posted on 2007-09-27, 00:00authored byAmy Y. Shih, Anton Arkhipov, Peter L. Freddolino, Stephen G. Sligar, Klaus Schulten
The self-assembly of reconstituted discoidal high-density lipoproteins, known as nanodiscs, was studied using
coarse-grained molecular dynamics and small-angle X-ray scattering. In humans, high-density lipoprotein
particles transport cholesterol in the blood and facilitate the removal of excess cholesterol from the body.
Native high-density lipoprotein exhibits a wide variety of shapes and sizes, forming lipid-free/poor, nascent
discoidal, and mature spherical particles. Little is known about how these lipoprotein particles assemble and
transform from one state to another. Multiple 10 μs coarse-grained simulations reveal the assembly of discoidal
high-density lipoprotein particles from disordered protein−lipid complexes. Small-angle X-ray scattering
patterns were calculated from the final assembled structures and compared with experimental measurements
carried out for this study to verify the accuracy of the coarse-grained simulations. Results show that hydrophobic
interactions assemble, within several microseconds, the amphipathic helical proteins and lipids into roughly
discoidal particles, while the proteins assume a final approximate double-belt configuration on a slower time
scale.