Roles of troponin isoforms in pH dependence of contraction in rabbit fast and slow skeletal and cardiac muscles.

Skinned fibers prepared from rabbit fast and slow skeletal and cardiac muscles showed acidotic depression of the Ca2+ sensitivity of force generation, in which the magnitude depends on muscle type in the order of cardiac>fast skeletal>slow skeletal. Using a method that displaces whole troponin-complex in myofibrils with excess troponin T, the roles of Tn subunits in the differential pH dependence of the Ca2+ sensitivity of striated muscle were investigated by exchanging endogenous troponin I and troponin C in rabbit skinned cardiac muscle fibres with all possible combinations of the corresponding isoforms expressed in rabbit fast and slow skeletal and cardiac muscles. In fibers exchanged with fast skeletal or cardiac troponin I, cardiac troponin C confers a higher sensitivity to acidic pH on the Ca2+ sensitive force generation than fast skeletal troponin C independently of the isoform of troponin I present. On the other hand, fibres exchanged with slow skeletal troponin I exhibit the highest resistance to acidic pH in combination with either isoform of troponin C. These results indicate that troponin C is a determinant of the differential pH sensitivity of fast skeletal and cardiac muscles, while troponin I is a determinant of the pH sensitivity of slow skeletal muscle.     

Troponin from the myocardium and skeletal muscles: structure and properties

The literary and experimental data on the structure and properties of cardiac and skeletal muscle troponin are reviewed. The cation--binding sites of cardiac and skeletal muscle troponin C are distinguished by specificity; the sites localized in the C-terminal part of the protein molecule can bind both Ca2+ and Mg2+, whereas the sites localized at the N-end specifically bind Ca2+. The use of bifunctional reagents revealed a number of helical sites within the structure of cardiac troponin C (residues 84-92 and 150-158) and of skeletal muscle troponin C (residues 90-98 and 125-136). A comparison of experimental data with the results of an X-ray analysis testifies to the presence in the central part of the troponin C molecule of a long alpha-helical sequence responsible for troponin C interaction with the inhibiting peptide of troponin I. The efficiency of interaction of troponin components depends on Ca2+ concentration; the integrity of the overall troponin complex is mainly provided for by troponin C interaction with troponin I and by troponin I interaction with troponin T. The interaction between troponins T and C is relatively weak, especially in the case of cardiac troponin components. Both skeletal and cardiac muscles synthesize several troponin T isoforms differing in length and amino acid composition of N-terminal 40-60 member peptides. Troponin T isoforms can undergo phosphorylation by several protein kinases. The single site of troponin T which exists in a phosphorylated state in vivo (residue Ser-1) undergoes phosphorylation by specific protein kinase (troponin T kinase) related to casein kinases II. It was assumed that the phosphorylation of Ser-1 residue of troponin T as well as the synthesis of troponin T isoforms differing in the structure of the N-terminal peptide, provides for the regulation of interaction between two neighbouring tropomyosin molecules.     

Phosphorylation of troponin in the heart and skeletal muscle by Ca2+-phospholipid-dependent protein kinase

The phosphorylation of the whole troponin complex and of the cardiac and skeletal troponin components by Ca2+-phospholipid-dependent protein kinase was studied. The activity of enzyme isolated from rat brain by ion-exchange chromatography on DEAE-Sephadex and by affinity chromatography on phosphatidylserine immobilized on polyacrylamide gel was shown to be completely dependent on Ca2+ and phospholipids and was equal to 0.4-0.6 mumol of phosphate/min.mg protein with histone H1 as substrate. The resulting preparation of Ca2+-phospholipid-dependent protein kinase was able to phosphorylate the isolated troponin I; the amount of phosphate transferred per mol of cardiac and skeletal troponin I was equal to 1.1 and 0.4, respectively. The maximal degree of phosphorylation of isolated troponin T by Ca2+-phospholipid-dependent protein kinase was 0.6 mol of phosphate per mol of troponin T both for skeletal and cardiac proteins. The rate and degree of phosphorylation were independent of the initial level of troponin T phosphorylation. Ca2+-phospholipid-dependent protein kinase did not phosphorylate the first serine residue of troponin T, i.e., the site which was phosphorylated in the highest degree after isolation of troponin T from skeletal muscles. The data obtained and the fact that the rate and degree of phosphorylation of troponins I and T within the whole troponin complex are 10-20 times less than those for isolated components provide little evidence for the participation of protein kinase C in troponin phosphorylation in vivo.     

