Mutagenesis of cardiac troponin I. Role of the unique NH2-terminal peptide in myofilament activation

Phosphorylation of Ser residues in the NH2-terminal extension unique to cardiac troponin I (cTnI) is known to occur through protein kinase A and to alter myofilament Ca2+ activation (Robertson, S. P., Johnson, J. D., Holroyde, M. J., Kranias, E. G., Potter, J. D., and Solaro, R. J. (1982) J. Biol. Chem. 257, 260-263). Yet, how the NH2-terminal extension may itself affect thin filament Ca2+ signaling is unknown. To approach this question we have used molecular cloning, mutagenesis, and bacterial synthesis of a full-length cTnI and a truncated mutant (cTnI/NH2) missing the 32 amino acids. Using reconstituted preparations we could show no differences between cTnI and cTnI/NH2 either in inhibition of actomyosin ATPase activity, in Ca(2+)-reversible inhibitory activity, or in the relation between pCa and Ca2+ binding to the regulatory site of cTnC at either pH 7.0 or 6.5. There were also no significant differences at either pH in the pCa-MgATPase activity relation of myofibrils into which the various species of TnI has been exchanged. Our results indicate: 1) that phosphorylation most likely induces a new state of TnI activity rather than altering an intrinsic effect of the NH2-terminal peptide on Ca2+ activation; and 2) that domains outside the NH2-terminal extension are important with regard to differences in effects of acidic pH on Ca2+ activation on cardiac and skeletal myofilaments.     

Stepwise subunit interaction changes by mono- and bisphosphorylation of cardiac troponin I

Four phosphorylation degrees of cardiac troponin I (cTnI) have been characterized, namely, a dephospho, a bisphospho, and two monophospho states. Here we describe for the first time a role of the monophosphorylated forms. We have investigated the interaction between the cardiac troponin subunits dependent on the phosphorylation state of cTnI by surface plasmon resonance (SPR) spectroscopy. The monophosphorylated forms were generated by mutating each of the two serine residues, located in human cTnI at positions 22 and 23, to alanine. Association and dissociation rate constants of binary (cTnI-cTnT and cTnI-cTnC) and ternary (cTnI/cTnC complex-cTnT) complexes were determined. Mono- and consecutive bisphosphorylation of cTnI gradually reduces the affinity to cTnC and cTnT by lowering the association rate constants; the dissociation rate constants remain unchanged. Phosphorylation also affects formation of the ternary complexes; however, in this instance, association rate constants are constant, and dissociation rate constants are enhanced. A model of cardiac troponin is presented describing an induction of distinct conformational changes by mono- and bisphosphorylation of cTnI.     

Expression of regulated cardiac troponin I in Escherichia coli

The study of the functional effects of troponin isoform changes would be greatly aided by the development of a strategy permitting protein engineering and mutational analysis. To assess the role of troponin isoforms in regulating myofibrillar ATPase activity, we have expressed rat cardiac troponin I (cTnI) in E. coli and purified the protein to near homogeneity. We utilized the inducible expression vector pGEX-KG to create a glutathione-S-transferase fusion protein which can be cleaved with thrombin. Approximately 6 mg of cTnI can be purified from 1 l of culture. Ca2+Mg2+ ATPase activity was measured using the bacterially synthesized cTnI and the remaining components of the regulated actomyosin complex (troponin T, troponin C, tropomyosin, actin, and myosin) purified to homogeneity from mammalian hearts. In the presence of free Ca2+ ranging from 10(-2) to 10(-8) M, bacterially synthesized cTnI exhibits specific activity similar to that observed for control cTnI isolated from rat hearts. The bacterially synthesized protein is capable of stoichiometric phosphorylation and demonstrates appropriately regulated specific activity. These results establish the feasibility of using bacterial expression to study functional consequences of changes in expression of troponin isoforms.     

