Inhibitory region of troponin I: Ca(2+)-dependent structural and environmental changes in the troponin-tropomyosin complex and in reconstituted thin filaments

In muscle thin filaments, the inhibitory region (residues 96-117) of troponin I (TnI) is thought to interact with troponin C (TnC) in the presence of Ca(2+) and with actin in the absence of Ca(2+). To better understand these interactions, we prepared mutant TnIs which contained a single Cys-96 or Cys-117 and labeled them with the thiol-specific fluorescent probe N-(iodoacetyl)-N'-(1-sulfo-5-naphthyl)ethylenediamine (IAEDANS). We characterized the microenvironments of the AEDANS labels on TnI in the presence and absence of Ca(2+) by measuring the extent of acrylamide quenching of fluorescence and lifetime-resolved anisotropy. In the troponin-tropomyosin (Tn-Tm) complex, the AEDANS labels on both Cys-96 and Cys-117 were less accessible to solvent and less flexible in the presence of Ca(2+), reflecting closer interactions with TnC under these conditions. In reconstituted thin filaments, the environment of the AEDANS on Cys-96 was not greatly affected by Ca(2+), while the AEDANS on Cys-117 was more accessible but significantly less flexible as it moved away from actin and interacted strongly with TnC in the presence of Ca(2+). We used fluorescence resonance energy transfer (FRET) to measure distances between AEDANS on TnI Cys-96 or Cys-117 and 4-?[(dimethylamino)phenyl]azo?phenyl-4'-maleimide (DABmal) on actin Cys-374 in reconstituted thin filaments. In the absence of Ca(2+), the mean distances were 40.2 A for Cys-96 and 35.2 A for Cys-117. In the presence of Ca(2+), Cys-96 moved away from actin Cys-374 by approximately 3.6 A, while Cys-117 moved away by approximately 8 A. This suggests the existence of a flexible "hinge" region near the middle of TnI, allowing amino acid residues in the N-terminal half of TnI to interact with TnC in a Ca(2+)-independent manner, while the C-terminal half of TnI binds to actin in the absence of Ca(2+) or to TnC in the presence of Ca(2+). This is the first report to demonstrate structural movement of the inhibitory region of TnI in the thin filament.     

Photocrosslinking of benzophenone-labeled single cysteine troponin I mutants to other thin filament proteins

The interaction sites of rabbit skeletal troponin I (TnI) with troponin C (TnC), troponin T (TnT), tropomyosin (Tm) and actin were mapped systematically using nine single cysteine residue TnI mutants with mutation sites at positions 6, 48, 64, 89, 104, 121, 133, 155 or 179 (TnI6, TnI48 etc.). Each mutant was labeled with the heterobifunctional photocrosslinker 4-maleimidobenzophenone (BP-Mal), and incorporated into the TnI.TnC binary complex, the TnI.TnC.TnT ternary troponin (Tn) complex, and the Tn.Tm.F-actin synthetic thin filament. Photocrosslinking reactions carried out in the presence and absence of Ca(2+) yielded the following results: (1) BP-TnI6 photocrosslinked primarily to TnC with a small degree of Ca(2+)-dependence in all the complex forms. (2) BP-TnI48, TnI64 and TnI89 photocrosslinked to TnT with no Ca(2+)-dependence. Photocrosslinking to TnC was reduced in the ternary versus the binary complex. BP-TnI89 also photocrosslinked to actin with higher yields in the absence of Ca(2+) than in its presence. (3) BP-TnI104 and TnI133 photocrosslinked to actin with much higher yields in the absence than in the presence of Ca(2+). (4) BP-TnI121 photocrosslinked to TnC with a small degree of Ca(2+)-dependence, and did not photocrosslink to actin. (5) BP-TnI155 and TnI179 photocrosslinked to TnC, TnT and actin, but all with low yields. All the labeled mutants photocrosslinked to TnC with varying degrees of Ca(2+)-dependence, and none to Tm. These results, along with those published allowed us to construct a structural and functional model of TnI in the Tn complex: in the presence of Ca(2+), residues 1-33 of TnI interact with the C-terminal domain hydrophobic cleft of TnC, approximately 48-89 with TnT, approximately 90-113 with TnC's central helix, approximately 114-125 with TnC's N-terminal domain hydrophobic cleft, and approximately 130-150 with TnC's A-helix. In the absence of Ca(2+), residues approximately 114-125 move out of TnC's N-terminal domain hydrophobic cleft and trigger the movements of residues approximately 89-113 and approximately 130-150 away from TnC and towards actin.     