RESOLUTION OF BRAIN TROPONIN COMPLEX

Affinity chromatography was used to partially purify the troponin complex from crude regulatory proteins obtained from bovine brain cortex. Three components were obtained from this partially purified troponin complex by treatment with 6 M-urea and 1 mM-EGTA followed by chromatography on DEAE-Sephadex-A50. The effects of the three components on skeletal muscle actin activated MgATPase activity of muscle myosin (ATP phosphohydrolase, EC 3.6.1.3.) suggested that they were analogous to that of the skeletal muscle troponins I, C, and T. The apparent molecular weights of the brain troponin subunits (I, C, and T) were 18, 700, 14, 000 and 36, 400, respectively. The molecular weights of the former two proteins were less than those reported for the analogous skeletal muscle troponins. Thus, brain actomyosin complex may be regulated in a manner similar to that of striated muscle actomyosin.     

Separation and characterization of the troponin components from bovine cardiac muscle.

The three major components of bovine cardiac troponin were separated by successive chromatography on sulfopropyl-Sephadex and DEAE-Sephadex columns in the presence of 6 M urea. All three of the bovine cardiac troponin subunits were necessary to restore full troponin activity in both skeletal and cardiac actomyosin ATPase assay systems. The 38,000-dalton subunit bound tropomyosin, and the 20,000-dalton subunit bound calcium, like skeletal TN-T and TN-C, respectively. The 28,000 component, although presumably analogous to skeletal TN-I, gave very little inhibition of actomyosin ATPase activity. Differences between cardiac and skeletal troponin subunits were also found in the elution patterns from ion exchange columns and in amino acid composition, thus demonstrating a significant muscle-type specificity.     

Replacement of three troponin components with cardiac troponin components within single glycerinated skeletal muscle fibers.

The tension of single glycerinated rabbit skeletal muscle fiber was desensitized to a Ca(2+)-concentration after treatment with an excessive amount of bovine cardiac troponin T and reached a level of about 70% of the maximum tension of the untreated fiber. A SDS-gel electrophoretic examination indicated that troponin C.I.T complex in the fiber was replaced with the added cardiac troponin T. The Ca(2+)-sensitivity of the tension of the troponin T-treated fiber was then recovered by the addition of bovine cardiac troponins I and C. The rabbit skeletal muscle fiber thus hybridized with bovine cardiac troponin C.I.T showed the same cooperativity of Ca(2+)-activation as the cardiac muscle.     

The side chain of glutamine 13 is the acyl-donor amino acid modified by type 2 transglutaminase in subunit T of the native rabbit skeletal muscle troponin complex

Subunit T of the native muscle troponin complex is a recognised substrate of transglutaminase both in vitro and in situ with formation of isopeptide bonds. Using a proteomic approach, we have now determined the precise site of in vitro labelling of the protein. A preparation of troponin purified from ether powder from mixed rabbit skeletal muscles was employed as transglutaminase substrate. The only isoform TnT2F present in our preparation was recognised as acyl-substrate by human type 2 transglutaminase which specifically modified glutamine 13 in the N-terminal region. During the reaction, the troponin protein complex was polymerized. Results are discussed in relation to the structure of the troponin T subunit, in the light of the role of troponins in skeletal and cardiac muscle diseases, and to the rules governing glutamine side chain selection by tissue transglutaminase.     

Divalent cation binding properties of slow skeletal muscle troponin in comparison with those of cardiac and fast skeletal muscle troponins

1. New methods of preparing troponins from slow skeletal and cardiac muscle of the chicken have been developed. The electrophoretic mobilities of slow skeletal muscle troponin subunits were different from those of the corresponding fast skeletal muscle subunits. 2. A new method for determining the amount of divalent cations bound to troponin was developed. The principle of the method is to immobilize troponin by conjugating it with Sepharose 4B resin, thus making it readily sedimentable. 3. The numbers of Sr and Ca ions bound to slow muscle troponin at concentrations sufficient to produce maximum contraction were 1.73 and 1.36 mol per mol, respectively, being nearly equal to those of cardiac troponin but half of those of fast muscle troponin. 4. The concentrations of Sr and Ca ions giving half-maximal ion binding to slow muscle troponin (K50%) were 5.5 X 10(-6) M and 4.6 X 10(-7) M, respectively. 5. K50% for Sr of cardiac troponin was significantly higher than that of slow muscle troponin. Although K50% for Sr of cardiac troponin was the same as that of fast muscle troponin, cardiac troponin bound more Sr ions than fast muscle troponin at lower Sr ion concentrations. The mechanism underlying the high sensitivity of cardiac muscle contraction to Sr ions is discussed in comparison with that of slow muscle.     

