Cardiac troponin T R92L and R92W mutations independently altered the interaction between the Ca(2+) ion and cardiac troponin I subunit, revealing a novel allosteric mechanism for cardiomyopathy.
This study reveals a novel allosteric mechanism by which troponin T mutations alter calcium handling in the cardiac thin filament, providing atomic-level insights for targeted drug design in genetic cardiomyopathies.
Calcium binding and dissociation within the cardiac thin filament (CTF) is a fundamental regulator of normal contraction and relaxation. Although the disruption of this complex, allosterically mediated process has long been implicated in human disease, the precise atomic-level mechanisms remain opaque, greatly hampering the development of novel targeted therapies. To address this question, we used a fully atomistic CTF model to test both Ca(2+) binding strength and the energy required to remove Ca(2+) from the N-lobe binding site in WT and mutant troponin complexes that have been linked to genetic cardiomyopathies. This computational approach is combined with measurements of in vitro Ca(2+) dissociation rates in fully reconstituted WT and cardiac troponin T R92L and R92W thin filaments. These human disease mutations represent known substitutions at the same residue, reside at a significant distance from the calcium binding site in cardiac troponin C, and do not affect either the binding pocket affinity or EF-hand structure of the binding domain. Both have been shown to have significantly different effects on cardiac function in vivo. We now show that these mutations independently alter the interaction between the Ca(2+) ion and cardiac troponin I subunit. This interaction is a previously unidentified mechanism, in which mutations in one protein of a complex indirectly affect a third via structural and dynamic changes in a second to yield a pathogenic change in thin filament function that results in mutation-specific disease states. We can now provide atom-level insight that is potentially highly actionable in drug design.
Williams et al. (Tue,) conducted a other in Genetic cardiomyopathies. Cardiac troponin T R92L and R92W mutations vs. Wild-type (WT) troponin complexes was evaluated on Ca(2+) binding strength and dissociation rates. Cardiac troponin T R92L and R92W mutations independently altered the interaction between the Ca(2+) ion and cardiac troponin I subunit, revealing a novel allosteric mechanism for cardiomyopathy.