Effects of patch size and number within a simple model of patchy colloids

Giacometti, Andrea; Lado, F.; Largo, J.; Pastore, G.; Sciortino, Francesco

doi:10.1063/1.3415490

Cited by 116 publications

(136 citation statements)

References 56 publications

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“…Given that both natural proteins 3-8 and synthetic colloids [18][19][20][21][22][23][24][25][26][27][28][29] have been shown to readily assemble into symmetric, higher order structures, we anticipate that our SuPrA strategy can now be generalized to create synthetic, scalable…”

Section: 31mentioning

confidence: 99%

“…16,17 In contrast, studies of simple synthetic colloids suggests that higher order structures can be derived based solely on packing and energetic and considerations. Computational and experimental studies of polyhedral or spherical colloids indicate that complementary particle shapes 18-24 and simple attractive "patches" [24][25][26][27][28][29] alone can enable formation of complex symmetrical assemblies. Shape complementarity has likewise been exploited to arrange synthetic linear biomolecules, i.e., double-stranded DNA strands, into distinct structures, demonstrating its utility for for the higher order arrangement of synthetic linear biomolecules, suggesting a utility beyond inorganic systems.…”

Section: Introductionmentioning

confidence: 99%

“…Notably, while some GFP variants, including the parent protein originally found in Aeqorea Victoria dimerize, the native dimer structure fits poorly into the electron density maps of the protomer, suggesting that the architecture of the protomer is completely novel. 54 The formation of SuPrA protomers appears to be largely independent of the placement of charges, suggesting that oppositely supercharging protein variants may generally drive formation into 'stacked' or brick-like structures whose overall form is determined by symmetric interactions.Given that both natural proteins 3-8 and synthetic colloids [18][19][20][21][22][23][24][25][26][27][28][29] have been shown to readily assemble into symmetric, higher order structures, we anticipate that our SuPrA strategy can now be generalized to create synthetic, scalableAll rights reserved. No reuse allowed without permission.…”

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Supercharging enables organized assembly of synthetic biomolecules

Simon

Ramasubramani

Gläser

et al. 2018

Preprint

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Abstract:There are few methods for the assembly of defined protein oligomers and higher order structures that could serve as novel biomaterials. Using fluorescent proteins as a model system, we have engineered novel oligomerization states by combining oppositely supercharged variants. A well-defined, highly symmetrical 16-mer (two stacked, circular octamers) can be formed from alternating charged proteins; higher order structures then form in a hierarchical fashion from this discrete protomer. During SUpercharged PRotein Assembly (SuPrA), electrostatic attraction between oppositely charged variants drives interaction, while shape and patchy physicochemical interactions lead to spatial organization along specific interfaces, ultimately resulting in protein assemblies never before seen in nature.All rights reserved. No reuse allowed without permission.(which was not peer-reviewed) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.The copyright holder for this preprint . http://dx.doi.org/10.1101/323261 doi: bioRxiv preprint first posted online May. 16, 2018; 2 The assembly of genetically-encoded molecules into symmetric, supramolecular materials enables complex functions in natural biosystems and would likewise prove valuable in the development of bionanotechnologies including drug delivery, energy transport, and biological information storage. [1][2][3][4][5][6][7] Repeated, symmetric interactions between molecular building blocks enable the formation of complex, defined, assemblies from a small total number of components as well as dynamic propagation of conformational change. [3][4][5][6][7][8] However, while de novo engineering of artificial symmetrical biomolecular complexes has begun to be explored, 9-15 these efforts generally rely upon precise design of molecular interfaces. 16,17 In contrast, studies of simple synthetic colloids suggests that higher order structures can be derived based solely on packing and energetic and considerations. Computational and experimental studies of polyhedral or spherical colloids indicate that complementary particle shapes 18-24 and simple attractive "patches" [24][25][26][27][28][29] alone can enable formation of complex symmetrical assemblies. Shape complementarity has likewise been exploited to arrange synthetic linear biomolecules, i.e., double-stranded DNA strands, into distinct structures, demonstrating its utility for for the higher order arrangement of synthetic linear biomolecules, suggesting a utility beyond inorganic systems. 30,31Herein we demonstrate a simple, robust strategy to assemble normally monomeric proteins into well defined, oligomeric quaternary structures and micron-scale particles. This strategy centers on driving protein interactions by engineering oppositely supercharged variants. Generally, oppositely-charged proteins interact through simple electrostativ interactions. 32 Previously, this propensity has been exploited in artificial biosystems to engineer binary protein crystals from naturally oppos...

