Interaction of troponin C and troponin C fragments with troponin I and the troponin I inhibitory peptide.

We have quantitated the interactions of two rabbit skeletal troponin C fragments with troponin I and the troponin I inhibitory peptide. The calcium binding properties of the fragments and the ability of the fragments to exert control in the regulated actomyosin ATPase assay have also been studied. The N- and C-terminal divalent metal binding domains of rabbit skeletal troponin C, residues 1-97 and residues 98-159, respectively, were prepared by specific cleavage at cysteine-98 and separation by gel exclusion chromatography. Both of the troponin C fragments bind calcium. The calcium affinity of the weak sites within the N-terminal fragment is about an order of magnitude greater than is reported for these sites in troponin C, suggesting interaction between the calcium-saturated strong sites and the weak sites. Stoichiometric binding (1:1) of the troponin I inhibitory peptide to each fragment and to troponin C increased the calcium affinities of the fragments and troponin C. Complex formation was detected by fluorescence quenching or enhancement using dansyl-labeled troponin C (and fragments) or tryptophan-labeled troponin I inhibitory peptide. The troponin C fragments bind to troponin I with 1:1 stoichiometry and approximately equal affinities (1.6 x 10(6) M-1) which are decreased 4-fold in the presence of magnesium versus calcium. These calcium effects are much smaller than is observed for troponin C. The summed free energies for the binding of the troponin C fragments to troponin I are much larger than the free energy of binding troponin C. This suggests a large positive interaction free energy for troponin C binding to troponin I relative to the fragments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of troponin I and troponin C: 19F NMR studies of the binding of the inhibitory troponin I peptide to turkey skeletal troponin C.

We have used 19F nuclear magnetic resonance spectroscopy to study the interaction of the inhibitory region of troponin (TnI) with apo- and calcium(II)-saturated turkey skeletal troponin C (TnC), using the synthetic TnI analogue N alpha-acetyl[19FPhe106]TnI(104-115)amide. Dissociation constants of Kd = (3.7 +/- 3.1) x 10(-5) M for the apo interaction and Kd = (4.8 +/- 1.8) x 10(-5) M for the calcium(II)-saturated interaction were obtained using a 1:1 binding model of peptide to protein. The 19F NMR chemical shifts for the F-phenylalanine of the bound peptide are different from the apo- and calcium-saturated protein, indicating a different environment for the bound peptide. The possibility of 2:1 binding of the peptide to Ca(II)-saturated TnC was tested by calculating the fit of the experimental titration data to a series of theoretical binding curves in which the dissociation constants for the two hypothetical binding sites were varied. We obtained the best fit for 0.056 mM less than or equal to Kd1 less than or equal to 0.071 mM and 0.5 mM less than or equal to Kd2 less than or equal to 2.0 mM. These results allow the possibility of a second peptide binding site on calcium(II)-saturated TnC with an affinity 10- to 20-fold weaker than that of the first site.     

Proximity relationship in the binary complex formed between troponin I and troponin C

We have determined six molecular distances among four sites in the binary complex formed between troponin C (TnC) and troponin I (TnI) by fluorescence resonance energy transfer between donor and acceptor probes that were either an intrinsic fluorophore (Trp158 of TnI) or extrinsic probes attached to the sites. The three extrinsic probes were dansylaziridine (DNZ), N'-(iodoacetyl)-N'-(8-sulfo-1-naphthyl)ethylenediamine (IAEDANS) and 5-(iodoacetamido)eosin (IAE). The four fluorophores provided four donor-acceptor pairs: DNZ----IAE, Trp----IAEDANS, IAEDANS----IAE, and Trp----DNZ. They allowed determinations of separations between specific sites from measurements of energy transfer from (1) Met25 (DNZ) to Cys98 (IAE) in TnC, (2) Trp158 to Cys133 (IAEDANS) in TnI, (3) Cys98 (IAEDANS) of TnC to Cys133(IAE) of TnI, (4) Trp158 of TnI to Cys98(IAEDANS) of TnC, and (6) Met25(DNZ) of TnC to Cys133(IAE) of TnI. Distance (1) in TnC was little affected when the isolated protein was complexed with TnI, whereas distance (2) in TnI increased by 6A (29%) when TnI was incorporated into the binary complex. In the presence of EGTA, the six donor-acceptor separations (R) in the complex were in the range 28 to 57 A based on kappa 2 = 2/3. Mg2+ had only small effects on R, but Ca2+ induced substantial increases or decreases of R in five of the six distances. These changes were not accompanied by significant changes in the axial depolarization of the fluorophores. The results indicate global structural perturbations of regions of the two proteins in the complex by Ca2+ binding to the TnC, and suggest that large-scale movements of domains of troponin subunits may be the initial molecular events that occur in the transmission of the Ca2+ signal in the regulation of contraction by calcium.     