Effect of removal and reconstitution of troponins C and I on the Ca(2+)-activated tension development of single glycerinated rabbit skeletal muscle fibers.

The effect of troponin T treatment on the Ca(2+)-activated tension of single glycerinated rabbit skeletal muscle fibers was examined. The tension of the fiber was completely desensitized to Ca2+ by incubation in a solution containing an excessive amount of troponin T and reached a level of about 70% of the maximum tension of the control fiber. SDS/PAGE showed that most of troponins C and I was removed from the fiber by troponin T treatment. During the course of troponin T treatment, the cooperativity of Ca2+ activation (Hill coefficient) was decreased while pCa at half-maximal Ca(2+)-sensitive tension (pK) increased. Using the 26-K fragment of troponin T, the study indicated that the removal of troponins C and I was due to the replacement of the troponin C.I.T complex in the myofibrils of the fiber with the added troponin T. The troponin-T-treated fiber was again sensitized to Ca2+ by the addition of troponin C.I. The removal of troponin C by treatment with trans-1,2-cyclohexanediamine-N,N,N',N'-tetraacetic acid did not change the minimum tension of the fiber, from which troponin C.I was partially removed by troponin T treatment, but it decreased the height of maximum tension with a concomitant decrease in the Hill coefficient as well as a decrease in pK. The above findings suggested that pK is determined by the balance between two opposite actions through troponins C and I, while the extent of cooperativity of Ca2+ activation seemed to be related mainly to the content of troponin C.     

Effect of Arg145Gly mutation in human cardiac troponin I on the ATPase activity of cardiac myofibrils

In order to determine the functional consequences of the Arg145Gly mutation in troponin I found in familial hypertrophic cardiomyopathy, human cardiac troponin I and its mutant were expressed in Escherichia coli and purified, and then their effects on the ATPase activity of porcine cardiac myofibrillar preparations from which both troponins C and I had been depleted were examined. Both the wild-type and mutant troponin Is suppressed the ATPase activity of the troponin C.I-depleted myofibrils, but the maximum inhibition caused by mutant troponin I was weaker than that by wild-type troponin I. In the Ca(2)(+)-activation profile of the myofibrillar ATPase activity after reconstitution with both troponins I and C, the Ca(2)(+)-sensitivity with mutant troponin I was higher than that with wild-type troponin I, whereas the maximum level of the ATPase activity with mutant troponin I was lower than that with wild-type troponin I. These findings strongly suggest that the Arg145Gly mutation in human cardiac troponin I modulates the Ca(2)(+)-regulation of contraction by impairing the interaction of troponin I with both actin-tropomyosin and troponin C.     

Calcium ion regulation of muscle contraction: The regulatory role of troponin T

The relaxation and contraction in vertebrate skeletal muscle are regulated by Ca2+ through troponin and tropomyosin, which are located in the thin filament. Troponin is composed of three components, troponins C, I and T. In this review article, the Ca2+-regulatory mechanism is discussed with particular reference to the regulatory properties of troponin T.     

Purification and characterization of cardiac tropomyosins.

A new procedure was developed to purify tropomyosin. The procedure was an adaptation of that described for purification of myosin. By eliminating troponin before precipitating with (NH4)2 SO4, it was possible to obtain pure tropomyosin from the same preparation from which myosin was purified. When tropomyosin was subjected to isoelectrofocusing two tropomyosins were present, having similar isoelectric points of pH 5.4 and 5.6; two tropomyosin subunits were resolved in the presence of 6 M urea. The two subunits had very similar isoelectric points, pH 4.7 and 5.0. According to Ouchterlony analyses the tropomyosins from canine skeletal and cardiac tissue were immunologically identical when incubated with goat gammaG antitropomyosin (cardiac).     