Ca(2+)-dependent, myosin subfragment 1-induced proximity changes between actin and the inhibitory region of troponin I.

In order to help understand the spatial rearrangements of thin filament proteins during the regulation of muscle contraction, we used fluorescence resonance energy transfer (FRET) to measure Ca(2+)-dependent, myosin-induced changes in distances and fluorescence energy transfer efficiencies between actin and the inhibitory region of troponin I (TnI). We labeled the single Cys-117 of a mutant TnI with N-(iodoacetyl)-N'-(1-sulfo-5-naphthyl)ethylenediamine (IAEDANS) and Cys-374 of actin with 4-dimethylaminophenylazophenyl-4'-maleimide (DABmal). These fluorescent probes were used as donor and acceptor, respectively, for the FRET measurements. We reconstituted a troponin-tropomyosin (Tn-Tm) complex which contained the AEDANS-labeled mutant TnI, together with natural troponin T (TnT), troponin C (TnC) and tropomyosin (Tm) from rabbit fast skeletal muscle. Fluorescence titration of the AEDANS-labeled Tn-Tm complex with DABmal-labeled actin, in the presence and absence of Ca(2+), resulted in proportional, linear increases in energy transfer efficiency up to a 7:1 molar excess of actin over Tn-Tm. The distance between AEDANS on TnI Cys-117 and DABmal on actin Cys-374 increased from 37.9 A to 44.1 A when Ca(2+) bound to the regulatory sites of TnC. Titration of reconstituted thin filaments, containing AEDANS-labeled Tn-Tm and DABmal-labeled actin, with myosin subfragment 1 (S1) decreased the energy transfer efficiency, in both the presence and absence of Ca(2+). The maximum decrease occurred at well below stoichiometric levels of S1 binding to actin, showing a cooperative effect of S1 on the state of the thin filaments. S1:actin molar ratios of approximately 0.1 in the presence of Ca(2+), and approximately 0.3 in the absence of Ca(2+), were sufficient to cause a 50% reduction in normalized transfer efficiency. The distance between AEDANS on TnI Cys-117 and DABmal on actin Cys-374 increased by approximately 7 A in the presence of Ca(2+) and by approximately 2 A in the absence of Ca(2+) when S1 bound to actin. Our results suggest that TnI's interaction with actin inhibits actomyosin ATPase activity by modulating the equilibria among active and inactive states of the thin filament. Structural rearrangements caused by myosin S1 binding to the thin filament, as detected by FRET measurements, are consistent with the cooperative behavior of the thin filament proteins.     

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.     

