Condensed Matter Theory

Active Matter Invasion

(2019)

Authors:

Felix Kempf, Romain Mueller, Erwin Frey, Julia M Yeomans, Amin Doostmohammadi

Sustained Oscillations of Epithelial Cell Sheets.

Biophysical journal 117:3 (2019) 464-478

Authors:

Grégoire Peyret, Romain Mueller, Joseph d'Alessandro, Simon Begnaud, Philippe Marcq, René-Marc Mège, Julia M Yeomans, Amin Doostmohammadi, Benoît Ladoux

Abstract:

Morphological changes during development, tissue repair, and disease largely rely on coordinated cell movements and are controlled by the tissue environment. Epithelial cell sheets are often subjected to large-scale deformation during tissue formation. The active mechanical environment in which epithelial cells operate have the ability to promote collective oscillations, but how these cellular movements are generated and relate to collective migration remains unclear. Here, combining in vitro experiments and computational modeling, we describe a form of collective oscillations in confined epithelial tissues in which the oscillatory motion is the dominant contribution to the cellular movements. We show that epithelial cells exhibit large-scale coherent oscillations when constrained within micropatterns of varying shapes and sizes and that their period and amplitude are set by the smallest confinement dimension. Using molecular perturbations, we then demonstrate that force transmission at cell-cell junctions and its coupling to cell polarity are pivotal for the generation of these collective movements. We find that the resulting tissue deformations are sufficient to trigger osillatory mechanotransduction of YAP within cells, potentially affecting a wide range of cellular processes.

Superconducting order of $\mathrm{Sr}_2\mathrm{RuO}_4$ from a three-dimensional microscopic model

(2019)

Authors:

Henrik S Røising, Thomas Scaffidi, Felix Flicker, Gunnar F Lange, Steven H Simon

Applications of integrable models in condensed matter and cold atom physics

Chapter in Integrability: From Statistical Systems to Gauge Theory, Oxford University Press (OUP) (2019) 319-351

TacoxDNA: A user-friendly web server for simulations of complex DNA structures, from single strands to origami

Journal of Computational Chemistry Wiley 40:29 (2019) 2586-2595

Authors:

Antonio Suma, Erik Poppleton, Michael Matthies, Petr Šulc, Flavio Romano, Ard A Louis, Jonathan PK Doye, Cristian Micheletti, Lorenzo Rovigatti

Abstract:

Simulations of nucleic acids at different levels of structural details are increasingly used to complement and interpret experiments in different fields, from biophysics to medicine and materials science. However, the various structural models currently available for DNA and RNA and their accompanying suites of computational tools can be very rarely used in a synergistic fashion. The tacoxDNA webserver and standalone software package presented here are a step toward a long-sought interoperability of nucleic acids models. The webserver offers a simple interface for converting various common input formats of DNA structures and setting up molecular dynamics (MD) simulations. Users can, for instance, design DNA rings with different topologies, such as knots, with and without supercoiling, by simply providing an XYZ coordinate file of the DNA centre-line. More complex DNA geometries, as designable in the cadnano, CanDo and Tiamat tools, can also be converted to all-atom or oxDNA representations, which can then be used to run MD simulations. Though the latter are currently geared toward the native and LAMMPS oxDNA representations, the open-source package is designed to be further expandable. TacoxDNA is available at http://tacoxdna.sissa.it. © 2019 Wiley Periodicals, Inc.