Mg-ATPase and CA2+ activated myosin ATPase activity in ventricular myofibrils from non-failing and diseased human hearts – effects of calcium sensitizing agents MCI-154, DPI 201–106, and caffeine

We investigated the effects of two purported calcium sensitizing agents, MCI-154 and DPI 201–106, and a known calcium sensitizer caffeine on Mg-ATPase (myofibrillar ATPase) and myosin ATPase activity of left ventricular myofibrils isolated from non-failing, idiopathic (IDCM) and ischemic cardiomyopathic (ISCM) human hearts (i.e. failing hearts). The myofibrillar ATPase activity of non-failing myofibrils was higher than that of diseased myofibrils. MCI-154 increased myofibrillar ATPase Ca²⁺ sensitivity in myofibrils from non-failing and failing human hearts. Effects of caffeine similarly increased Ca²⁺ sensitivity. Effects of DPI 201–106 were, however, different. Only at the 10^–6 M concentration was a significant increase in myofibrillar ATPase calcium sensitivity seen in myofibrils from non-failing human hearts. In contrast, in myofibrils from failing hearts, DPI 201–106 caused a concentration-dependent increase in myofibrillar ATPase Ca²⁺ sensitivity. Myosin ATPase activity in failing myocardium was also decreased. In the presence of MCI-154, myosin ATPase activity increased by 11, 19, and 24% for non-failing, IDCM, and ISCM hearts, respectively. DPI 201–106 caused an increase in the enzymatic activity of less than 5% for all preparations, and caffeine induced an increase of 4, 11, and 10% in non-failing, IDCM and ISCM hearts, respectively. The mechanism of restoring the myofibrillar Ca²⁺ sensitivity and myosin enzymatic activity in diseased human hearts is most likely due to enhancement of the Ca²⁺ activation of the contractile apparatus induced by these agents. We propose that myosin light chain-related regulation may play a complementary role to the troponin-related regulation of myocardial contractility.     

Troponin subunits contribute to altered myosin ATPase activity in diabetic cardiomyopathy

Our group has documented that myocardial performance is impaired in the hearts of chronically diabetic rats and rabbits. Abnormalities in the contractile proteins and regulatory proteins may be responsible for the mechanical defects in the streptozotocin (STZ)-diabetic hearts. Previously, the major focus of our research on contractile proteins in abnormal states has concentrated on myosin ATPase and its isoenzymes. Our present study is based on the overall hypothesis that regulatory proteins, in addition to contractile protein, myosin contribute to altered cardiac contractile performance in the rat model of diabetic cardiomyopathy. The purpose of our research was to define the role of cardiac regulatory proteins (troponin-tropomyosin) in the regulation of actomyosin system in diabetic cardiomyopathy.For baseline data, myofibrillar ATPase studies were conducted in the myofibrils from control and diabetic rats. To focus on the regulatory proteins (troponin and tropomyosin), individual proteins of the cardiac system were reconstituted under controlled conditions. By this approach, myosin plus actin and troponin-tropomyosin from the normal and diabetic animals could be studied enzymatically. The proteins were isolated from the cardiac muscle of control and STZ-diabetic (4 weeks) rats. Sodium dodecyl sulfate gel electrophoretic patterns demonstrate differences in the cardiac TnT and TnI regions of diabetic animals suggesting the different amounts of TnT and/or TnI or possibly different cardiac isozymes in the regulatory protein complex. Myofibrils probed with a monoclonal antibody TnI-1 (specific for adult cardiac TnI) show a downregulation of cardiac TnI in diabetics when compared to its controls. Enzymatic data confirm a diminished calcium sensitivity in the regulation of the cardiac actomyosin system when regulatory protein(s) complex was recombined from diabetic hearts. Actomyosin ATPase activity in the hearts of diabetic animals was partially reversed when myosin from diabetic rats was regulated with the regulatory protein complex isolated from control hearts. To our knowledge, this is the first study which demonstrates that the regulatory proteins from normal hearts can upregulate cardiac myosin isolated from a pathologic rat model of diabetes. This diminished calcium sensitivity along with shifts in cardiac myosin heavy chain (V1V3) may be partially responsible for the impaired cardiac function in the hearts of chronic diabetic rats. (Mol Cell Biochem151: 165–172, 1995)     

Changes in myocardial contractile protein ATPases in chronically adrenalectomized rats with and without glucocorticoid replacement