Calcium-induced flexibility changes in the troponin C-troponin I complex

The contraction of vertebrate striated muscle is modulated by Ca(2+) binding to the regulatory protein troponin C (TnC). Ca(2+) binding causes conformational changes in TnC which alter its interaction with the inhibitory protein troponin I (TnI), initiating the regulatory process. We have used the frequency domain method of fluorescence resonance energy transfer (FRET) to measure distances and distance distributions between specific sites in the TnC-TnI complex in the presence and absence of Ca(2+) or Mg(2+). Using sequences based on rabbit skeletal muscle proteins, we prepared functional, binary complexes of wild-type TnC and a TnI mutant which contains no Cys residues and a single Trp residue at position 106 within the TnI inhibitory region. We used TnI Trp-106 as the FRET donor, and we introduced energy acceptor groups into TnC by labeling at Met-25 with dansyl aziridine or at Cys-98 with N-(iodoacetyl)-N'-(1-sulfo-5-naphthyl)ethylenediamine. Our distance distribution measurements indicate that the TnC-TnI complex is relatively rigid in the absence of Ca(2+), but becomes much more flexible when Ca(2+) binds to regulatory sites in TnC. This increased flexibility may be propagated to the whole thin filament, helping to release the inhibition of actomyosin ATPase activity and allowing the muscle to contract. This is the first report of distance distributions between TnC and TnI in their binary complex.     

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.     

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.     

Biologically important interactions between synthetic peptides of the N-terminal region of troponin I and troponin C.

The interaction between troponin I and troponin C plays a critical role in the regulation of muscle contraction. In this study the interaction between troponin C (TnC) and the N-terminal region of TnI was investigated by the synthesis of three TnI peptides (residues 1-40/Rp, 10-40, and 20-40). The regulatory peptide (Rp) on binding to TnC prevents the ability of TnC to release the inhibition of the acto-S1-tropomyosin ATPase activity caused by TnI or the TnI inhibitory peptide (Ip), residues 104-115. A stable complex between TnC and Rp in the presence of Ca2+ was demonstrated by polyacrylamide gel electrophoresis in the presence of 6 M urea. Rp was able to displace TnI from a preformed TnI.TnC complex. In the absence of Ca2+, Rp was unable to maintain a complex with TnC in benign conditions of polyacrylamide gel electrophoresis which demonstrates the Ca(2+)-dependent nature of this interaction. Size-exclusion chromatography demonstrated that the TnC.Rp complex consisted of a 1:1 complex. The results of these studies have shown that the N-terminal region of TnI (1-40) plays a critical role in modulating the Ca(2+)-sensitive release of TnI inhibition by TnC.     

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.     

Inhibition of actin-myosin subfragment 1 ATPase activity by troponin I and IC: relationship to the thin filament states of muscle

Troponin I (TnI) is the component of the troponin complex that inhibits actomyosin ATPase activity, and Ca(2+) binding to the troponin C (TnC) component reverses the inhibition. Effects of the binding of TnI and the TnI-TnC (TnIC) complex to actin-tropomyosin (actinTm) on ATPase and on the binding kinetics of myosin subfragment 1 (S1) were studied to clarify the mechanism of the inhibition. TnI and TnIC in the absence of Ca(2+) bind to actinTm and inhibit ATPase to similar levels with a stoichiometry of one TnI or one TnIC per one Tm and seven actin subunits. TnI also binds to actinTmTn in the presence of Ca(2+) with a stoichiometry and inhibition constant similar to those for the binding to actinTm of TnI and Tn in the absence of Ca(2+). Thus, in the presence of Ca(2+), the intrinsic TnI which is released from its binding site on actinTm does not interfere with the binding of an extra molecule of TnI to actinTmTn. The rate of S1 binding to actinTmTnI and to actinTmTnTnI in the presence of Ca(2+) was inhibited to the same extent as upon removal of Ca(2+) from actinTmTn. These studies show that TnI inhibits ATPase by the same mechanism as Tn in the absence of Ca(2+), by shifting the thin filament equilibria from the open state to the closed and blocked states.     

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.     

