Parallel measurement of Ca2+ binding and fluorescence emission upon Ca2+ titration of recombinant skeletal muscle troponin C. Measurement of sequential calcium binding to the regulatory sites

Calcium binding to chicken recombinant skeletal muscle TnC (TnC) and its mutants containing tryptophan (F29W), 5-hydroxytryptophan (F29HW), or 7-azatryptophan (F29ZW) at position 29 was measured by flow dialysis and by fluorescence. Comparative analysis of the results allowed us to determine the influence of each amino acid on the calcium binding properties of the N-terminal regulatory domain of the protein. Compared with TnC, the Ca(2+) affinity of N-terminal sites was: 1) increased 6-fold in F29W, 2) increased 3-fold in F29ZW, and 3) decreased slightly in F29HW. The Ca(2+) titration of F29ZW monitored by fluorescence displayed a bimodal curve related to sequential Ca(2+) binding to the two N-terminal Ca(2+) binding sites. Single and double mutants of TnC, F29W, F29HW, and F29ZW were constructed by replacing aspartate by alanine at position 30 (site I) or 66 (site II) or both. Ca(2+) binding data showed that the Asp --> Ala mutation at position 30 impairs calcium binding to site I only, whereas the Asp --> Ala mutation at position 66 impairs calcium binding to both sites I and II. Furthermore, the Asp --> Ala mutation at position 30 eliminates the differences in Ca(2+) affinity observed for replacement of Phe at position 29 by Trp, 5-hydroxytryptophan, or 7-azatryptophan. We conclude that position 29 influences the affinity of site I and that Ca(2+) binding to site I is dependent on the previous binding of metal to site II.     

Construction and characterization of a spectral probe mutant of troponin C: application to analyses of mutants with increased Ca2+ affinity.

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

Functional role of Ca(2+)-binding site IV of scallop troponin C

Scallop troponin C (TnC) binds only one Ca(2+)/mol and the single Ca(2+)-binding site has been suggested to be site IV on the basis of the primary structure [K. Nishita, H. Tanaka, and T. Ojima (1994) J. Biol. Chem. 269, 3464-3468; T. Ojima, H. Tanaka, and K. Nishita (1994) Arch. Biochem. Biophys. 311, 272-276]. In the present study, the functional role of Ca(2+)-binding site IV of akazara scallop (Chlamys nipponensis akazara) TnC in Ca(2+)-regulation was investigated using a site-directed mutant with an inactivated site IV (TnC-ZEQ), N- and C-terminal half molecule mutants (TnC(N) and TnC(C)), and wild-type TnC (TnC(W)). Equilibrium dialysis using (45)Ca(2+) demonstrated that TnC(W) and TnC(C) bind 0.6-0.8 mol of Ca(2+)/mol, but that TnC-ZEQ and TnC(N) bind virtually no Ca(2+). The UV difference spectra of TnC(W) and TnC(C) showed bands at around 280-290 nm due to the perturbation of Tyr and Trp upon Ca(2+)-binding, while TnC-ZEQ and TnC(N) did not show these bands. In addition, TnC(W) and TnC(C) showed retardation of elution from Sephacryl S-200 upon the addition of 1 mM CaCl(2), unlike TnC-ZEQ and TnC(N). These results indicate that Ca(2+) binds only to site IV and that Ca(2+)-binding causes structural changes in both the whole TnC molecule and the C-terminal half molecule. In addition, TnC(W), TnC-ZEQ, and TnC(C), but not TnC(N), were shown to form soluble complexes with scallop TnI at physiological ionic strength. On the other hand, the Mg-ATPase activity of reconstituted rabbit actomyosin in the presence of scallop tropomyosin was inhibited by scallop TnI and recovered by the addition of an equimolar amount of TnC(W), TnC-ZEQ, or TnC(C), but not TnC(N). These results imply that the site responsible for the association with TnI is located in the C-terminal half domain of TnC. Ternary complex constructed from scallop TnT, TnI, and TnC(W) conferred Ca(2+)-sensitivity to the Mg-ATPase of rabbit actomyosin to the same extent as native troponin, but the TnC(N)-TnT-TnI and TnC-ZEQ-TnT-TnI complexes conferred no Ca(2+)-sensitivity, while the TnC(C)-TnT-TnI complex conferred weak Ca(2+)-sensitivity. Thus, the major functions of scallop TnC, such as Ca(2+)-binding and interaction with TnI, are located in the C-terminal domain, however, the full Ca(2+)-regulatory function requires the presence of the N-terminal domain.     

