Light scattering study of complex formation between protein and polyelectrolyte at various ionic strengths

Formation of protein-polyelectrolyte complexes (PPCs) between bovine serum albumin (BSA) and potassium poly (vinyl alcohol) sulfate (KPVS) was studied at pH 3 as a function of ionic strength. Turbidimetric titration was employed by a combination of dynamic light scattering (DLS) and electrophoretic light scattering (ELS). The formal charge (Z(PPC)) of the resulting PPCs at different ionic strengths were estimated from ELS data by assuming the free draining and the non-free draining model. The radius of a BSA molecule in the complex was used in the former model for calculation of Z(PPC) with the Henry's equation, while in the latter case the hydrodynamic radius of a PPC particle determined from DLS was employed. The results obtained were compared with the Z(PPC) values calculated using a relation of Z(PPC)=n(b)Z(BSA)+alphaZ(KPVS), where Z(BSA) (> or =0) and Z(KPVS) (< or =0) denote the formal charge of BSA and KPVS, respectively. Moreover, n(b) is the number of bound proteins per complex composed of alpha polymer chains. It was suggested that the PPC between BSA and KPVS behaves as a free draining molecule during the electrophoresis, at least at a high ionic strength. Also suggested is that the PPC formation at low ionic strength follows a 1:1 stoichiometry in the charge neutralization.

Effect of monovalent cations on the aggregation of tobacco mosaic virus by chondroitin sulfate

The mechanism of precipitation of tobacco mosaic virus by chondroitin sulfate in the presence of various monovalent cations was investigated kinetically by means of turbidimetry. The virus solution became turbid on the addition of chondroitin sulfate, and led to separation of the virus as a crystalline phase. In the presence of monovalent cations the degree of precipitation of the virus by chondroitin was reduced with the increase in monovalent cation concentration. The order of the reduction was Li+ less than Na+ less than K+, which is reversely analogous to the lyotropic series. The least hydrated cation, K+, reduced the degree of precipitation of tobacco mosaic virus the most because the radius of the sphere equivalent to chondroitin sulfate was diminished most strongly by K+ ion. The effect of the monovalent cations on the precipitation supports our assumption that the virus precipitation results from incompatibility and mutual spatial exclusion between the virus and chondroitin. The maximum turbidities, the initial slopes, and the aggregation half-time were measured by varying the monovalent cation concentrations. The former two parameters decreased with the increase in cation concentration, whereas the aggregation half-time increased. A lag time was present and the effect of the cations increased in the order K+ less than Na+ less than Li+.

Aggregation of tobacco mosaic virus by sodium chondroitin sulfate

The precipitation of tobacco mosaic virus by sodium chondroitin sulfate in an aqueous solution was investigated kinetically by means of turbidimetry. The virus solution became turbid after the addition of chondroitin sulfate. A threshold concentration of chondroitin, 1.33 mg/ml, was required for virus precipitation, irrespective of the virus concentration. The precipitation resulted from a mutual spatial exclusion phenomenon, leading to the separation of the virus as a crystalline phase. The dimension of chondroitin sulfate calculated at the threshold concentration agreed well with that obtained by other methods. The initial slopes and the aggregation half-times of the virus aggregates depended on both chondroitin and virus concentrations and the former increased with the increase in concentration of each. Above the threshold concentration of chondroitin sulfate, tobacco mosaic virus aggregation was a rapid-aggregation process and ended within 100 sec.