Studies were conducted to examine the effects of chronic adrenalectomy (Adx) and adrenalectomy plus glucocorticoid replacement therapy on rat cardiac contractile protein ATPase activities. The Ca2+-dependent Mg-ATPase activity of myofibrils isolated from rat ventricles 3 weeks postadrenalectomy (Adx) was significantly decreased at all pCa2+ concentrations (P less than 0.01), compared to sham-operated (SO) rats. Similarly, Ca2+-, K+-EDTA, and actin-activated myosin ATPase activities of Adx rat hearts were markedly decreased below that of SO rats (P less than 0.01). Dexamethasone administration to Adx rats prevented the decrease of Ca2+- and K+-ATPase activities of myosin, but not of myofibrillar Ca2+-dependent Mg-ATPase or actin-activated myosin Mg-ATPase activities. These studies suggest that glucocorticoid insufficiency induced by adrenalectomy results in altered myocardial contractile protein ATPase activity which may underlie impaired cardiac performance.     

The exchange of Ca2+-receptive protein complex (troponin) in the myofibrils of fast and slow skeletal muscles

In order to compare the role of the Ca²⁺-receptive protein (troponin), in the characteristic myofibrillar contractile response of chicken fast and slow skeletal muscles, the troponin in both kinds of myofibrils were partially exchanged, under slightly acidic conditions. The Ca²⁺- or Sr²⁺-activation of the ATPase of fast (or slow) skeletal myofibrils hybridized with slow (or fast) skeletal troponin profiles were also investigated. The results indicated that the Ca²⁺- or Sr²⁺-affinity of the myofibrillar ATPase activity were related to the species of troponin. This procedure for replacing troponin in myofibrils under physiological conditions in thus considered to be useful for the study of the Ca²⁺-regulatory mechanism in myofibrillar contraction.     

Effects of acute and chronic ethanol on cardiac contractile protein ATPase activity of Syrian hamsters

Ethanol consumption is known to affect cardiac and skeletal muscle. In vivo experiments on cardiac muscle showed that ethanol affects cardiac contractility and Vmax, suggesting that contractile proteins of the myocardium were affected by ethanol. Therefore, experiments were carried out to examine the effects of ethanol on the cardiac contractile protein ATPase activities. Cardiac myofibrils isolated from ethanol-fed hamsters showed a significant decrease in myofibrillar ATPase activities between pCa 6 and 4. On the other hand, addition of ethanol (0.1%) in vitro to cardiac myofibrils from control hamster had no significant effect on the ATPase activities, suggesting that hamsters need to be exposed for longer periods of time to induce demonstratable changes in the contractile protein ATPase activity. Actin-activated myosin ATPase activities were significantly lower in myofibrils from ethanol-fed hamsters at 1:1 and 1:2 ratios of myosin to actin. These investigations revealed that chronic (4 weeks) exposure of hamsters to ethanol reduced cardiac contractile protein ATPase activity, which may help explain impaired cardiac function in chronic alcoholics.     

Effects of isoproterenol treatment of isolated perfused rat hearts on myofibrillar phosphorylation and ATPase activity

Perfusion of isolated rat hearts with isoproterenol resulted in increases in the level of protein-bound phosphate of the myofibrils. After perfusion of the hearts with 32P, followed by SDS-polyacrylamide gel electrophoresis of the purified myofibrils, four major 32P-containing protein bands were identified. Most of the increased 32P incorporation produced by isoproterenol was localized on the troponin I and myosin light chain bands, and, to lesser extent, on the M-protein band. ATPase activity was tested in the purified myofibrils. No changes in Ca2+ requirement for activation were found after isoproterenol perfusion. However, maximal ATPase activity was markedly reduced in the myofibrils obtained from isoproterenol-treated hearts. It would appear that the myofibrillar protein phosphorylation induced by isoproterenol perfusion results in a decrease in actomyosin ATPase activity.     

Erythrocyte troponin inhibitor-like protein: Isolation and characterization

A protein was isolated from a human erythrocyte lysate with an apparent molecular weight of 23,000–24,000 daltons. This protein was purified by batch DEAE cellulose followed by column DEAE cellulose chromatography and a gradient of NaCl. On sodium dodecyl sulfate acrylamide electrophoresis, the erythrocyte protein comigrated with muscle troponin inhibitor. An isoelectric precipitation (pH 9.25) was used for the separation of muscle troponin inhibitor from a complex with another troponin component. Both the erythrocyte protein and the muscle troponin inhibitor partially inhibited muscle myosin Ca²⁺ and K⁺-EDTA ATPase activity. Furthermore, they inhibited actin-activated Mg²⁺-ATPase of muscle myosin. The inhibitory effects were absent in the presence of muscle troponin calcium-binding component. Muscle troponin inhibitor and the erythrocyte troponin inhibitor-like protein bound to muscle myosin when myosin was precipitated twice at low ionic strength. The presence of a troponin inhibitor-like protein in erythrocytes suggests that it may be a component in the regulation of contractile activity.     

