Mutations disrupting the highly conserved heptad repeat motif in Troponin T severely reduced or abolished its binding to Troponin I without affecting Troponin C binding.
Evolutionarily conserved heptad repeat motifs in troponin T are essential for its interaction and dimerization with troponin I, likely through the formation of alpha-helical coiled coils.
Troponin T (TnT), a thin filament myofibrillar protein, is essential for the Ca2+ regulation of striated muscle contraction in vertebrates, both in vivo and in vitro. To understand the role of TnT in this process, its interaction with two other troponin components, troponin I (TnI) and troponin C (TnC) was examined by using the yeast two hybrid system, which is a genetic approach to detect protein-protein interactions. Computer assisted analysis of phylogenetically distant TnT amino acid sequences unveiled a highly conserved protein domain that is characterized by a heptad repeat (HR) motif with a potential for alpha-helical coiled coil formation. A similar, potentially coiled coil forming domain is also conserved in all known TnI sequences. These protein motifs appeared to be the regions where TnI-TnT interaction may take place. Deletions and point mutations in TnT, which disrupted its HR motif, severely reduced or abolished TnI binding, but binding to TnC was not affected, indicating that the TnT-TnI and TnT-TnC binary interactions can be uncoupled. Remarkably, the truncated fragments of TnT and TnI in which the HR motifs were retained showed binary interaction in the yeast two hybrid system. It was also observed that the formation of the TnT-TnI heterodimers is favored over the homodimers TnT-TnT and TnI-TnI. These results indicate that the evolutionarily conserved HR motifs may play a role in TnT-TnI dimerization, presumably through the formation of alpha-helical coiled coils.
Stefancsik et al. (Tue,) reported a other. Troponin T mutagenesis (heptad repeat domain) vs. Wild-type Troponin T was evaluated on Troponin I binding (measured by yeast two-hybrid reporter gene activation). Mutations disrupting the highly conserved heptad repeat motif in Troponin T severely reduced or abolished its binding to Troponin I without affecting Troponin C binding.