Residues 48 and 82 at the N-terminal hydrophobic pocket of rabbit skeletal muscle troponin-C photo-cross-link to Met121 of troponin-I.

It has been proposed [Herzberg et al. (1986) J. Biol. Chem. 261, 2638-2644], and confirmed by structural studies [Gagne et al. (1995) Nat. Struct. Biol. 2, 784-789], that the binding of Ca2+ to the triggering sites in troponin-C (TnC) causes the opening of the N-terminal hydrophobic pocket bound by the B, C, and D helices. This conformational change is believed to provide an additional binding site for troponin-I (TnI) and to lead to further events in the Ca2+ regulation process. To answer the question of which part of TnI interacts with this hydrophobic patch of TnC, we constructed two TnC mutants, each with a single cysteine, one at residue 48 between helices B and C and the other at residue 82 on the D helix. Each mutant was labeled with the photoactivatable cross-linker benzophenone-4-iodoacetamide, followed by reconstitution and UV irradiation. Studies were made in the binary complex composed of TnC and TnI, the ternary complex composed of TnC, TnI, and troponin-T (TnT), and the synthetic thin filament composed of troponin, tropomyosin, and F-actin. TnC-TnI photo-cross-linking was observed for both mutants and for all three types of complexes. Although no Ca2+ dependence in the photo-cross-linking was observed on the binary and ternary complexes, the extent of cross-linking was reduced in the absence vs the presence of Ca2+ in the thin filament. TnI Met121, five residues from the C-terminus of the inhibitory region, was identified as the cross-linking site for both TnC mutants using microsequencing and mass spectrometry following proteolysis. These results, obtained with intact TnC.TnI complexes, indicate that the TnI segment containing Met121 is in close contact with the N-terminal hydrophobic patch of TnC, and that in the thin filament the segment containing this residue moves away slightly from the hydrophobic patch in the absence of Ca2+, possibly triggering the translocation of the actin-binding region(s) of TnI toward actin.     

Ca(2+)-dependence of structural changes in troponin-C in demembranated fibers of rabbit psoas muscle.

The Ca(2+)-dependence of structural changes in troponin-C (TnC) has been detected by monitoring the fluorescence from TnC labeled at Methionine-25, in the NH2-terminal domain, with danzylaziridine (TnC-DANZ) and then exchanged for endogenous TnC in glycerinated single fibers. The fluorescence-pCa relation obtained from fibers stretched to a sarcomere length greater than 4.0 microns evidenced two transitions: a small one, attributable to the binding of Ca2+ to the high affinity, Ca(2+)-Mg(2+)-binding sites of TnC; and a large one, attributable to the binding of Ca2+ to the low affinity, Ca(2+)-specific binding sites of TnC. In the fluorescence-pCa relation determined with fibers set to a sarcomere length of 2.4 microns, hence obtained in the presence of cycling cross-bridges, the large transition had the same Ca(2+)-dependence as did the development of tension. These results indicate that the NH2-terminal globular domain of TnC is modified by the binding of Ca2+ to sites located in both globular domains and that the structural changes in TnC resulting from the binding of Ca2+ to the low-affinity sites, but not to the high-affinity sites, are directly associated with the triggering of contraction.     

Localization of Cys133 of rabbit skeletal troponin-I with respect to troponin-C by resonance energy transfer.

We have used the technique of resonance energy transfer in conjunction with distance geometry analysis to localize Cys133 of troponin-I (TnI) with respect to troponin-C (TnC) in the ternary troponin complex and the binary TnC.TnI complex in the presence and absence of Ca2+. Cys133 of TnI was chosen because our previous work has shown that the region of TnI containing this residue undergoes Ca2+-dependent movements between actin and TnC, and may play an important role in the regulatory function of troponin. For this purpose, a TnI mutant with a single Cys at position 133, and TnC mutants, each with a single Cys at positions 5, 12, 21, 41, 49, 89, 98, 133, and 158, were constructed by site-directed mutagenesis. The distances between TnI Cys133 and each of the nine residues in TnC were then measured. Using a least-squares minimization procedure, we determined the position of TnI Cys133 in the coordinate system of the crystal structure of TnC. Our results show that in the presence of Ca2+, TnI Cys133 is located near residue 12 beneath the N-terminal lobe of TnC, and moves away by 12.6 A upon the removal of Ca2+. TnI Cys133 and the region of TnC that undergoes major change in conformation in response to Ca2+ are located roughly on opposite sides of TnC's central helix. This suggests that the region in TnI that undergoes Ca2+-dependent interaction with TnC is distinct from that interacting with actin.     