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Section: 31mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

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Supercharging enables organized assembly of synthetic biomolecules

Simon

Ramasubramani

Gläser

et al. 2018

Preprint

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“…7 In fact, one of the most attractive features of the general model stems from the fact that it smoothly interpolates between an isotropic HS fluid (zero coverage) and an equally isotropic SW fluid (full coverage). 8,9 The thermophysical and structural properties of the Janus fluid have been recently investigated within the framework of the Kern-Frenkel model using numerical simulations, 7,10 thus rationalizing the cluster formation mechanism characteristic of the experiments. 3 The fluidfluid transition was found to display an unconventional and particularly interesting phase diagram, with a reentrant transition associated with the formation of a cluster phase at low temperatures and densities.…”

Section: Introductionmentioning

confidence: 99%

Janus fluid with fixed patch orientations: Theory and simulations

Maestre

Fantoni

Giacometti

et al. 2013

The Journal of Chemical Physics

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We study thermophysical properties of a Janus fluid with constrained orientations, using analytical techniques and numerical simulations. The Janus character is modeled by means of a Kern-Frenkel potential where each sphere has one hemisphere of square-well and the other of hard-sphere character. The orientational constraint is enforced by assuming that each hemisphere can only point either North or South with equal probability. The analytical approach hinges on a mapping of the above Janus fluid onto a binary mixture interacting via a "quasi" isotropic potential. The anisotropic nature of the original Kern-Frenkel potential is reflected by the asymmetry in the interactions occurring between the unlike components of the mixture. A rationalfunction approximation extending the corresponding symmetric case is obtained in the sticky limit, where the square-well becomes infinitely narrow and deep, and allows a fully analytical approach. Notwithstanding the rather drastic approximations in the analytical theory, this is shown to provide a rather precise estimate of the structural and thermodynamical properties of the original Janus fluid.

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“…For future work we are planning to apply the version of our theory developed for the model with two patches to describe the phase behaviour of triblock Janus colloids. [39][40][41] …”

Section: Discussionmentioning

confidence: 99%

Second-order resummed thermodynamic perturbation theory for central-force associating potential: Multi-patch colloidal models

Kalyuzhnyi

Marshall

Chapman

et al. 2013

The Journal of Chemical Physics

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We propose a second-order version of the resummed thermodynamic perturbation theory for patchy colloidal models with arbitrary number of multiply bondable patches. The model is represented by the hard-sphere fluid system with several attractive patches on the surface and resummation is carried out to account for blocking effects, i.e., when the bonding of a particle restricts (blocks) its ability to bond with other particles. The theory represents an extension of the earlier proposed first order resummed thermodynamic perturbation theory for central force associating potential and takes into account formation of the rings of the particles. In the limiting case of singly bondable patches (total blockage), the theory reduces to Wertheim thermodynamic perturbation theory for associating fluids. Closed-form expressions for the Helmholtz free energy, pressure, internal energy, and chemical potential of the model with an arbitrary number of equivalent doubly bondable patches are derived. Predictions of the theory for the model with two patches appears to be in a very good agreement with predictions of new NVT and NPT Monte Carlo simulations, including the region of strong association.

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Effects of patch size and number within a simple model of patchy colloids

Cited by 116 publications

References 56 publications

Supercharging enables organized assembly of synthetic biomolecules

Supercharging enables organized assembly of synthetic biomolecules

Janus fluid with fixed patch orientations: Theory and simulations

Second-order resummed thermodynamic perturbation theory for central-force associating potential: Multi-patch colloidal models

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