Abstract
Interactions between troponin C and troponin I play a critical role in the regulation of skeletal muscle contraction and relaxation. We individually substituted 27 hydrophobic Phe, Ile, Leu, Val, and Met residues in the regulatory domain of the fluorescent troponin C(F29W) with polar Gln to examine the effects of these mutations on: (a) the calcium binding and dynamics of troponin C(F29W) complexed with the regulatory fragment of troponin I (troponin I(96-148)) and (b) the calcium sensitivity of force production. Troponin I(96-148) was an accurate mimic of intact troponin I for measuring the calcium dynamics of the troponin C(F29W)-troponin I complexes. The calcium affinities of the troponin C(F29W)-troponin I(96-148) complexes varied approximately 243-fold, whereas the calcium association and dissociation rates varied approximately 38- and approximately 33-fold, respectively. Interestingly, the effect of the mutations on the calcium sensitivity of force development could be better predicted from the calcium affinities of the troponin C(F29W)-troponin I(96-148) complexes than from that of the isolated troponin C(F29W) mutants. Most of the mutations did not dramatically affect the affinity of calcium-saturated troponin C(F29W) for troponin I(96-148). However, the Phe(26) to Gln and Ile(62) to Gln mutations led to >10-fold lower affinity of calcium-saturated troponin C(F29W) for troponin I(96-148), causing a drastic reduction in force recovery, even though these troponin C(F29W) mutants still bound to the thin filaments. In conclusion, elucidating the determinants of calcium binding and exchange with troponin C in the presence of troponin I provides a deeper understanding of how troponin C controls signal transduction.
Highlights
Troponin C (TnC)1 regulates striated muscle contraction and relaxation through the binding and release of Ca2ϩ
We individually substituted 27 hydrophobic Phe, Ile, Leu, Val, and Met residues in the regulatory domain of the fluorescent troponin CF29W with polar Gln to examine the effects of these mutations on: (a) the calcium binding and dynamics of troponin CF29W complexed with the regulatory fragment of troponin I and (b) the calcium sensitivity of force production
The goal of the present study was to examine the effect of the hydrophobic mutations on the Ca2ϩ binding properties of the TnCF29W-TnI96–148 complex and on the affinity of TnCF29W for TnI96–148
Summary
Troponin C (TnC) regulates striated muscle contraction and relaxation through the binding and release of Ca2ϩ In part because of its high Ca2ϩ and Mg2ϩ affinities and slow Ca2ϩ exchange rates (as compared with the kinetics of muscle contraction and relaxation), the C-domain is thought to play a structural role in muscle function by anchoring TnC into the Tn complex. The Ca2ϩ exchange rates of the N-domain of TnC are rapid enough to be involved in the dynamic Ca2ϩ-dependent regulation of muscle mechanics Skeletal muscle contraction begins when cytoplasmic [Ca2ϩ] rises and binds to the N-terminal EF hands of TnC. One of the steps that may influence the rate of muscle relaxation is Ca2ϩ dissociation from the N-domain of TnC. The rate of Ca2ϩ dissociation from the Tn complex and not TnC alone may be the more meaningful rate when considering factors that control muscle relaxation kinetics
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