Three-dimensional bead position histograms reveal single-molecule nanomechanics

NB Becker; SM Altmann; T Scholz; JKH Hoerber; EHK Stelzer; A Rohrbach

Three-dimensional bead position histograms reveal single-molecule nanomechanics

NB Becker, SM Altmann, T Scholz, JKH Hoerber, EHK Stelzer, A Rohrbach

School of Physics

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

Abstract

We describe a method to investigate the structure and elasticity of macromolecules by a combination of single molecule experiments and kinematic modeling. With a photonic force microscope, we recorded spatial position histograms of a fluctuating microsphere tethered to full-length myosin-II. Assuming only that the molecule consists of concatenated rigid segments, a model derived from robot kinematics allows us to relate these histograms to the molecule's segment lengths and bending stiffnesses. Both our calculated position distributions and the experimental data show an asymmetry characteristic of a mixed entropic-enthalpic spring. Our model that fits best to experimental line profiles has two intramolecular hinges, one at the bound head domain, and another about 50 nm down the myosin tail, with a summed bending stiffness of about 3 k(B)T/rad.

Translated title of the contribution	Three-dimensional bead position histograms reveal single-molecule nanomechanics
Original language	English
Article number	Part 1
Pages (from-to)	021907
Journal	Physical Review E: Statistical, Nonlinear, and Soft Matter Physics
Volume	71(2)
Publication status	Published - 2005

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Publisher: American Physical Society

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title = "Three-dimensional bead position histograms reveal single-molecule nanomechanics",

abstract = "We describe a method to investigate the structure and elasticity of macromolecules by a combination of single molecule experiments and kinematic modeling. With a photonic force microscope, we recorded spatial position histograms of a fluctuating microsphere tethered to full-length myosin-II. Assuming only that the molecule consists of concatenated rigid segments, a model derived from robot kinematics allows us to relate these histograms to the molecule's segment lengths and bending stiffnesses. Both our calculated position distributions and the experimental data show an asymmetry characteristic of a mixed entropic-enthalpic spring. Our model that fits best to experimental line profiles has two intramolecular hinges, one at the bound head domain, and another about 50 nm down the myosin tail, with a summed bending stiffness of about 3 k(B)T/rad.",

author = "NB Becker and SM Altmann and T Scholz and JKH Hoerber and EHK Stelzer and A Rohrbach",

note = "Publisher: American Physical Society",

year = "2005",

language = "English",

volume = "71(2)",

pages = "021907",

journal = "Physical Review E: Statistical, Nonlinear, and Soft Matter Physics",

issn = "1539-3755",

publisher = "American Physical Society (APS)",

}

TY - JOUR

T1 - Three-dimensional bead position histograms reveal single-molecule nanomechanics

AU - Becker, NB

AU - Altmann, SM

AU - Scholz, T

AU - Hoerber, JKH

AU - Stelzer, EHK

AU - Rohrbach, A

N1 - Publisher: American Physical Society

PY - 2005

Y1 - 2005

N2 - We describe a method to investigate the structure and elasticity of macromolecules by a combination of single molecule experiments and kinematic modeling. With a photonic force microscope, we recorded spatial position histograms of a fluctuating microsphere tethered to full-length myosin-II. Assuming only that the molecule consists of concatenated rigid segments, a model derived from robot kinematics allows us to relate these histograms to the molecule's segment lengths and bending stiffnesses. Both our calculated position distributions and the experimental data show an asymmetry characteristic of a mixed entropic-enthalpic spring. Our model that fits best to experimental line profiles has two intramolecular hinges, one at the bound head domain, and another about 50 nm down the myosin tail, with a summed bending stiffness of about 3 k(B)T/rad.

AB - We describe a method to investigate the structure and elasticity of macromolecules by a combination of single molecule experiments and kinematic modeling. With a photonic force microscope, we recorded spatial position histograms of a fluctuating microsphere tethered to full-length myosin-II. Assuming only that the molecule consists of concatenated rigid segments, a model derived from robot kinematics allows us to relate these histograms to the molecule's segment lengths and bending stiffnesses. Both our calculated position distributions and the experimental data show an asymmetry characteristic of a mixed entropic-enthalpic spring. Our model that fits best to experimental line profiles has two intramolecular hinges, one at the bound head domain, and another about 50 nm down the myosin tail, with a summed bending stiffness of about 3 k(B)T/rad.

M3 - Article (Academic Journal)

SN - 1539-3755

VL - 71(2)

SP - 021907

JO - Physical Review E: Statistical, Nonlinear, and Soft Matter Physics

JF - Physical Review E: Statistical, Nonlinear, and Soft Matter Physics

M1 - Part 1

ER -

Three-dimensional bead position histograms reveal single-molecule nanomechanics

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