Ca2+-dependent interaction of the inhibitory region of troponin I with acidic residues in the N-terminal domain of troponin C

Ca2+ regulation of vertebrate striated muscle contraction is initiated by conformational changes in the N-terminal, regulatory domain of the Ca2+-binding protein troponin C (TnC), altering the interaction of TnC with the other subunits of troponin complex, TnI and TnT. We have investigated the role of acidic amino acid residues in the N-terminal, regulatory domain of TnC in binding to the inhibitory region (residues 96-116) of TnI. We constructed three double mutants of TnC (E53A/E54A, E60A/E61A and E85A/D86A), in which pairs of acidic amino acid residues were replaced by neutral alanines, and measured their affinities for synthetic inhibitory peptides. These peptides had the same amino acid sequence as TnI segments 95-116, 95-119 or 95-124, except that the natural Phe-100 of TnI was replaced by a tryptophan residue. Significant Ca2+-dependent increases in the affinities of the two longer peptides, but not the shortest one, to TnC could be detected by changes in Trp fluorescence. In the presence of Ca2+, all the mutant TnCs showed about the same affinity as wild-type TnC for the inhibitory peptides. In the presence of Mg2+ and EGTA, the N-terminal, regulatory Ca2+-binding sites of TnC are unoccupied. Under these conditions, the affinity of TnC(E85A/D86A) for inhibitory peptides was about half that of wild-type TnC, while the other two mutants had about the same affinity. These results imply a Ca2+-dependent change in the interaction of TnC Glu-85 and/or Asp-86 with residues (117-124) on the C-terminal side of the inhibitory region of TnI. Since Glu-85 and/or Asp-86 of TnC have also been demonstrated to be involved in Ca2+-dependent regulation through interaction with TnT, this region of TnC must be critical for troponin function.     

Kinetic analysis of the interactions between troponin C (TnC) and troponin I (TnI) binding peptides: evidence for separate binding sites for the 'structural' N-terminus and the 'regulatory' C-terminus of TnI on TnC

The Ca(2+)/Mg(2+)-dependent interactions between TnC and TnI play a critical role in regulating the 'on' and 'off' states of muscle contraction as well as maintaining the structural integrity of the troponin complex in the off state. In the present study, we have investigated the binding interactions between the N-terminus of TnI (residues 1-40 of skeletal TnI) and skeletal TnC in the presence of Ca(2+) ions, Mg(2+) ions and in the presence of the C-terminal regulatory region peptides: TnI(96-115), TnI(96-131) and TnI(96-139). Our results show the N-terminus of TnI can bind to TnC with high affinity in the presence of Ca(2+) or Mg(2+) ions with apparent equilibrium dissociation constants of K(d(Ca(2+) ) ) = 48 nM and K(d(Mg(2+) ) ) = 29 nM. The apparent association and dissociation rate constants for the interactions were, k(on) = 4.8 x 10(5) M (-1) s(-1), 3.4 x 10(5) M (-1) s(-1) and k(off) = 2.3 x 10(-2) s(-1), 1.0 x 10(-2) s(-1) for TnC(Ca(2+)) and TnC(Mg(2+)) states, respectively. Competition studies between each of the TnI regions and TnC showed that both TnI regions can bind simultaneously to TnC while native gel electrophoresis and SEC confirmed the formation of stable ternary complexes between TnI(96-139) (or TnI(96-131)) and TnC-TnI(1-40). Further analysis of the binding interactions in the ternary complex showed the binding of the TnI regulatory region to TnC was critically dependent upon the presence of both TnC binding sites (i.e. TnI(96-115) and TnI(116-131)) and the presence of Ca(2+). Furthermore, the presence of TnI(1-40) slightly weakened the affinity of the regulatory peptides for TnC. Taken together, these results support the model for TnI-TnC interaction where the N-terminus of TnI remains bound to the C-domain of TnC in the presence of high and low Ca(2+) levels while the TnI regulatory region (residues 96-139) switches in its binding interactions between the actin-tropomyosin thin filament and its own sites on the N- and C-domain of TnC at high Ca(2+) levels, thus regulating muscle contraction.     

The role of the NH(2)- and COOH-terminal domains of the inhibitory region of troponin I in the regulation of skeletal muscle contraction.