Engineering competitive magnesium binding into the first EF-hand of skeletal troponin C

The goal of this study was to examine the mechanism of magnesium binding to the regulatory domain of skeletal troponin C (TnC). The fluorescence of Trp(29), immediately preceding the first calcium-binding loop in TnC(F29W), was unchanged by addition of magnesium, but increased upon calcium binding with an affinity of 3.3 microm. However, the calcium-dependent increase in TnC(F29W) fluorescence could be reversed by addition of magnesium, with a calculated competitive magnesium affinity of 2.2 mm. When a Z acid pair was introduced into the first EF-hand of TnC(F29W), the fluorescence of G34DTnC(F29W) increased upon addition of magnesium or calcium with affinities of 295 and 1.9 microm, respectively. Addition of 3 mm magnesium decreased the calcium sensitivity of TnC(F29W) and G34DTnC(F29W) approximately 2- and 6-fold, respectively. Exchange of G34DTnC(F29W) into skinned psoas muscle fibers decreased fiber calcium sensitivity approximately 1.7-fold compared with TnC(F29W) at 1 mm [magnesium](free) and approximately 3.2-fold at 3 mm [magnesium](free). Thus, incorporation of a Z acid pair into the first EF-hand allows it to bind magnesium with high affinity. Furthermore, the data suggests that the second EF-hand, but not the first, of TnC is responsible for the competitive magnesium binding to the regulatory domain.     

Effect of hydrophobic residue substitutions with glutamine on Ca(2+) binding and exchange with the N-domain of troponin C

Troponin C (TnC) is an EF-hand Ca(2+) binding protein that regulates skeletal muscle contraction. The mechanisms that control the Ca(2+) binding properties of TnC and other EF-hand proteins are not completely understood. We individually substituted 27 Phe, Ile, Leu, Val, and Met residues with polar Gln to examine the role of hydrophobic residues in Ca(2+) binding and exchange with the N-domain of a fluorescent TnC(F29W). The global N-terminal Ca(2+) affinities of the TnC(F29W) mutants varied approximately 2340-fold, while Ca(2+) association and dissociation rates varied less than 70-fold and more than 45-fold, respectively. Greater than 2-fold increases in Ca(2+) affinities were obtained primarily by slowing of Ca(2+) dissociation rates, while greater than 2-fold decreases in Ca(2+) affinities were obtained by slowing of Ca(2+) association rates and speeding of Ca(2+) dissociation rates. No correlation was found between the Ca(2+) binding properties of the TnC(F29W) mutants and the solvent accessibility of the hydrophobic amino acids in the apo state, Ca(2+) bound state, or the difference between the two states. However, the effects of these hydrophobic mutations on Ca(2+) binding were contextual possibly because of side chain interactions within the apo and Ca(2+) bound states of the N-domain. These results demonstrate that a single hydrophobic residue, which does not directly ligate Ca(2+), can play a crucial role in controlling Ca(2+) binding and exchange within a coupled and functional EF-hand system.     