Modulation of cardiac troponin C-cardiac troponin I regulatory interactions by the amino-terminus of cardiac troponin I

Multidimensional heteronuclear magnetic resonance studies of the cardiac troponin C/troponin I(1-80)/troponin I(129-166) complex demonstrated that cardiac troponin I(129-166), corresponding to the adjacent inhibitory and regulatory regions, interacts with and induces an opening of the cardiac troponin C regulatory domain. Chemical shift perturbation mapping and (15)N transverse relaxation rates for intact cardiac troponin C bound to either cardiac troponin I(1-80)/troponin I(129-166) or troponin I(1-167) suggested that troponin I residues 81-128 do not interact strongly with troponin C but likely serve to modulate the interaction of troponin I(129-166) with the cardiac troponin C regulatory domain. Chemical shift perturbations due to troponin I(129-166) binding the cardiac troponin C/troponin I(1-80) complex correlate with partial opening of the cardiac troponin C regulatory domain previously demonstrated by distance measurements using fluorescence methodologies. Fluorescence emission from cardiac troponin C(F20W/N51C)(AEDANS) complexed to cardiac troponin I(1-80) was used to monitor binding of cardiac troponin I(129-166) to the regulatory domain of cardiac troponin C. The apparent K(d) for cardiac troponin I(129-166) binding to cardiac troponin C/troponin I(1-80) was 43.3 +/- 3.2 microM. After bisphosphorylation of cardiac troponin I(1-80) the apparent K(d) increased to 59.1 +/- 1.3 microM. Thus, phosphorylation of the cardiac-specific N-terminus of troponin I reduces the apparent binding affinity of the regulatory domain of cardiac troponin C for cardiac troponin I(129-166) and provides further evidence for beta-adrenergic modulation of troponin Ca(2+) sensitivity through a direct interaction between the cardiac-specific amino-terminus of troponin I and the cardiac troponin C regulatory domain.     

Phosphorylation and mutation of human cardiac troponin I deferentially destabilize the interaction of the functional regions of troponin I with troponin C

We have utilized 2D [(1)H,(15)N]HSQC NMR spectroscopy to elucidate the binding of three segments of cTnI in native, phosphorylated, and mutated states to cTnC. The near N-terminal region (cRp; residues 34-71) contains the protein kinase C (PKC) phosphorylation sites S41 and S43, the inhibitory region (cIp; residues 128-147) contains another PKC site T142 and a familial hypertrophic cardiomyopathy (FHC) mutation R144G, and the switch region (cSp; residues 147-163) contains the novel p21-activated kinase (PAK) site S149 and another FHC mutation R161W. While S41/S43 phosphorylation of cRp had minimal disruption in the interaction of cRp and cTnC.3Ca(2+), T142 phosphorylation reduced the affinity of cIp for cCTnC.2Ca(2+) by approximately 14-fold and S149 phosphorylation reduced the affinity of cSp for cNTnC.Ca(2+) by approximately 10-fold. The mutation R144G caused an approximately 6-fold affinity decrease of cIp for cCTnC.2Ca(2+) and mutation R161W destabilized the interaction of cSp and cNTnC.Ca(2+) by approximately 1.4-fold. When cIp was both T142 phosphorylated and R144G mutated, its affinity for cCTnC.2Ca(2+) was reduced approximately 19-fold, and when cSp was both S149 phosphorylated and R161W mutated, its affinity for cNTnC.Ca(2+) was reduced approximately 4-fold. Thus, while the FHC mutation R144G enhances the effect of T142 phosphorylation on the interaction of cIp and cCTnC.2Ca(2+), the FHC mutation R161W suppresses the effect of S149 phosphorylation on the interaction of cSp and cNTnC.Ca(2+), demonstrating linkages between the FHC mutation and phosphorylation of cTnI. The observed alterations corroborate well with structural data. These results suggest that while the modifications in the cRp region have minimal influence, those in the key functional cIp-cSp region have a pronounced effect on the interaction of cTnI and cTnC, which may correlate with the altered myofilament function and cardiac muscle contraction under pathophysiological conditions.     