The role of the inhibitory region of troponin (Tn) I in the regulation of skeletal muscle contraction was studied with three deletion mutants of its inhibitory region: 1) complete (TnI-(Delta96-116)), 2) the COOH-terminal domain (TnI-(Delta105-115)), and 3) the NH(2)-terminal domain (TnI-(Delta95-106)). Measurements of Ca(2+)-regulated force and relaxation were performed in skinned skeletal muscle fibers whose endogenous TnI (along with TnT and TnC) was displaced with high concentrations of added troponin T. Reconstitution of the Tn-displaced fibers with a TnI.TnC complex restored the Ca(2+) sensitivity of force; however, the levels of relaxation and force development varied. Relaxation of the fibers (pCa 8) was drastically impaired with two of the inhibitory region deletion mutants, TnI-(Delta96-116).TnC and TnI-(Delta105-115).TnC. The TnI-(Delta95-106).TnC mutant retained approximately 55% relaxation when reconstituted in the Tn-displaced fibers. Activation in skinned skeletal muscle fibers was enhanced with all TnI mutants compared with wild-type TnI. Interestingly, all three mutants of TnI increased the Ca(2+) sensitivity of contraction. None of the TnI deletion mutants, when reconstituted into Tn, could inhibit actin-tropomyosin-activated myosin ATPase in the absence of Ca(2+), and two of them (TnI-(Delta96-116) and TnI-(Delta105-115)) gave significant activation in the absence of Ca(2+). These results suggest that the COOH terminus of the inhibitory region of TnI (residues 105-115) is much more critical for the biological activity of TnI than the NH(2)-terminal region, consisting of residues 95-106. Presumably, the COOH-terminal domain of the inhibitory region of TnI is a part of the Ca(2+)-sensitive molecular switch during muscle contraction.     

Ca(2+)- and S1-induced movement of troponin T on reconstituted skeletal muscle thin filaments observed by fluorescence energy transfer spectroscopy

Troponin T (TnT) is an essential component of troponin (Tn) for the Ca(2+)-regulation of vertebrate striated muscle contraction. TnT consists of an extended NH(2)-terminal domain that interacts with tropomyosin (Tm) and a globular COOH-terminal domain that interacts with Tm, troponin I (TnI), and troponin C (TnC). We have generated two mutants of a rabbit skeletal beta-TnT 25-kDa fragment (59-266) that have a unique cysteine at position 60 (N-terminal region) or 250 (C-terminal region). To understand the spatial rearrangement of TnT on the thin filament in response to Ca(2+) binding to TnC, we measured distances from Cys-60 and Cys-250 of TnT to Gln-41 and Cys-374 of F-actin on the reconstituted thin filament by using fluorescence resonance energy transfer (FRET). The distances from Cys-60 and Cys-250 of TnT to Gln-41 of F-actin were 39.5 and 30.0 A, respectively in the absence of Ca(2+), and increased by 2.6 and 5.8 A, respectively upon binding of Ca(2+) to TnC. The rigor binding of myosin subfragment 1 (S1) further increased these distances by 4 and 5 A respectively, when the thin filaments were fully decorated with S1. This indicates that not only the C-terminal but also the N-terminal region of TnT showed the Ca(2+)- and S1-induced movement, and the C-terminal region moved more than N-terminal region. In the absence of Ca(2+), the rigor S1 binding also increased the distances to the same extent as the presence of Ca(2+) when the thin filaments were fully decorated with S1. The addition of ATP completely reversed the changes in FRET induced by rigor S1 binding both in the presence and absence of Ca(2+). However, plots of the extent of S1-induced conformational change vs. molar ratio of S1 to actin showed hyperbolic curve in the presence of Ca(2+) but sigmoidal curve in the absence of Ca(2+). FRET measurement of the distances from Cys-60 and Cys-250 of TnT to Cys-374 of actin showed almost the same results as the case of Gln-41 of actin. The present FRET measurements demonstrated that not only TnI but also TnT change their positions on the thin filament corresponding to three states of thin filaments (relaxed, Ca(2+)-induced or closed, and S1-induced or open states).     