A comparative study of the rat heart sarcolemmal Ca2+-dependent ATPase and myosin ATPase

In order to gain some information regarding Ca²⁺-dependent ATPase, the enzyme was purified from cardiac sarcolemma and its properties were compared with Ca²⁺-ATPase activity of myosin purified from rat heart. Both Ca²⁺-dependent ATPase and myosin ATPase were stimulated by Ca²⁺ but the maximal activation of Ca²⁺-dependent ATPase required 4 mM Ca²⁺ whereas that of myosin ATPase required 10 mM Ca²⁺. These ATPases were also activated by other divalent cations in the order of Ca²⁺ > Mn²⁺ > Sr²⁺ > Br²⁺ > Mg²⁺; however, there was a marked difference in the pattern of their activation by these cations. Unlike the myosin ATPase, the ATP hydrolysis by Ca²⁺-dependent ATPase was not activated by actin. The pH optima of Ca²⁺-dependent ATPase and myosin ATPase were 9.5 and 6.5 respectively. Na⁺ markedly inhibited Ca²⁺-dependent ATPase but had no effect on the myosin ATPase activity. N-ethylmaleimide inhibited Ca²⁺-dependent ATPase more than myosin ATPase whereas the inhibitory effect of vanadate was more on myosin ATPase than Ca²⁺-dependent ATPase. Both Ca²⁺-dependent ATPase and myosin ATPase were stimulated by K-EDTA and NH₄-EDTA. When myofibrils were treated with trypsin and passed through columns similar to those used for purifying Ca²⁺-ATPase from sarcolemma, an enzyme with ATPase activity was obtained. This myofibrillar ATPase was maximally activated at 3–4 mM Ca²⁺ and 3 to 4 mM ATP like sarcolemmal Ca²⁺-dependent ATPase. K⁺ stimulated both ATPase activities in the absence of Ca²⁺ and inhibited in the presence of Ca²⁺. Both enzymes were inhibited by Na⁺, Mg²⁺, La³⁺, and azide similarly. However, Ca²⁺ ATPase from myofibrils showed three peptide bands in SDS polyacrylamide gel electrophoresis whereas Ca²⁺ ATPase from sarcolemma contained only two bands. Sarcolemmal Ca²⁺-ATPase had two affinity sites for ATP (0.012 mM and 0.23 mM) while myofibrillar Ca²⁺-ATPase had only one affinity site (0.34 mM). Myofibrillar Ca²⁺-ATPase was more sensitive to maleic anhydride and iodoacetamide than sarcolemmal Ca²⁺-ATPase. These observations suggest that Ca²⁺-dependent ATPase may be a myosin like protein in the heart sarcolemma and is unlikely to be a tryptic fragment of myosin present in the myofibrils.     

A kinetic model of troponin dissociation in relation to thin filament regulation in striated muscle

The apparent rate of troponin (Tn) dissociation from myofibrils has been used as a method to study thin filament regulation in striated muscle. The rate is dependent upon calcium and strong crossbridges and supports the three-state model for thin filament regulation. The dissociation rate of Tn is extremely low so it is not intuitively clear that such a slow process would probe thin filament regulation. We have investigated this issue by developing a simple kinetic model to explain the Tn dissociation rate measured by labeled Tn exchange in the myofibrils. Tn is composed of three interacting subunits, TnC, TnI and TnT. In our model, TnI’s regulatory domain switches from actin-tropomyosin to TnC followed by TnT dissociation from actin-tropomyosin. This TnI regulatory domain switching is linked to the transition of the thin filament from the blocked state to the closed state. It is calcium dependent and several orders of magnitude faster than TnT dissociation from actin-tropomyosin. By integrating the dimensionless rate equations of this model, we have computed the time course of each of the various components. In our numerical simulations, the rate constant for TnI switching from actin-tropomyosin to TnC was varied from 10 s^?1 to 1000 s^?1 to simulate the low calcium, blocked state to high calcium, closed state. The computed progress curves for labeled Tn exchange into the myofibrils and the derived intensity ratio between the non-overlap and overlap regions well explains the intensity ratio progress curves observed experimentally. These numerical simulations and experimental observations reveal that the apparent rate of Tn dissociation probes the blocked state to closed state equilibrium of the myofibrillar thin filament.     