Proximity relationships between residue 6 of troponin I and residues in troponin C: further evidence for extended conformation of troponin C in the troponin complex

Skeletal muscle troponin C (TnC) adopts an extended conformation when crystallized alone and a compact one when crystallized with an N-terminal troponin I (TnI) peptide, TnI(1-47) [Vassylyev et al. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 4847-4852]. The N-terminal region of TnI (residues 1-40) was suggested to play a functional role of facilitating the movement of TnI's inhibitory region between TnC and actin [Tripet et al. (1997) J. Mol. Biol. 271, 728-750]. To test this hypothesis and to investigate the conformation of TnC in the intact troponin complex and in solution, we attached fluorescence and photo-cross-linking probes to a mutant TnI with a single cysteine at residue 6. Distances from this residue to residues of TnC were measured by the fluorescence resonance energy transfer technique, and the sites of photo-cross-linking in TnC were determined by microsequencing and mass spectrometry following enzymatic digestions. Our results show that in the troponin complex neither the distance between TnI residue 6 and TnC residue 89 nor the photo-cross-linking site in TnC, Ser133, changes with Ca(2+), in support of the notion that this region plays mainly a structural rather than a regulatory role. The distances to residues 12 and 41 in TnC's N-domain are both considerably longer than those predicted by the crystal structure of TnC.TnI(1-47), supporting an extended rather than a compact conformation of TnC. In the binary TnC.TnI complex and the presence of Ca(2+), Met43 in TnC's N-domain was identified as the photo-cross-linking site, and multiple distances between TnI residue 6 and TnC residue 41 were detected. This was taken to indicate increased flexibility in TnC's central helix and that TnC dynamically changes between a compact and an extended conformation when troponin T (TnT) is absent. Our results further emphasize the difference between the binary TnC.TnI and the ternary troponin complexes and the importance of using intact proteins in the study of structure-function relationships of troponin.     

The mobility of troponin C and troponin I in muscle

In vertebrate skeletal muscle, contraction is initiated by the elevation of the intracellular Ca²⁺ concentration. The binding of Ca²⁺ to TnC induces a series of conformational changes which ultimately release the inhibition of the actomyosin ATPase activity by Tnl. In this study we have characterized the dynamic behavior of TnC and Tnl in solution, as well as in reconstituted fibers, using EPR and ST-EPR spectroscopy. Cys98 of TnC and Cys133 of Tnl were specifically labeled with malemide spin label (MSL) and indane dione nitroxide spin label (InVSL). In solution, the labeled TnC and Tnl exhibited fast nanosecond motion. MSL-TnC is sensitive to cation binding to the high affinity sites (τ_r increases from 1.5 to 3.7 ns), InVSL-TnC s sensitive to the replacement of Mg²⁺ by Ca²⁺ at these sites (τ_r increase from 1.7 to 6 ns). Upon reconstitution into fibers, the nanosecond mobility is reduced by interactions with other proteins. TnC and Tnl both exhibited microsecond anisotropic motion in fibers similar to that of the actin monomers within the filament. The microsecond motion of TnC was found to be modulated by the binding of Ca²⁺ and by cross-bridge attachment, but this was not the case for the global mobility of Tnl. © 1997 John Wiley & Sons, Ltd.     

Characterization of the biologically important interaction between troponin C and the N-terminal region of troponin I

The N-terminal regulatory region of Troponin I, residues 1-40 (TnI 1-40, regulatory peptide) has been shown to have a biologically important function in the interactions of troponin I and troponin C. Truncated analogs corresponding to shorter versions of the N-terminal region (1-30, 1-28, 1-26) were synthesized by solid-phase methodology. Our results indicate that residues 1-30 of TnI comprises the minimum sequence to retain full biological activity as measured in the acto-S1-TM ATPase assay. Binding of the TnI N-terminal regulatory peptides (TnI 1-30 and the N-terminal regulatory peptide (residues 1-40) labeled with the photoprobe benzoylbenzoyl group, BBRp) were studied by gel electrophoresis and photochemical cross-linking experiments under various conditions. Fluorescence titrations of TnI 1-30 were carried out with TnC mutants that carry a single tryptophan fluorescence probe in either the N- or C-domain (F105W, F105W/C domain (88-162), F29W and F29W/N domain (1-90)) (Fig. 1). Low Kd values (Kd < 10(-7) M) were obtained for the interaction of F105W and F105W/C domain (88-162) with TnI 1-30. However, there was no observable change in fluorescence when the fluorescence probe was located at the N-domain of the TnC mutant (F29W and F29W/N domain (1-90)). These results show that the regulatory peptide binds strongly to the C-terminal domain of TnC.     

