NH2-terminal truncation of skeletal muscle troponin T reduced its affinity for tropomyosin, but the small effect of Ca2+ on thin filament assembly energetics was not attributable to this region.
To investigate how Ca2+ binding to troponin C regulates muscle contraction, the Ca2+-sensitive properties of thin filament assembly were studied as the tropomyosin binding, NH2-terminal region of troponin T was progressively shortened. Troponin complexes were prepared that contained skeletal muscle troponin C, troponin I, and either intact troponin T (TnT) (residues 1-259) or fragment TnT-(70-259), TnT-(151-259), or TnT-(159-259). In the absence of Ca2+ their respective affinities for pyrene-labeled tropomyosin were 2.3 × 107M−1, 1.2 × 107M−1, 1.9 × 105M−1, and 1.9 × 105M−1. Ca2+ had only a small effect on these affinities: 1.1 × 107M−1 for whole troponin, 2 × 105M−1 for troponin-(151-259), and 2.8 × 105M−1 for troponin-(159-259). Forms of troponin that bound weakly to tropomyosin in the absence of actin increased the actin affinity of tropomyosin only 2-3-fold, even in the absence of Ca2+; weak binding of troponin to tropomyosin correlated with weak effects on tropomyosin-actin binding. In contrast, whole troponin had an approximately 500-fold effect on tropomyosin binding to actin, regardless of whether Ca2+ was present. The small effect of Ca2+ on the energetics of thin filament assembly is not attributable to the amino-terminal region of troponin T. The results suggest that Ca2+ causes the interaction between actin and the globular region of troponin to switch between two energetically similar states. To investigate how Ca2+ binding to troponin C regulates muscle contraction, the Ca2+-sensitive properties of thin filament assembly were studied as the tropomyosin binding, NH2-terminal region of troponin T was progressively shortened. Troponin complexes were prepared that contained skeletal muscle troponin C, troponin I, and either intact troponin T (TnT) (residues 1-259) or fragment TnT-(70-259), TnT-(151-259), or TnT-(159-259). In the absence of Ca2+ their respective affinities for pyrene-labeled tropomyosin were 2.3 × 107M−1, 1.2 × 107M−1, 1.9 × 105M−1, and 1.9 × 105M−1. Ca2+ had only a small effect on these affinities: 1.1 × 107M−1 for whole troponin, 2 × 105M−1 for troponin-(151-259), and 2.8 × 105M−1 for troponin-(159-259). Forms of troponin that bound weakly to tropomyosin in the absence of actin increased the actin affinity of tropomyosin only 2-3-fold, even in the absence of Ca2+; weak binding of troponin to tropomyosin correlated with weak effects on tropomyosin-actin binding. In contrast, whole troponin had an approximately 500-fold effect on tropomyosin binding to actin, regardless of whether Ca2+ was present. The small effect of Ca2+ on the energetics of thin filament assembly is not attributable to the amino-terminal region of troponin T. The results suggest that Ca2+ causes the interaction between actin and the globular region of troponin to switch between two energetically similar states.
Fisher et al. (Sun,) reported a other. NH2-terminal truncation of skeletal muscle troponin T vs. Intact troponin T was evaluated on Affinity for pyrene-labeled tropomyosin and actin. NH2-terminal truncation of skeletal muscle troponin T reduced its affinity for tropomyosin, but the small effect of Ca2+ on thin filament assembly energetics was not attributable to this region.