Binding of cardiac troponin-I147-163 induces a structural opening in human cardiac troponin-C.

The interaction of troponin-C (TnC) with troponin-I (TnI) plays a central role in skeletal and cardiac muscle contraction. We have recently shown that the binding of Ca2+ to cardiac TnC (cTnC) does not induce an "opening" of the regulatory domain in order to interact with cTnI [Sia, S. K., et al. (1997) J. Biol. Chem. 272, 18216-18221; Spyracopoulos et al. (1997) Biochemistry 36, 12138-12146], which is in contrast to the regulatory N-domain of skeletal TnC (sTnC). This implies that the mode of interaction between cTnC and cTnI may be different than that between sTnC and sTnI. In sTnI, a region downstream from the inhibitory region (residues 115-131) has been shown to bind the exposed hydrophobic pocket of Ca2+-saturated sNTnC [McKay, R. T., et al. (1997) J. Biol. Chem. 272, 28494-28500]. The present study demonstrates that the corresponding region in cTnI (residues 147-163) binds to the regulatory domain of cTnC only in the Ca2+-saturated state to form a 1:1 complex, with an affinity approximately six times weaker than that between the skeletal counterparts. Thus, while Ca2+ does not cause opening, it is required for muscle regulation. The solution structure of the cNTnC.Ca2+.cTnI147-163 complex has been determined by multinuclear multidimensional NMR spectroscopy. The structure reveals an open conformation for cNTnC, similar to that of Ca2+-saturated sNTnC. The bound peptide adopts a alpha-helical conformation spanning residues 150-157. The C-terminus of the peptide is unstructured. The open conformation for Ca2+-saturated cNTnC in the presence of cTnI (residues 147-163) accommodates hydrophobic interactions between side chains of the peptide and side chains at the interface of A and B helices of cNTnC. Thus the mechanistic differences between the regulation of cardiac and skeletal muscle contraction can be understood in terms of different thermodynamics and kinetics equilibria between essentially the same structure states.     

A model of troponin-I in complex with troponin-C using hybrid experimental data: the inhibitory region is a beta-hairpin

We present a model for the skeletal muscle troponin-C (TnC)/troponin-I (TnI) interaction, a critical molecular switch that is responsible for calcium-dependent regulation of the contractile mechanism. Despite concerted efforts by multiple groups for more than a decade, attempts to crystallize troponin-C in complex with troponin-I, or in the ternary troponin-complex, have not yet delivered a high-resolution structure. Many groups have pursued different experimental strategies, such as X-ray crystallography, NMR, small-angle scattering, chemical cross-linking, and fluorescent resonance energy transfer (FRET) to gain insights into the nature of the TnC/TnI interaction. We have integrated the results of these experiments to develop a model of the TnC/TnI interaction, using an atomic model of TnC as a scaffold. The TnI sequence was fit to each of two alternate neutron scattering envelopes: one that winds about TnC in a left-handed sense (Model L), and another that winds about TnC in a right-handed sense (Model R). Information from crystallography and NMR experiments was used to define segments of the models. Tests show that both models are consistent with available cross-linking and FRET data. The inhibitory region TnI(95-114) is modeled as a flexible beta-hairpin, and in both models it is localized to the same region on the central helix of TnC. The sequence of the inhibitory region is similar to that of a beta-hairpin region of the actin-binding protein profilin. This similarity supports our model and suggests the possibility of using an available profilin/actin crystal structure to model the TnI/actin interaction. We propose that the beta-hairpin is an important structural motif that communicates the Ca2+-activated troponin regulatory signal to actin.     

