Influence of Protein Self-Association on Complex Coacervation
with Polysaccharide: A Monte Carlo Study
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Abstract
Coarse-grained
Monte Carlo simulations have been applied to study complex coacervation
of pectin with bovine serum albumin (BSA) and two isomers of beta-lactoglobulin
(BLGA and BLGB). The influence from the specific distribution of charge
and hydrophobic patches in protein surfaces on the self-association
of proteins and their complex coacervation were investigated. A simple
and direct method to quantify the contribution of hydrophobic interaction
on protein complex formation was introduced. Highly accordant pH dependence
of charges in proteins and phase boundaries for the complex coacervation
was observed. Comparing to BSA, beta-lactoglobulin had a higher probability
and a broader pH window to form complex coacervate. The major cause
is the higher self-association proneness of beta-lactoglobulin, as
evidenced by the more negative second virial coefficients. The double-point
mutations of G64D/V118A from BLGB to BLGA caused the latter one to
have a stronger self-association proneness. It was revealed that the
larger negative charge patch in BLGA synergistically enhanced the
attraction of the strongest binding site, a positive charge patch,
when pH was close to or above the isoelectric point of the protein.
These findings suggest that the coarse grained simulation is competent
to explore the delicate influences from different proteins in protein–polysaccharide
complex coacervates