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website contera

Prof Sonia Antoranz Contera

Professor of Biological Physics

Sub department

  • Condensed Matter Physics
Sonia.AntoranzContera@physics.ox.ac.uk
Telephone: 01865 (2)72269
Clarendon Laboratory, room 208
  • About
  • Publications
Conversation on physics bioinspired materials and the future of architecture
link to video of conversation with architect Amanda Levete on biophysics and the future of architecture

Direct mapping of the solid-liquid adhesion energy with subnanometre resolution

Nature Nanotechnology 5:6 (2010) 401-405

Authors:

K Voïtchovsky, JJ Kuna, SA Contera, E Tosatti, F Stellacci

Abstract:

Solid-liquid interfaces play a fundamental role in surface electrochemistry, catalysis, wetting, self-assembly and biomolecular functions. The interfacial energy determines many of the properties of such interfaces, including the arrangement of the liquid molecules at the surface of the solid. Diffraction techniques are often used to investigate the structure of solid-liquid interfaces, but measurements of irregular or inhomogeneous interfaces remain challenging. Here, we report atomic-and molecular-resolution images of various organic and inorganic samples in liquids, obtained with a commercial atomic force microscope operated dynamically with small-amplitude modulation. This approach uses the structured liquid layers close to the solid to enhance lateral resolution. We propose a model to explain the mechanism dominating the image formation, and show that the energy dissipated during this process is related to the interfacial energy through a readily achievable calibration curve. Our topographic images and interfacial energy maps could provide insights into important interfaces. © 2010 Macmillan Publishers Limited. All rights reserved.
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Clustering and Functional Interaction of MscL Channels

Biophysical Journal Elsevier 98:3 (2010) 324a

Authors:

Asbed M Keleshian, Stephan L Grage, Tamta Turdzeladze, Andrew R Battle, Wee C Tay, Stephen A Holt, Sonia Antoranz Contera, Michael Haertlein, Martine Moulin, Prithwish Pal, Paul R Rohde, Kerwyn C Huang, Anthony Watts, Anne S Ulrich, Boris Martinac
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Clustering and Functional Interaction of MscL Channels

BIOPHYSICAL JOURNAL 98:3 (2010) 323A-323A

Authors:

Asbed M Keleshian, Stephan L Grage, Tamta Turdzeladze, Andrew R Battle, Wee C Tay, Stephen A Holt, Sonia Antoranz Contera, Michael Haertlein, Martine Moulin, Prithwish Pal, Paul R Rohde, Kerwyn C Huang, Anthony Watts, Anne S Ulrich, Boris Martinac
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Lateral coupling and cooperative dynamics in the function of the native membrane protein bacteriorhodopsin

Soft Matter 5:24 (2009) 4899-4904

Authors:

K Voïtchovsky, SA Contera, JF Ryan

Abstract:

Membrane proteins are laterally coupled to the surrounding cell membrane through complex interactions that can modulate their function. Here, we directly observe and quantify the dynamics of functioning bacteriorhodopsin (bR) in its native membrane, a crystalline aggregate of bR trimers. We show that much of a monomer's isomerization energy is mechanically redistributed into the membrane, producing cooperative activity within the trimer while simultaneously generating functionally relevant long-range lateral pressure waves. Our results provide evidence of coordinated short and long-range effects in the cell membrane. © 2009 The Royal Society of Chemistry.
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Dynamics of bacteriorhodopsin 2D crystal observed by high-speed atomic force microscopy.

J Struct Biol 167:2 (2009) 153-158

Authors:

Hayato Yamashita, Kislon Voïtchovsky, Takayuki Uchihashi, Sonia Antoranz Contera, John F Ryan, Toshio Ando

Abstract:

We have used high-speed atomic force microscopy to study the dynamics of bacteriorhodopsin (bR) molecules at the free interface of the crystalline phase that occurs naturally in purple membrane. Our results reveal temporal fluctuations at the crystal edges arising from the association and dissociation of bR molecules, most predominantly pre-formed trimers. Analysis of the dissociation kinetics yields an estimate of the inter-trimer single-bond energy of -0.9kcal/mol. Rotational motion of individual bound trimers indicates that the inter-trimer bond involves W10-W12 tryptophan residues.
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