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.     

Structural kinetics of cardiac troponin C mutants linked to familial hypertrophic and dilated cardiomyopathy in troponin complexes

The key events in regulating cardiac muscle contraction involve Ca(2+) binding to and release from cTnC (troponin C) and structural changes in cTnC and other thin filament proteins triggered by Ca(2+) movement. Single mutations L29Q and G159D in human cTnC have been reported to associate with familial hypertrophic and dilated cardiomyopathy, respectively. We have examined the effects of these individual mutations on structural transitions in the regulatory N-domain of cTnC triggered by Ca(2+) binding and dissociation. This study was carried out with a double mutant or triple mutants of cTnC, reconstituted into troponin with tryptophanless cTnI and cTnT. The double mutant, cTnC(L12W/N51C) labeled with 1,5-IAEDANS at Cys-51, served as a control to monitor Ca(2+)-induced opening and closing of the N-domain by F?rster resonance energy transfer (FRET). The triple mutants contained both L12W and N51C labeled with 1,5-IAEDANS, and either L29Q or G159D. Both mutations had minimal effects on the equilibrium distance between Trp-12 and Cys-51-AEDANS in the absence or presence of bound Ca(2+). L29Q had no effect on the closing rate of the N-domain triggered by release of Ca(2+), but reduced the Ca(2+)-induced opening rate. G159D reduced both the closing and opening rates. Previous results showed that the closing rate of cTnC N-domain triggered by Ca(2+) dissociation was substantially enhanced by PKA phosphorylation of cTnI. This rate enhancement was abolished by L29Q or G159D. These mutations alter the kinetics of structural transitions in the regulatory N-domain of cTnC that are involved in either activation (L29Q) or deactivation (G159D). Both mutations appear to be antagonistic toward phosphorylation signaling between cTnI and cTnC.     

Interaction of cardiac troponin C with calmodulin antagonist [corrected] W7 in the presence of three functional regions of cardiac troponin I

W7 is a well-known calmodulin (CaM) antagonist and has been implicated as an inhibitor of the troponin C-mediated Ca(2+) activation of cardiac muscle contraction. In this study, we use NMR spectroscopy to study binding of W7 to cardiac troponin C (cTnC) free or in complex with cardiac troponin I (cTnI) peptides. Titration of cTnC.3Ca(2+) with W7 shows that residues throughout the sequence, including the N- and C-domains of cTnC and the central linker, are affected. Analysis of the binding stoichiometry and the trajectories of chemical shift changes indicate that W7 binding occurs at multiple sites. To address the issue of whether multiple-site binding is relevant within the troponin complex, W7 is titrated to a cTnC-cTnI complex (cTnC.3Ca(2+).cTnI(34)(-)(71).cTnI(128)(-)(163)). In the presence of the N-terminal (residues approximately 34-71), inhibitory (residues approximately 128-147), and switch (residues approximately 147-163) regions of cTnI, W7 induces chemical shift changes only in the N-domain and not in the C-domain or the central linker of cTnC. The results indicate that in the presence of cTnI, W7 no longer binds to multiple sites of cTnC but instead binds specifically to the N-domain, and the binding (K(D) = 0.5 +/- 0.1 mM) can occur together with the switch region of cTnI. Hence, W7 may play a role in directly modulating the Ca(2+) sensitivity of the regulatory domain of cTnC and the interaction of the switch region of cTnI and cTnC.     

Ca2+-induced conformational transition in the inhibitory and regulatory regions of cardiac troponin I