Effect of myocardial stunning on thiol status,myofibrillar ATPase and troponin I proteolysis

To investigate the mechanism underlying postischemic contractile dysfunction (myocardial stunning) we examined myocardial sulfhydryl group content, myofibrillar Ca²⁺-dependent Mg²⁺-ATPase activity and protein profile after global ischemia and reperfusion. The Langerdorff-perfused rabbit hearts were subjected to 15 min normothermic ischemia followed by 10 min reperfusion and myofibrils were isolated from homogenates of left ventricular tissues. Depressed contractile function during reperfusion was accompanied by a decrease in total sulfhydryl group content. However, myofibrillar protein profile was unchanged and Western immunoblotting analysis showed no significant differences in troponin I immunoreactive bands between control and stunned hearts. Likewise, myofibrillar Mg²⁺-ATPase activity was unaltered after ischemia and reperfusion. We conclude that myocardial stunning is not caused by altered myofibrillar function and protein degradation but may be partly due to the oxidative modification of as yet undefined proteins.     

Calcium regulation of cardiac myofibrillar activation: Effects of MgATP

In 2 mM MgATP, 0.08 ionic strength and 1 mM free Mg⁺⁺ cardiac myofibrils bound 3.5 nmoles Ca/mg protein at maximal ATPase activation. Significant amounts of Ca were also bound to cardiac myosin with these same conditions. By subtraction of this myosin-bound Ca we obtained an estimate of 4 moles Ca bound per mole of myofibrillar troponin at maximal ATPase. We found, however, that Ca activation of myofibrillar ATPase could be estimated assuming that only two of troponin's Ca-binding sites are engaged in regulation of crossbridge activity. Increase in MgATP from 0.3 to 5.0 mM raised the free Ca, giving half-maximal isometric tension or ATPase. Although part of this shift is most probably due to changes in the number of rigor (nucleotidefree) actin-myosin linkages, the rightward shift of the free Ca⁺⁺-activation relation with increase in MgATP from 2 to 5 mM appears to be due to effects of active (nucleotide-containing) actin-myosin linkages.     

Expression of myofibrillar proteins and parvalbumin isoforms in white muscle of dorada during development

Several polyacrylamide gel electrophoresis techniques were used to study developmental changes in myofibrillar protein composition and parvalbumin distribution in the myotomal muscle of Brycon moorei . Two myosin LC2 chains and two troponin I isoforms were successively detected. Up to four troponin T isoforms were synthesized. Slow red-muscle myofibrils from adult fish showed no common component (except actin) with larval, juvenile or adult fast white-muscle myofibrils. During growth of B. moorei , two classes of parvalbumin isoforms were sequentially expressed: larval PA I, PA IIa, and PA IIb and adult PA III. In adult fish, the content in Tn T-2 isoform decreased from the anterior to the posterior myomeres, in favour of Tn T-1 and Tn T-4. The parvalbumin content also diminished from the rostral to the caudal muscle. The fast rate of transition from larval to adult isoforms appeared to parallel the extremely fast growth of B. moorei . Sequential expression of these isoforms presumably reflected variations in the contractile properties of the muscle fibres, required by changes in physiological demands of the propulsive musculature.     

甲壳动物横纹肌的收缩蛋白质与调节机制

甲壳动物横纹肌肌原纤维的肌丝陈列,收缩蛋白质和收缩的Ca²⁺依赖性调节机制与脊椎动物横纹肌有不少差异.脊椎动物横纹肌、甲壳动物快肌与慢肌的粗丝与细丝的数量比依次为1:2,1:3和1:6,肌丝阵列各异.甲壳动物粗肌丝由肌球蛋白和副肌球蛋白组成,其分子装配与脊椎动物不同.细肌丝含有肌动蛋白、原肌球蛋白和肌钙蛋白,肌钙蛋白-T分子量较高,肌钙蛋白-C仅1个Ca²⁺结合位点.甲壳动物横纹肌兼有细肌丝调节与粗肌丝调节.     