Troponin C modulates the activation of thin filaments by rigor cross-bridges

Extraction of troponin C (TnC) from skinned muscle fibers reduces maximum Ca2+ and rigor cross-bridge (RXB)-activated tensions and reduces cooperativity between neighboring regulatory units (one troponin-tropomyosin complex and the seven associated actins) of thin filaments. This suggests that TnC has a determining role in RXB, as well as in Ca(2+)-dependent activation processes. To investigate this possibility further, we replaced fast TnC (fTnC) of rabbit psoas fibers with either CaM[3,4TnC] or cardiac TnC (cTnC) and compared the effects of these substitutions on Ca2+ and RXB activation of tension. CaM[3,4TnC] substitution has the same effect on Ca(2+)- and RXB-activated tensions; they are reduced 50%, and cooperativity between regulatory units is reduced 40%. cTnC substitution also reduces the maximum Ca(2+)-activated tension and cooperativity. But with RXB activation the effects on tension and cooperativity are opposite; cTnC substitution potentiates tension but reduces cooperativity. We considered whether tension potentiation could be explained by increased activation by cycling cross-bridges (CXBs), but the concerted transition formalism predicts fibers will fail to relax in high substrate and high pCa when CXBs are activator ligands. It predicts resting tension, which is not observed in either control or cTnC-substituted fibers. Rather, it appears that cTnC facilitates RXB activation of fast fibers more effectively than fTnC. The order of RXB-activated tension facilitation is cTnC > fTnC > CaM[3,4TnC] > empty TnC-binding sites. Comparison of the structures of fTnC, CaM[3,4TnC], and cTnC indicates that the critical region for this property lies in the central helix or N-terminal domain, including EF hand motifs 1 and 2.     

Mutations in the cardiac troponin I gene associated with hypertrophic cardiomyopathy

Hypertrophic cardiomyopathy (HCM), the most common cause of sudden death in the young, is an autosomal dominant disease characterized by ventricular hypertrophy accompanied by myofibrillar disarrays. Linkage studies and candidate-gene approaches have demonstrated that about half of the patients have mutations in one of six disease genes: cardiac beta-myosin heavy chain (c beta MHC), cardiac troponin T (cTnT), alpha-tropomyosin (alpha TM), cardiac myosin binding protein C (cMBPC), ventricular myosin essential light chain (vMLC1) and ventricular myosin regulatory light chain (vMLC2) genes. Other disease genes remain unknown. Because all the known disease genes encode major contractile elements in cardiac muscle, we have systematically characterized the cardiac sarcomere genes, including cardiac troponin I (cTnI), cardiac actin (cACT) and cardiac troponin C (cTnC) in 184 unrelated patients with HCM and found mutations in the cTnI gene in several patients. Family studies showed that an Arg145Gly mutation was linked to HCM and a Lys206Gln mutation had occurred de novo, thus strongly suggesting that cTnI is the seventh HCM gene.     

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.     

Structural determinants of Ca2+ exchange and affinity in the C terminal of cardiac troponin C

The C terminal of cardiac troponin C (TnC) has two Ca2+-Mg2+ sites which exhibit approximately 20-fold higher Ca2+ affinity than the two C-terminal Ca2+ specific sites in calmodulin (CaM). Substitution of the third EF-hand of TnC for the corresponding EF-hand of CaM produced a mutant (CaM[3TnC]) with a 10-fold higher C-terminal Ca2+ and Mg2+ affinity. Substitution of loop 3 of TnC for loop 3 of CaM produced a mutant (CaM[loop3TnC]) with a 10-fold faster Ca2+ on rate and a 5-fold faster Ca2+ off rate than CaM. A mutant CaM (CaM[loop3X, Z]) which contained the identical coordinating amino acids and X and Z acid pairs of TnC loop 3 had a 3-fold higher C-terminal Ca2+ affinity without the increased Ca2+ exchange rates exhibited by CaM[loop3TnC]. Thus, loop factors other than the acid pairs must be responsible for the rapid Ca2+ exchange rates of CaM[loop3TnC]. Helix 6 and helix 5 in the third EF-hand of TnC support the rapid Ca2+ on rate of TnC's loop 3 and produce an approximately 4-fold reduction in its Ca2+ off rate, explaining the high Ca2+ affinity of the third EF-hand of TnC. Exchanging loop 3 or helix 5 of TnC into CaM increased the Mg2+ affinity by decreasing the Mg2+ off rate. Our results are consistent with the high Ca2+ and Mg2+ affinity of the third EF-hand of TnC resulting from the two (X and Z) acid pairs in loop 3, coupled with the greater hydrophobicity of helix 6 and helix 5 compared to that of the third EF-hand of CaM.     