Effect of temperature and the F27W mutation on the Ca2+ activated structural transition of trout cardiac troponin C

The Ca(2+) sensitivity of cardiac contractile element is reduced at lower temperatures, in contrast to that in fast skeletal muscle. Cardiac troponin C (cTnC) replacement in mammalian skinned fibers showed that TnC plays a critical role in this phenomenon (Harrison and Bers, (1990), Am. J. Physiol. 258, C282-8). Understanding the differences in affinity and structure between cTnCs from cold-adapted ectothermic species and mammals may bring new insights into how the different isoforms provide different resistances to cold. We followed the Ca(2+) titration to the regulatory domain of rainbow trout cTnC by NMR (wild type at 7 and 30 degrees C and F27W mutant at 30 degrees C) and fluorescence (F27W mutant, at 7 and 30 degrees C) spectroscopies. Using NMR spectroscopy, we detected Ca(2+) binding to site I of trout cTnC at high concentrations. This places trout cTnC between mammalian cTnC, in which site I is completely inactive, and skeletal TnC, in which site I binds Ca(2+) during muscle activation, and which is not as much affected by lower temperatures. This binding was seen both at 7 and at 30 degrees C. Despite the low Ca(2+) affinity, trout TnC site I may increase the likelihood of an opening of the regulatory domain, thus increasing the affinity for TnI. This way, it may be responsible for trout cTnC's capacity to function at lower temperatures.     

Conformational changes in sarcoplasmic reticulum Ca(2+)-ATPase mutants: effect of mutations either at Ca(2+)-binding site II or at tryptophan 552 in the cytosolic domain

By analyzing, after expression in yeast and purification, the intrinsic fluorescence properties of point mutants of rabbit Ca(2+)-ATPase (SERCA1a) with alterations to amino acid residues in Ca(2+)-binding site I (E(771)), site II (E(309)), in both sites (D(800)), or in the nucleotide-binding domain (W(552)), we were able to follow the conformational changes associated with various steps in the ATPase catalytic cycle. Whereas Ca(2+) binding to purified wild-type (WT) ATPase in the absence of ATP leads to the rise in Trp fluorescence expected for the so-called E2 --> E1Ca(2) transition, the Ca(2+)-induced fluorescence rise is dramatically reduced for the E(309)Q mutant. As this purified E(309)Q mutant retains the ability to bind Ca(2+) at site I (but not at site II), we tentatively conclude that the protein reorganization induced by Ca(2+) binding at site II makes the major contribution to the overall Trp fluorescence changes observed upon Ca(2+) binding to both sites. Judging from the fluorescence response of W(552)F, similar to that of WT, these changes appear to be primarily due to membranous tryptophans, not to W(552). The same holds for the fluorescence rise observed upon phosphorylation from P(i) (the so-called E2 --> E2P transition). As for WT ATPase, Mg(2+) binding in the absence of Ca(2+) affects the fluorescence of the E(309)Q mutant, suggesting that this Mg(2+)-dependent fluorescence rise does not reflect binding of Mg(2+) to Ca(2+) sites; instead, Mg(2+) probably binds close to the catalytic site, or perhaps near transmembrane span M3, at a location recently revealed by Fe(2+)-catalyzed oxidative cleavage. Mutation of W(552) hardly affects ATP-induced fluorescence changes in the absence of Ca(2+), which are therefore mostly due to membranous Trp residues, demonstrating long-range communication between the nucleotide-binding domain and the membranous domain.     

Modulation of the rate of cardiac muscle contraction by troponin C constructs with various calcium binding affinities

We investigated whether changing thin filament Ca(2+) sensitivity alters the rate of contraction, either during normal cross-bridge cycling or when cross-bridge cycling is increased by inorganic phosphate (P(i)). We increased or decreased Ca(2+) sensitivity of force production by incorporating into rat skinned cardiac trabeculae the troponin C (TnC) mutants V44QTnC(F27W) and F20QTnC(F27W). The rate of isometric contraction was assessed as the rate of force redevelopment (k(tr)) after a rapid release and restretch to the original length of the muscle. Both in the absence of added P(i) and in the presence of 2.5 mM added P(i) 1) Ca(2+) sensitivity of k(tr) was increased by V44QTnC(F27W) and decreased by F20QTnC(F27W) compared with control TnC(F27W); 2) k(tr) at submaximal Ca(2+) activation was significantly faster for V44QTnC(F27W) and slower for F20QTnC(F27W) compared with control TnC(F27W); 3) at maximum Ca(2+) activation, k(tr) values were similar for control TnC(F27W), V44QTnC(F27W), and F20QTnC(F27W); and 4) k(tr) exhibited a linear dependence on force that was indistinguishable for all TnCs. In the presence of 2.5 mM P(i), k(tr) was faster at all pCa values compared with the values for no added P(i) for TnC(F27W), V44QTnC(F27W), and F20QTnC(F27W). This study suggests that TnC Ca(2+) binding properties modulate the rate of cardiac muscle contraction at submaximal levels of Ca(2+) activation. This result has physiological relevance considering that, on a beat-to-beat basis, the heart contracts at submaximal Ca(2+) activation.     

