posted on 2016-05-04, 00:00authored byGlen M. Hocky, Joseph L. Baker, Michael
J. Bradley, Anton V. Sinitskiy, Enrique M. De La Cruz, Gregory A. Voth
Ions
regulate the assembly and mechanical properties of actin filaments.
Recent work using structural bioinformatics and site-specific mutagenesis
favors the existence of two discrete and specific divalent cation
binding sites on actin filaments, positioned in the long axis between
actin subunits. Cation binding at one site drives polymerization,
while the other modulates filament stiffness and plays a role in filament
severing by the regulatory protein, cofilin. Existing structural methods
have not been able to resolve filament-associated cations, and so
in this work we turn to molecular dynamics simulations to suggest
a candidate binding pocket geometry for each site and to elucidate
the mechanism by which occupancy of the “stiffness site”
affects filament mechanical properties. Incorporating a magnesium
ion in the “polymerization site” does not seem to require
any large-scale change to an actin subunit’s conformation.
Binding of a magnesium ion in the “stiffness site” adheres
the actin DNase-binding loop (D-loop) to its long-axis neighbor, which
increases the filament torsional stiffness and bending persistence
length. Our analysis shows that bound D-loops occupy a smaller region
of accessible conformational space. Cation occupancy buries key conserved
residues of the D-loop, restricting accessibility to regulatory proteins
and enzymes that target these amino acids.