Cardiac muscle activation is initiated by the binding of Ca(2+) to the single N-domain regulatory site of cardiac muscle troponin C (cTnC). Ca(2+) binding causes structural changes between cTnC and two critical regions of cardiac muscle troponin I (cTnI): the regulatory region (cTnI-R, residues 150-165) and the inhibitory region (cTnI-I, residues130-149). These changes are associated with a decreased cTnI affinity for actin and a heightened affinity for cTnC. Using F?rster resonance energy transfer, we have measured three intra-cTnI distances in the deactivated (Mg(2+)-saturated) and Ca(2+)-activated (Ca(2+)-saturated) states in reconstituted binary (cTnC-cTnI) and ternary (cTnC-cTnI-cTnT) troponin complexes. Distance A (spanning cTnI-R) was unaltered by Ca(2+). Distances B (spanning both cTnI-R and cTnI-I) and C (from a residue flanking cTnI-I to a residue in the center of cTnI-R) exhibited Ca(2+)-induced increases of >8 A. These results compliment our previous determination of the distance between residues flanking cTnI-I alone. Together, the data suggest that Ca(2+) activation causes residues within cTnI-I to switch from a beta-turn/coil to an extended quasi-alpha-helical conformation as the actin-contacts are broken, whereas cTnI-R remains alpha-helical in both Mg(2+)- and Ca(2+)-saturated states. We have used the data to construct a structural model of the cTnI inhibitory and regulatory regions in the Mg(2+)- and Ca(2+)-saturated states.     

Structural transition of the inhibitory region of troponin I within the regulated cardiac thin filament

Contraction and relaxation of cardiac muscle are regulated by the inhibitory and regulatory regions of troponin I (cTnI). Our previous FRET studies showed that the inhibitory region of cTnI in isolated troponin experiences a structural transition from a beta-turn/coil motif to an extended conformation upon Ca(2+) activation. During the relaxation process, the kinetics of the reversal of this conformation is coupled to the closing of the Ca(2+)-induced open conformation of the N-domain of troponin C (cTnC) and an interaction between cTnC and cTnI in their interface. We have since extended the structural kinetic study of the inhibitory region to fully regulated thin filament. Single-tryptophan and single-cysteine mutant cTnI(L129W/S151C) was labeled with 1,5-IAEDANS at Cys151, and the tryptophan-AEDANS pair served as a donor-acceptor pair. Labeled cTnI mutant was used to prepare regulated thin filaments. Ca(2+)-induced conformational changes in the segment of Trp129-Cys151 of cTnI were monitored by FRET sensitized acceptor (AEDANS) emission in Ca(2+) titration and stopped-flow measurements. Control experiments suggested energy transfer from endogenous tryptophan residues of actin and myosin S1 to AEDANS attached to Cys151 of cTnI was very small and Ca(2+) independent. The present results show that the rate of Ca(2+)-induced structural transition and Ca(2+) sensitivity of the inhibitory region of cTnI were modified by (1) thin filament formation, (2) the presence of strongly bound S1, and (3) PKA phosphorylation of the N-terminus of cTnI. Ca(2+) sensitivity was not significantly changed by the presence of cTm and actin. However, the cTn-cTm interaction decreased the cooperativity and kinetics of the structural transition within cTnI, while actin filaments elicited opposite effects. The strongly bound S1 significantly increased the Ca(2+) sensitivity and slowed down the kinetics of structural transition. In contrast, PKA phosphorylation of cTnI decreased the Ca(2+) sensitivity and accelerated the structural transition rate of the inhibitory region of cTnI on thin filaments. These results support the idea of a feedback mechanism by strong cross-bridge interaction with actin and provide insights on the molecular basis for the fine tuning of cardiac function by beta-adrenergic stimulation.     

Solution structures of the C-terminal domain of cardiac troponin C free and bound to the N-terminal domain of cardiac troponin I.