Kinetics of Ca2+ release shows interactions between the two classes of sites of troponin-C

The kinetics of Ca2+-release from the two high affinity sites of troponin-C (TnC) was studied by the stopped flow technique following rapid mixing with either EDTA or excess TbCl3. The rate constants obtained by the two methods were 2.8 and 0.7 s-1, respectively. For the tryptic fragment of TnC that contains only the COOH-terminal half of the molecule, both methods generate rate constants of 2.2 s-1. These results are consistent with the interpretation that binding of Tb3+ to the Ca2+-specific sites reduces the rate of dissociation of Ca2+ from, and thereby enhances the affinity for, the Ca2+-Mg2+ sites; this, in turn, suggests interactions between the two halves of the TnC molecule.     

Comparative studies on the functional roles of N- and C-terminal regions of molluskan and vertebrate troponin-I

Vertebrate troponin regulates muscle contraction through alternative binding of the C-terminal region of the inhibitory subunit, troponin-I (TnI), to actin or troponin-C (TnC) in a Ca(2+)-dependent manner. To elucidate the molecular mechanisms of this regulation by molluskan troponin, we compared the functional properties of the recombinant fragments of Akazara scallop TnI and rabbit fast skeletal TnI. The C-terminal fragment of Akazara scallop TnI (ATnI(232-292)), which contains the inhibitory region (residues 104-115 of rabbit TnI) and the regulatory TnC-binding site (residues 116-131), bound actin-tropomyosin and inhibited actomyosin-tropomyosin Mg-ATPase. However, it did not interact with TnC, even in the presence of Ca(2+). These results indicated that the mechanism involved in the alternative binding of this region was not observed in molluskan troponin. On the other hand, ATnI(130-252), which contains the structural TnC-binding site (residues 1-30 of rabbit TnI) and the inhibitory region, bound strongly to both actin and TnC. Moreover, the ternary complex consisting of this fragment, troponin-T, and TnC activated the ATPase in a Ca(2+)-dependent manner almost as effectively as intact Akazara scallop troponin. Therefore, Akazara scallop troponin regulates the contraction through the activating mechanisms that involve the region spanning from the structural TnC-binding site to the inhibitory region of TnI. Together with the observation that corresponding rabbit TnI-fragment (RTnI(1-116)) shows similar activating effects, these findings suggest the importance of the TnI N-terminal region not only for maintaining the structural integrity of troponin complex but also for Ca(2+)-dependent activation.     

Cross-linking between the regulatory regions of troponin-I and troponin-C abolishes the inhibitory function of troponin

We reported previously that both residues 48 and 82 on opposite sides of troponin-C's (TnC's) N-terminal regulatory hydrophobic cleft photo-cross-linked to Met121 of troponin-I (TnI) [Luo, Y., Leszyk, J., Qian, Y., Gergely, J., and Tao, T. (1999) Biochemistry 38, 6678-6688]. Here we report that the Ca2+-absent inhibitory activity of troponin (Tn) was progressively lost as the extent of photo-cross-linking increased. To extend these studies, we constructed a mutant TnI with a single cysteine at residue 121 (TnI121). In Tn complexes containing TnI121 and mutant TnCs with a single cysteine at positions 12, 48, 82, 98, or 125 (TnC12, TnC48 etc.), TnI121 formed disulfide cross-links primarily with TnC48 and TnC82 when Ca2+ was present, and with only TnC48 when Ca2+ was absent. These results indicate that TnI Met121 is situated within the N-domain hydrophobic cleft of TnC in the presence of Ca2+, and that it moves out of the cleft upon Ca2+ removal but remains within the vicinity of TnC. Activity assays revealed that the Met121 to Cys mutation in TnI121 reduced the Ca2+-present activation of Tn, indicating that Met121 is important in hydrophobic interactions between this TnI region and TnC's N-domain cleft. The formation of a disulfide cross-link between TnI121 and TnC48 or TnC82 abolished the Ca2+-absent inhibitory activity of Tn, indicating that the movement of the Met121 region of TnI out of TnC's N-domain cleft is essential for the occurrence of further events in the inhibitory process of skeletal muscle contraction. On the basis of these and other results, a simple mechanism for Ca2+ regulation of skeletal muscle contraction is presented and discussed.     

Proximity relationships between residue 117 of rabbit skeletal troponin-I and residues in troponin-C and actin.