Characterization of the interaction between the N-terminal extension of human cardiac troponin I and troponin C

The N-terminal extension of cardiac troponin I (TnI) is bisphosphorylated by protein kinase A in response to beta-adrenergic stimulation. How this signal is transmitted between TnI and troponin C (TnC), resulting in accelerated Ca(2+) release, remains unclear. We recently proposed that the unphosphorylated extension interacts with the N-terminal domain of TnC stabilizing Ca(2+) binding and that phosphorylation prevents this interaction. We now use (1)H NMR to study the interactions between several N-terminal fragments of TnI, residues 1-18 (I1-18), residues 1-29 (I1-29), and residues 1-64 (I1-64), and TnC. The shorter fragments provide unambiguous information on the N-terminal regions of TnI that interact with TnC: I1-18 does not bind to TnC whereas the C-terminal region of unphosphorylated I1-29 does bind. Bisphosphorylation greatly weakens this interaction. I1-64 contains the phosphorylatable N-terminal extension and a region that anchors I1-64 to the C-terminal domain of TnC. I1-64 binding to TnC influences NMR signals arising from both domains of TnC, providing evidence that the N-terminal extension of TnI interacts with the N-terminal domain of TnC. TnC binding to I1-64 broadens NMR signals from the side chains of residues immediately C-terminal to the phosphorylation sites. Binding of TnC to bisphosphorylated I1-64 does not broaden these NMR signals to the same extent. Circular dichroism spectra of I1-64 indicate that bisphosphorylation does not produce major secondary structure changes in I1-64. We conclude that bisphosphorylation of cardiac TnI elicits its effects by weakening the interaction between the region of TnI immediately C-terminal to the phosphorylation sites and TnC either directly, due to electrostatic repulsion, or via localized conformational changes.     

Several peculiarities of the interaction of troponin T and troponin C of skeletal and cardiac muscle

Using several independent methods, the interaction between troponin T and troponin C from skeletal and cardiac muscles was studied. It was found that troponin T and troponin C from skeletal muscles form a complex whose stability depends on Ca2+ concentration. Study of interactions between these troponin components demonstrated that both electrostatic and hydrophobic forces are involved in the complex formation. Cardiac troponin T and troponin C weakly interact with each other irrespective of experimental conditions. It was assumed that the weakening of interactions between the components of cardiac troponin is due to structural peculiarities of cardiac troponin T.     

Characterization of troponin T dilated cardiomyopathy mutations in the fetal troponin isoform

The major goal of this study was to elucidate how troponin T (TnT) dilated cardiomyopathy (DCM) mutations in fetal TnT and fetal troponin affect the functional properties of the fetal heart that lead to infantile cardiomyopathy. The DCM mutations R141W and DeltaK210 were created in the TnT1 isoform, the primary isoform of cardiac TnT in the embryonic heart. In addition to a different TnT isoform, a different troponin I (TnI) isoform, slow skeletal TnI (ssTnI), is the dominant isoform in the embryonic heart. In skinned fiber studies, TnT1-wild-type (WT)-treated fibers reconstituted with cardiac TnI.troponin C (TnC) or ssTnI.TnC significantly increased Ca(2+) sensitivity of force development when compared with TnT3-WT-treated fibers at both pH 7.0 and pH 6.5. Porcine cardiac fibers treated with TnT1 that contained the DCM mutations (R141W and DeltaK210), when reconstituted with either cardiac TnI.TnC or ssTnI.TnC, significantly decreased Ca(2+) sensitivity of force development compared with TnT1-WT at both pH values. The R141W mutation, which showed no significant change in the Ca(2+) sensitivity of force development in the TnT3 isoform, caused a significant decrease in the TnT1 isoform. The DeltaK210 mutation caused a greater decrease in Ca(2+) sensitivity and maximal isometric force development compared with the R141W mutation in both the fetal and adult TnT isoforms. When complexed with cardiac TnI.TnC or ssTnI.TnC, both TnT1 DCM mutations strongly decreased maximal actomyosin ATPase activity as compared with TnT1-WT. Our results suggest that a decrease in maximal actomyosin ATPase activity in conjunction with decreased Ca(2+) sensitivity of force development may cause a severe DCM phenotype in infants with the mutations.     