The N-terminal domain of cardiac troponin I (cTnI) comprising residues 33-80 and lacking the cardiac-specific amino terminus forms a stable binary complex with the C-terminal domain of cardiac troponin C (cTnC) comprising residues 81-161. We have utilized heteronuclear multidimensional NMR to assign the backbone and side-chain resonances of Ca2+-saturated cTnC(81-161) both free and bound to cTnI(33-80). No significant differences were observed between secondary structural elements determined for free and cTnI(33-80)-bound cTnC(81-161). We have determined solution structures of Ca2+-saturated cTnC(81-161) free and bound to cTnI(33-80). While the tertiary structure of cTnC(81-161) is qualitatively similar to that observed free in solution, the binding of cTnI(33-80) results mainly in an opening of the structure and movement of the loop region between helices F and G. Together, these movements provide the binding site for the N-terminal domain of cTnI. The putative binding site for cTnI(33-80) was determined by mapping amide proton and nitrogen chemical shift changes, induced by the binding of cTnI(33-80), onto the C-terminal cTnC structure. The binding interface for cTnI(33-80), as suggested from chemical shift changes, involves predominantly hydrophobic interactions located in the expanded hydrophobic pocket. The largest chemical shift changes were observed in the loop region connecting helices F and G. Inspection of available TnC sequences reveals that these residues are highly conserved, suggesting a common binding motif for the Ca2+/Mg2+-dependent interaction site in the TnC/TnI complex.     

Site-directed spin labeling electron paramagnetic resonance study of the calcium-induced structural transition in the N-domain of human cardiac troponin C complexed with troponin I

Calcium-induced structural transition in the amino-terminal domain of troponin C (TnC) triggers skeletal and cardiac muscle contraction. The salient feature of this structural transition is the movement of the B and C helices, which is termed the "opening" of the N-domain. This movement exposes a hydrophobic region, allowing interaction with the regulatory domain of troponin I (TnI) as can be seen in the crystal structure of the troponin ternary complex [Takeda, S., Yamashita, A., Maeda, K., and Maeda, Y. (2003) Nature 424, 35-41]. In contrast to skeletal TnC, Ca(2+)-binding site I (an EF-hand motif that consists of an A helix-loop-B helix motif) is inactive in cardiac TnC. The question arising from comparisons with skeletal TnC is how both helices move according to Ca(2+) binding or interact with TnI in cardiac TnC. In this study, we examined the Ca(2+)-induced movement of the B and C helices relative to the D helix in a cardiac TnC monomer state and TnC-TnI binary complex by means of site-directed spin labeling electron paramagnetic resonance (EPR). Doubly spin-labeled TnC mutants were prepared, and the spin-spin distances were estimated by analyzing dipolar interactions with the Fourier deconvolution method. An interspin distance of 18.4 A was estimated for mutants spin labeled at G42C on the B helix and C84 on the D helix in a Mg(2+)-saturated monomer state. The interspin distance between Q58C on the C helix and C84 on the D helix was estimated to be 18.3 A under the same conditions. Distance changes were observed by the addition of Ca(2+) ions and the formation of a complex with TnI. Our data indicated that the C helix moved away from the D helix in a distinct Ca(2+)-dependent manner, while the B helix did not. A movement of the B helix by interaction with TnI was observed. Both Ca(2+) and TnI were also shown to be essential for the full opening of the N-domain in cardiac TnC.     

Using lanthanide ions to align troponin complexes in solution: order of lanthanide occupancy in cardiac troponin C

The potential for using paramagnetic lanthanide ions to partially align troponin C in solution as a tool for the structure determination of bound troponin I peptides has been investigated. A prerequisite for these studies is an understanding of the order of lanthanide ion occupancy in the metal binding sites of the protein. Two-dimensional [(1)H, (15)N] HSQC NMR spectroscopy has been used to examine the binding order of Ce(3+), Tb(3+), and Yb(3+) to both apo- and holo-forms of human cardiac troponin C (cTnC) and of Ce(3+) to holo-chicken skeletal troponin C (sTnC). The disappearance of cross-peak resonances in the HSQC spectrum was used to determine the order of occupation of the binding sites in both cTnC and sTnC by each lanthanide. For the lanthanides tested, the binding order follows that of the net charge of the binding site residues from most to least negative; the N-domain calcium binding sites are the first to be filled followed by the C-domain sites. Given this binding order for lanthanide ions, it was demonstrated that it is possible to create a cTnC species with one lanthanide in the N-domain site and two Ca(2+) ions in the C-domain binding sites. By using the species cTnC.Yb(3+).2 Ca(2+) it was possible to confer partial alignment on a bound human cardiac troponin I (cTnI) peptide. Residual dipolar couplings (RDCs) were measured for the resonances in the bound (15)N-labeled cTnI(129-148) by using two-dimensional [(1)H, (15)N] inphase antiphase (IPAP) NMR spectroscopy.     