Orientational information of troponin C within the thin filaments obtained by neutron fiber diffraction

In striated muscles contraction is regulated by the thin filament-based proteins, troponin consisting of three subunits (TnC, TnI, and TnT), and tropomyosin. Knowledge of in situ structures of these proteins is indispensable for elucidating this Ca(2+)-sensitive regulatory mechanism. We employed neutron scattering to investigate the structure of TnC within the thin filament, and found that TnC assumes extended dumbbell-like structures and moves toward the filament axis by binding of Ca(2+). Here, in order to obtain more detailed in situ structural information of TnC, neutron fiber diffraction measurements were performed. Sols of native thin filaments and the thin filaments containing deuterated TnC were prepared in (2)H(2)O. The oriented samples were obtained by placing these sols sealed in quartz capillaries with a diameter of 3 mm in a magnetic field of 18 Tesla. Neutron fiber diffraction patterns were obtained from these oriented samples in the absence and presence of Ca(2+). The patterns obtained showed strong equatorial diffraction due to the thin filaments, 59 A and 51 A layer-lines due to actin, and meridional reflections due to Tn-complex. Analysis of the meridional reflections due to Tn-complex with aid of model calculation showed that the angle between the thin filament axis and the long axis of TnC was estimated to be 67(+/-7) degrees and 49(+/-17) degrees , in the absence and presence of Ca(2+), respectively, suggesting that TnC, which assumes orientations rather perpendicular to the filament axis in the absence of Ca(2+), tilts toward the filament axis and the orientational and positional disorder increases by binding Ca(2+). It also showed that the relative position of the TnC moved by about 22 A by binding Ca(2+), and this apparent movement was concomitant with the movements of other Tn-subunits. This implies that by binding Ca(2+), significant structural rearrangements of Tn-subunits occur.     

NMR and mutagenesis studies on the phosphorylation region of human cardiac troponin I

Phosphorylation of the cardiac troponin complex by PKA at S22 and S23 of troponin I (TnI) accelerates Ca(2+) release from troponin C (TnC). The region of TnI around the bisphosphorylation site binds to, and stabilizes, the Ca(2+) bound N-terminal domain of TnC. Phosphorylation interferes with this interaction between TnI and TnC resulting in weaker Ca(2+) binding. In this study, we used (1)H-(15)N-HSQC NMR to investigate at the atomic level the interaction between an N-terminal fragment of TnI consisting of residues 1-64 of TnI (I1-64) and TnC. We produced several mutants of I1-64, TnI, and TnC to test the contribution of certain residues to the transmission of the phosphorylation signal in both NMR experiments and functional assays. We also investigated how phosphorylation of the PKC sites in I1-64 (S41 and S43) affects the interaction of I1-64 with TnC. We found that phosphorylation of S22 and S23 produced only localized effects in the structure of I1-64 between residues 24 and 34. Residues 1-17 of I1-64 did not bind to TnC, and residues 38-64 bound tightly to the C-terminal domain of TnC regardless of phosphorylation. Residues 22-34 bound weakly to TnC in a phosphorylation sensitive manner. Bisphosphorylation prevented this phosphorylation switch region from interacting with TnC. Systematic mutation of residues in the phosphorylation switch did not prevent PKA phosphorylation from accelerating Ca(2+) release from troponin. We conclude that the phosphorylation switch binds to TnC via an extended interaction site spanning residues R19 to A34.     

