Protein kinase C-mediated phosphorylation of troponin I and C-protein in isolated myocardial cells is associated with inhibition of myofibrillar actomyosin MgATPase

Differential regulation of cardiac actomyosin S-1 MgATPase by protein kinase C isozyme-specific phosphorylation of specific sites in cardiac troponin I and its phosphorylation site mutants

The significance of site-specific phosphorylation by protein kinase C (PKC) isozymes alpha and delta and protein kinase A (PKA) of troponin I (TnI) and its phosphorylation site mutants in the regulation of Ca(2+)-stimulated MgATPase activity of reconstituted actomyosin S-1 was investigated. The genetically defined TnI mutants used were T144A, S43A/S45A, S43A/S45A/T144A (in which the PKC phosphorylation sites Thr-144 and Ser-43/Ser-45 were respectively substituted by Ala) and N32 (in which the first 32 amino acids in the NH2-terminal sequence containing Ser-23/Ser-24 were deleted). Although the PKC isozymes displayed different substrate phosphorylation kinetics, PKC-alpha phosphorylated equally well TnI wild type and all mutants, whereas N32 was a much poorer substrate for PKC-delta. Furthermore, the two PKC isozymes exhibited discrete specificities in phosphorylating distinct sites in TnI and its mutants, either as individual subunits or as components of the reconstituted troponin complex. Unlike PKC-alpha, PKC-delta favorably phosphorylated the PKA-preferred site Ser-23/Ser-24 and hence, like PKA, reduced the Ca2+ sensitivity of the reconstituted actomyosin S-1 MgATPase. In contrast, PKC-alpha preferred to phosphorylate Ser-43/Ser-45 (common sites for all isozymes) and thus reduced the maximal Ca(2+)-stimulated activity of the MgATPase. In this respect, PKC-delta, by cross-phosphorylating the PKA sites, functioned as a hybrid of PKC-alpha and PKA. The site specificities and hence functional differences between PKC-alpha and -delta were most evident at low phosphorylation (1 mol of phosphate/mol) of TnI wild type and were magnified when S43A/S45A and N32 were used as substrates. The present study has demonstrated, for the first time, that distinct functional consequences could arise from the site-selective preferences of PKC-alpha and -delta for phosphorylating a single substrate in the myocardium, i.e., TnI.

Translocation of protein kinase C-alpha, delta and epsilon isoforms in ischemic rat heart

To explore the spatial and temporal localization of PKC isoforms during ischemia, we quantified PKC isoforms in the subcellular fractions in perfused rat heart by immunoblotting using specific antibodies against PKC isoforms. PKCs-alpha and epsilon translocated from the 100000 x g supernatant (S, cytosolic) fraction to the 1000 x g pellet (PI, nucleus-myofibril) and the 1000-100000 x g pellet (P2, membrane) fractions during 5-40 min of ischemia. PKC-delta redistributed from the P2 to the S fraction. A 50-kDa fragment of PKC-alpha appeared during ischemia possibly through calpain action. Immunohistochemical observations showed the different localizations of PKC-alpha, delta, and epsilon in the myocytes. The PKC assay displayed high basal levels of Ca(2+)-independent PKC, the activation of Ca(2+)-dependent PKC in the P1 and P2 fractions, and the activation of Ca(2+)-independent PKC in the P1 fraction after 20 min of ischemia. These observations show that ischemia induces different patterns of translocation of the three PKC isoforms, suggesting differences in their roles.

Phosphorylation specificities of protein kinase C isozymes for bovine cardiac troponin I and troponin T and sites within these proteins and regulation of myofilament properties