Drug binding to cardiac troponin C.

Compounds that sensitize cardiac muscle to Ca(2+) by intervening at the level of regulatory thin filament proteins would have potential therapeutic benefit in the treatment of myocardial infarctions. Two putative Ca(2+) sensitizers, EMD 57033 and levosimendan, are reported to bind to cardiac troponin C (cTnC). In this study, we use heteronuclear NMR techniques to study drug binding to [methyl-(13)C]methionine-labeled cTnC when free or when complexed with cardiac troponin I (cTnI). In the absence of Ca(2+), neither drug interacted with cTnC. In the presence of Ca(2+), one molecule of EMD 57033 bound specifically to the C-terminal domain of free cTnC. NMR and equilibrium dialysis failed to demonstrate binding of levosimendan to free cTnC, and the presence of levosimendan had no apparent effect on the Ca(2+) binding affinity of cTnC. Changes in the N-terminal methionine methyl chemical shifts in cTnC upon association with cTnI suggest that cTnI associates with the A-B helical interface and the N terminus of the central helix in cTnC. NMR experiments failed to show evidence of binding of levosimendan to the cTnC.cTnI complex. However, levosimendan covalently bound to a small percentage of free cTnC after prolonged incubation with the protein. These findings suggest that levosimendan exerts its positive inotropic effect by mechanisms that do not involve binding to cTnC.     

Effects of PKA phosphorylation of cardiac troponin I and strong crossbridge on conformational transitions of the N-domain of cardiac troponin C in regulated thin filaments

Regulation of cardiac muscle function is initiated by binding of Ca2+ to troponin C (cTnC) which induces a series of structural changes in cTnC and other thin filament proteins. These structural changes are further modulated by crossbridge formation and fine-tuned by phosphorylation of cTnI. The objective of the present study is to use a new F?rster resonance energy transfer-based structural marker to distinguish structural and kinetic effects of Ca2+ binding, crossbridge interaction, and protein kinase A phosphorylation of cTnI on the conformational changes of the cTnC N-domain. The FRET-based structural marker was generated by attaching AEDANS to one cysteine of a double-cysteine mutant cTnC(13C/51C) as a FRET donor and attaching DDPM to the other cysteine as the acceptor. The doubly labeled cTnC mutant was reconstituted into the thin filament by adding cTnI, cTnT, tropomyosin, and actin. Changes in the distance between Cys13 and Cys51 induced by Ca2+ binding/dissociation were determined by FRET-sensed Ca2+ titration and stopped-flow studies, and time-resolved fluorescence measurements. The results showed that the presence of both Ca2+ and strong binding of myosin head to actin was required to achieve a fully open structure of the cTnC N-domain in regulated thin filaments. Equilibrium and stopped-flow studies suggested that strongly bound myosin head significantly increased the Ca2+ sensitivity and changed the kinetics of the structural transition of the cTnC N-domain. PKA phosphorylation of cTnI impacted the Ca2+ sensitivity and kinetics of the structural transition of the cTnC N-domain but showed no global structural effect on cTnC opening. These results provide an insight into the modulation mechanism of strong crossbridge and cTnI phosphorylation in cardiac thin filament activation/relaxation processes.     