Sensitivity of actomyosin ATPase to calcium and strontium ions. Effect of hybrid troponins

1. Hybrid or reconstituted troponins were prepared from troponin components of rabbit skeletal muscle and porcine cardiac muscle and their effect on the actomyosin ATPase activity was measured at various concentrations of Ca2+ or Sr2+. The Ca2+ concentration required for half-maximum activation of actomyosin ATPase with troponin containing cardiac troponin I was slightly higher than that with troponin containing skeletal troponin I. The Sr2+ concentration required for half-maximum activation of actomyosin ATPase with troponin containing skeletal troponin C was higher than that with troponin containing cardiac troponin C. 2. Reconstituted cardiac troponin was phosphorylated by cyclic AMP-dependent protein kinase. The Ca2+ sensitivity of actomyosin ATPase with cardiac troponin decreased upon phosphorylation of troponin I; maximum ATPase activity was depressed and the Ca2+ concentration at half-maximum activation increased. On the other hand, phosphorylation of troponin I did not change Sr2+ sensitivity. 3. The inhibitory effect of cardiac troponin I on the actomyosin ATPase activity was neutralized by increasing the amount of brain calmodulin at high Ca2+ and Sr2+ concentrations but not at low concentrations. 4. ATPase activity of actomyosin with a mixture of troponin I and calmodulin was assayed at various concentrations of Ca2+ or Sr2+. The Ca2+ or Sr2+ sensitivity of actomyosin ATPase containing skeletal troponin I was approximately the same as that of actomyosin ATPase containing cardiac troponin I. Phosphorylation of cardiac troponin I did not change the Ca2+ sensitivity of the ATPase. 5. The Ca2+ or Sr2+ concentration required for half-maximum activation of actomyosin ATPase with troponin I-T-calmodulin was higher than that of actomyosin ATPase with the mixture of troponin I and calmodulin. Maximum ATPase activity was lower than that with the mixture of troponin I and calmodulin.     

Phosphorylation of isolated components of the troponin complex of skeletal and cardiac muscle phosphorylase kinase from bird skeletal muscles

Pigeon and chicken skeletal muscle phosphorylase kinase purified to a nearly homogeneous state is able to phosphorylate both cardiac and skeletal troponin I and T. After 1-hr incubation, the enzyme transfers up to 0.35 mole of phosphorus per mole of skeletal troponin I, up to 0.5 mole of cardiac troponin I and up to 0.1 mole of cardiac and skeletal troponin T. Avian muscle phosphorylase kinase does not phosphorylate the first serine residue of cardiac and skeletal troponin T, but catalyzes the phosphate incorporation into the site(s) of troponin T located in the central or C-terminal parts of the protein molecule. The rate of troponin phosphorylation by pigeon muscle phosphorylase kinase is pH-dependent: the 6.8/8.2 ratio for troponin I is close to 0,2, whereas that with troponin T varies in the range of 0.5-0.7. Troponin phosphorylation by avian phosphorylase kinase depends on the presence of Ca2+ in the incubation mixture. In the presence of 3 mM EGTA troponin I phosphorylation is inhibited by 70-90%, whereas that of troponin T--by 50%. The experimental results indicate that the phosphorylation of troponin I and T is catalyzed either by two different active centers or by different conformations of the single center of avian phosphorylase kinase.     

Cardiac tropomyosin crystals and their interactions with troponin subunits

Crystals and paracrystals of bovine cardiac tropomyosin and their mixtures with different combinations of troponin subunits were examined in the electron microscope after negative staining. Although the cardiac proteins gave most of the same crystalline and paracrystalline patterns as observed previously with skeletal muscle tropomyosin and troponin, two important differences were noted. Cardiac troponin T was incapable of forming hexagonal networks with either skeletal or cardiac muscle tropomyosins, while skeletal troponin T readily associated in this manner with tropomyosins from either tissue source. Also the characteristic paracrystalline pattern seen with skeletal muscle tropomyosin, troponin T and troponin C only in the presence of calcium was consistently obtained with mixtures of the corresponding cardiac components when calcium was absent.     

Purification and Characterization of Cardiac Tropomyosins

A new procedure was developed to purify tropomyosin. The procedure was an adaptation of that described for purification of myosin. By eliminating troponin before precipitating with (NH₄), SO₄ it was possible to obtain pure tropomyosin from the same preparation from which myosin was purified. When tropomyosin was subjected to isoelectrofocusing two tropomyosins were present, having similar isoelectric points of pH 5, 4 and 5.6; two tropomyosin subunits were resolved in the presence of 6 M urea. The two subunits had very similar isoelectric points, pH 4.7 and 5.0. According to Ouchterlony analyses the tropomyosins from canine skeletal and cardiac tissue were immunologically identical when incubated with goat γG antitropomyosin (cardiac).     