We used resonance energy transfer and site-directed photo-cross-linking to probe the Ca(2+)-dependent proximity relationships between residue 117 next to the C-terminus of the inhibitory region in rabbit skeletal troponin-I (TnI) and residues in troponin-C (TnC) and in actin. A mutant TnI that contains a single cysteine at position 117 (I117) was constructed, and the distance between TnI residue 117 and TnC residue 98 was measured with the following results: for both the binary TnC-TnI complex and the ternary troponin complex, this distance was 30 and 41 A in the presence and absence of Ca(2+), respectively. The distance between TnI residue 117 and Cys374 of actin was 48 and 41 A in the presence and absence of Ca(2+), respectively. Six additional distances from this TnI residue to cysteines in TnC mutants were measured and used to localize this residue with respect to the crystal structure of TnC. The results show that in the presence of Ca(2+) it is localized near the B and C helices of TnC's N-terminal domain. In the absence of Ca(2+) this residue moves away from this location by approximately 8 A. Photo-cross-linking experiments show that I117 labeled with 4-maleimidobenzophenone photo-cross-linked to TnC but not to actin in both the presence and absence of Ca(2+). Taken together these results provide independent experimental support for the proposal (Y. Luo, J. L. Wu, B. Li, K. Langsetmo, J. Gergely, and T. Tao, 2000, J. Mol. Biol. 296:899-910) that upon Ca(2+) removal the region comprising TnI residues 114-125 triggers the movements of residues 89-113 and 130-150 toward actin, but does not itself interact with actin.     

Defining the region of troponin-I that binds to troponin-C

The kinetics and energetics of the binding of three troponin-I peptides, corresponding to regions 96-131 (TnI96-131), 96-139 (TnI96-139), and 96-148 (TnI96-148), to skeletal chicken troponin-C were investigated using multinuclear, multidimensional NMR spectroscopy. The kinetic off-rate and dissociation constants for TnI96-131 (400 s-1, 32 microM), TnI96-139 (65 s-1, <1 microM), and TnI96-148 (45 s-1, <1 microM) binding to TnC were determined from simulation and analysis of the behavior of 1H,15N-heteronuclear single quantum correlation NMR spectra taken during titrations of TnC with these peptides. Two-dimensional 15N-edited TOCSY and NOESY spectroscopy were used to identify 11 C-terminal residues from the 15N-labeled TnI96-148 that were unperturbed by TnC binding. TnI96-139 labeled with 13C at four positions (Leu102, Leu111, Met 121, and Met134) was complexed with TnC and revealed single bound species for Leu102 and Leu111 but multiple bound species for Met121 and Met134. These results indicate that residues 97-136 (and 96 or 137) of TnI are involved in binding to the two domains of troponin-C under calcium saturating conditions, and that the interaction with the regulatory domain is complex. Implications of these results in the context of various models of muscle regulation are discussed.     

Salt-induced conformational changes in skeletal myosin light chains, troponin-C, and parvalbumin

Evidence for salt-induced changes in myosin light chains [dissociated by treatment with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB)], troponin-C (TnC), and parvalbumin was obtained from chymotryptic digestion, circular dichroism, fluorescence, and difference absorption studies. High salt (0.6 M NaCl) protects the DTNB light chain from proteolysis, increases its alpha-helical content, and quenches the tryptophan fluorescence. These effects are similar to the changes induced by Ca2+ but smaller in magnitude. TnC is affected by monovalent cations in a similar manner. Changes in the alpha-helical content resemble the effect of Ca2+. The enhancement of tyrosine fluorescence reflects conformational changes in the Ca2+-Mg2+ binding sites. The increase in the fluorescence of dansylaziridine-labeled TnC suggests perturbation of Ca2+-specific sites by salt. Cancellation of this effect by Mg2+ binding to the high-affinity sites is indicative of site-site interactions. In Whiting parvalbumin, salt-induced a perturbation of tryptophan absorption similar in nature to the Ca2+ effect.     