Effects of protein kinase C dependent phosphorylation and a familial hypertrophic cardiomyopathy-related mutation of cardiac troponin I on structural transition of troponin C and myofilament activation

In experiments reported here, we compared tension and thin filament Ca(2+) signaling in preparations containing either wild-type cardiac troponin I (cTnI) or a mutant cTnI with an R146G mutation [cTnI(146G)] linked to familial hypertrophic cardiomyopathy. Myofilament function is altered in association with cTnI phosphorylation by protein kinase C (PKC), which is activated in hypertrophy. Whether there are differential effects of PKC phosphorylation on cTnI compared to cTnI(146G) remains unknown. We therefore also studied cTnI and cTnI(146G) with PKC sites mutated to Glu, which mimics phosphorylation. Compared to cTnI controls, binary complexes with either cTnI(146G) or cTnI(43E/45E/144E) had a small effect on Ca(2+)-dependent structural opening of the N-terminal regulatory domain of cTnC as measured using F?rster resonance energy transfer. However, this structural change was significantly reduced in the cTnC-cTnI(43E/45E/144E/146G) complex. Exchange of cTnI in skinned fiber bundles with cTnI(146G) induced enhanced Ca(2+) sensitivity and an elevated resting tension. Exchange of cTnI with cTnI(43E/45E/144E) induced a depression in Ca(2+) sensitivity and maximum tension. However, compared to cTnI(146G), cTnI(43E/45E/144E/146G) had little additional effects on myofilament response to Ca(2+). By comparing activation of tension to the open state of the N-domain of cTnC with variations in the state of cTnI, we were able to provide data supporting the hypothesis that activation of cardiac myofilaments is tightly coupled to the open state of the N-domain of cTnC. Our data also support the hypothesis that pathological effects of phosphorylation are influenced by mutations in cTnI.     

Kinetics of conformational transitions in cardiac troponin induced by Ca2+ dissociation determined by Förster resonance energy transfer

Upon Ca2+ activation of cardiac muscle, several structural changes occur in the troponin subunits. These changes include the opening of the cardiac troponin C (cTnC) N-domain, the change of secondary structure of the inhibitory region of cardiac troponin I (cTnI), and the change in the separation between these two proteins in the cTnC-cTnI interface. We have used F?rster resonance energy transfer in Ca2+ titration and stopped-flow experiments to delineate these transitions using a reconstituted cardiac troponin. Energy transfer results were quantified to yield time-dependent profiles of changes in intersite distances during Ca2+ dissociation. The closing of the cTnC N-domain induced by release of regulatory Ca2+ from cTnC occurs in one step (t1/2 approximately 5 ms), and this transition is not affected by Ca2+ release from the C-domain. The other two transitions triggered by Ca2+ dissociation are biphasic with the fast phase (t1/2 approximately 5 ms) correlated with Ca2+ release from the cTnC N-domain. These transitions are slower than the release of bound regulatory Ca2+ (t1/2 3.6 ms) and are coupled to one another in a cooperative manner in restoring their conformations in the deactivated state. The kinetic results define the magnitudes of structural changes relevant in Ca2+ switching between activation and deactivation of cardiac muscle contraction.     

Differential pH effect on calcium-induced conformational changes of cardiac troponin C complexed with cardiac and fast skeletal isoforms of troponin I and troponin T

The aim of this study is to investigate the molecular events associated with the deleterious effects of acidosis on the contractile properties of cardiac muscle as in the ischemia of heart failure. We have conducted a study of the effects of increasing acidity on the Ca(2+) induced conformational changes of pyrene labelled cardiac troponin C (PIA-cTnC) in isolation and in complex with porcine cardiac or chicken pectoral skeletal muscle TnI and/or TnT. The pyrene label has been shown to serve as a useful fluorescence reporter group for conformational and interaction events of the N-terminal regulatory domain of TnC with only minimal fluorescence changes associated with C-terminal domain. Results obtained show that the significant decreases at pH 6.0 of site II Ca(2+) affinity of PIA-cTnC when complexed as a binary complex with either cTnI or cTnT are significantly reduced when cTnI is replaced with sTnI or cTnT with sTnT. However, this effect is appreciably diminished when the cTnI and cTnT in the ternary complex are replaced by sTnI and sTnT. The smaller effects in the ternary complex of replacing both cTnI and cTnT by their skeletal counterparts on depressing the Ca(2+) affinity from pH 7.0 to 6.0 arise from TnI replacement. Thus, changes in TnC conformation resulting from isoform-specific interactions with TnI and TnT could be an integral part of the effect of pH on myofilament Ca(2+)sensitivity.     

