Effects of Polyelectrolyte Chain Stiffness, Charge Mobility, and Charge Sequences on Binding to Proteins and Micelles

Cooper, Carlton R.; Goulding, Ann; Kayitmazer, A. Basak; Ulrich, Serge; Stoll, Serge; Turksen, Sibel; Yusa, § Shin-ichi; Kumar, Anil; Dubin, Paul L.

doi:10.1021/bm050592j

Cited by 128 publications

(148 citation statements)

References 56 publications

(136 reference statements)

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“…[1][2][3][4][5][6] The range of parameters influencing polyelectrolyte conformation, chemical reactivity, and complexation processes is not completely understood and continues to stimulate intensive research in this field because they control directly many industrial [7][8][9][10] and biological processes. [11][12][13][14] The particular physicochemical properties of polyelectrolyte chains arise from the long-range nature of the Coulomb interactions. In addition, in the vicinity of chains, small charged mobile counterions interact strongly with the chain backbone, leading to a rich conformational behavior by reducing Coulomb repulsions and introducing ion-ion mediated attractions.…”

Section: Introductionmentioning

confidence: 99%

Influence of Explicit Ions on Titration Curves and Conformations of Flexible Polyelectrolytes: A Monte Carlo Study

2010

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Acid/base and conformational properties of a weak polyelectrolyte chain surrounded by explicit ions (counterions and salt particles) are investigated using Monte Carlo simulations. The influence of the pH, monomer size, presence of explicit ions, salt particles, salt size, and valency on the polyelectrolyte titration process is systematically investigated. It is shown that the presence of explicit ions, the increase in pH and monomer sizes, and the decrease in salt radius are parameters that favor the monomer deprotonation processes hence affecting the global acid/base polyelectrolyte chain properties. The competition between attractive and repulsive, long-range and local electrostatic interactions leads to a heterogeneous distribution of charges and ions along the polyelectrolyte backbones. This subtle electrostatic competition leads to equilibrated chain conformations ranging from extended to globular conformations. A simple screening effect is achieved with monovalent salt resulting in a slight limitation of the formation of extended structures at high pH values. Focusing on trivalent salt, the local complexation of several chain monomers around each trivalent cation leads to the formation of collapsed structures. The decrease in the size of trivalent cations promotes the deprotonation process, in particular, when trivalent salt cations are smaller than the monomer size.

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Section: Introductionmentioning

confidence: 99%

Influence of Explicit Ions on Titration Curves and Conformations of Flexible Polyelectrolytes: A Monte Carlo Study

2010

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“…29,30 However, the charge heterogeneity of protein introduces repulsive forces between polyanion and protein negative domains. 11 No particles formed for PSS above 10 mg/L ( Figure 5B), indicating that the repulsion as well as repulsion between excess polymer sulfonate groups appears to be sufficient to inhibit a-gliadin aggregation at pH 6.8. The optimal polymer composition for interaction with protein would maximize electrostatic and hydrophobic attraction, but minimize repulsion with protein.…”

Section: Interaction Of A-gliadin With Polyanions 425mentioning

confidence: 99%

“…The optimal polymer composition for interaction with protein would maximize electrostatic and hydrophobic attraction, but minimize repulsion with protein. 11 In copolymers with less SS, the hydrophilic and electrically neutral HEMA segments may sterically hinder the attraction of SS segments with a-gliadin and yet provide stabilization by enrichment on the periphery of complex particles. These factors may explain why PHS1 at 1 mg/L did not, unlike PSS, induce an increase in complex size, but instead suppressed protein aggregation ( Figures 7A and 7B).…”

Section: Interaction Of A-gliadin With Polyanions 425mentioning

confidence: 99%

“…10 Copolymerization of SS with HEMA may be controlled to obtain variations in the resulting polymer charge density, which has been reported recently to affect polymer interaction with proteins. 11,12 Moreover, the inclusion of HEMA units may affect hydrophobic interaction between SS phenyl and protein hydrophobic residues. In this work, interactions between a-gliadin and polymers with different SS and HEMA contents were studied at gastric and intestinal pH using circular dichroism (CD), turbidity, dynamic light scattering (DLS), and zeta potential measurements.…”

