posted on 2013-01-08, 00:00authored byChristopher
G. Dudzik, Eric D. Walter, Benjamin S. Abrams, Melissa S. Jurica, Glenn L. Millhauser
Aggregation of the 140-amino acid protein α-synuclein
(α-syn)
is linked to the development of Parkinson’s disease (PD). α-Syn
is a copper binding protein with potential function as a regulator
of metal-dependent redox activity. Epidemiological studies suggest
that human exposure to excess copper increases the incidence of PD.
α-Syn exists in both solution and membrane-bound forms. Previous
work evaluated the Cu2+ uptake for α-syn in solution
and identified Met1-Asp2 and His50 as primary contributors to the
coordination shell, with a dissociation constant of approximately
0.1 nM. When bound to the membrane bilayer, α-syn takes on a
predominantly helical conformation, which spatially separates His50
from the N-terminus of the protein and is therefore incompatible with
the copper coordination geometry of the solution state. Here we use
circular dichroism and electron paramagnetic resonance (continuous
wave and pulsed) to evaluate the coordination of copper to the membrane-bound
form of α-syn. In this molecular environment, Cu2+ binds exclusively to the N-terminus of the protein (Met1-Asp2) with
no participation from His50. Copper does not alter the membrane-bound
α-syn conformation or enhance the release of the protein from
the bilayer. The Cu2+ affinity is similar to that identified
for solution α-syn, suggesting that copper coordination is retained
in the membrane. Consideration of these results demonstrates that
copper exerts its greatest conformational effect on the solution form
of α-syn.