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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

Multifrequency AFM reveals lipid membrane mechanical properties and the effect of cholesterol in modulating viscoelasticity

Proceedings of the National Academy of Sciences National Academy of Sciences 115:11 (2018) 2658-2663

Authors:

Z Al Rekabi, Sonia Contera

Abstract:

The physical properties of lipid bilayers comprising the cell membrane occupy the current spotlight of membrane biology. Their traditional representation as a passive 2D fluid has gradually been abandoned in favor of a more complex picture: an anisotropic time-dependent viscoelastic biphasic material, capable of transmitting or attenuating mechanical forces that regulate biological processes. In establishing new models, quantitative experiments are necessary when attempting to develop suitable techniques for dynamic measurements. Here, we map both the elastic and viscous properties of the model system 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) lipid bilayers using multifrequency atomic force microscopy (AFM), namely amplitude modulation–frequency modulation (AM–FM) AFM imaging in an aqueous environment. Furthermore, we investigate the effect of cholesterol (Chol) on the DPPC bilayer in concentrations from 0 to 60%. The AM–AFM quantitative maps demonstrate that at low Chol concentrations, the lipid bilayer displays a distinct phase separation and is elastic, whereas at higher Chol concentration, the bilayer appears homogenous and exhibits both elastic and viscous properties. At low-Chol contents, the Estorage modulus (elastic) dominates. As the Chol insertions increases, higher energy is dissipated; and although the bilayer stiffens (increase in Estorage), the viscous component dominates (Eloss). Our results provide evidence that the lipid bilayer exhibits both elastic and viscous properties that are modulated by the presence of Chol, which may affect the propagation (elastic) or attenuation (viscous) of mechanical signals across the cell membrane.

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Author Correction: How to probe the spin contribution to momentum relaxation in topological insulators.

Nature communications (2018)

Authors:

Moon-Sun Nam, BH Williams, Y Chen, S Contera, S Yao, M Lu, Y-F Chen, GA Timco, CA Muryn, Arzhang Ardavan

Abstract:

The original version of this Article contained an error in the spelling of the author Benjamin H. Williams, which was incorrectly given as Benjamin H. Willams. This has now been corrected in both the PDF and HTML versions of the Article.
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Author Correction: How to probe the spin contribution to momentum relaxation in topological insulators.

Nature communications (2018)

Authors:

MOON-SUN Nam, Benjamin Williams, YULIN Chen, S Contera, S Yao, M Lu, YULIN Chen, GA Timco, CA Muryn, ARZHANG Ardavan

Abstract:

The original version of this Article contained an error in the spelling of the author Benjamin H. Williams, which was incorrectly given as Benjamin H. Willams. This has now been corrected in both the PDF and HTML versions of the Article.
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How to probe the spin contribution to momentum relaxation in topological insulators (vol 8, 2017)

NATURE COMMUNICATIONS 9 (2018) ARTN 729

Authors:

Moon-Sun Nam, Benjamin H Willams, Yulin Chen, Sonia Contera, Shuhua Yao, Minghui Lu, Yan-Feng Chen, Grigore A Timco, Christopher A Muryn, Richard EP Winpenny, Arzhang Ardavan
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Amphiphilic DNA tiles for controlled insertion and 2D assembly on fluid lipid membranes: Effect on mechanical properties

Nanoscale Royal Society of Chemistry 9:9 (2017) 3051-3058

Authors:

Chikara Dohno, Shingo Makishi, Kzuhiko Nakatani, Sonia Antoranz Contera

Abstract:

Future lipid membrane-associated DNA nanostructures are expected to find applications ranging from synthetic biology to nanomedicine. Here we have designed and synthesized DNA tiles and modified them by amphiphilic covalent moieties. dod-DEG groups, which consist of a hydrophilic diethylene glycol (DEG) and a hydrophobic dodecyl group, are introduced at the phosphate backbone to create amphiphilic DNA strands which are subsequently introduced into one face of DNA tiles. In this way the tile becomes able to stably bind to lipid membranes by insertion of the hydrophobic groups inside the bilayer core. The functionalized tiles do not aggregate in solution. Our results show that these amphiphilic DNA tiles can bind and assemble into 2D lattices on both gel and fluid lipid bilayers. The binding of the DNA structures to membranes is dependent on the lipid phase of the membrane, the concentration of Mg2+ cation, the length of the amphiphilic modifications to the DNA as well as on the density of the modifications within the tile. Atomic force microscopy–based force spectroscopy is used to investigate the effect of the inserted DNA tiles on the mechanical properties of the lipid membranes. The results indicate that the insertion of DNA tiles produces an approx. 20% increase of the bilayer breakthrough force.
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