Reduced cardiac myofibrillar Mg-ATPase activity without changes in myosin isozymes in patients with end-stage heart failure

In this study we tested the hypothesis that reduced myofibrillar ATPase activities in end-stage heart failure are associated with a redistribution of myosin isozymes. Cardiac myofibrils were isolated from left ventricular free wall from normal human hearts and hearts at end-stage heart failure caused by coronary artery diseases, cardiomyopathy or immunological rejection. The hearts had been excised in preparation for a heart transplant. Myofibrillar Ca^2–-dependent Mg-ATPase and myosin Ca^–- and K^–EDTA-ATPase activities were compared. Possible changes in myosin isozyme distribution in the diseased heart were investigated using polyacrylamide gel electrophoresis of native myosin in the presence of pyrophosphate. Significant reduction in myofibrillar Ca²⁺-dependent Mg-ATPase with no changes in the sensitivity of the myofibrils to Ca⁺ was observed in heart with coronary artery diseases (25.2 to 27.1% at pCa 5.83 to pCa 5.05), cardiomyopathy (21.1 to 25.5% at pCa 5.41 to pCa 5.05), and in the immunologically rejected heart (18.4 to 22.8% at pCa 5.41 to pCa 5.05). Significantly lower myosin Ca²⁺-ATPase was observed with coronary artery diseases only and myosin K-EDTA activities did not differ in diseased and normal hearts. Polyacrylamide gel electrophoresis of native myosin from the normal and three models of end-stage heart failure revealed two distinct bands in the human left ventricle and one diffuse band in the human right atria. No apparent differences in myosin isoenzyme pattern were observed between the normal and diseased hearts. Further evaluation is needed to clarify the ATPase nature of the two bands.     

Effects of removal and reconstitution of myosin regulatory light chain and troponin C on the Ca(2+)-sensitive ATPase activity of myofibrils from scallop striated muscle

In order to examine the involvement of troponin-linked Ca(2+)-regulation, in addition to well-known myosin-linked Ca(2+)-regulation, in the contraction of molluscan striated muscle, myofibrils from Ezo-giant scallop striated muscle were desensitized to Ca(2+) by removing both myosin regulatory light chain and troponin C by treatment with a strong divalent cation chelator, CDTA. The ATPase level in the desensitized myofibrils was about half the maximum level in intact myofibrils regardless of the Ca(2+)-concentration at 25 and 15 degrees C. In the absence of Ca(2+), the ATPase of the desensitized myofibrils was suppressed by myosin regulatory light chain but not affected by troponin C at either temperature. The ATPase was activated at higher Ca(2+)-concentrations by both myosin regulatory light chain and troponin C, but the activating effects of these two proteins were affected differently by temperature. The activation of ATPase by myosin regulatory light chain was much greater than that by troponin C at 25 degrees C, whereas the activation by troponin C was much greater than that by myosin regulatory light chain at 15 degrees C. The maximum activation was only obtained in the presence of both myosin regulatory light chain and troponin C at these temperatures. These findings strongly suggest that the contraction of scallop striated muscle is regulated through both myosin-linked and troponin-linked Ca(2+)-regulation, and that the troponin-linked Ca(2+)-regulation is more significant at lower temperature.     

Preserved Close Linkage Between the Genes Encoding Troponin I and Troponin T, Reflecting an Evolution of Adapter Proteins Coupling the Ca2+ Signaling of Contractility

Ca²⁺-regulated motility is essential to numerous cellular functions, including muscle contraction. Systems with troponin C, myosin light chain, or calmodulin as the Ca²⁺ receptor have evolved in striated muscle and other types of cells to transduce the cytoplasm Ca²⁺ signals into allosteric conformational changes of contractile proteins. While these Ca²⁺ receptors are homologous proteins, their coupling to the responding elements is quite different in various cell types. The Ca²⁺ regulatory system in vertebrate striated muscle represents a highly specialized such signal transduction pathway consisting of the troponin complex and tropomyosin associated with the actin filament. To understand the molecular mechanism in the Ca²⁺ regulation of muscle contraction and cell motility, we have revealed a preserved ancestral close linkage between the genes encoding two of the troponin subunits, troponin I and troponin T, in the genome of mouse. The data suggest that the troponin I and troponin T genes may have originated from a single locus and evolved in parallel to encode a striated muscle-specific adapter to couple the Ca²⁺ receptor, troponin C, to the actin–myosin contractile machinery. This hypothesis views the three troponin subunits as two structure–function domains: the Ca²⁺ receptor and the signal transducing adapter. This model may help to further our understanding of the Ca²⁺ regulation of muscle contraction and the structure–function relationship of other potential adapter proteins which are converged to constitute the Ca²⁺ signal transduction pathways governing nonmuscle cell motility. Received: 15 April 1999 / Accepted: 15 July 1999     