Study of the structure of troponin-I by measuring the relative reactivities of lysines with acetic anhydride

A competitive labeling method that measures the relative reactivity of lysines was used to study the structure of troponin-I. Troponin-I was acetylated free and complexed with troponin-C and troponin-T in the native state with [3H]acetic anhydride. The [3H]troponin-I was combined with [14C]troponin-I that had been acetylated in 6 M guanidine HCl and completely chemically labeled. Peptides containing labeled lysines were isolated following digestion with trypsin and Staphylococcus aureus protease and identified in the published sequence. The 3H/14C ratio of these peptides was used as a measure of the relative reactivity of the lysines. Troponin-I contains 24 lysines; we have identified 23 of these in 16 peptides. When troponin-I is labeled in a native complex, the lysines in the region from residues 40 to 98 are influenced: five become relatively less reactive (40, 65, 70, 78, and 90) and three become relatively more reactive (84, 87), and 98). All of these changes except Lys 70 can be seen when troponin-I binds to troponin-T. Lys 70 is reduced in reactivity when it binds to troponin-C. The lysines that appear to be important in binding of troponin-I to troponin-T are influenced by the binding of Ca2+ to troponin-C in the native troponin complex (in the presence of 2 mM MgCl2), suggesting for the first time that the troponin-IT interaction is affected by Ca2+.     

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

The backbone resonance assignments have been completed for the apo (1H and 15N) and calcium-loaded (1H, 15N, 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 3JHNH alpha coupling constants, permitted the determination and quantification of the Ca(2+)-induced secondary structural change in the N-domain of TnC. For both structures, 5 helices and 2 short beta-strands were found, as was observed in the apo N-domain of the crystal structure of whole TnC (Herzberg O, James MNG, 1988, J Mol 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 Ca(2+)-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 alpha-helical content associated with the transition from apo to the 2Ca2+ state of the N-domain of TnC. Therefore, the Ca(2+)-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.     

Calcium binding to the low affinity sites in troponin C induces conformational changes in the high affinity domain. A possible route of information transfer in activation of muscle contraction

Residues 89-100 of troponin C (C89-100) and 96-116 of troponin I (I96-116) interact with each other in the troponin complex (Dalgarno, D.C., Grand, R.J.A., Levine, B.A. Moir, A., J.G., Scott, G.M.M., and Perry, S.V. (1982) FEBS Lett. 150, 54-58) and are necessary for the Ca2+ sensitivity of actomyosin ATPase (Syska, H., Wilkinson, J.M., Grand, R.J.A., and Perry, S.V. (1976) Biochem. J. 153, 375-387 and Grabarek, Z., Drabikowski, W., Leavis, P.C., Rosenfeld, S.S., and Gergely, J. (1981) J. Biol. Chem. 256, 13121-13127). We have studied Ca2+-induced changes in the region C89-100 by monitoring the fluorescence of troponin C (TnC) labeled at Cys-98 with 5-(iodoacetamidoethyl)aminonaphthalene-1-sulfonic acid. Equilibrium titration of the labeled TnC with Ca2+ indicates that the probe is sensitive to binding to both classes of sites in free TnC as well as in its complex with TnI. When Mg2 X TnC is mixed with Ca2+ in a stopped flow apparatus, there is a rapid fluorescence increase related to Ca2+ binding to the unoccupied sites I and II followed by a slower increase (k = 9.9 s-1) that represents Mg2+-Ca2+ exchange at sites III and IV. In the TnC X TnI complex, the fast phase is much larger and the Mg2+-Ca2+ exchange at sites III and IV results in a small decrease rather than an increase in the fluorescence of the probe. The possibility is discussed that the fast change in the environment of Cys-98 upon Ca2+ binding to sites I and II may be instrumental in triggering activation of the thin filament by facilitating a contact between C89-100 and I96-116.     

A disulfide crosslink between Cys98 of troponin-C and Cys133 of troponin-I abolishes the activity of rabbit skeletal troponin.

Various thio-reactive bifunctional crosslinkers as well as 5,5'-dithiobis(2-nitrobenzoate)-mediated disulfide bond formation were used to crosslink troponin-C and troponin-I, the Ca(2+)-binding and inhibitory subunits of troponin, respectively. In all cases, substantial crosslinking was obtained when the reactions were carried out in the absence of Ca2+. No disulfide crosslinking occurred if either Cys98 of TnC, or Cys133 of TnI were blocked, indicating that these thiols are involved in the crosslinking. Troponin containing the disulfide crosslink is no longer capable of regulating actomyosin ATPase activity in a Ca(2+)-dependent manner. Our results suggest that the relative movement between the Cys98 region of TnC and the Cys133 region of TnI is required for the Ca(2+)-regulatory process in skeletal muscle.     

