Alzheimer’s disease (AD) is
a protein misfolding disease
commonly characterized by neuritic amyloid plaques and proteinaceous
fibrillar aggregate deposits composed of β-amyloid (Aβ)
aggregates. The dynamic aggregation of Aβ forms toxic, nanoscale
aggregate species which proceed from oligomers to fibrils. Currently,
there is need for rapid and direct detection of Aβ peptide aggregation
and interaction with lipid membranes, as detecting an interaction
with various lipid environments will provide insights to better understand
how interactions may modulate membrane function on cellular surfaces,
leading to the progression of AD. The goal of this study was to utilize
a colorimetric, biomimetic, vesicle-binding assay as a biosensor to
detect and investigate the occurrence of neurodegenerative disease-associated
protein aggregation and interaction with lipid membranes. Lipid/polydiacetylene
(PDA) vesicles were exposed to monomeric preparations of Wild Type
Aβ(1–40) or point mutations in Aβ with amino acid
substitutions that are commonly associated with familial AD (E22G
Arctic, E22Q Dutch, A21G Flemish, D23N Iowa, and E22K Italian). We
investigated how these substitutions affect Aβ(1–40)
aggregation and interaction with lipid vesicles designed to mimic
biological membranes. Time-resolved colorimetric measurements were
obtained and reveal that exposure to lipid/PDA vesicle biosensors
results in the direct detection of mutant Aβ(1–40) peptide–lipid
interaction events. Aβ(1–40) peptide aggregate membrane
activity varies among Aβ peptide variants and lipid composition.
In addition, we used atomic force microscopy and Thioflavin T fluorescence
assays to distinguish the stages of Aβ(1–40) aggregate
formation, morphology, and membrane activity. These studies provide
a simple means of aggregate detection and insight into the role of
cellular surfaces in the mechanism of AD aggregation.
Our focus is the effects of cholesterol on the activity of the Adenosine A 2a receptor (A 2a R), a class A GPCR. Membrane cholesterol concentrations were varied in Human embryonic kidney (HEK-293) cells by the use of methylb-cyclodextrin (MbCD), which is capable of capturing cholesterol in its inner cavity (Pucadyil et al., 2006). We tested the role that bulk cholesterol depletion played in expression, ligand binding and downstream synthesis of cyclic AMP (cAMP) in HEK-293 cells. Continuing work from our lab will study the specific interaction between cholesterol and A 2a R by making point mutations in the residues of the CCM. In A 2a R those residues include Tyr43(2.41), Ser47(2.45), Lys122(4.43), Ile125(4.46) and Trp129(4.50) (Lee et al., 2013). Our lab will investigate whether these point mutations effect the interaction between cholesterol and purified receptor, as well as the receptors activity in both yeast and mammalian cell model systems.
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