posted on 2015-07-14, 00:00authored byMarta Owczarz, Anna C. Motta, Massimo Morbidelli, Paolo Arosio
We apply a kinetic analysis platform
to study the intermolecular
interactions underlying the colloidal stability of dispersions of
charged amyloid fibrils consisting of a model amphiphilic peptide
(RADA 16-I). In contrast to the aggregation mechanisms observed in
the large majority of proteins and peptides, where several elementary
reactions involving both monomers and fibrils are present simultaneously,
the system selected in this work allows the specific investigation
of the fibril–fibril aggregation process. We examine the intermolecular
interactions driving the aggregation reaction at pH 2.0 by changing
the buffer composition in terms of salt concentration, type of ion
as well as type and concentration of organic solvent. The aggregation
kinetics are followed by dynamic light scattering, and the experimental
data are simulated by Smoluchowski population balance equations, which
allow to estimate the energy barrier between two colliding fibrils
in terms of the Fuchs stability ratio (W). When normalized
on a dimensionless time weighted on the Fuchs stability ratio, the
aggregation profiles under a broad range of conditions collapse on
a single master curve, indicating that the buffer composition modifies
the aggregation kinetics without affecting the aggregation mechanism.
Our results show that the aggregation process does not occur under
diffusion-limited conditions. Rather, the reaction rate is limited
by the presence of an activation energy barrier that is largely dominated
by electrostatic repulsive interactions. Such interactions could be
reduced by increasing the concentration of salt, which induces charge
screening, or the concentration of organic solvent, which affects
the dielectric constant. It is remarkable that the dependence of the
activation energy on the ionic strength can be described quantitatively
in terms of charge screening effects in the frame of the DLVO theory,
although specific anion and cation effects are also observed. While
anion effects are mainly related to the binding to the positive groups
of the fibril surface and to the resulting decrease of the surface
charge, cation effects are more complex and involve additional solvation
forces.