Protein kinase C (PKC) isozymes alpha, delta, epsilon, and zeta, shown to be expressed in adult rat cardiomyocytes, displayed distinct substrate specificities in phosphorylating troponin I and troponin T subunits in the bovine cardiac troponin complex. Thus, because they have different substrate affinities, PKC-alpha, -delta, and -epsilon phosphorylated troponin I more than troponin T, but PKC-zeta conversely phosphorylated the latter more than the former. Furthermore, PKC isozymes exhibited discrete specificities in phosphorylating distinct sites in these proteins as free subunits or in the troponin complex. Unlike other isozymes, PKC-delta was uniquely able to phosphorylate Ser-23/Ser-24 in troponin I, the bona fide phosphorylation sites for protein kinase A (PKA); and consequently, like PKA, it reduced Ca2+ sensitivity of Ca2+-stimulated MgATPase of reconstituted actomyosin S-1. In addition, PKC-delta, like PKC-alpha, readily phosphorylated Ser-43/Ser-45 (sites common for all PKC isozymes) and reduced maximal activity of MgATPase. In this respect, PKC-delta functioned as a hybrid of PKC-alpha and PKA. In contrast to PKC-alpha, -delta, and -epsilon, PKC-zeta exclusively phosphorylated two previously unknown sites in troponin T. Phosphorylation of troponin T by PKC-alpha resulted in decreases in both Ca2+ sensitivity and maximal activity, whereas phosphorylation by PKC-zeta resulted in a slight increase of the Ca2+ sensitivity without affecting the maximal activity of MgATPase. Most of the in vitro phosphorylation sites in troponin I and troponin T were confirmed in situ in adult rat cardiomyocytes. The present study has demonstrated for the first time distinct specificities of PKC isozymes for phosphorylation of two physiological substrates in the myocardium, with functional consequences.

Calcium preconditioning elicits strong protection against ischemic injury via protein kinase C signaling pathway

We tested the hypothesis that elevation of [Ca2+]i during Ca2+ preconditioning (CPC) is a strong activator of protein kinase C (PKC) and confers unique protection against ischemic injury. CPC consisted of three cycles of Ca2+ depletion (1 minute each) and Ca2+ repletion (5 minutes each). Langendorff-perfused rat hearts were subjected to 40 minutes of global ischemia followed by 30 minutes of reperfusion. Significant functional recovery and decreased lactate dehydrogenase release were observed in CPC hearts compared with ischemic control hearts. In addition, ATP contents were significantly higher and cell structure was better preserved in CPC hearts than in ischemic control hearts. Administration of chelerythrine, a specific PKC inhibitor, completely abolished the CPC-induced cardioprotection. In other groups, in which Ca2+ influx during CPC was inhibited with verapamil, amiloride, and low Na+ perfusion, cardioprotection was significantly reduced. The prominent increase in the membrane PKC activity after CPC was in agreement with immunolocalization of PKC-alpha and PKC-delta in the cell membrane of CPC hearts. These results demonstrate that (1) a transient increase in [Ca2+]i is a prominent feature of CPC and is a strong stimulus for the activation of PKC, (2) the elevation of [Ca2+]i likely occurs via an L-type Ca2+ channel and Na(+)-Ca2+ exchanger, and (3) PKC plays a crucial role in the subcellular mechanisms of protection by CPC.

Delayed cardioprotection is associated with the sub-cellular relocalisation of ventricular protein kinase C epsilon, but not p42/44MAPK

Both noradrenaline administration to rats and rapid cardiac pacing in dogs induces delayed protection of the heart against ischaemia-induced ventricular arrhythmias. In an attempt to establish molecular mechanisms underlying the delayed cardioprotection, we have examined the potential role of two kinases, PKC epsilon and p42/44MAPK. These protein kinases are expressed in the ventricles of the heart and are characterised by their ability to regulate ion-flux and gene transcription. In the rat p42MAPK is predominantly localised in the high-speed supernatant fraction of the ventricle homogenate, whereas p44MAPK is enriched in the nuclear low speed pellet. A small proportion of the p42MAPK is activated even in hearts from control animals. However, neither kinase is relocalised or activated by noradrenaline administration and this provides preliminary evidence the p42/44MAPK may not play a significant role in delayed protection in this species. In contrast, noradrenaline does induce the translocation of PKC epsilon to cell membranes, a response that is sustained for up to 4 h. However, PKC epsilon is down-regulated from the cytoplasm after 24 h post noradrenaline treatment. PKC epsilon is also translocated to the membrane in dogs that have been classically pre-conditioned and cardiac paced. In the latter case, translocation of PKC epsilon from the cytoplasm to the cell membrane is evident 24 h after pacing. These results indicate that the release of endogenous mediators may either inhibit down-regulation or elicit an increase in PKC epsilon mRNA expression. Therefore, in dog heart the subcellular relocalisation of PKC epsilon persists into the 'second window' and may play a central role in the molecular mechanism governing delayed cardioprotection. It is important in the future to identify either the gene products that are induced or the target protein(s) that are phosphorylated by PKC epsilon.

