FHC mutations (Arg92Leu and Arg92Trp) in cardiac Troponin T resulted in an opening of the helix between residues 105-110 in molecular dynamics simulations compared to wild type.
Computational modeling reveals that FHC-causing mutations in cardiac Troponin T alter protein dynamics by causing localized helical compaction and distant expansion, providing structural insights into the disease mechanism.
Cardiac Troponin T (cTnT) is a central modulator of thin filament regulation of myofilament activation. The lack of structural data for the TNT1 tail domain, a proposed α-helical region, makes the functional implications of the FHC mutations difficult to determine. Studies have suggested that flexibility of TNT1 is important in normal protein-protein interactions within the thin filament. Our groups have previously shown through Molecular Dynamics (MD) simulations that some FHC mutations, Arg92Leu(R92L) and Arg92Trp(R92W), result in increased flexibility at a critical hinge region 12 residues distant from the mutation. To explain this distant effect and its implications for FHC mutations, we characterized the dynamics of wild type and mutational segments of cTnT using MD. Our data shows an opening of the helix between residues 105-110 in mutants. Consequently, the dihedral angles of these residues correspond to non-α-helical regions on Ramachandran plots. We hypothesize the removal of a charged residue decreases electrostatic repulsion between the point mutation and surrounding residues resulting in local helical compaction. Constrained ends of the helix and localized compaction results in expansion within the nearest non-polar helical turn from the mutation site, residues 105-109.
Guinto et al. (Sat,) conducted a other in Familial Hypertrophic Cardiomyopathy. FHC mutations (Arg92Leu and Arg92Trp) in cTnT vs. Wild type cTnT was evaluated on Dynamics and structural changes of cTnT segments. FHC mutations (Arg92Leu and Arg92Trp) in cardiac Troponin T resulted in an opening of the helix between residues 105-110 in molecular dynamics simulations compared to wild type.