Conformational switching of chiral colloidal rafts regulates raft–raft attractions and repulsions

Membrane-mediated particle interactions depend both on the properties of the particles themselves and the membrane environment in which they are suspended. Experiments have shown that chiral rod-like inclusions dissolved in a colloidal membrane of opposite handedness assemble into colloidal rafts, w...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 116; no. 32; pp. 15792 - 15801
Main Authors Miller, Joia M., Joshi, Chaitanya, Sharma, Prerna, Baskaran, Arvind, Baskaran, Aparna, Grason, Gregory M., Hagan, Michael F., Dogic, Zvonimir
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 06.08.2019
SeriesPNAS Plus
Subjects
Assembly
Chirality
Colloids
Computational fluid dynamics
Continuum modeling
Couplings
Crystallites
Crystals
Domains
Handedness
Inclusions
Lipid bilayers
Lipids
Particle interactions
Physical Sciences
PNAS Plus
Properties (attributes)
Rafts
Rods
Twisting
membranes
self-assembly
liquid crystals
colloids
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Summary:Membrane-mediated particle interactions depend both on the properties of the particles themselves and the membrane environment in which they are suspended. Experiments have shown that chiral rod-like inclusions dissolved in a colloidal membrane of opposite handedness assemble into colloidal rafts, which are finite-sized reconfigurable droplets consisting of a large but precisely defined number of rods. We systematically tune the chirality of the background membrane and find that, in the achiral limit, colloidal rafts acquire complex structural properties and interactions. In particular, rafts can switch between 2 chiral states of opposite handedness, which alters the nature of the membrane-mediated raft–raft interactions. Rafts with the same chirality have long-ranged repulsions, while those with opposite chirality acquire attractions with a well-defined minimum. Both attractive and repulsive interactions are qualitatively explained by a continuum model that accounts for the coupling between the membrane thickness and the local tilt of the constituent rods. These switchable interactions enable assembly of colloidal rafts into intricate higher-order architectures, including stable tetrameric clusters and “ionic crystallites” of counter-twisting domains organized on a binary square lattice. Furthermore, the properties of individual rafts, such as their sizes, are controlled by their complexation with other rafts. The emergence of these complex behaviors can be rationalized purely in terms of generic couplings between compositional and orientational order of fluids of rod-like elements. Thus, the uncovered principles might have relevance for conventional lipid bilayers, in which the assembly of higher-order structures is alsomediated by complex membrane-mediated interactions.
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Edited by Monica Olvera de la Cruz, Northwestern University, Evanston, IL, and approved June 19, 2019 (received for review January 25, 2019)
Author contributions: J.M.M. and Z.D. designed research; J.M.M., C.J., and Arvind Baskaran performed research; P.S. acquired preliminary data; J.M.M., C.J., Arvind Baskaran, Aparna Baskaran, and G.M.G. analyzed data; and J.M.M., M.F.H., and Z.D. wrote the paper.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1900615116