posted on 2013-07-23, 00:00authored byJustin A. Lemkul, David
R. Bevan
Numerous
studies have concluded that the interaction of the amyloid
β-peptide (Aβ) and cellular membranes contributes to the
toxicity and cell death observed in the progression of Alzheimer’s
disease. Aggregated Aβ species disrupt membranes, leading to
physical instability and ion leakage. Further, the presence of Aβ
on the membrane surface increases the aggregation rate of the peptide,
as diffusion occurs in two dimensions, increasing the probability
of interpeptide interactions. Molecular dynamics (MD) simulations
have been used to investigate Aβ in a number of environments,
including aqueous solution and membranes. We previously showed that
monomeric Aβ40 remains embedded in membranes composed
of the most common lipids found in the cell membrane, but that the
presence of ganglioside GM1 promotes release of the peptide into the
extracellular medium. Here, we explore the interactions of two Aβ40 peptides in model membranes to understand whether aggregation
can occur prior to the release of the peptide into the aqueous environment.
We found that aggregation occurred, to different extents, in each
of the model membranes and that the aggregates, once formed, did not
exit the membrane environment. This information may have important
implications for understanding the affinity of Aβ for membranes
and the mechanism of Aβ toxicity in Alzheimer’s disease.