Interaction of cardiac troponin C with Ca(2+) sensitizer EMD 57033 and cardiac troponin I inhibitory peptide

The binding of Ca(2+) to cardiac troponin C (cTnC) triggers contraction in cardiac muscle. In diseased heart, the myocardium is often desensitized to Ca(2+), leading to weak cardiac contractility. Compounds that can sensitize cardiac muscle to Ca(2+) would have potential therapeutic value in treating heart failure. The thiadiazinone derivative EMD 57033 is an identified 'Ca(2+) sensitizer', and cTnC is a potential target of the drug. In this work, we used 2D ?(1)H, (15)N?-HSQC NMR spectroscopy to monitor the binding of EMD 57033 to cTnC in the Ca(2+)-saturated state. By mapping the chemical shift changes to the structure of cTnC, EMD 57033 is found to bind to the C-domain of cTnC. To test whether EMD 57033 competes with cardiac TnI (cTnI) for cTnC and interferes with the inhibitory function, we examined the interaction of cTnC with an inhibitory cTnI peptide (residues 128-147, cIp) in the absence and presence of EMD 57033, respectively. cTnC was also titrated with EMD 57033 in the presence of cIp. The results show that although both the drug and cIp interact with the C-domain of cTnC, they do not displace each other, suggesting noncompetitive binding sites for the two targets. Detailed chemical shift mapping of the binding sites reveals that the regions encompassing helix G-loop IV-helix H are more affected by EMD 57033, while residues located on helix E-loop III-helix F and the linker between sites III and IV are more affected by cIp. In both cases, the binding stoichiometry is 1:1. The binding affinities for the drug are 8.0 +/- 1.8 and 7.4 +/- 4.8 microM in the absence and presence of cIp, respectively, while those for the peptide are 78.2 +/- 10.3 and 99.2 +/- 30.0 microM in the absence and presence of EMD 57033, respectively. These findings suggest that EMD 57033 may exert its positive inotropic effect by not directly enhancing Ca(2+) binding to the Ca(2+) regulatory site of cTnC, but by binding to the structural domain of cTnC, modulating the interaction between cTnC and other thin filament proteins, and increasing the apparent Ca(2+) sensitivity of the contractile system.     

An interdomain distance in cardiac troponin C determined by fluorescence spectroscopy

The distance between Ca2+-binding site III in the C-terminal domain and Cys35 in the N-terminal domain in cardiac muscle troponin C (cTnC) was determined with a single-tryptophan mutant using bound Tb3+ as the energy donor and iodoacetamidotetramethylrhodamine linked to the cysteine residue as energy acceptor. The luminescence of bound Tb3+ was generated through sensitization by the tryptophan located in the 12-residue binding loop of site III upon irradiation at 295 nm, and this sensitized luminescence was the donor signal transferred to the acceptor. In the absence of bound cation at site II, the mean interdomain distance was found to be 48-49 A regardless of whether the cTnC was unbound or bound to cardiac troponin I, or reconstituted into cardiac troponin. These results suggest that cTnC retains its overall length in the presence of bound target proteins. The distribution of the distances was wide (half-width >9 A) and suggests considerable interdomain flexibility in isolated cTnC, but the distributions became narrower for cTnC in the complexes with the other subunits. In the presence of bound cation at the regulatory site II, the interdomain distance was shortened by 6 A for cTnC, but without an effect on the half-width. The decrease in the mean distance was much smaller or negligible when cTnC was complexed with cTnI or cTnI and cTnT under the same conditions. Although free cTnC has considerable interdomain flexibility, this dynamics is slightly reduced in troponin. These results indicate that the transition from the relaxed state to an activated state in cardiac muscle is not accompanied by a gross alteration of the cTnC conformation in cardiac troponin.     