Maintained contractile reserve in a transgenic mouse model of myocardial stunning

Cardiac excitation-contraction (E-C) coupling is impaired at the myofilament level in the reversible postischemic dysfunction known as "stunned" myocardium. We characterized tension development and calcium cycling in intact isolated trabeculae from transgenic (TG) mice expressing the major proteolytic degradation fragment of troponin I (TnI) found in stunned myocardium (TnI(1-193)) and determined the ATPase activity of myofibrils extracted from TG and non-TG mouse hearts. The phenotype of these mice at baseline recapitulates that of stunning. Here, we address the question of whether contractile reserve is preserved in these mice, as it is in genuine stunned myocardium. During twitch contractions, calcium cycling was normal, whereas tension was greatly reduced, compared with non-TG controls. A decrease in maximum Ca2+-activated tension and Ca2+ desensitization of the myofilaments accounted for this contractile dysfunction. The decrease in maximum tension was paralleled by an equivalent decrease in maximum Ca2+-activated myofibrillar ATPase activity. Exposure to high calcium or isoproterenol recruited a sizable contractile reserve in TG muscles, which was proportionately similar to that in control muscles but scaled downward in amplitude. These results suggest that calcium regulatory pathways and beta-adrenergic signal transduction remain intact in isolated trabeculae from stunned TG mice, further recapitulating key features of genuine stunned myocardium.     

Evidence from insect fibrillar muscle about the elementary contractile process

Bundles of myofibrils prepared from the dorsal longitudinal flight muscles of giant water bugs show oscillatory contractile activity in solutions of low ionic strength containing ATP and 10^-8-10^-7 M Ca²⁺. This is due to delay between changes of length and changes of tension under activating conditions. The peculiarities of insect fibrillar muscle which give rise to this behavior are (1) the high elasticity of relaxed myofibrils, (2) a smaller degree of Ca²⁺ activation of ATPase activity in unstretched myofibrils and extracted actomyosin, and (3) a direct effect of stretch on ATPase activity. It is shown that the cross-bridges of striated muscle are probably formed from the heads of three myosin molecules and that in insect fibrillar muscle the cycles of mechanochemical energy conversion in the cross-bridges can be synchronized by imposed changes of length. This material is more suitable than vertebrate striated muscle for a study of the nature of the elementary contractile process.     

Myofibrillar creatine kinase and cardiac contraction

This article is a review on the organization and function of myofibrillar creatine kinase in striated muscle. The first part describes myofibrillar creatine kinase as an integral structural part of the complex organization of myofibrils in striated muscle. The second part considers the intrinsic biochemical and mechanical properties of myofibrils and the functional coupling between myofibrillar CK and myosin ATPase. Skinned fiber studies have been developed to evidence this functional coupling and the consequences for cardiac contraction. The data show that creatine kinase in myofibrils is effective enough to sustain normal tension and relaxation, normal Ca sensitivity and kinetic characteristics. Moreover, the results suggest that myofibrillar creatine kinase is essential in maintaining adequate ATP/ADP ratio in the vicinity of myosin ATPase active site to prevent dysfunctioning of this enzyme. Implications for the physiology and physiopathology of cardiac muscle are discussed.     

Calcium ion and troponin: Professor S. Ebashi's epoch-making achievement

The processes by which Professor Setsuro Ebashi accomplished his great work are described. Independently of Marsh, Ebashi discovered the relaxing factor in homogenized muscle and showed that it has a lipid-containing particulate fraction with ATPase activity, later identified as the sarcoplasmic reticulum. He then solved the mechanism of relaxation of the relaxing factor through the following findings. A minute amount of calcium ion (Ca²⁺) is necessary for the physiological contractile reaction. The relaxing factor strongly accumulates Ca²⁺ in the presence of ATP and sufficiently removes Ca²⁺ from the contractile system to bring about relaxation. Ebashi found that the contractile reaction of myosin and actin is regulated by Ca²⁺ only in the presence of a tropomyosin-like protein factor, which he later showed to be a complex of tropomyosin and a new protein, troponin. He proved that troponin is the Ca²⁺-receptive protein and proposed the correct scheme for the molecular mechanism of regulation of contraction and relaxation.