Troponin I phosphorylation in heart homogenate from diabetic rat

Although cardiac myofibrillar ATPase activity has been shown to be depressed during the development of diabetic heart dysfunction, the mechanisms of this alteration are not fully understood. Since phosphorylation of troponin I (TnI) is known to decrease the myofibrillar ATPase activity, the present study was undertaken to examine the TnI phosphorylation capacity in the diabetic heart homogenate. For this purpose rats were made diabetic by injecting streptozotocin (65 mg/kg; i.v.) and the hearts were removed 8 wk later. Some 6 wk diabetic animals were injected with insulin (3 U/day) for 2 wk. TnI content in the heart homogenate was measured by immunoblot assay, the mRNA abundance for TnI gene was determined by Northern blot analysis and the in vitro phosphorylation level of TnI was estimated by the ratio of phosphorylated TnI and total (phosphorylated and unphosphorylated) TnI. No significant changes in TnI content and gene expression of TnI were observed in right and left ventricles from the diabetic rats. However, the phosphorylation of TnI was higher (approximately 40%) in the diabetic hearts; this change was reversible upon insulin treatment. These results regarding TnI phosphorylation measured under in vitro conditions suggest that increased phosphorylation of TnI may contribute toward the depression in cardiac myofibrillar ATPase activity in chronic diabetes.

Effect of endothelin-1 on actomyosin ATPase activity. Implications for the efficiency of contraction

Endothelin is a powerful inotropic peptide that increases isometric force in isolated papillary muscle and the extent of shortening in isolated single cardiac myocytes. Its mechanism of action has been variously attributed to increased Ca2+ activation, increased Ca2+ sensitivity of the contractile proteins, and increased intracellular pH, but the physiological function of the changes in cardiac performance remains obscure. In this study, the effects of endothelin-1 on both force development and the kinetics of contraction have been examined. Isometric force, actomyosin ATPase activity, and unloaded shortening velocity were measured. The effects were dose dependent. From 1 to 50 pmol/L endothelin-1 did not alter force development in isolated trabeculae with intact endothelial cells, but actomyosin ATPase activity was increased. Between 100 pmol/L and 10 nmol/L endothelin-1 raised isometric force, decreased actomyosin ATPase activity, and decreased unloaded shortening velocity. The reduction in ATPase activity was progressively enhanced as sarcomere length was increased from 1.9 t0 2.4 microns. These results indicate that the effects of endothelin-1 on the force of contraction and the rate of ATP hydrolysis are not tightly coupled and are changed in the opposite directions by endothelin-1 over most of its effective dose-range. This raises the possibility that endothelin-1 may increase the economy of contraction. A novel function of endothelin may be the modulation of the efficiency of contraction, particularly when increased preload raises the contractile work of the heart.

Optimal myocardial preservation: cooling, cardioplegia, and conditioning

Myocardial preservation techniques have evolved in conjunction with cardiac surgery and currently offer substantial protection against myocardial injury. We propose that cardiac preconditioning, a robust, endogenous mechanism of cardioprotection, is emerging as an important adjunct to current cardioplegic techniques. By reviewing the physiologic basis for current cardioplegic strategies, and understanding the cardioprotective benefits of preconditioning, we postulate that cardiac preconditioning may represent an important, clinically accessible component of myocardial protection.

Functional significance of alterations in cardiac contractile protein isoforms

Multiple closely related, yet distinct, isoforms exist for each of the cardiac contractile proteins. The isoform composition of the heart changes in response to developmental and physiologic cues. This paper reviews the molecular basis for cardiac contractile protein isoform diversity and the functional consequences of isoform shifts.