Cardiac troponin T isoforms affect the Ca(2+) sensitivity of force development in the presence of slow skeletal troponin I: insights into the role of troponin T isoforms in the fetal heart

In this study we investigated the physiological role of the cardiac troponin T (cTnT) isoforms in the presence of human slow skeletal troponin I (ssTnI). ssTnI is the main troponin I isoform in the fetal human heart. In reconstituted fibers containing the cTnT isoforms in the presence of ssTnI, cTnT1-containing fibers showed increased Ca(2+) sensitivity of force development compared with cTnT3- and cTnT4-containing fibers. The maximal force in reconstituted skinned fibers was significantly greater for the cTnT1 (predominant fetal cTnT isoform) when compared with cTnT3 (adult TnT isoform) in the presence of ssTnI. Troponin (Tn) complexes containing ssTnI and reconstituted with cTnT isoforms all yielded different maximal actomyosin ATPase activities. Tn complexes containing cTnT1 and cTnT4 (both fetal isoforms) had a reduced ability to inhibit actomyosin ATPase activity when compared with cTnT3 (adult isoform) in the presence of ssTnI. The rate at which Ca(2+) was released from site II of cTnC in the cTnI.cTnC complex (122/s) was 12.5-fold faster than for the ssTnI.cTnC complex (9.8/s). Addition of cTnT3 to the cTnI.cTnC complex resulted in a 3.6-fold decrease in the Ca(2+) dissociation rate from site II of cTnC. Addition of cTnT3 to the ssTnI.cTnC complex resulted in a 1.9-fold increase in the Ca(2+) dissociation rate from site II of cTnC. The rate at which Ca(2+) dissociated from site II of cTnC in Tn complexes also depended on the cTnT isoform present. However, the TnI isoforms had greater effects on the Ca(2+) dissociation rate of site II than the cTnT isoforms. These results suggest that the different N-terminal TnT isoforms would produce distinct functional properties in the presence of ssTnI when compared with cTnI and that each isoform would have a specific physiological role in cardiac muscle.     

Identification of a region of troponin I important in signaling cross-bridge-dependent activation of cardiac myofilaments

Force generating strong cross-bridges are required to fully activate cardiac thin filaments, but the molecular signaling mechanism remains unclear. Evidence demonstrating differential extents of cross-bridge-dependent activation of force, especially at acidic pH, in myofilaments in which slow skeletal troponin I (ssTnI) replaced cardiac TnI (cTnI) indicates the significance of a His in ssTnI that is an homologous Ala in cTnI. We compared cross-bridge-dependent activation in myofilaments regulated by cTnI, ssTnI, cTnI(A66H), or ssTnI(H34A). A drop from pH 7.0 to 6.5 induced enhanced cross-bridge-dependent activation in cTnI myofilaments, but depressed activation in cTnI(A66H) myofilaments. This same drop in pH depressed cross-bridge-dependent activation in both ssTnI myofilaments and ssTnI(H34A) myofilaments. Compared with controls, cTnI(A66H) myofilaments were desensitized to Ca(2+), whereas there was no difference in the Ca(2+)-force relationship between ssTnI and ssTnI(H34A) myofilaments. The mutations in cTnI and ssTnI did not affect Ca(2+) dissociation rates from cTnC at pH 7.0 or 6.5. However, at pH 6.5, cTnI(A66H) had lower affinity for cTnT than cTnI. We also probed cross-bridge-dependent activation in myofilaments regulated by cTnI(Q56A). Myofilaments containing cTnI(Q56A) demonstrated cross-bridge-dependent activation that was similar to controls containing cTnI at pH 7.0 and an enhanced cross-bridge-dependent activation at pH 6.5. We conclude that a localized N-terminal region of TnI comprised of amino acids 33-80, which interacts with C-terminal regions of cTnC and cTnT, is of particular significance in transducing signaling of thin filament activation by strong cross-bridges.     