Cross-linking of residue 57 in the regulatory domain of a mutant rabbit skeletal muscle troponin C to the inhibitory region of troponin I

Interactions between troponin C (TnC) and troponin I (TnI) play an important role in the Ca(2+)-dependent regulation of vertebrate striated muscle contraction. In the present study, we investigated the sites of interaction between the N-terminal regulatory domain of TnC and the inhibitory region (residues 96-116) of TnI, using a mutant rabbit skeletal TnC (designated as TnC57) that contains a single Cys at residue 57 in the C-helix. TnC57 was modified with the photoreactive cross-linker 4-maleimidobenzophenone (BP-Mal), and, after formation of a binary complex with TnI, cross-linking between the proteins was induced by photolysis. The resulting product was cleaved with CNBr and several proteases, and peptides containing cross-links were purified and subjected to amino acid sequencing. The results show that Cys-57 of TnC57 is cross-linked to the segment of TnI spanning residues 113-121. Previously, we showed that Cys-98 of TnC can be cross-linked via BP-Mal to TnI residues 103-110 (Leszyk, J., Collins, J.H., Leavis, P.C., and Tao, T. (1987) Biochemistry 26, 7042-7047). Taken together, these results demonstrate that both the C- and the N-terminal domains of TnC interact with the inhibitory region of TnI and are consistent with the hypothesis that, in a complex with TnI, TnC adopts a more compact conformation than in the crystal structure.     

Isolation, expression, and mutation of a rabbit skeletal muscle cDNA clone for troponin I. The role of the NH2 terminus of fast skeletal muscle troponin I in its biological activity.

A cDNA for rabbit fast skeletal muscle troponin I (TnI) was isolated and sequenced. The clone contains a coding sequence predicting a 182-amino-acid protein with a molecular mass of 21,162 daltons. The translated sequence is different from that reported by Wilkinson and Grand (Wilkinson, J. M., and Grand, R. J. A. (1978) Nature 271, 31-35) in that Arg-153, Asp-154, and Leu-155 must be inserted into their original sequence. Amino acid sequencing of adult rabbit TnI confirmed this result. In order to investigate the role of the NH2 terminus of TnI in its biological activity, we have expressed a recombinant deletion mutant (TnId57), which lacks residues 1-57, in a bacterial expression system. Both wild type TnI (WTnI) and TnId57 inhibited acto-S1-ATPase activity and this inhibition could be fully reversed by troponin C (TnC) in the presence of Ca2+. Additionally both WTnI and TnId57 bound to an actin affinity column. Thus, both inhibitory actin binding and Ca(2+)-dependent neutralization by TnC were retained in TnId57. TnC affinity chromatography was used to compare the binding of TnI and TnId57 to TnC. Using this method, two types of interaction between TnC and TnI were observed: 1) one which is metal independent (or structural) and 2) one dependent on Ca2+ or Mg2+ binding to the Ca(2+)-Mg2+ sites of TnC. The same experiments with TnId57 demonstrated that the type 1 interaction was weakened, and type 2 binding was lost. This method also revealed an interaction between TnC and TnI which is dependent upon Ca2+ binding to the Ca(2+)-specific sites of TnC and which is retained in TnId57. Taken together, these results suggest that the NH2 terminus of TnI may constitute a Ca(2+)-Mg(2+)-dependent interaction site between TnC and TnI and play, in part, a structural role in maintaining the stability of the troponin complex while the COOH terminus of TnI contains a Ca(2+)-specific site-dependent interaction site for TnC as well as the previously demonstrated Ca(2+)-sensitive inhibitory and actin binding activities.     