Phosphorylation of both serine residues in cardiac troponin I is required to decrease the Ca2+ affinity of cardiac troponin C

The phosphorylation of cardiac muscle troponin I (CTnI) at two adjacent N-terminal serine residues by cAMP-dependent protein kinase (PKA) has been implicated in the inotropic response of the heart to beta-agonists. Phosphorylation of these residues has been shown to reduce the Ca2+ affinity of the single Ca(2+)-specific regulatory site of cardiac troponin C (CTnC) and to increase the rate of Ca2+ dissociation from this site (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). Recent studies (Zhang, R., Zhao, J., and Potter, J. D. (1995) Circ. Res. 76, 1028-1035) have correlated this increase in Ca2+ dissociation with a reduced Ca2+ sensitivity of force development and a faster rate of cardiac muscle relaxation in a PKA phosphorylated skinned cardiac muscle preparation. To further determine the role of the two PKA phosphorylation sites in mouse CTnI (serine 22 and 23), serine 22 or 23, or both were mutated to alanine. The wild type and the mutated CTnIs were expressed in Escherichia coli and purified. Using these mutants, it was found that serine 23 was phosphorylated more rapidly than serine 22 and that both serines are required to be phosphorylated in order to observe the characteristic reduction in the Ca2+ sensitivity of force development seen in a skinned cardiac muscle preparation. The latter result confirms that PKA phosphorylation of CTnI, and not other proteins, is responsible for this change in Ca2+ sensitivity. The results also suggest that one of the serines (23) may be constitutively phosphorylated and that serine 22 may be functionally more important.

Cardiac troponin I mutants. Phosphorylation by protein kinases C and A and regulation of Ca(2+)-stimulated MgATPase of reconstituted actomyosin S-1

The significance of site-specific phosphorylation of cardiac troponin I (TnI) by protein kinase C and protein kinase A in the regulation of Ca(2+)-stimulated MgATPase of reconstituted actomyosin S-1 was investigated. The TnI mutants used were T144A, S43A/S45A, and S43A/S45A/T144A (in which the identified protein kinase C phosphorylation sites, Thr-144 and Ser-43/ Ser-45, were, respectively, substituted by Ala) and S23A/S24A and N32 (in which the protein kinase A phosphorylation sites Ser-23/Ser-24 were either substituted by Ala or deleted). The mutations caused subtle changes in the kinetics of phosphorylation by protein kinase C, and all mutants were maximally phosphorylated to various extents (1.3-2.7 mol of phosphate/mol of protein). Protein kinase C could cross-phosphorylate protein kinase A sites but the reverse essentially could not occur. Compared to wild-type TnI and T144A, un-phosphorylated S43A/S45A, S43A/S45A/T144, S23A/ S24A, and N32 caused a decreased Ca2+ sensitivity of Ca(2+)-stimulated MgATPase of reconstituted actomyosin. S-1. Phosphorylation by protein kinase C of wild-type and all mutants except S43A/S45A and S43A/S45A/T144A caused marked reductions in both the maximal activity of Ca(2+)-stimulated MgATPase and apparent affinity of myosin S-1 for reconstitued (regulated) actin. It was further noted that protein kinase C acted in an additive manner with protein kinase A by phosphorylating Ser-23/Ser-24 to bring about a decreased Ca2+ sensitivity of the myofilament. It is suggested that Ser-43/Ser-45 and Ser-23/Ser-24 in cardiac TnI are important for normal Ca2+ sensitivity of the myofilament, and that phosphorylation of Ser-43/Ser-45 and Ser-23/Ser-24 is primarily involved in the protein kinase C regulation of the activity and Ca2+ sensitivity, respectively, of actomyosin S-1 MgATPase.