Structural mapping of single cysteine mutants of cardiac troponin I

The global conformation of cardiac muscle troponin I (cTnI) was investigated with single-cysteine mutants by using a combination of sulfhydryl reactivity and fluorescence resonance energy transfer (FRET) to determine cysteine accessibility and intersite distances. The reactivity was determined with a fluorescent reagent for its reaction with cysteine residues singly located at positions 5, 40, 81, 98, 115, 133, 150, 167, and 192. FRET measurements were made by using the endogenous single Trp-192 as the energy donor and an acceptor probe covalently attached to the cysteines as energy acceptor. The results suggest an open and extended conformation of cTnI with a large curvature in which the cysteines are highly exposed to the solvent. These conformational features are largely retained in the segment between residues 40 and 192 upon phosphorylation at Ser-23 and Ser-24. The sulfhydryl groups of the Cys-133 and Cys-150 of the cTnI incorporated into the binary cTnC-cTnI and fully reconstituted troponin complexes experience large reduced exposure resulting from the binding of Ca(2+) to the regulatory site of cTnC, suggesting that key regions of cTnI involved in activation become highly shielded upon activation. In the cTnC-cTnI complex, every intramolecular distance in the cTnI is lengthened and the overall conformation of the bound cTnI remains elongated with reduced exposure for the cysteines. The global conformation of the troponin C-troponin I complex from cardiac muscle has an elongated shape with constrained flexibility. The highly flexible nature of the N-terminal extension of cTnI is preserved in the complex, suggesting that this segment of cTnI is either not bound or only loosely bound to the C-domain of cTnC.     

A cross-linking study of the N-terminal extension of human cardiac troponin I

Phosphorylation of the unique N-terminal extension of cardiac troponin I (TnI) by PKA modulates Ca(2+) release from the troponin complex. The mechanism by which phosphorylation affects Ca(2+) binding, however, remains unresolved. To investigate this question, we have studied the interaction of a fragment of TnI consisting of residues 1-64 (I1-64) with troponin C (TnC) by isothermal titration microcalorimetry and cross-linking. I1-64 binds extremely tightly to the C-terminal domain of TnC and weakly to the N-terminal domain. Binding to the N-domain is weakened further by phosphorylation. Using the heterobifunctional cross-linker benzophenone-4-maleimide and four separate cysteine mutants of I1-64 (S5C, E10C, I18C, R26C), we have probed the protein-protein interactions of the N-terminal extension. All four I1-64 mutants cross-link to the N-terminal domain of TnC. The cross-linking is enhanced by Ca(2+) and reduced by phosphorylation. By introducing the same monocysteine mutations into full-length TnI, we were able to probe the environment of the N-terminal extension in intact troponin. We find that the full length of the extension lies in close proximity to both TnC and troponin T (TnT). Ca(2+) enhances the cross-linking to TnC. Cross-linking to both TnC and TnT is reduced by prior phosphorylation of the TnI. In binary complexes the mutant TnIs cross-link to both the isolated TnC N-domain and whole TnC. Cyanogen bromide digestion of the covalent TnI-TnC complex formed from intact troponin demonstrates that cross-linking is predominantly to the N-terminal domain of TnC.     

The importance of the carboxyl-terminal domain of cardiac troponin C in Ca2+-sensitive muscle regulation

The interactions between troponin I and troponin C are central to the Ca(2+)-regulated control of striated muscle. Using isothermal titration microcalorimetry we have studied the binding of human cardiac troponin C (cTnC) and its isolated domains to human cardiac troponin I (cTnI). We provide the first binding data for these proteins while they are free in solution and unmodified by reporter groups. Our data reveal that the C-terminal domain of cTnC is responsible for most of the free energy change upon cTnC.cTnI binding. Importantly, the interaction between cTnI and the C-terminal domain of cTnC is 8-fold stronger in the presence of Ca(2+) than in the presence of Mg(2+), suggesting that the C-terminal domain of cTnC may play a modulatory role in cardiac muscle regulation. Changes in the affinity of cTnI for cTnC and its isolated C-terminal domain in response to ionic strength support this finding, with both following similar trends. At physiological ionic strength the affinity of cTnC for cTnI changed very little in response to Ca(2+), although the thermodynamic data show a clear distinction between binding in the presence of Ca(2+) and in the presence of Mg(2+).