Structural and functional studies on Troponin I and Troponin C interactions

Troponin I (TnI) peptides (TnI inhibitory peptide residues 104-115, Ip; TnI regulatory peptide resides 1-30, TnI1-30), recombinant Troponin C (TnC) and Troponin I mutants were used to study the structural and functional relationship between TnI and TnC. Our results reveal that an intact central D/E helix in TnC is required to maintain the ability of TnC to release the TnI inhibition of the acto-S1-TM ATPase activity. Ca(2+)-titration of the TnC-TnI1-30 complex was monitored by circular dichroism. The results show that binding of TnI1-30 to TnC caused a three-folded increase in Ca(2+) affinity in the high affinity sites (III and IV) of TnC. Gel electrophoresis and high performance liquid chromatography (HPLC) studies demonstrate that the sequences of the N- and C-terminal regions of TnI interact in an anti-parallel fashion with the corresponding N- and C-domain of TnC. Our results also indicate that the N- and C-terminal domains of TnI which flank the TnI inhibitory region (residues 104 to 115) play a vital role in modulating the Ca(2+)- sensitive release of the TnI inhibitory region by TnC within the muscle filament. A modified schematic diagram of the TnC/TnI interaction is proposed.     

Structural consequences of cardiac troponin I phosphorylation

beta-Adrenergic stimulation of the heart results in bisphosphorylation of the N-terminal extension of cardiac troponin I (TnI). Bisphosphorylation of TnI reduces the affinity of the regulatory site on troponin C (TnC) for Ca(2+) by increasing the rate of Ca(2+) dissociation. What remains unclear is how the phosphorylation signal is transmitted from one subunit of troponin to another. We have produced a series of mutations in the N-terminal extension of TnI designed to further our understanding of the mechanisms involved. The ability of phosphorylation of the mutant TnIs to affect Ca(2+) sensitivity has been assessed. We find that the Pro residues found in a conserved (Xaa-Pro)(4) motif N-terminal to the phosphorylation sites are not required for the effect of the N-terminal extension on Ca(2+) binding in the presence or absence of phosphorylation. Our experiments also reveal that the full effects of phosphorylation are seen even when residues 1-15 of TnI are deleted. If further residues are removed, not only does the effect of phosphorylation diminish but deletion of the N-terminal extension mimics phosphorylation. We propose that TnI residues 16-29 bind to TnC stabilizing the "open" Ca(2+)-bound state. Phosphorylation (or deletion) prevents this binding, accelerating Ca(2+) release.     

Ca(2+) induces an extended conformation of the inhibitory region of troponin I in cardiac muscle troponin.

The inhibitory region of troponin I (TnI) plays a central regulatory role in the contraction and relaxation cycle of skeletal and cardiac muscle through its Ca(2+)-dependent interaction with actin. Detailed structural information on the interface between TnC and this region of TnI has been long in dispute. We have used fluorescence resonance energy transfer (FRET) to investigate the global conformation of the inhibitory region of a full-length TnI mutant from cardiac muscle (cTnI) in the unbound state and in reconstituted complexes with the other cardiac troponin subunits. The mutant contained a single tryptophan residue at the position 129 which was used as an energy transfer donor, and a single cysteine residue at the position 152 labeled with IAEDANS as energy acceptor. The sequence between Trp129 and Cys152 in cTnI brackets the inhibitory region (residues 130-149), and the distance between the two sites was found to be 19.4 A in free cTnI. This distance was insensitive to reconstitution of cTnI with cardiac troponin T (cTnT), cTnC, or cTnC and cTnT in the absence of bound regulatory Ca(2+) in cTnC. An increase of 9 A in the Trp129-Cys152 separation was observed upon saturation of the Ca(2+) regulatory site of cTnC in the complexes. This large increase suggests an extended conformation of the inhibitory region in the interface between cTnC and cTnI in holo cardiac troponin. This extended conformation is different from a recent model of the Ca(2+)-saturated skeletal TnI-TnC complex in which the inhibitory region is modeled as a beta-turn. The observed Ca(2+)-induced conformational change may be a switch mechanism by which movement of the regulatory region of cTnI to the exposed hydrophobic patch of the open regulatory N-domain of cTnC pulls the inhibitory region away from actin upon Ca(2+) activation in cardiac muscle.