Regulation of phospholamban and troponin-I phosphorylation in the intact rat cardiomyocytes by adrenergic and cholinergic stimuli: roles of cyclic nucleotides, calcium, protein kinases and phosphatases and depolarization

Protein phosphorylation was investigated in [32P]-labeled cardiomyocytes isolated from adult rat heart ventricles. The beta-adrenergic stimulation (by isoproterenol, ISO) increased the phosphorylation of inhibitory subunit of troponin (TN-I), C-protein and phospholamban (PLN). Such stimulation was largely mediated by increased adenylyl cyclase (AC) activity, increased myoplasmic cyclic AMP and increased cyclic AMP dependent protein kinase (A-kinase)-catalyzed phosphorylation of these proteins in view of the following observations: (a) dibutyryl-and bromo-derivatives of cyclic AMP mimicked the stimulatory effect of ISO on protein phosphorylation while (b) Rp-cyclic AMP was found to attenuate ISO-dependent stimulation. Unexpectedly, 8-bromo cyclic GMP was found to markedly increase TN-I and PLN phosphorylation. Both beta 1- and beta 2-adrenoceptors were present and ISO binding to either receptor was found to stimulate myocyte AC. However, the stimulation of the beta 2-AR only marginally increased while the stimulation of beta 1-AR markedly increased PLN phosphorylation. Other stimuli that increase tissue cyclic AMP levels also increased PLN and TN-I phosphorylation and these included isobutylmethylxanthine (non-specific phosphodiesterase inhibitor), milrinone (inhibits cardiotonic inhibitable phosphodiesterase, sometimes called type III or IV) and forskolin (which directly stimulates adenylyl cyclase). Cholinergic agonists acting on cardiomyocyte M2-muscarinic receptors that are coupled to AC via pertussis toxin(PT)-sensitive G proteins inhibited AC and attenuated ISO-dependent increases in PLN and TN-I phosphorylation. The in vivo PT treatment, which ADP-ribosylated Gi-like protein(s) in the myocytes, markedly attenuated muscarinic inhibitory effect on PLN and TN-I phosphorylation on one hand and, increased the beta-adrenergic stimulation, on the other. Controlled exposure of isolated myocytes to N-ethyl maleimide, also led to the findings similar to those seen following the PT treatment. Exposure of myocytes to phorbol, 12-myristate, 13-acetate (PMA) increased the protein phosphorylation, augmenting the stimulation by ISO, and such augmentation was antagonized by propranolol suggesting modulation of the beta-adrenoceptor coupled AC pathway by PMA. Okadaic acid (OA) exposure of myocytes also increased protein phosphorylation with the results supporting the roles for type 1 and 2A protein phosphatases in the dephosphorylation of PLN and TN-I. Interestingly OA treatment attenuated the muscarinic inhibitory effect which was restored by subsequent brief exposure of myocytes to PMA. While the stimulation of alpha adrenoceptors exerted little effect on the phosphorylation of PLN and TN-I, inactivation of alpha adrenoceptors by chloroethylclonidine (CEC), augmented beta-adrenergically stimulated phosphorylation. KCl-dependent depolarization of myocytes was observed to potentiate ISO-dependent increase in phosphorylation (incubation period 15 sec to 1 min) as well as to accelerate the time-dependent decline in this phosphorylation seen upon longer incubation. Verapamil decreased ISO-stimulated protein phosphorylation in the depolarized myocytes. Depolarization was found to have little effect on the muscarinic inhibitory action on phosphorylation. Prior treatment of myocytes with PMA, was found to augment ISO-stimulated protein phosphorylation in the depolarized myocytes. Such augmented increases were completely blocked by propranolol. Forskolin also stimulated PLN and TN-I phosphorylation. Prior exposure of myocytes to forskolin followed by incubation in the depolarized and polarized media showed that PLN was dephosphorylated more rapidly in the depolarized myocytes. The results support the view that both cyclic AMP and calcium signals cooperatively increase the rates of phosphorylation of TN-I and PLN in the depolarized cardiomyocytes during beta-adrenergic stimulation. (ABSTRACT TRUNCATED)

Alpha 1-adrenergic receptor stimulation decreases maximum shortening velocity of skinned single ventricular myocytes from rats