Function of the N-terminal calcium-binding sites in cardiac/slow troponin C assessed in fast skeletal muscle fibers

Fast skeletal troponin C (sTnC) has two low affinity Ca(2+)-binding sites (sites I and II), whereas in cardiac troponin C (cTnC) site I is inactive. By modifying the Ca2+ binding properties of sites I and II in cTnC it was demonstrated that binding of Ca2+ to an activated site I alone is not sufficient for triggering contraction in slow skeletal muscle fibers (Sweeney, H.L., Brito, R. M.M., Rosevear, P.R., and Putkey, J.A. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 9538-9542). However, a similar study using sTnC showed that Ca2+ binding to site I alone could partially activate force production in fast skeletal muscle fibers (Sheng, Z., Strauss, W.L., Francois, J.M., and Potter, J.D. (1990) J. Biol. Chem. 265, 21554-21560). The purpose of the current study was to examine the functional characteristics of modified cTnC derivatives in fast skeletal muscle fibers to assess whether or not either low affinity site can mediate force production when coupled to fast skeletal isoforms of troponin (Tn) I and TnT. Normal cTnC and sTnC were compared with engineered derivatives of cTnC having either both sites I and II active, or only site I active. In contrast to what is seen in slow muscle, binding of Ca2+ to site I alone recovered about 15-20% of the normal calcium-activated force and ATPase activity in skinned fast skeletal muscle fibers and myofibrils, respectively. This is most likely due to structural differences between TnI and/or TnT isoforms that allow for partial recognition and translation of the signal represented by binding Ca2+ to site I of TnC when associated with fast skeletal but not slow skeletal muscle.     

Biological cross-reactivity of rat testis phosphodiesterase activator protein and rabbit skeletal muscle troponin-C.

Phosphodiesterase activator protein and troponin-C have been purified from rat testis and rabbit skeletal muscle, respectively. The two proteins appear to be structurally distinct since the activator protein migrates faster than troponin-C on sodium dodecyl sulfate-polyacrylamide gels. Each of the calcium-binding proteins will, however, substitute for the other in their respective biological systems. Testis activator protein forms a complex with rabbit muscle troponin subunits TnI and TnT soluble in low salt. This hybrid complex (AIT) can regulate rabbit skeletal muscle actomyosin ATPase activity. AIT regulation, although influenced by free Aa2+ levels, is distinct from that of native troponin. Likewise, muscle troponin-C can substitute for activator protein in the stimulation of cyclic nucleotide phosphodiesterase. Troponin-C will fully stimulate phosphodiesterase although its affinity is 600-fold lower than that of activator protein. Ca2+ regulation studies demonstrate that both proteins require micormolar levels of free Ca2+ to induce phosphodiesterase activation. Activator protein requires 1.2 x 10(6) M and troponin-C, 1.9 X 10(6) M free Ca2+ for half-maximal stimulation of phosphodiesterase. The biological cross-reactivity of these proteins supports the sequence homology recently reported by Watterson et al. (Watterson, D.M., Harrelson, W.G., Keller, P.M., Sharief, F., and Vanaman, T.C. (1976) J.Biol. Chem. 251, 4501-4513). In addition, this preliminary study suggests that this nonmuscle troponin-C-like protein potentially may function in other Ca2+-regulated cellular events in addition to its moculation of cyclic nucleotide levels.     

Proton magnetic resonance studies on peptide fragments of troponin-C containing single calcium-binding sites

Proton magnetic resonance spectroscopy has been employed to study the solution conformation of three cleavage fragments of troponin-C, each containing a single Ca(II)-binding site and corresponding to different regions in the primary sequence; viz. CB8 (residues 46–77), CB9 (residues 85–134) and TH2 (residues 121–159). Although all three peptides lack a well-defined tertiary fold in the absence of metal ions, several spectral features indicate the presence of local conformational constraints in each apopeptide. Ca(II) binding led to spectral changes consistent with increased restriction of backbone motility and the adoption of a more compact conformation. Studies using paramagnetic ions as conformational probes support current views concerning the nature of the ligands at the metal binding sites.The nature and kinetics of the structural influence of metal binding suggest that the conformational constraints existing in the CB8 apo-peptide provide an adequate Ca(II)-binding configuration. In contrast, the CB9 and TH2 peptides exhibit spectral changes consistent with an increased local structure in the region of helix E (residues 94–102) in the case of CB9 and helix H (residues 148–159) in the case of TH2. In CB9, conformation changes also appear to be transmitted to a portion of the sequence (residues 87–93) preceding helix E, a putative site of interaction between troponin-C and troponin-I. These data are discussed with reference to the contribution of long-range (interdomain) interactions within troponin-C and the modulation of troponin subunit protein-protein interactions by Ca(II) binding.