Slow skeletal troponin I gene transfer, expression, and myofilament incorporation enhances adult cardiac myocyte contractile function

The functional significance of the developmental transition from slow skeletal troponin I (ssTnI) to cardiac TnI (cTnI) isoform expression in cardiac myocytes remains unclear. We show here the effects of adenovirus-mediated ssTnI gene transfer on myofilament structure and function in adult cardiac myocytes in primary culture. Gene transfer resulted in the rapid, uniform, and nearly complete replacement of endogenous cTnI with the ssTnI isoform with no detected changes in sarcomeric ultrastructure, or in the isoforms and stoichiometry of other myofilament proteins compared with control myocytes over 7 days in primary culture. In functional studies on permeabilized single cardiac myocytes, the threshold for Ca2+-activated contraction was significantly lowered in adult cardiac myocytes expressing ssTnI relative to control values. The tension-Ca2+ relationship was unchanged from controls in primary cultures of cardiac myocytes treated with adenovirus containing the adult cardiac troponin T (TnT) or cTnI cDNAs. These results indicate that changes in Ca2+ activation of tension in ssTnI-expressing cardiac myocytes were isoform-specific, and not due to nonspecific functional changes resulting from overexpression of a myofilament protein. Further, Ca2+-activated tension development was enhanced in cardiac myocytes expressing ssTnI compared with control values under conditions mimicking the acidosis found during myocardial ischemia. These results show that ssTnI enhances contractile sensitivity to Ca2+ activation under physiological and acidic pH conditions in adult rat cardiac myocytes, and demonstrate the utility of adenovirus vectors for rapid and efficient genetic modification of the cardiac myofilament for structure/function studies in cardiac myocytes.     

Oligomerization and divalent ion binding properties of the S100P protein: a Ca2+/Mg2+-switch model

S100P is a 95 amino acid residue protein which belongs to the S100 family of proteins containing two putative EF-hand Ca2+-binding motifs. In order to characterize conformational properties of S100P in the presence and absence of divalent cations (Ca2+, Mg2+ and Zn2+) in solution, we have analyzed hydrodynamic and spectroscopic characteristics of wild-type and several variants (Y18F, Y88F and C85S) of S100P using equilibrium centrifugation, gel-filtration chromatography, circular dichroism and fluorescence spectroscopies. Analysis of the experimental data shows the following. (1) In agreement with the predictions there are two Ca2+-binding sites in the S100P molecule with different affinity; the high affinity binding site has an apparent binding constant of approximately 10(7) M-1 and the low affinity binding site has an apparent binding constant of approximately 10(4) M-1. (2) The high and low affinity Ca2+-binding sites are located in the C and N-terminal parts of the S100P molecule, respectively. (3) These C and N-terminal sites can also bind other divalent ions. The C-terminal site binds Zn2+ (with relatively low affinity approximately 10(3) M-1), but not Mg2+. The N-terminal site binds Mg2+ with the apparent binding constant approximately 10(2) M-1. (4) Binding of Ca2+ to the C-terminal site and binding of Mg2+ to the N-terminal site occur in the physiological concentration range of these ions (micromolar for Ca2+ and millimolar for Mg2+). (5) Oligomerization state of the S100P molecule appears to change upon addition of Ca2+. On the basis of these observations a plausible model for S100P as a Ca2+/Mg2+ switch has been proposed.     

NMR studies of Ca2+ binding to the regulatory domains of cardiac and E41A skeletal muscle troponin C reveal the importance of site I to energetics of the induced structural changes

Ca2+ binding to the N-domain of skeletal muscle troponin C (sNTnC) induces an "opening" of the structure [Gagné, S. M., et al. (1995) Nat. Struct. Biol. 2, 784-789], which is typical of Ca2+-regulatory proteins. However, the recent structures of the E41A mutant of skeletal troponin C (E41A sNTnC) [Gagné, S. M., et al. (1997) Biochemistry 36, 4386-4392] and of cardiac muscle troponin C (cNTnC) [Sia, S. K., et al. (1997) J. Biol. Chem. 272, 18216-18221] reveal that both of these proteins remain essentially in the "closed" conformation in their Ca2+-saturated states. Both of these proteins are modified in Ca2+-binding site I, albeit differently, suggesting a critical role for this region in the coupling of Ca2+ binding to the induced structural change. To understand the mechanism and the energetics involved in the Ca2+-induced structural transition, Ca2+ binding to E41A sNTnC and to cNTnC have been investigated by using one-dimensional 1H and two-dimensional {1H,15N}-HSQC NMR spectroscopy. Monitoring the chemical shift changes during Ca2+ titration of E41A sNTnC permits us to assign the order of stepwise binding as site II followed by site I and reveals that the mutation reduced the Ca2+ binding affinity of the site I by approximately 100-fold [from KD2 = 16 microM [sNTnC; Li, M. X., et al. (1995) Biochemistry 34, 8330-8340] to 1.3 mM (E41A sNTnC)] and of the site II by approximately 10-fold [from KD1 = 1.7 microM (sNTnC) to 15 microM (E41A sNTnC)]. Ca2+ titration of cNTnC confirms that cNTnC binds only one Ca2+ with a determined dissociation constant KD of 2.6 microM. The Ca2+-induced chemical shift changes occur over the entire sequence in cNTnC, suggesting that the defunct site I is perturbed when site II binds Ca2+. These measurements allow us to dissect the mechanism and energetics of the Ca2+-induced structural changes.     

