Your search keyword '"Robert W. Style"' showing total 4 results

1. Phase-separated droplets swim to their dissolution

Author

Etienne Jambon-Puillet, Andrea Testa, Charlotta Lorenz, Robert W. Style, Aleksander A. Rebane, and Eric R. Dufresne

Subjects

Science

Abstract

Abstract Biological macromolecules can condense into liquid domains. In cells, these condensates form membraneless organelles that can organize chemical reactions. However, little is known about the physical consequences of chemical activity in and around condensates. Working with model bovine serum albumin (BSA) condensates, we show that droplets swim along chemical gradients. Active BSA droplets loaded with urease swim toward each other. Passive BSA droplets show diverse responses to externally applied gradients of the enzyme’s substrate and products. In all these cases, droplets swim toward solvent conditions that favor their dissolution. We call this behavior “dialytaxis”, and expect it to be generic, as conditions which favor dissolution typically reduce interfacial tension, whose gradients are well-known to drive droplet motion through the Marangoni effect. These results could potentially suggest alternative physical mechanisms for active transport in living cells, and may enable the design of fluid micro-robots.

Published

2024

2. Sustained enzymatic activity and flow in crowded protein droplets

Author

Andrea Testa, Mirco Dindo, Aleksander A. Rebane, Babak Nasouri, Robert W. Style, Ramin Golestanian, Eric R. Dufresne, and Paola Laurino

Subjects

Science

Abstract

Living cells can harvest environmental energy to drive chemical processes. Here the authors design a minimal artificial system that achieves steady states at similar metabolic densities to microorganisms.

Published

2021

3. Direct measurement of strain-dependent solid surface stress

Author

Qin Xu, Katharine E. Jensen, Rostislav Boltyanskiy, Raphaël Sarfati, Robert W. Style, and Eric R. Dufresne

Subjects

Science

Abstract

Solid surface stress is a fundamental property of solid interfaces. Here authors measure the solid surface stress of a gel, and show its dependence on surface strain through a surface modulus.

Published

2017

4. Sustained enzymatic activity and flow in crowded protein droplets

Author

Andrea, Testa, Mirco, Dindo, Aleksander A., Rebane, Babak, Nasouri, Robert W., Style, Ramin, Golestanian, Eric R., Dufresne, Paola, Laurino, Andrea, Testa, Mirco, Dindo, Aleksander A., Rebane, Babak, Nasouri, Robert W., Style, Ramin, Golestanian, Eric R., Dufresne, and Paola, Laurino

Abstract

Living cells harvest energy from their environments to drive the chemical processes that enable life. We introduce a minimal system that operates at similar protein concentrations, metabolic densities, and length scales as living cells. This approach takes advantage of the tendency of phase-separated protein droplets to strongly partition enzymes, while presenting minimal barriers to transport of small molecules across their interface. By dispersing these microreactors in a reservoir of substrate-loaded buffer, we achieve steady states at metabolic densities that match those of the hungriest microorganisms. We further demonstrate the formation of steady pH gradients, capable of driving microscopic flows. Our approach enables the investigation of the function of diverse enzymes in environments that mimic cytoplasm, and provides a flexible platform for studying the collective behavior of matter driven far from equilibrium., source:https://www.nature.com/articles/s41467-021-26532-0

Published

2021