

AU - Coffey, W. T.

AU - Sackmann, E.

AU - Felderhof, B. U.

AU - Maaloum, M.

AU - Titmuss, S.

AU - Crothers, D. S.F.

AU - Bartlett, P.

PY - 2003/4/15

Y1 - 2003/4/15

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AB - Understanding the mechanisms of protein folding is a major challenge that is being addressed effectively by collaboration between researchers in the physical and life sciences. Recently, it has become possible to mechanically unfold proteins by pulling on their two termini using local force probes such as the atomic force microscope. Here, we present data from experiments in which synthetic protein polymers designed to mimic naturally occurring polyproteins have been mechanically unfolded. For many years protein folding dynamics have been studied using chemical denaturation, and we therefore firstly discuss our mechanical unfolding data in the context of such experiments and show that the two unfolding mechanisms are not the same, at least for the proteins studied here. We also report unexpected observations that indicate a history effect in the observed unfolding forces of polymeric proteins and explain this in terms of the changing number of domains remaining to unfold and the increasing compliance of the lengthening unstructured polypeptide chain produced each time a domain unfolds.

KW - Atomic force microscope

KW - Force

KW - Mechanical resistance

KW - Mechanical unfolding

KW - Protein folding

KW - Single molecule

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JF - Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences

IS - 1805

ER -

Unfolding dynamics of proteins under applied force

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Keywords

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