Lawrence B. Smillie scite author profile

Regulation of contraction in skeletal muscle occurs through calcium binding to the protein troponin C. The solution structures of the regulatory domain of apo and calcium-loaded troponin C have been determined by multinuclear, multidimensional nuclear magnetic resonance techniques. The structural transition in the regulatory domain of troponin C on calcium binding involves an opening of the structure through large changes in interhelical angles. This leads to the increased exposure of an extensive hydrophobic patch, an event that triggers skeletal muscle contraction.

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Quantification of the calcium‐induced secondary structural changes in the regulatory domain of troponin‐C

Gagné

et al. 1994

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The backbone resonance assignments have been completed for the apo ('H and "N) and calcium-loaded ('H, IsN, and 13C) regulatory N-domain of chicken skeletal troponin-C (1-90), using multidimensional homonuclear and heteronuclear NMR spectroscopy. The chemical-shift information, along with detailed NOE analysis and 3JHNHa coupling constants, permitted the determination and quantification of the Ca2+-induced secondary structural change in the N-domain of TnC. For both structures, 5 helices and 2 short 0-strands were found, as was observed in the apo N-domain of the crystal structure of whole TnC (Herzberg 0, James MNG, 1988, JMol Biol 203:761-779). The NMR solution structure of the apo form is indistinguishable from the crystal structure, whereas some structural differences are evident when comparing the 2Ca2+ state solution structure with the apo one. The major conformational change observed is the straightening of helix-B upon Ca2+ binding. The possible importance and role of this conformational change is explored. Previous CD studies on the regulatory domain of TnC showed a significant Ca2+-induced increase in negative ellipticity, suggesting a significant increase in helical content upon Ca2+ binding. The present study shows that there is virtually no change in a-helical content associated with the transition from apo to the 2Ca2+ state of the N-domain of TnC. Therefore, the Ca2+-induced increase in ellipticity observed by CD does not relate to a change in helical content, but more likely to changes in spatial orientation of helices.Keywords: calcium; CD; NMR; regulatory domain of troponin-C; secondary structural change Troponin-C has a key role in muscle contraction of vertebrate striated muscle (skeletal and cardiac). The binding of Ca2+ to TnC induces a conformational change that affects the interaction between TnC, troponin-I (TnI), and troponin-T (TnT). This interaction blocks the inhibitory action of TnI, allowing formation of the Mg2+-activated ATPase actomyosin complex, and ultimately leads to muscle contraction. The roles and interactions of proteins in the regulatory system of striated muscle have been studied extensively (Leavis & Gergely, 1984; Ohtsuki et al.,

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Construction and characterization of a spectral probe mutant of troponin C: application to analyses of mutants with increased calcium affinity

Pearlstone¹,

Borgford²,

Chandra³

et al. 1992

Biochemistry

151

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A spectral probe mutant (F29W) of chicken skeletal muscle troponin C (TnC) has been prepared in which Phe-29 has been substituted by Trp. Residue 29 is at the COOH-terminal end of the A helix immediately adjacent to the Ca2+ binding loop of site I (residues 30-41) of the regulatory N domain. Since this protein is naturally devoid of Tyr and Trp, spectral features can be assigned unambiguously to the single Trp. The fluorescent quantum yield at 336 nm is increased almost 3-fold in going from the Ca(2+)-free state to the 4Ca2+ state with no change in the wavelength of maximum emission. Comparisons of the Ca2+ titration curves of the change in far-UV CD and fluorescence emission indicated that the latter was associated only with the binding of 2Ca2+ to the regulatory sites I and II. No change in fluorescence was detected by titration with Mg2+. The Ca(2+)-induced transitions of both the N and C domains were highly cooperative. Addition of Ca2+ also produced a red shift in the UV absorbance spectrum and a reduction in positive ellipticity as monitored by near-UV CD measurements. The fluorescent properties of F29W were applied to an investigation of five double mutants: F29W/V45T, F29W/M46Q, F29W/M48A, F29W/L49T, and F29W/M82Q. Ca2+ titration of their fluorescent emissions indicated in each case an increased Ca2+ affinity of their N domains. The magnitude of these changes and the decreased cooperativity observed between Ca2+ binding sites I and II for some of the mutants are discussed in terms of the environment of the mutated residues in the 2Ca2+ and modeled 4Ca2+ states.(ABSTRACT TRUNCATED AT 250 WORDS)

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