Vladimir I. Razinkov scite author profile

Specific-ion effects are ubiquitous in nature; however, their underlying mechanisms remain elusive. Although Hofmeister-ion effects on proteins are observed at higher (>0.3M) salt concentrations, in dilute (<0.1M) salt solutions nonspecific electrostatic screening is considered to be dominant. Here, using effective charge (Q*) measurements of hen-egg white lysozyme (HEWL) as a direct and differential measure of ion-association, we experimentally show that anions selectively and preferentially accumulate at the protein surface even at low (<100 mM) salt concentrations. At a given ion normality (50 mN), the HEWL Q* was dependent on anion, but not cation (Li 1 , Na 1 , K 1 , Rb 1 , Cs 1 , GdnH 1 , and Ca 21 ), identity. The Q* decreased in the order, demonstrating progressively greater binding of the monovalent anions to HEWL and also show that the SO 2À 4 anion, despite being strongly hydrated, interacts directly with the HEWL surface. Under our experimental conditions, we observe a remarkable asymmetry between anions and cations in their interactions with the HEWL surface.

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Aggregation of anti-streptavidin immunoglobulin gamma‐1 involves Fab unfolding and competing growth pathways mediated by pH and salt concentration

Kim

Remmele

Liu

et al. 2013

Biophysical Chemistry

135

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Acid-Induced Aggregation of Human Monoclonal IgG1 and IgG2: Molecular Mechanism and the Effect of Solution Composition

et al. 2010

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The prevention of aggregation in therapeutic antibodies is of great importance to the biopharmaceutical industry. In our investigation, acid-induced aggregation of monoclonal IgG1 and IgG2 antibodies was studied at pH 3.5 as a function of salt concentration and buffer type. The extent of aggregation was estimated using a native cation-exchange chromatography (CEX) method based on the loss of soluble monomer. This approach allowed quantitative analysis of antibody aggregation kinetics for individual and mixed protein solutions. Information regarding the aggregation mechanism was gained by assessing stabilities of intact antibodies relative to their Fc and Fab fragments. The role of protein thermodynamic stability in aggregation was deduced from differential scanning calorimetry (DSC). The rate of aggregation under conditions mimicking the viral inactivation step during monoclonal antibody (mAb) processing was found to be strongly dependent on the antibody subclass (IgG1 vs IgG2). At 25 °C, IgG1s were resistant to low pH aggregation, but IgG2s aggregated readily in the presence of salt. The observed distinction between IgG1 and IgG2 aggregation resulted from differential stability of the corresponding C(H)2 domains. This was further confirmed by experimenting with an IgG1 molecule containing an aglycosylated C(H)2 domain. Interestingly, comparative analysis of two buffer systems (based on acetic acid vs citric acid) revealed differences in mAb aggregation under identical pH conditions. Evidence is provided for the importance of the total acid concentration for antibody aggregation at low pH. The effects of C(H)2 instability and solution composition on aggregation are significant and deserve careful consideration during the development of mAb- or Fc-based therapeutics.

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Specific-Ion Effects on the Aggregation Mechanisms and Protein–Protein Interactions for Anti-streptavidin Immunoglobulin Gamma-1

et al. 2015

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Non-native protein aggregation is common in the biopharmaceutical industry and potentially jeopardizes product shelf life, therapeutic efficacy, and patient safety. The present article focuses on the relationship(s) among protein-protein interactions, aggregate growth mechanisms, aggregate morphologies, and specific-ion effects for an anti-streptavidin (AS) immunoglobulin gamma 1 (IgG1). Aggregation mechanisms of AS-IgG1 were determined as a function of pH and NaCl concentration with sodium acetate buffer and compared to previous work with sodium citrate. Aggregate size and shape were determined using a combination of laser light scattering and small-angle neutron or X-ray scattering. Protein-protein interactions were quantified in terms of the protein-protein Kirkwood-Buff integral (G22) determined from static light scattering and in terms of the protein effective charge (Zeff) measured using electrophoretic light scattering. Changing from citrate to acetate resulted in significantly different protein-protein interactions as a function of pH for low NaCl concentrations when the protein displayed positive Zeff. Overall, the results suggest that electrostatic repulsions between proteins were lessened because of preferential accumulation of citrate anions, compared to acetate anions, at the protein surface. The predominant aggregation mechanisms correlated well with G22, indicating that ion-specific effects beyond traditional mean-field descriptions of electrostatic protein-protein interactions are important for predicting qualitative shifts in protein aggregation state diagrams. Interestingly, while solution conditions dictated which mechanisms predominated, aggregate average molecular weight and size displayed a common scaling behavior across both citrate- and acetate-based systems.

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