Like-charged protein-polyelectrolyte complexation driven by charge patches

Yigit, Cemil; Heyda, Jan; Ballauff, Matthias; Dzubiella, Joachim

doi:10.1063/1.4928078

Cited by 51 publications

(88 citation statements)

References 66 publications

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“…We finally note that the discontinuity observed in the PE-PE association process may also emerge during the complexation of PEs and globular proteins as indicated in recent coarse-grained computer simulations of more [39] or less [38] resolved protein models with heterogeneous charge distributions. In these cases, counterion-release effects after PE binding to protein surface charge patches have also been identified as the main non-specific interaction responsible for the PE-protein complexation.…”

Section: Summary and Concluding Remarksmentioning

confidence: 99%

“…Similar values of r 0 can be estimated from an inspection of the radial distribution of counterions (not shown) around the PE beads (see, e.g., Refs. [38,39,53]). …”

Section: B Charge Densities and Counterion Condensationmentioning

confidence: 99%

“…The density of the bound ions [38,39] is defined by the number of condensed counterions N and their occupied volume V , i.e., c b = N/V . The condensed counterions reside around each rod at a radial distance between the inner radius σ LJ and the outer radius r 0 .…”

Section: Pe Alignment Order Parametermentioning

confidence: 99%

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Potential of mean force and transient states in polyelectrolyte pair complexation

Kanduč

et al. 2016

The Journal of Chemical Physics

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The association between polyelectrolytes (PEs) of the same size but opposite charge is systematically studied in terms of the potential of mean force (PMF) along their center-of-mass reaction coordinate via coarse-grained, implicit-solvent, explicit-salt computer simulations. The focus is set on the onset and the intermediate, transient stages of complexation. At conditions above the counterion-condensation threshold, the PE association process exhibits a distinct sliding-rod-like behavior where the polymer chains approach each other by first stretching out at a critical distance close to their contour length, then 'shaking hand' and sliding along each other in a parallel fashion, before eventually folding into a neutral complex. The essential part of the PMF for highly charged PEs can be very well described by a simple theory based on sliding charged 'Debye-Hückel' rods with renormalized charges in addition to an explicit entropy contribution owing to the release of condensed counterions. Interestingly, at the onset of complex formation, the mean force between the PE chains is found to be discontinuous, reflecting a bimodal structural behavior that arises from the coexistence of interconnected-rod and isolated-coil states. These two microstates of the PE complex are balanced by subtle counterion release effects and separated by a free-energy barrier due to unfavorable stretching entropy.1 arXiv:1602.06547v1 [cond-mat.soft]

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Section: Summary and Concluding Remarksmentioning

confidence: 99%

“…Similar values of r 0 can be estimated from an inspection of the radial distribution of counterions (not shown) around the PE beads (see, e.g., Refs. [38,39,53]). …”

Section: B Charge Densities and Counterion Condensationmentioning

confidence: 99%

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Potential of mean force and transient states in polyelectrolyte pair complexation

Kanduč

et al. 2016

The Journal of Chemical Physics

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“…As pointed out in Section 2.1, this class of proteins is related to charged patchy colloids, and several models are being developed in this respect. 100,103 The appropriate modeling of directional interactions caused by charge inhomogeneities can be challenging, in particular with respect to specific ion effects: for instance, by forming salt bridges, multivalent ions have very drastic effects on the effective interactions between proteins in solution to the point of rendering directional charge repulsions attractive. 116 More refined models which take into account electric multipoles as well as the distribution of charged, neutral and hydrophobic residues have been developed.…”

Section: Patchy Proteinsmentioning

confidence: 99%

“…97 A different modeling of charged Janus colloids was proposed to investigate the relation between the order of the multipolar expansion of the inter-particle potential and the resulting minimum-energy clusters. 98 In the context of globular proteins, a set of charged patchy particle models was introduced 99 to study the adsorption of such units on a polyelectrolyte chain 100 or on a polyelectrolyte brush layer. 101 These charged patchy models 99 have also been used to investigate the effect of multivalent electrolytes on the orientational correlations between the patchy units: it was shown that a careful choice of electrolytes could be used to steer the particle assembly.…”

Section: Charged Patchy Colloidsmentioning

confidence: 99%

Limiting the valence: advancements and new perspectives on patchy colloids, soft functionalized nanoparticles and biomolecules

Bianchi

Capone

Coluzza

et al. 2017

Phys. Chem. Chem. Phys.

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Limited bonding valence, usually accompanied by well-defined directional interactions and selective bonding mechanisms, is nowadays considered among the key ingredients to create complex structures with tailored properties: even though isotropically interacting units already guarantee access to a vast range of functional materials, anisotropic interactions can provide extra instructions to steer the assembly of specific architectures. The anisotropy of effective interactions gives rise to a wealth of self-assembled structures both in the realm of suitably synthesized nano-and micro-sized building blocks and in nature, where the isotropy of interactions is often a zero-th order description of the complicated reality.In this review, we span a vast range of systems characterized by limited bonding valence, from patchy colloids of new generation to polymer-based functionalized nanoparticles, DNA-based systems and proteins, and describe how the interaction patterns of the single building blocks can be designed to tailor the properties of the target final structures.

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Atomic force microscopy as a tool to study the adsorption of DNA onto lipid interfaces

Luque-Caballero

Maldonado-Valderrama

Quesada‐Pérez

2016

Microscopy Res & Technique

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The Atomic Force Microscopy (AFM) technique appears as a central tool for the characterization of DNA adsorption onto lipid interfaces. Regardless of the huge number of surveys devoted to this issue, there are still fascinating phenomena in this field that have not been explored in detail by AFM. For instance, adsorption of DNA onto like-charged lipid surfaces mediated by cations is still not fully understood even though it is gaining popularity nowadays in gene therapy and nanotechnology. Studies related to the complexation of DNA with anionic lipids as a non-viral gene delivery vehicle as well as the formation of self-assembled nanoscale DNA constructs (DNA origami) are two of the most attractive systems. Unfortunately, molecular mechanisms underlying the adsorption of DNA onto anionic lipid interfaces remain unclear so far. In view of that, AFM becomes an appropriate technique to provide valuable information to understand the adsorption of DNA to anionic lipid surfaces. As a second part of this review we provide an illustrative example of application of the AFM technique to probe the DNA adsorption onto a model lipid monolayer negatively charged. Microsc. Res. Tech. 80:11-17, 2017. © 2016 Wiley Periodicals, Inc.

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Like-charged protein-polyelectrolyte complexation driven by charge patches

Cited by 51 publications

References 66 publications

Potential of mean force and transient states in polyelectrolyte pair complexation

Potential of mean force and transient states in polyelectrolyte pair complexation

Limiting the valence: advancements and new perspectives on patchy colloids, soft functionalized nanoparticles and biomolecules

Atomic force microscopy as a tool to study the adsorption of DNA onto lipid interfaces

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