Comparative NMR studies on cardiac troponin C and a mutant incapable of binding calcium at site II

One- and two-dimensional NMR techniques were used to study both the influence of mutations on the structure of recombinant normal cardiac troponin C (cTnC3) and the conformational changes induced by Ca2+ binding to site II, the site responsible for triggering muscle contraction. Spin systems of the nine Phe and three Tyr residues were elucidated from DQF-COSY and NOESY spectra. Comparison of the pattern of NOE connectivities obtained from a NOESY spectrum of cTnC3 with a model of cTnC based on the crystal structure of skeletal TnC permitted sequence-specific assignment of all three Tyr residues, as well as Phe-101 and Phe-153. NOESY spectra and calcium titrations of cTnC3 monitoring the aromatic region of the 1H NMR spectrum permitted localization of six of the nine Phe residues to either the N- or C-terminal domain of cTnC3. Analysis of the downfield-shifted C alpha H resonances permitted sequence-specific assignment of those residues involved in the beta-strand structures which are part of the Ca(2+)-binding loops in both the N- and C-terminal domains of cTnC3. The short beta-strands in the N-terminal domain of cTnC3 were found to be present and in close proximity even in the absence of Ca2+ bound at site II. Using these assignments, we have examined the effects of mutating Asp-65 to Ala, CBM-IIA, a functionally inactive mutant which is incapable of binding Ca2+ at site II [Putkey, J.A., Sweeney, H. L., & Campbell, S. T. (1989) J. Biol. Chem. 264, 12370]. Comparison of the apo, Mg(2+)-, and Ca(2+)-bound forms of cTnC3 and CBM-IIA demonstrates that the inability of CBM-IIA to trigger muscle contraction is not due to global structural changes in the mutant protein but is a consequence of the inability of CBM-IIA to bind Ca2+ at site II. The pattern of NOEs between aromatic residues in the C-terminal domain is nearly identical in cTnC3 and CBM-IIA. Similar interresidue NOEs were also observed between Phe residues assigned to the N-terminal domain in the Ca(2+)-saturated forms of both cTnC3 and CBM-IIA. However, chemical shift changes were observed for the N-terminal Phe residues in CBM-IIA. This suggests that binding of Ca2+ to site II alters the chemical environment of the residues in the N-terminal hydrophobic cluster without disrupting the spatial relationship between the Phe residues located in helices A and D.     

Hybrid myosin light chains containing a calcium-specific site from troponin C.

Recombinant DNA approaches have allowed us to probe the mechanisms by which the regulatory light chains (RLCs) regulate myosin function by identifying the functional importance of specific regions of the RLC molecule. For example, we have demonstrated that the presence of high-affinity Ca2+/Mg(2+)-binding site in the N-terminal domain of the RLC is essential for the regulation of myosin-actin interaction [Reinach, F. C., Nagai, K. & Kendrick-Jones, J. (1986) Nature 322, 80-83]. To explore further the role of this metal-binding site in the RLC and generate an RLC with a Ca(2+)-specific site, we constructed four chicken skeletal muscle myosin regulatory light chain hybrid 'genes'. In these, the first domain containing the high-affinity Ca2+/Mg(2+)-binding site in the RLC was replaced with that containing the lower-affinity, Ca(2+)-specific, regulatory site from troponin C (TnC). In two of these hybrids, we replaced only the Ca(2+)-binding EF hand, while in the other two the EF hand and the N-terminal helix of TnC were transplanted. These hybrids were expressed in Escherichia coli in high yields and the purified proteins were used in calcium-binding experiments to assay the affinity and specificity of the sites and incorporated into scallop myosin to assay their regulatory behaviour. The results obtained show that the calcium-binding site from TnC, when transplanted into the RLC backbone, had a low affinity although most of its specificity appeared to be retained. As a result, although the TnC/RLC hybrids bound to scallop myosin and were able to activate the MgATPase activity of scallop acto-myosin, they were unable to regulate it. These results are in agreement with our previous findings that occupancy of the Ca2+/Mg2+ site in the RLC is essential for regulation. Our results suggest that the specificity and affinity of the calcium-binding site in troponin C is dependent on both intra- and inter-domain interactions within troponin C and that these latter interactions appear to be missing when this binding site is transplanted into the light chain backbone.     

