posted on 2014-01-03, 00:00authored byGeorgi Z. Genchev, Tomoyoshi Kobayashi, Hui Lu
The interaction between calcium and the regulatory site(s) of striated muscle regulatory protein troponin switches on and
off muscle contraction. In skeletal troponin binding of calcium to sites I and II of the TnC subunit results in a set of structural
changes in the troponin complex, displaces tropomyosin along the actin filament and allows myosin-actin interaction to
produce mechanical force. In this study, we used molecular dynamics simulations to characterize the calcium dependent
dynamics of the fast skeletal troponin molecule and its TnC subunit in the calcium saturated and depleted states. We
focused on the N-lobe and on describing the atomic level events that take place subsequent to removal of the calcium ion
from the regulatory sites I and II. A main structural event - a closure of the A/B helix hydrophobic pocket results from the
integrated effect of the following conformational changes: the breakage of H-bond interactions between the backbone
nitrogen atoms of the residues at positions 2, 9 and sidechain oxygen atoms of the residue at position 12 (N2-OE12/N9-OE12)
in sites I and II; expansion of sites I and II and increased site II N-terminal end-segment flexibility; strengthening of the bsheet
scaffold; and the subsequent re-packing of the N-lobe hydrophobic residues. Additionally, the calcium release allows
the N-lobe to rotate relative to the rest of the Tn molecule. Based on the findings presented herein we propose a novel
model of skeletal thin filament regulation.
Funding
This work is supported by the National Science Foundation through XSEDE resources provided by TACC-Lonestar (TG-MCB090005), and R01HL082923
and T32HL007692 from the National Institutes of Health U.S.A.