Two-dimensional electrophoresis of troponin complex with nonequilibrium pH gradient-sodium dodecyl sulfate polyacrylamide slab gel

A two-dimensional electrophoresis procedure for the separation and analysis of troponin subunits is described in which the protein solution supplemented with 50 mM each of both glutamic and aspartic acids is subjected to nonequilibrium pH gradient electrophoresis in the first dimension. Complete dissolution and gelation of the sample with agarose are essential for analysis of constituent proteins of cardiac myofibrils. Electrophoresis in the first dimension gel is carried out for a relatively short time, 2-3 h. In combination with sodium dodecyl sulfate slab gel electrophoresis (second dimension), three subunits, troponin T, troponin I, and troponin C, of dog cardiac troponin-tropomyosin complex and myofibrils can be simultaneously analyzed quantitatively on a slab gel. The contents of troponin and tropomyosin of cardiac myofibrils were 275 +/- 34 pmol/mg of myofibrillar protein. The molar ratio of troponin T, troponin I, troponin C, and tropomyosin was close to 1 : 1 : 1 : 1 in troponin-tropomyosin complex and myofibrils.     

Structure and regulation of human troponin genes

The recent completion of a first draft of the human genome has allowed "in silico" genome browsing to become routine. Such computer-based research is now a useful adjunct to experiments based at the bench, and is accelerating gene discovery and the analysis and understanding of genes in their genomic contexts. This review summarises recent findings on genes encoding proteins of the troponin complex. We describe the organization of the three pairs of genes which encode isoforms of troponins I and T, and discuss how this relates to their evolution and regulation. Detailed analysis of the chromosomal context of the cardiac troponin I and slow skeletal troponin T genes reveals a region of densely packed differentially expressed genes, including new genes identified by automatic genome annotation. This information is discussed within the context of detailed analysis of the best-studied gene in this region, cardiac troponin I. In this way, we illustrate the uses to which a combination of conventional bench experiments and "in silico" analyses may be put in understanding the relationship between structure and function within the genome.     

Role of troponin I isoform switching in determining the pH sensitivity of Ca(2+) regulation in developing rabbit cardiac muscle

Skinned muscle fibers prepared from fetal rabbit heart (28 days of gestation) showed a marked resistance to acidic pH in the Ca(2+) regulation of force generation, compared to the fibers prepared from adult heart. SDS-PAGE and immunoblot analysis showed that the slow skeletal troponin I was predominantly expressed in the fetal cardiac muscle, while the cardiac isoform was predominantly expressed in the adult cardiac muscle. Direct exchange of purified slow skeletal and cardiac troponin I isoforms into these skinned muscle fibers revealed that cardiac troponin I made the Ca(2+) regulation of contraction sensitive to acidic pH just as in the adult fibers, whereas slow skeletal troponin I made the Ca(2+) regulation of contraction resistant to acidic pH just as in the fetal fibers. These results demonstrate that the troponin I isoform switching accounts fully for the change in the pH dependence of Ca(2+) regulation of contraction in developmental cardiac muscle.     

Elucidation of isoform-dependent pH sensitivity of troponin i by NMR spectroscopy

Myocardial ischemia is characterized by reduced blood flow to cardiomyocytes, which can lead to acidosis. Acidosis decreases the calcium sensitivity and contractile efficiency of cardiac muscle. By contrast, skeletal and neonatal muscles are much less sensitive to changes in pH. The pH sensitivity of cardiac muscle can be reduced by replacing cardiac troponin I with its skeletal or neonatal counterparts. The isoform-specific response of troponin I is dictated by a single histidine, which is replaced by an alanine in cardiac troponin I. The decreased pH sensitivity may stem from the protonation of this histidine at low pH, which would promote the formation of electrostatic interactions with negatively charged residues on troponin C. In this study, we measured acid dissociation constants of glutamate residues on troponin C and of histidine on skeletal troponin I (His-130). The results indicate that Glu-19 comes in close contact with an ionizable group that has a pK(a) of ～6.7 when it is in complex with skeletal troponin I but not when it is bound to cardiac troponin I. The pK(a) of Glu-19 is decreased when troponin C is bound to skeletal troponin I and the pK(a) of His-130 is shifted upward. These results strongly suggest that these residues form an electrostatic interaction. Furthermore, we found that skeletal troponin I bound to troponin C tighter at pH 6.1 than at pH 7.5. The data presented here provide insights into the molecular mechanism for the pH sensitivity of different muscle types.