Characterization of the single tyrosine containing troponin C from lungfish white muscle. Comparison with several fast skeletal muscle troponin C's from fish species

Troponin C molecules from fast skeletal muscle of the following fish species (trout, whiting, lungfish, tilapia, and cod) have been purified to homogeneity. Upon binding of Ca2+ or Mg2+, lungfish troponin C is the only troponin C from fish white muscle to show the typical increase of tyrosine fluorescence emission quantum yield reported for rabbit fast skeletal muscle troponin C. The increase of tyrosine fluorescence signal occurring upon Ca2+ and Mg2+ titration of lungfish troponin C has been used to determine the corresponding affinity constants. With K(Ca) = 7.0 10(7) M-1 and K(Mg) = 3.6 10(3) M-1, the sites probed by the tyrosine residue of lungfish troponin C are typical of the COOH-terminal domain of fast skeletal troponin C's. The amino acid sequencing of the tyrosine containing tryptic peptides has allowed us to position the single tyrosine residue at position 7 in the Ca2+ binding loop of the third site, in identical position to Tyr109 of troponin C from rabbit fast skeletal muscle. Metal ion binding studies followed by intrinsic fluorescence or Tb3+ luminescence indicate that the conformation of the structural domain of lungfish troponin C with one metal ion bound is close to the physiological conformation of this domain.     

Macrolides and drug interactions: review of the literature]

Annexin I is a member of the annexin family of calcium-dependent membrane binding proteins. The core domain of these proteins is similar in all annexins but the N-terminal domain is specific for each member. This domain is thought to regulate annexin function through phosphorylation. In annexin I, Ser-27 is one of the amino acids that can be phosphorylated by protein kinase C. Phosphorylations are thought to regulate some annexin I functions by increasing calcium requirement. Two mutants were prepared in this study: S27E and S27A proteins. The first mimics phosphorylation while the second prevents phosphorylation at residue 27. Wild-type annexin I and S27A mutant protein showed the same calcium dependence for phospholipid vesicles aggregation, while S27E mutant protein showed a higher calcium requirement and a low maximal extent of aggregation. By contrast, liposome binding and self-association required identical calcium concentrations for the wild-type and the two mutant proteins. To examine whether the regulation observed is due to modification of the N-terminal structure, we investigated conformational changes by using two approaches. Firstly we analysed proteinase sensibility. Limited proteolysis of the N-terminal tail showed similar patterns for the three proteins. Using drastic conditions of proteolysis, we observed strong resistance of the core domain to digestion in the presence of calcium. Secondly, since Ser-27 is located on the N-terminal domain that contains a tryptophan located at position 12, the fluorescence of this residue was analysed during Ca2+-binding of wild-type annexin I and S27E mutant protein. The results demonstrated that Ca2+ induces a slight change in the Trp environment of wild-type annexin I, corresponding to a burying of the residue. No changes in fluorescence features were observed with S27E mutant protein. The results obtained show that phosphorylation of the N-terminal tail plays a regulatory role in phospholipid vesicle aggregation, which is based on a mechanism distinct from protein self-association. This phosphorylation induces a conformational change in the tail probably related to aggregation property.     