alpha 1-Adrenergic agonists have negative inotropic effects on mammalian myocardium under some conditions, and biochemical experiments measuring the Ca(2+)-activated actomyosin ATPase activity of myofibrillar preparations suggest that this may result from a decrease in cross-bridge cycling rate caused by phosphorylation of myofilament proteins. Experiments with intact ventricular preparations, however, have failed to demonstrate a mechanical manifestation of a decrease in cycling rate. The present study examined the effect of alpha 1-adrenergic receptor stimulation on maximum shortening velocity in skinned single ventricular myocytes from rats. Enzymatically isolated myocytes were incubated with the beta-receptor antagonist propranolol in the presence or absence of the alpha 1-adrenergic receptor agonist phenylephrine and were then rapidly skinned to preserve the phosphorylation state of myofilament proteins. The velocity of unloaded shortening (Vo) was determined by use of the slack-test method and compared between skinned control and phenylephrine-treated cells. The relationship between isometric tension and [Ca2+] was also assessed for each myocyte. Vo was significantly lower in the alpha 1-adrenergic receptor agonist-treated cells than in the control cells, but there was no effect on Ca2+ sensitivity of isometric tension. In addition, the myosin heavy chain isoform composition accounted for a significant amount of the variation in Vo within the treatment groups. On the basis of these and previous results we propose that alpha 1-adrenergic receptor stimulation inhibits cross-bridge cycling rate at the level of myofilament proteins by a mechanism that may involve phosphorylation of troponin I by protein kinase C.

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.

Arachidonic acid-dependent phosphorylation of troponin I and myosin light chain 2 in cardiac myocytes

Recent evidence has suggested that arachidonic acid (AA) may be an important signaling molecule in cardiac excitation-contraction coupling. We previously showed that AA and endothelin-1 (ET) inhibit distinct K+ channels via protein kinase C-dependent pathways in rat ventricular myocytes. In addition, we demonstrated that Ca2+ transients in populations of fura 2-loaded myocytes were potentiated by AA and ET via activation of protein kinase C. In this study, we have used suspensions of [32P]orthophosphate (32Pi)-labeled rat ventricular myocytes to study the effects of AA and ET at the level of the myofilaments. After a 10-minute incubation of the labeled cells with phorbol 12-myristate 13-acetate (PMA), AA, or ET in the presence or absence of the protein kinase C inhibitor calphostin C, the myofibrillar proteins were separated by PAGE. Measurement of unloaded cell shortening using video edge detection in single electrically stimulated myocytes was also used to assess the effects of AA and ET on myocyte contractility. Incubation with either PMA, AA, or ET resulted in similar increases in 32Pi incorporation into troponin I (TnI) and myosin light chain 2 (MLC2), which was inhibited by preincubation with the protein kinase C antagonist calphostin C. In addition, the ability of these agonists to stimulate phosphorylation of TnI or MLC2 did not require extracellular Ca2+ or intact intracellular Ca2+ stores. The effects of AA and ET together on phosphorylation of TnI or MLC2 were not additive.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of the phosphatase inhibitor calyculin A on the phosphorylation of C-protein in mammalian ventricular cardiomyocytes

The effects of inhibitors of protein phosphatase activity on C-protein phosphorylation were studied in preparations from mammalian ventricles. Calyculin A (CyA), an inhibitor of type 1 and 2A protein phosphatases, was studied. CyA concentration- and time-dependency increased the phosphorylation state of C-protein in isolated 32P-labelled guinea pig ventricular cardiomyocytes. C-protein was identified by its reaction with a polyclonal antibody and immunoprecipitation. It is concluded that C-protein in intact cardiomyocytes could be a substrate for type 1 and 2A protein phosphatases.

Calcium sensitivity of isometric tension is increased in canine experimental heart failure