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.     

In situ orientations of protein domains: troponin C in skeletal muscle fibers

A recently developed approach for mapping protein-domain orientations in the cellular environment was used to investigate the Ca(2+)-dependent structural changes in the tropomyosin/troponin complex on the actin filament that regulate muscle contraction. Polarized fluorescence from bifunctional rhodamine probes attached along four alpha helices of troponin C (TnC) was measured in permeabilized skeletal muscle fibers. In relaxed muscle, the N-terminal lobe of TnC is less closed than in crystal structures of the Ca(2+)-free domain, and its D helix is approximately perpendicular to the actin filament. In contrast to crystal structures of isolated TnC, the D and E helices are not collinear. On muscle activation, the N lobe orientation becomes more disordered and the average angle between the C helix and the filament changes by 32 degrees +/- 5 degrees. These results illustrate the potential of in situ measurements of helix and domain orientations for elucidating structure-function relations in native macromolecular complexes.     

Binding properties of the calcium-activated F2 isoform of Lethocerus troponin C

While in most muscles contraction is triggered by calcium effluxes, insect flight muscles are also activated by mechanical stretch. We are interested in understanding the role that the troponin C protein, usually the calcium sensor, plays in stretch activation. In the flight muscles of Lethocerus, a giant water bug often used as a model system, there are two isoforms of TnC, F1 and F2, present in an approximately 10:1 ratio. F1 TnC is responsible for activating the muscle following a stretch, whereas F2 TnC produces a sustained contraction, the magnitude of which depends on the concentration of Ca(2+) in the fiber. We have previously shown that F1 TnC binds only one Ca(2+) ion in its C-terminal domain and that interaction with troponin H, the insect ortholog of troponin I, is insensitive to Ca(2+). Here, we have studied the effect of Ca(2+) and Mg(2+) on the affinities of the interaction of F2 TnC with troponin H peptides. We show that the presence of two Ca(2+) ions, one in each of the globular domains, increases the affinity for TnH by at least 1 order of magnitude. The N lobe has a lower affinity for Ca(2+), but it is also sensitive to Mg(2+). The C lobe is insensitive to Mg(2+) as previously demonstrated by mutations of the individual EF-hands. The interaction with TnH seems also to have significant structural differences from that observed for the F1 TnC isoform. We discuss how our findings could account for stretch activation.     

Fourier transform infrared spectroscopic study on the binding of Mg2+ to a mutant Akazara scallop troponin C (E142Q)

Troponin C (TnC) is the Ca(2+)-binding regulatory protein of the troponin complex in muscle tissue. Vertebrate fast skeletal muscle TnCs bind four Ca(2+), while Akazara scallop (Chlamys nipponensis akazara) striated adductor muscle TnC binds only one Ca(2+) at site IV, because all the other EF-hand motifs are short of critical residues for the coordination of Ca(2+). Fourier transform infrared (FTIR) spectroscopy was applied to study coordination structure of Mg(2+) bound in a mutant Akazara scallop TnC (E142Q) in D(2)O solution. The result showed that the side-chain COO(-) groups of Asp 131 and Asp 133 in the Ca(2+)-binding site of E142Q bind to Mg(2+) in the pseudo-bridging mode. Mg(2+) titration experiments for E142Q and the wild-type of Akazara scallop TnC were performed by monitoring the band at about 1600 cm(-1), which is due to the pseudo-bridging Asp COO(-) groups. As a result, the binding constants of them for Mg(2+) were the same value (about 6 mM). Therefore, it was concluded that the side-chain COO(-) group of Glu 142 of the wild type has no relation to the Mg(2+) ligation. The effect of Mg(2+) binding in E142Q was also investigated by CD and fluorescence spectroscopy. The on-off mechanism of the activation of Akazara scallop TnC is discussed on the basis of the coordination structures of Mg(2+) as well as Ca(2+).     

