Molecular Complex Composed of β‑Cyclodextrin-Grafted Chitosan and pH-Sensitive Amphipathic Peptide for Enhancing Cellular Cholesterol Efflux under Acidic pH
Excess
of cholesterol in peripheral cells is known to lead to atherosclerosis.
In this study, a molecular complex composed of β-cyclodextrin-grafted
chitosan (BCC) and cellular cholesterol efflux enhancing peptide (CEEP),
synthesized by modifying pH sensitive amphipathic GALA peptide, is
introduced with the eventual aim of treating atherosclerosis. BCC
has a markedly enhanced ability to induce cholesterol efflux from
cell membranes compared to β-cyclodextrin, and the BCC-CEEP
complex exhibited a 2-fold increase in cellular cholesterol efflux
compared to BCC alone under weakly acidic conditions. Isothermal titration
calorimetry and fluorescence spectroscopy measurements demonstrated
that the random coil structure of CEEP at neutral pH converted to
the α-helical structure at acidic pH, resulting in a three-order
larger binding constant to BCC (K = 3.7 × 107 at pH 5.5) compared to that at pH 7.4 (K = 7.9 × 104). Such high-affinity binding of CEEP
to BCC at acidic pH leads to the formation of 100-nm-sized aggregate
with positive surface charge, which would efficiently interact with
cell membranes and induce cholesterol efflux. Since the cholesterol
efflux ability of HDL is thought to be impaired under acidic environments
in advanced atherosclerotic lesions, the BCC-CEEP complex might serve
as a novel nanomaterial for treating atherosclerosis.