Recombinant troponin I substitution and calcium responsiveness in skinned cardiac muscle

Abstract

Using treatment with vanadate solutions, we extracted native cardiac troponin I and troponin C (cTnI and cTnC) from skinned fibers of porcine right ventricles. These proteins were replaced by exogenously supplied TnI and TnC isoforms, thereby restoring Ca²⁺-dependent regulation. Force then depended on the negative logarithm of Ca²⁺ concentration (pCa) in a sigmoidal manner, the pCa for 50% force development, pCa₅₀, being about 5.5. For reconstitution we used fast-twitch rabbit skeletal muscle TnI and TnC (sTnI and sTnC), bovine cTnI and cTnC or recombinant sTnIs that were altered by site-directed mutagenesis. Incubation with TnI inhibited isometric tension in TnI-extracted fibers in the absence of Ca²⁺, but restoration of Ca²⁺ dependence required incubation with both TnI and TnC. Relaxation at low Ca²⁺ levels and the steepness of the force/pCa relation depended on the concentration of exogenously supplied TnI in the reconstitution solution (range 20-150 µM), while Ca²⁺ sensitivity, i.e. the pCa₅₀, was dependent on the isoform, and also on the concentration of TnC in the reconstitution solution. At pH 6.7, skinned fibers reconstituted with optimal concentrations of sTnC and sTnI (120 µM and 150 µM, respectively) were more sensitive to Ca²⁺ than those reconstituted with cTnC and cTnI (difference in pCa₅₀ approx. 0.2 units). Rabbit sTnI was cloned and expressed in Escherichia coli using a high yield expression plasmid. We introduced point mutations into the TnI inhibitory region comprising the sequence of the minimal common TnC/actin binding site (-G¹⁰⁴-K-F-K-R-P-P-L-R-R-V-R¹¹⁵-). The four mutants produced by substitution of T for P¹¹⁰, G for P¹¹⁰, G for L¹¹¹, and G for K¹⁰⁵ were chosen, based on previous work with synthetic peptides showing that single amino acid substitution in this region diminished the capacity of these peptides to inhibit acto-S₁ ATPase or contraction of skinned fibers. Therefore, all amino acid residues of the inhibitory region are thought to contribute to biological activity of TnI. However, each of the recombinant TnIs could substitute for endogenous TnI. In combination with exogenous TnC, Ca²⁺ dependence could be restored when ^gly110_sTnI, ^thr110sTnI or ^gly111s TnI was used for reconstitution. The mutant ^glyl05sTnI, on the other hand, reduced the ability of skinned fibers to relax at low Ca²⁺ concentrations and it caused an increase in Ca²⁺ sensitivity.