Critical minimum length of the central helix in troponin C for the Ca2+ switch in muscular contraction.

In the troponin C (TnC) dumbbell, the NH2- and COOH-terminal lobes are well delineated, but the role of the central helix and especially the function of its long length remain doubtful. To study this, we used a cDNA construct encoding rabbit fast-twitch muscle TnC, comprising multiple restriction sequences to facilitate mutagenesis (Babu, A., Su, H., Ryu, Y. by 12 deletions, the inhibition was complete. The critical minimum length for the central helix is thereby estimated as 27 A. The Ca2+ binding capacity (4 mol of Ca2+/mol of protein) as well as the structural characteristics (alpha-helicity by CD measurements and the fluorescence emitted by Tyr-109) indicated a well preserved global conformation of the short mutant. However, surprisingly, two of these short mutants filled each TnC slot under highly specific superloading conditions: one short molecule was taken up in EGTA solution, and the second molecule was captured and retained with Ca2+. They also rescued the contractile switch, evidently in a bimolecular reaction. Another short variant (putative skeletal fast muscle TnC-I-II), in which the NH2-terminal Ca(2+)-binding sites were incapacitated, failed to respond to superloading, indicating that sites III and IV could not substitute for sites I and II. The results suggest that a critical role of the central helix linker in TnC is to keep the two lobes optimally apart, evidently in proximity of their respective target sites on troponin I in the fiber.