Reduced positive feedback regulation between myosin crossbridge and cardiac troponin C in fast skeletal myofibrils

Several studies have shown that substitution of cardiac troponin C into fast skeletal muscle causes a marked reduction in cooperativity of Ca(2+)-activation of both myofibrillar ATPase and tension development. To clarify the underlying mechanisms, in the present study, Ca2+ binding to cardiac troponin C inserted into fast skeletal myofibrils was measured. Two classes of binding sites with different affinities (classes 1 and 2) were clearly identified, which were equivalent stoichiometrically to the two high-affinity sites (sites III and IV) and a single low-affinity site (site II) of troponin C, respectively. Ca2+ binding to class-2 sites and Ca(2+)-activation of myofibrillar ATPase occurred in roughly the same Ca2+ concentration range, indicating that site II is responsible for Ca2+ -regulation. Myosin crossbridge interactions with actin, both in the presence and absence of ATP, enhanced the Ca2+ binding affinity of only class-2 sites. These effects of myosin crossbridges, however, were much smaller than the effects on the Ca2+ binding to the low-affinity sites of fast skeletal troponin C, which are responsible for regulating fast skeletal myofibrillar ATPase. These findings provide strong evidence that the reduction in the cooperative response to Ca2+ upon substituting cardiac troponin C into fast skeletal myofibrils is due to a decrease in the positive feedback interaction between myosin crossbridge attachment and Ca2+ binding to the regulatory site of troponin C.     

Epitope mapping of anti-troponin I monoclonal antibodies

Two groups of monoclonal antibodies (MAbs) specific to human cardiac troponin I (cTnI) were generated by immunization of mice by isolated cTnI (group I, 16 MAbs) or by the whole troponin complex (group II, 15 MAbs). Two sets of overlapping decapeptides covering the complete sequence of cTnI were prepared and used for epitope mapping by SPOT technique. Majority of MAbs (28 out of 31) interacts with synthetic peptides thus indicating that they recognize liner epitopes. MAbs raised against isolated cTnI preferentially recognize epitopes located at the N- or C-terminal ends of cTnI. Nine out of fifteen MAbs raised against whole troponin complex interact with epitopes located in the N-terminal part of cTnI. Generation of MAbs recognizing both isolated cTnI and cTnI inside of troponin complex and mapping their epitopes provides reliable detection of TnI in serum of patients with acute myocardial infarction.     

Phosphorylation of contractile proteins in heart and skeletal muscle

Contractile performance of cardiac and skeletal muscles may be regulated by cyclic AMP or Ca2+, two second messengers that stimulate the phosphorylation of specific myofibrillar proteins. Cyclic AMP-dependent protein kinase catalyzed the rapid phosphorylation of a single site in the inhibitory subunit of cardiac troponin in vitro and in perfused hearts. Skeletal muscle troponin was not phosphorylated by this enzyme in vivo. Although there was a correlation between cardiac troponin phosphorylation and the positive inotropic response to catecholamines, a biochemical mechanism that could account for a functional relationship between the two processes has not been discovered. Phosphorylation of skeletal muscle myosin was catalyzed by myosin light chain kinase in the presence of Ca2+ and the ubiguitous, multifunctional Ca2+-dependent regulator protein (CDR). The activation of kinase activity appeared to proceed via a trimolecular reaction process in which Ca2+ bound to CDR and the Ca2+.CDR complex then interacted with the enzyme. In rat extensor digitorum longus muscle, a 1 sec tetanic contraction resulted in phosphorylation of myosin light chain with the maximal phosphate incorporated 20 sec after the contraction. The light chain phosphate content declined slowly and correlated to post-tetanic potentiation of isometric twitch tension. Phosphorylation of skeletal muscle myosin may be important in modulating contraction.     

Cardiac troponin I phosphorylation increases the rate of cardiac muscle relaxation

Cardiac troponin (Tn) I (CTnI), compared with skeletal TnI, contains extra amino acids (32 to 33) at its amino terminus, including two adjacent serine residues. These two serine residues are believed to be phosphorylated by protein kinase A (PKA) upon stimulation of the heart by beta-agonists. In this study, we found that phosphorylation of a cardiac skinned muscle preparation by PKA, mainly at CTnI, results in a decrease in the Ca2+ sensitivity of muscle contraction. The pCa50 decreased by approximately 0.27 +/- 0.06 pCa units upon phosphorylation. To study cardiac muscle relaxation, we used diazo-2, a photolabile Ca2+ chelator with a low Ca2+ affinity in its intact form that is converted to a high-affinity form after photolysis. We found that the rate of cardiac muscle relaxation increased from a time of half-relaxation (t1/2) = 110 +/- 10 milliseconds to t1/2 = 70 +/- 8 milliseconds after CTnI phosphorylation. This result demonstrates that CTnI phosphorylation can be linked with the increased rate of muscle relaxation in a relatively intact muscle preparation. Since CTnI phosphorylation has been shown previously to affect the Ca2+ affinity and Ca2+ off-rate of CTnC in vitro, it is likely that the faster relaxation seen here reflects faster dissociation of Ca2+ from cardiac TnC (CTnC). Model calculations show that increased dissociation of Ca2+ from CTnC, coupled with the faster uptake of Ca2+ by the sarcoplasmic reticulum stimulated by PKA phosphorylation of phospholamban, can account for the faster relaxation seen in the inotropic response of the heart to catecholamines.     