To examine the role of alterations in myofibrillar function in chronic heart failure, we determined isometric tension-pCa relations in permeabilized myocardium from a canine model of dilated cardiomyopathy (DCM) produced by chronic rapid pacing. In the initial series of experiments, seven dogs were paced at 250 beats per minute for 28.9 +/- 7.0 days, resulting in ventricular dilatation and reduced ejection fractions by echocardiography and elevated intracardiac filling pressures. Isometric tension-pCa relations were measured by using mechanically disrupted and permeabilized myocyte-sized preparations obtained from left ventricular biopsies before (n = 11) and after (n = 10) chronic rapid pacing-induced heart failure. Resting sarcomere length (SL) was set at 2.35 microns, and preparations had low end compliance (SL was 2.23 +/- 0.03 microns during maximal activation). Passive tension (2.1 +/- 1.0 versus 2.4 +/- 0.6 mN/mm2) and maximal Ca(2+)-activated tension (25.9 +/- 9.3 versus 27.8 +/- 6.8 mN/mm2) were similar for control and DCM preparations, respectively. However, the calcium sensitivity of isometric tension was increased in failing myocardium (pCa50 5.95 +/- 0.11 [DCM] versus 5.83 +/- 0.10 [control], P = .001). Treatment of myofibrillar preparations with the catalytic subunit of protein kinase A decreased calcium sensitivity of tension to a greater degree in failing preparations (shift of pCa50 from 6.04 +/- 0.06 to 5.75 +/- 0.09, n = 7) than in nonfailing preparations (5.91 +/- 0.08 to 5.74 +/- 0.07, n = 8), and isometric tension-pCa relations in the two groups were not significantly different after protein kinase A treatment.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of regulatory proteins (troponin-tropomyosin) in pathologic states

In vertebrate striated muscle, troponin-tropomyosin is responsible, in part, not only for transducing the effect of calcium on contractile protein activation, but also for inhibiting actin and myosin interaction when calcium is absent. The regulatory troponin (Tn) complex displays several molecular and calcium binding variations in cardiac muscles of different species and undergoes genetic changes with development and in various pathologic states. Extensive reviews on the role of tropomyosin (Tm) and Tn in the regulation of striated muscle contraction have been published describing the molecular mechanisms involved in contractile protein regulation. In our studies, we have found an increase in Mg2+ ATPase activity in cardiac myofibrils from dystrophic hamsters and in rats with chronic coronary artery narrowing. The abnormalities in myofibrillar ATPase activity from cardiomyopathic hamsters were largely corrected by recombining the preparations with a TnTm complex isolated from normal hamsters indicating that the TnTm may play a major role in altered myocardial function. We have also observed down regulation of Ca2+ Mg2+ ATPase of myofibrils from hypertrophic guinea pig hearts, myocardial infarcted rats and diabetic-hypertensive rat hearts. In myosin from diabetic rats, this abnormality was substantially corrected by adding troponin-tropomyosin complex from control hearts. All of these disease models are associated with decreased ATPase activities of pure myosin and in the case of rat and hamster models, shifts of myosin heavy chain from alpha to beta predominate. In summary, there are three main troponin subunit components which might alter myofibrillar function however, very few direct links of molecular alterations in the regulatory proteins to physiologic and pathologic function have been demonstrated so far.

Beta-adrenergic receptor stimulation increases unloaded shortening velocity of skinned single ventricular myocytes from rats

In vitro biochemical experiments have suggested that stimulation of beta-adrenergic receptor may increase the rate of crossbridge cycling in mammalian myocardium, but recent attempts to demonstrate a mechanical correlate have yielded conflicting results. To investigate this issue, we measured the effect of isoproterenol (ISO) and cAMP-dependent protein kinase (PKA) on unloaded shortening velocity (Vo). Vo is thought to be determined by the rate-limiting step of the crossbridge cycle, ie, the rate of crossbridge detachment from actin, and is therefore an index of the cycling rate. Single rat ventricular myocytes were enzymatically isolated, incubated in Ringer's solution without (control) or with 0.1 mumol/L ISO, and then rapidly skinned. Some control cells were subsequently treated with 3 micrograms/mL PKA for 40 minutes. Vo was then measured during maximal activation (pCa 4.5) in control, ISO-treated, and PKA-treated cells using the slack-test method. To test the efficacy of the agonist treatments, Ca2+ sensitivity of isometric tension was also assessed for each treatment by determining the [Ca2+] required for half-maximal tension (ie, pCa50). Both ISO and PKA treatment reduced the Ca2+ sensitivity of isometric tension compared with same-day control cells, in agreement with previous studies in intact and in skinned preparations. Vo was increased 38% by ISO treatment and 41% by PKA treatment compared with same-day control cells. 32P autoradiography showed that troponin I and C protein were the principal proteins phosphorylated by PKA treatment. We conclude that beta-adrenergic stimulation increases the rate of crossbridge release from actin, by a mechanism that most likely involves the phosphorylation of troponin I and/or C protein by PKA.