Interaction of bepridil with the cardiac troponin C/troponin I complex

Mammalian cells are characterized by an endomembrane system. Nevertheless, some cells lose these membranes during their terminal differentiation, e.g. red blood cells and lens fiber cells of the eye. 15-Lipoxygenase is believed to be critical for this membrane degradation. Here we use cultivated rabbit reticulocytes in the presence or absence of a lipoxygenase inhibitor to provide further evidence for the importance of 15-lipoxygenase for the in vivo degradation of mitochondria. We find that inhibitor treatment retarded mitochondrial degradation, as shown by persistence of marker proteins and by direct visualization of mitochondria by electron microscopy.     

Folding and function of the troponin tail domain. Effects of cardiomyopathic troponin T mutations

Troponin contains a globular Ca(2+)-binding domain and an elongated tail domain composed of the N terminus of subunit troponin T (TnT). The tail domain anchors troponin to tropomyosin and actin, modulates myosin function, and is a site of cardiomyopathy-inducing mutations. Critical interactions between tropomyosin and troponin are proposed to depend on tail domain residues 112-136, which are highly conserved across phyla. Most cardiomyopathy mutations in TnT flank this region. Three such mutations were examined and had contrasting effects on peptide TnT-(1-156), promoting folding and thermal stability assessed by circular dichroism (F110I) or weakening folding and stability (T104V and to a small extent R92Q). Folding of both TnT-(1-156) and whole troponin was promoted by replacing bovine TnT Thr-104 with human TnT Ala-104, further indicating the importance of this cardiomyopathy site residue for protein folding. Mutation F110I markedly stabilized the troponin tail but weakened binding of holo-troponin to actin-tropomyosin 8-fold, suggesting that loss of flexibility impairs troponin tail function. The effect of the F110I mutation on troponin-tropomyosin binding to actin was much less, indicating this flexibility is particularly important for the interactions of troponin with tropomyosin. We suggest that most cardiomyopathic mutations in the troponin tail alter muscle function indirectly, by perturbing interactions between troponin and tropomyosin requisite for the complex effects of these proteins on myosin.     

Effect of calcium ions on the interaction of troponin C with rabbit skeletal muscle troponin I and troponin T immobilized on polyvinyl chloride

Using a new methodological approach based on the binding of 125I-labeled troponin C to troponins I and T immobilized on polyvinylchloride, the Ca2+-dependent interaction of troponin components was investigated. In the absence of Ca2+, two types of sites of troponin C--troponin T interaction were revealed (Kd = 3.6.10(-8) M and 5.10(-7) M). It was found that Ca2+ induced the formation of a troponin I--troponin C complex which was resistant to 5 M urea (Kd = 4.10(-8) M). In the absence of Ca2+, the binary troponin T--troponin C complex also revealed two types of interaction sites (Kd = 7.1.10(-8) M and 2.10(-7) M); however, in the presence of Ca2+ only high affinity sites whose number increased almost 2-fold were revealed. The events that may take place in the whole troponin complex during Ca2+ binding by troponin C are discussed.     

Interaction of troponin I and troponin C. Use of the two-dimensional nuclear magnetic resonance transferred nuclear Overhauser effect to determine the structure of the inhibitory troponin I peptide when bound to skeletal troponin C

We have used two-dimensional 1H nuclear magnetic resonance spectroscopy to determine the structure of the synthetic inhibitory peptide N alpha-acetyl TnI(104-115) amide bound to calcium-saturated skeletal troponin C (TnC). Conformational changes in the peptide induced by the formation of the troponin I (TnI) peptide-TnC complex were followed by the study of the transferred nuclear Overhauser effect, a technique that allows one to determine the structure of a ligand bound to a macromolecule. The structure of the bound TnI peptide reveals an amphiphilic alpha-helix, distorted around the two central proline residues. The central bend in the peptide functions to bring the residues on the hydrophobic face into closer proximity with each other, thereby forming a small hydrophobic pocket. The hydrophilic, basic residues extend off the opposite face of the peptide. Hydrophobic surfaces on TnC that become exposed upon binding of calcium are involved in the binding of the TnI peptide, but electrostatic interactions also contribute to the strength of the interaction. The role of amphiphilic helices in the targeting of calcium-binding proteins such as troponin C will be discussed.     