Reconstitution of the photosystem II Ca2+ binding site

The roles of Ca(2+) in H(2)O oxidation may be as a site of substrate binding, and as a structural component of the photosystem II O(2)-evolving complex. One indication of this dual role of the metal is revealed by probing the Mn cluster in the Ca(2+) depleted O(2) evolving complex that retains extrinsic 23- and 17-kDa polypeptides with reductants (NH(2)OH and hydroquinone) [Biochemistry 41 (2002) 958]. Calcium appears to bind to photosystem II at a site where it could bind substrate H(2)O. Equilibration of Ca(2+) with this binding site is facilitated by increased ionic strength, and incubation of Ca(2+) reconstitution mixtures at 22 degrees C accelerates equilibration of Ca(2+) with the site. The Ca(2+) reconstituted enzyme system regains properties of unperturbed photosystem II: Sensitivity to NH(2)OH inhibition is decreased, and Cl(-) binding with increased affinity can be detected. The ability of ionic strength and temperature to facilitate rebinding of Ca(2+) to the intact O(2) evolving complex suggests that the structural environment of the oxidizing side of photosystem II may be flexible, rather than rigid.     

Temperature dependence of dynamics and thermodynamics of the regulatory domain of human cardiac troponin C

Binding of Ca(2+) to the regulatory domain of troponin C (TnC) in cardiac muscle initiates a series of protein conformational changes and modified protein-protein interactions that initiate contraction. Cardiac TnC contains two Ca(2+) binding sites, with one site being naturally defunct. Previously, binding of Ca(2+) to the functional site in the regulatory domain of TnC was shown to lead to a decrease in conformational entropy (TDeltaS) of 2 and 0.5 kcal mol(-1) for the functional and nonfunctional sites, respectively, using (15)N nuclear magnetic resonance (NMR) relaxation studies [Spyracopoulos, L., et al. (1998) Biochemistry 37, 18032-18044]. In this study, backbone dynamics of the Ca(2+)-free regulatory domain are investigated by backbone amide (15)N relaxation measurements at eight temperatures from 5 to 45 degrees C. Analysis of the relaxation measurements yields an order parameter (S(2)) indicating the degree of spatial restriction for a backbone amide H-N vector. The temperature dependence of S(2) allows estimation of the contribution to protein heat capacity from pico- to nanosecond time scale conformational fluctuations on a per residue basis. The average heat capacity contribution (C(p,j)) from backbone conformational fluctuations for regions of secondary structure for the regulatory domain of cardiac apo-TnC is 6 cal mol(-1) K(-1). The average heat capacity for Ca(2+) binding site 1 is larger than that for site 2 by 1.3 +/- 0.8 cal mol(-1) K(-1), and likely represents a mechanism where differences in affinity between Ca(2+) binding sites for EF hand proteins can be modulated.     

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.     

Functional importance of Ca2+-deficient N-terminal lobe of molluscan troponin C in troponin regulation