Section: Introductionmentioning

confidence: 99%

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Interaction of α‐gliadin with polyanions: Design considerations for sequestrants used in supportive treatment of celiac disease

et al. 2010

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Copolymers of sodium 4-styrene sulfonate (SS) and hydroxyethyl methacrylate (HEMA) were investigated as sequestrants of alpha-gliadin, a gluten protein, for the treatment of gluten intolerance. The interactions of alpha-gliadin with poly(SS) and poly(HEMA-co-SS) with 9 and 26 mol% SS content were studied at gastric (1.2) and intestinal (6.8) pH using circular dichroism and measurements of turbidity, dynamic light scattering and zeta potential. The interactions and their influence on alpha-gliadin secondary and aggregated structures depended mainly on the ratio of polymer negative and protein positive charges at pH 1.2, and on polymer SS content at polymer concentrations providing in excess of negative charges at either pH. Poly(SS) could not form complex particles with alpha-gliadin in a sufficient excess of negative charges. Copolymerization with HEMA enhanced the formation of complex particles. Poly(HEMA-co-SS) with intermediate SS content was found to be the most effective sequestrant for alpha-gliadin. This study provides insight into design considerations for polymer sequestrants used in the supportive treatment of celiac disease.

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“…4 The complexation of PEs on various substrates has been investigated by a range of experimental methods, theoretical models, and computer simulations. [5][6][7] A series of contributions from Dubin and co-workers 6,[8][9][10][11][12] was made on the adsorption of PEs to spherical nanometric size micelles, dendrimers, and proteins using both experimental and computer simulations. These contributions pointed out the importance of the NP surface charge density and revealed that for PEs of high linear charge density, complexation was electrostatically driven.…”

Section: Introductionmentioning

confidence: 99%

Dielectric discontinuity effects on the adsorption of a linear polyelectrolyte at the surface of a neutral nanoparticle

Seijo

Pohl

Ulrich

et al. 2009

The Journal of Chemical Physics

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The formation of complexes between nanoparticles and polyelectrolytes is a key process for the control of the reactivity of manufactured nanoparticles and rational design of core shell nanostructures. In this work, we investigate the influence of the nanoparticle dielectric constant on the adsorption of a linear charged polymer ͑polyelectrolyte͒ at the surface of a neutral nanoparticle. The polyelectrolyte linear charge density, as well as the image charges in the nanoparticle due to the dielectric discontinuity, is taken into account. Monte Carlo simulations are used to predict the adsorption/desorption limits and system properties. Effects of the nanoparticle size and polyelectrolyte length are also investigated. The polyelectrolyte is found adsorbed on the nanoparticle when the dielectric constant of the nanoparticle is greater than the dielectric constant of the medium. Attractive interactions induced by the presence of opposite sign image charges are found strong enough to adsorb the polyelectrolyte showing that the reaction field contribution has to be considered. The affinity between the polyelectrolyte and the nanoparticle is found to increase in magnitude by increasing the nanoparticle size and dielectric constant. The reaction field magnitude is also found to depend in a nonlinear way from the polyelectrolyte length.

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Effects of Polyelectrolyte Chain Stiffness, Charge Mobility, and Charge Sequences on Binding to Proteins and Micelles

Cited by 128 publications

References 56 publications

Influence of Explicit Ions on Titration Curves and Conformations of Flexible Polyelectrolytes: A Monte Carlo Study

Influence of Explicit Ions on Titration Curves and Conformations of Flexible Polyelectrolytes: A Monte Carlo Study

Interaction of α‐gliadin with polyanions: Design considerations for sequestrants used in supportive treatment of celiac disease

Dielectric discontinuity effects on the adsorption of a linear polyelectrolyte at the surface of a neutral nanoparticle

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