Effect of stress-like concentrations of cortisol on gonadotroph function in orchidectomized sheep

The effects of the small noncatalytic subunit of myosin light chain phosphatase (MLCPsr) on the Ca2+-induced contraction of smooth muscle were investigated in the Triton X-100-permeabilized porcine renal artery. The full-length recombinant chicken MLCPsr obtained by the bacterial expression system induced an additional contraction at a constant [Ca2+]i and shifted the [Ca2+]i-force relation curve to the left. A deletion mutant containing the N-terminal 78 amino acids of MLCPsr retained the full action, compared with the full-length MLCPsr, while the deletion of this region completely abolished its effect. The process of relaxation was also delayed by the fragment containing the N-terminal 78 amino acids. These results indicated that MLCPsr increases the Ca2+ sensitivity of the contractile apparatus while the N-terminal 78 amino acids are responsible for this effect in vascular smooth muscle.     

Plasma selenium in patients with cirrhosis

S100B(betabeta) is a dimeric Ca2+-binding protein that is known to inhibit the protein kinase C (PKC)-dependent phosphorylation of several proteins. To further characterize this inhibition, we synthesized peptides based on the PKC phosphorylation domains of p53 (residues 367-388), neuromodulin (residues 37-53), and the regulatory domain of PKC (residues 19-31), and tested them as substrates for PKC. All three peptides were shown to be good substrates for the catalytic domain of PKC. As for full-length p53 (Baudier J, Delphin C, Grunwald D, Khochbin S, Lawrence JJ. 1992. Proc Natl Acad Sci USA 89:11627-11631), S100B(betabeta) binds the p53 peptide and inhibits its PKC-dependent phosphorylation (IC50 = 10 +/- 7 microM) in a Ca2+-dependent manner. Similarly, phosphorylation of the neuromodulin peptide and the PKC regulatory domain peptide were inhibited by S100B(betabeta) in the presence of Ca2+ (IC50 = 17 +/- 5 microM; IC50 = 1 +/- 0.5 microM, respectively). At a minimum, the C-terminal EF-hand Ca2+-binding domain (residues 61-72) of each S100beta subunit must be saturated to inhibit phosphorylation of the p53 peptide as determined by comparing the Ca2+ dependence of inhibition ([Ca]IC50 = 29.3 +/- 17.6 microM) to the dissociation of Ca2+ from the C-terminal EF-hand Ca2+-binding domain of S100B(betabeta).     

The active state of the thin filament is destabilized by an internal deletion in tropomyosin

The function of three of tropomyosin's sequential quasiequivalent regions was studied by deletion from skeletal muscle alpha-tropomyosin of internal residues 49-167. This deletion mutant tropomyosin spans four instead of the normal seven actins, and most of the tropomyosin region believed to interact with troponin is retained and uninterrupted in the mutant. The mutant tropomyosin was compared with a full-length control molecule that was modified to functionally resemble muscle tropomyosin (Monteiro, P. B., Lataro, R. C., Ferro, J. A., and Reinach, F. C. (1994) J. Biol. Chem. 269, 10461-10466). The tropomyosin deletion suppressed the actin-myosin subfragment 1 MgATPase rate and the in vitro sliding of thin filaments over a heavy meromyosin-coated surface. This inhibition was not reversed by troponin plus Ca2+. Comparable tropomyosin affinities for actin, regardless of the deletion, suggest that the deleted region has little interaction with actin in the absence of other proteins. Similarly, the deletion did not weaken binding of the troponin-tropomyosin complex to actin. Furthermore, Ca2+ had a 2-fold effect on troponin-tropomyosin's affinity for actin, regardless of the deletion. Notably, the deletion greatly weakened tropomyosin binding to myosin subfragment 1-decorated actin, with the full-length tropomyosin having a 100-fold greater affinity. The inhibitory properties resulting from the deletion are attributed to defective stabilization of the myosin-induced active state of the thin filament.