Ca(2+)-binding sites I and II in the N-terminal lobe of molluscan troponin C (TnC) have lost the ability to bind Ca(2+) due to substitutions of the amino acid residues responsible for Ca(2+) liganding. To evaluate the functional importance of the Ca(2+)-deficient N-terminal lobe in the Ca(2+)-regulatory function of molluscan troponin, we constructed chimeric TnCs comprising the N-terminal lobes from rabbit fast muscle and squid mantle muscle TnCs and the C-terminal lobe from akazara scallop TnC, TnC(RA), and TnC(SA), respectively. We characterized their biochemical properties as compared with those of akazara scallop wild-type TnC (TnC(AA)). According to equilibrium dialysis using (45)Ca(2+), TnC(RA), and TnC(SA) bound stoichiometrically 3 mol Ca(2+)/mol and 1 mol Ca(2+)/mol, respectively, as expected from their primary structures. All the chimeric TnCs exhibited difference-UV-absorption spectra at around 280-290 nm upon Ca(2+) binding and formed stable complexes with akazara scallop troponin I, even in the presence of 6M urea, if Ca(2+) was present. However, when the troponin complexes were constructed from chimeric TnCs and akazara scallop troponin T and troponin I, they showed different Ca(2+)-regulation abilities from each other depending on the TnC species. Thus, the troponin containing TnC(SA) conferred as high a Ca(2+) sensitivity to Mg-ATPase activity of rabbit actomyosin-akazara scallop tropomyosin as did the troponin containing TnC(AA), whereas the troponin containing TnC(RA) conferred virtually no Ca(2+) sensitivity. Our findings indicate that the N-terminal lobe of molluscan TnC plays important roles in molluscan troponin regulation, despite its inability to bind Ca(2+).     

Calcium binding to the photosystem II subunit CP29

We have identified a Ca(2+)-binding site of the 29-kDa chlorophyll a/b-binding protein CP29, a light harvesting protein of photosystem II most likely involved in photoregulation. (45)Ca(2+) binding studies and dot blot analyses of CP29 demonstrate that CP29 is a Ca(2+)-binding protein. The primary sequence of CP29 does not exhibit an obvious Ca(2+)-binding site therefore we have used Yb(3+) replacement to analyze this site. Near-infrared Yb(3+) vibronic side band fluorescence spectroscopy (Roselli, C., Boussac, A., and Mattioli, T. A. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 12897-12901) of Yb(3+)-reconstituted CP29 indicated a single population of Yb(3+)-binding sites rich in carboxylic acids, characteristic of Ca(2+)-binding sites. A structural model of CP29 presents two purported extra-membranar loops which are relatively rich in carboxylic acids, one on the stromae side and one on the lumenal side. The loop on the lumenal side is adjacent to glutamic acid 166 in helix C of CP29, which is known to be the binding site for dicyclohexylcarbodiimide (Pesaresi, P., Sandonà, D., Giuffra, E. , and Bassi, R. (1997) FEBS Lett. 402, 151-156). Dicyclohexylcarbodiimide binding prevented Ca(2+) binding, therefore we propose that the Ca(2+) in CP29 is bound in the domain including the lumenal loop between helices B and C.     

Effects of cardiac thin filament Ca2+: statistical mechanical analysis of a troponin C site II mutant.

Cardiac thin filaments contain many troponin C (TnC) molecules, each with one regulatory Ca2+ binding site. A statistical mechanical model for the effects of these sites is presented and investigated. The ternary troponin complex was reconstituted with either TnC or the TnC mutant CBMII, in which the regulatory site in cardiac TnC (site II) is inactivated. Regardless of whether Ca2+ was present, CBMII-troponin was inhibitory in a thin filament-myosin subfragment 1 MgATPase assay. The competitive binding of [3H]troponin and [14C]CBMII-troponin to actin.tropomyosin was measured. In the presence of Mg2+ and low free Ca2+ they had equal affinities for the thin filament. When Ca274+ was added, however, troponin's affinity for the thin filament was 2.2-fold larger for the mutant than for the wild type troponin. This quantitatively describes the effect of regulatory site Ca2+ on troponin's affinity for actin.tropomyosin; the decrease in troponin-thin filament binding energy is small. Application of the theoretical model to the competitive binding data indicated that troponin molecules bind to interdependent rather than independent sites on the thin filament. Ca2+ binding to the regulatory site of TnC has a long-range rather than a merely local effect. However, these indirect TnC-TnC interactions are weak, indicating that the cooperativity of muscle activation by Ca2+ requires other sources of cooperativity.