Identification by Integrated Computer Modeling and Light Scattering Studies of an Electrostatic Serum Albumin-Hyaluronic Acid Binding Site

Grymonpre, Kristopher R.; Staggemeier, Bethany A.; Dubin, Paul L.; Mattison, Kevin

doi:10.1021/bm005656z

Cited by 96 publications

(126 citation statements)

References 66 publications

(68 reference statements)

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“…48 Z c . BSA in the vicinity of Z ) 0 exhibits a relatively flat positive domain (see Figure 8) that accommodates a 5-nm length of the locally stiff polyanion HA; 23 further increase in chain stiffness does not impede binding to this protein domain. For small spherical micelles, the effect of polymer stiffness is obviously more important.…”

Section: Resultsmentioning

confidence: 99%

“…In so doing, we sought to identify possible binding sites for DMF25 on the protein at the critical binding conditions. The criteria established for identifying the electrostatic binding site of a protein were previously put forward 23 as follows: (1) the binding site location and size must be the same at all critical binding conditions along the phase boundary, (2) the binding domain must become appropriately larger or smaller upon pH adjustment, and (3) the mean potential ψ on or within the binding domain should satisfy the relationship zψ ≈ kT (i.e., close to thermal energy), where z is the number of polyelectrolyte charges binding cooperatively. For our purposes, we focus on the first two of these criteria.…”

Section: Resultsmentioning

confidence: 99%

“…22 The exact location of this electrostatic binding site is not a priori known, nor is it constant over the entire I range, although Grymonpré et al suggested criteria by which it might be identified. 23 The question of a positive electrostatic binding site encompassed within a globally negative protein is certainly of biological interest, as anionic biopolyelectrolytes such as GAGs do bind to proteins with pI < 7, i.e., proteins with net negative charge under physiological conditions. 24 But the nonuniformity of protein charge distributions obscures the relevance of eq 1 to polyelectrolyte-protein interactions, despite the tantalizing finding for at least one polyelectrolyte-protein system, of a linear dependence on I 1/2 of the net protein charge at the onset of binding, corresponding to eq 1, with b ) 1.…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2006

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The binding affinities of polyanions for bovine serum albumin in NaCl solutions from I ) 0.01-0.6 M, were evaluated on the basis of the pH at the point of incipient binding, converting each such pH c value into a critical protein charge Z c . Analogous values of critical charge for mixed micelles were obtained as the cationic surfactant mole fraction Y c . The data were well fitted as Y c or Z c ) KI a , and values of K and a were considered as a function of normalized polymer charge densities (τ), charge mobility, and chain stiffness. Binding increased with chain flexibility and charge mobility, as expected from simulations and theory. Complex effects of τ were related to intrapolyanion repulsions within micelle-bound loops (seen in the simulations) or negative protein domainpolyanion repulsions. The linearity of Z c with I at I < 0.3 M was explained by using protein electrostatic images, showing that Z c at I < 0.3 M depends on a single positive "patch"; the appearance of multiple positive domains I > 0.3 M (lower pH c ) disrupts this simple behavior.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

et al. 2006

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“…This variation was seen within the pH range of 4.5-6. The possibility of such variations above IEP of the protein, on the wrong side of the IEP, was attributed to the existence of a local protein domain forming a charge patch with an effective charge opposite in sign to net protein charge [30]. Around pH 3.5 a strong increase in system turbidity was observed and this point was generally symbolized as pH φ , coacervate formation pH [1][2][3][4][5][6].…”

Section: Turbidimetric Titration Under Acidificationmentioning

confidence: 99%

Complex coacervation of silk fibroin and hyaluronic acid

Malay

Bayraktar

Batıgün

2007

International Journal of Biological Macromolecules

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This study aimed to investigate the pH-induced complexation of silk fibroin (SF) and hyaluronic acid (HA). SF-HA complex coacervation was investigated by monitoring turbidity of the SF-HA system under slow acidification. Gravimetric analysis was performed to determine the yield of complex coacervation and viscosity of the system was measured to study the formation of the complexes at different pH values. The influences of total biopolymer concentration and biopolymer weight ratio on complex coacervation were examined during the analyses. Formation of the complexes was evidenced by the minimum viscosity and the maximum turbidity observed in the system. SF-HA complexes were formed within the pH-window of 2.5-3.5 regardless of the total biopolymer concentration or biopolymer ratio. Complex coacervation of SF-HA showed a reversible behavior and coacervation could be handled even in excess amounts of the biopolymers, which pointed out a non-stoichiometric complexation.

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“…31 The "charge patch", representing the spatial domain in which some sequence of the heparin chain resides in its bound state, does not correspond to the protein surface but to a region of highly positive electrostatic potential, 60 best displayed in the DelPhi images of Figure 5.…”

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confidence: 99%

Effect of Heparin on Protein Aggregation: Inhibition versus Promotion

Seeman

Yan

et al. 2012

Biomacromolecules

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The effect of heparin on both native and denatured protein aggregation was investigated by turbidimetry and dynamic light scattering (DLS). Turbidimetric data show that heparin is capable of inhibiting and reversing the native aggregation of bovine serum albumin (BSA), β-lactoglobulin (BLG), and Zn−insulin at a pH near pI and at low ionic strength I; however, the results vary with regard to the range of pH, I, and protein−heparin stoichiometry required to achieve these effects. The kinetics of this process were studied to determine the mechanism by which interaction with heparin could result in inhibition or reversal of native protein aggregates. For each protein, the binding of heparin to distinctive intermediate aggregates formed at different times in the aggregation process dictates the outcome of complexation. This differential binding was explained by changes in the affinity of a given protein for heparin, partly due to the effects of protein charge anisotropy as visualized by electrostatic modeling. The heparin effect can be further extended to include inhibition of denaturing protein aggregation, as seen from the kinetics of BLG aggregation under conditions of thermally induced unfolding with and without heparin.

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Identification by Integrated Computer Modeling and Light Scattering Studies of an Electrostatic Serum Albumin-Hyaluronic Acid Binding Site

Cited by 96 publications

References 66 publications

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

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

Complex coacervation of silk fibroin and hyaluronic acid

Effect of Heparin on Protein Aggregation: Inhibition versus Promotion

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