Dephosphorylation specificities of protein phosphatase for cardiac troponin I, troponin T, and sites within troponin T

Protein dephosphorylation by protein phosphatase 1 (PP1), acting in concert with protein kinase C (PKC) and protein kinase A (PKA), is a pivotal regulatory mechanism of protein phosphorylation. Isolated rat cardiac myofibrils phosphorylated by PKC/PKA and dephosphorylated by PP1 were used in determining dephosphorylation specificities, Ca(2+)-stimulated Mg(2+)ATPase activities, and Ca(2+) sensitivities. In reconstituted troponin (Tn) complex, PP1 displayed distinct substrate specificity in dephosphorylation of TnT preferentially to TnI, in vitro. In situ phosphorylation of cardiomyocytes with calyculin A, a protein phosphatase inhibitor, resulted in an increase in the phosphorylation stiochiometry of TnT (0.3 to 0.5 (67%)), TnI (2.6 to 3.6 (38%)), and MLC2 (0.4 to 1.7 (325%)). These results further confirmed that though MLC2 is the preferred target substrate for protein phosphatase in the thick filament, the Tn complex (TnI and TnT) from thin filament and C-protein in the thick filament are also protein phosphatase substrates. Our in vitro dephosphorylation experiments revealed that while PP1 differentially dephosphorylated within TnT at multiple sites, TnI was uniformly dephosphorylated. Phosphopeptide maps from the in vitro experiments show that TnT phosphopeptides at spots 4A and 4B are much more resistant to PP1 dephosphorylation than other TnT phosphopeptides. Mg(2+)ATPase assays of myofibrils phosphorylated by PKC/PKA and dephosphorylated by PP1 delineated that while PKC and PKA phosphorylation decreased the Ca(2+)-stimulated Mg(2+)ATPase activities, dephosphorylation antagonistically restored it. PKC and PKA phosphorylation decreased Ca(2+) sensitivity to 3.6 microM and 5.0 microM respectively. However, dephosphorylation restored the Mg(2+)ATPase activity of PKC (99%) and PKA (95%), along with the Ca(2+) sensitivities (3.3 microM and 3.0 microM, respectively).     

Calcium- and magnesium-dependent interactions between the C-terminus of troponin I and the N-terminal, regulatory domain of troponin C

The muscle thin filament protein troponin (Tn) regulates contraction of vertebrate striated muscle by conferring Ca2+ sensitivity to the interaction of actin and myosin. Troponin C (TnC), the Ca2+ binding subunit of Tn contains two homologous domains and four divalent cation binding sites. Two structural sites in the C-terminal domain of TnC bind either Ca2+ or Mg2+, and two regulatory sites in the N-terminal domain are specific for Ca2+. Interactions between TnC and the inhibitory Tn subunit troponin I (TnI) are of central importance to the Ca2+ regulation of muscle contraction and have been intensively studied. Much remains to be learned, however, due mainly to the lack of a three-dimensional structure for TnI. In particular, the role of amino acid residues near the C-terminus of TnI is not well understood. In this report, we prepared a mutant TnC which contains a single Trp-26 residue in the N-terminal, regulatory domain. We used fluorescence lifetime and quenching measurements to monitor Ca2+- and Mg2+-dependent changes in the environment of Trp-26 in isolated TnC, as well as in binary complexes of TnC with a Trp-free mutant of TnI or a truncated form of this mutant, TnI(1-159), which lacked the C-terminal 22 amino acid residues of TnI. We found that full-length TnI and TnI(1-159) affected Trp-26 similarly when all four binding sites of TnC were occupied by Ca2+. When the regulatory Ca2+-binding sites in the N-terminal domain of TnC were vacant and the structural sites in the C-terminal domain of were occupied by Mg2+, we found significant differences between full-length TnI and TnI(1-159) in their effect on Trp-26. Our results provide the first indica- tion that the C-terminus of TnI may play an important role in the regulation of vertebrate striated muscle through Ca2+-dependent interactions with the regula- tory domain of TnC.