Enhancement of Cardiac Function and Suppression of Heart Failure Progression By Inhibition of Protein Phosphatase 1
http://www.100md.com
循环研究杂志 2005年第4期
the Departments of Pharmacology and Cell Biophysics (A.P., W.Z., J.-E.S., I.B., A.C., J.Q., G.C., E.G.K.), Molecular and Cellular Physiology (J.N.L.), Internal Medicine (H.H., F.S., D.W.M.)
Molecular Genetics and Biochemistry (L.J.), University of Cincinnati, Ohio
Cardiology Division (F.d.M., E.K.H., J.L.G., R.J.H.), Harvard Medical School and Massachusetts General Hospital, Boston, Mass
Department of Pharmacology and Cancer Biology (D.W.), Duke University Medical Center, Durham, NC
Department of Biochemistry and Molecular Biology (N.M., A.A.D.-R.), Indiana University, Indianapolis, Ind.
Abstract
Abnormal calcium cycling, characteristic of experimental and human heart failure, is associated with impaired sarcoplasmic reticulum calcium uptake activity. This reflects decreases in the cAMP-pathway signaling and increases in type 1 phosphatase activity. The increased protein phosphatase 1 activity is partially due to dephosphorylation and inactivation of its inhibitor-1, promoting dephosphorylation of phospholamban and inhibition of the sarcoplasmic reticulum calcium-pump. Indeed, cardiac-specific expression of a constitutively active inhibitor-1 results in selective enhancement of phospholamban phosphorylation and augmented cardiac contractility at the cellular and intact animal levels. Furthermore, the -adrenergic response is enhanced in the transgenic hearts compared with wild types. On aortic constriction, the hypercontractile cardiac function is maintained, hypertrophy is attenuated and there is no decompensation in the transgenics compared with wild-type controls. Notably, acute adenoviral gene delivery of the active inhibitor-1, completely restores function and partially reverses remodeling, including normalization of the hyperactivated p38, in the setting of pre-existing heart failure. Thus, the inhibitor 1 of the type 1 phosphatase may represent an attractive new therapeutic target.
Key Words: protein phosphatase 1 protein phosphatase 1 inhibitor 1 heart failure hypertrophy phospholamban gene therapy
Introduction
Reversible protein phosphorylation represents the cellular basis for integration of key signaling pathways, mediating a fine crosstalk between external effector molecules and intracellular events. In the heart, Ca2+ cycling and contractility are controlled by a fine balance of protein kinase and phosphatase activities in response to various second messenger signals. Demands on the heart’s pumping action, during fight-or-flight situations, can increase human cardiac output by nearly 5-fold. This is linked to -adrenergic activation of the cAMP dependent protein kinase (PKA). PKA then phosphorylates a set of key regulatory Ca2+ handling proteins that control excitation-contraction coupling cycle, such as phospholamban, the ryanodine receptor, the L-type Ca2+ channel, and troponin I.1
The protein kinases and their phosphoprotein substrates underlying augmentation of the heart’s pumping action have been well characterized. However, similar studies on the protein phosphatases, reversing the increased cardiac contractility, are less well developed. The major Ser/Thr phosphatases [type 1, type 2A, and type 2B (calcineurin)] stem from a common gene family and are highly homologous proteins (40% to 50%) that play critical roles in the control of cardiac contractility and hypertrophy.
Overexpression of the catalytic subunit of the protein phosphatase 1 at similar levels observed in human heart failure was associated with dephosphorylation of phospholamban, depressed cardiac function, dilated cardiomyopathy, and premature mortality.2 Furthermore, PP2A and PP2B (calcineurin) overexpression have been shown to result in decreased function and pathological hypertrophy.3,4
In human and experimental heart failure, the activity of the type 1 phosphatase, associated with the sarcoplasmic reticulum (SR) is significantly increased.5,6 It has been suggested that this increase may be a contributing factor to depressed function, dilated cardiomyopathy, and premature death.2 Some studies indicate that the increased SR-protein phosphatase 1 activity5 may be due to dephosphorylation of its inhibitor protein, inhibitor-1.2,7 Accordingly, expression of the constitutively active inhibitor-1 in human failing cardiomyocytes2 increased contractility, indicating that this may represent a viable approach for enhancing the depressed function in heart failure. However, even though such inhibition of protein phosphatase 1, leading to enhanced PKA phosphorylation of calcium-handling proteins, may be initially beneficial, it may become detrimental in the long term. Specifically, phosphorylation of the ryanodine receptor may alter its function by changing its sensitivity to calcium. This would result in leaky channels, which may cause diastolic calcium increases and exacerbate contractile dysfunction.8 To address the potential benefits and limitations of chronic protein phosphatase 1 suppression, we used transgenesis and gene-transfer of the constitutively active inhibitor-1. Our findings indicate that inhibition of the type 1 phosphatase is associated with enhanced cardiac function in the long term and may confer protection against heart failure propensity. Furthermore, acute gene transfer of active inhibitor-1 in failing hearts restores cardiac function and rescues left-ventricular contractility. The beneficial effects of inhibitor-1 are mediated, at least partially, through increased phospholamban phosphorylation. Thus, the inhibitor-1 of protein phosphatase 1 may hold promise as a therapeutic agent in heart failure.
Materials and Methods
Generation of Mice
A 5.6-kb transgene, consisting of the -MHC promoter, the mouse I-T35D (AA1eC65) cDNA, and the simian virus 40 polyadenylation site was used for pronuclear microinjection. The transgenic (TG) mice were generated at the University of Cincinnati and were handled as approved by the Institutional Animal Care and Use Committee.
Cardiac Function
In vivo cardiac function was assessed by noninvasive echocardiography, whereas in vitro contractility was examined using the Langendorff perfusion system. Cardiac catheritization and pressure-volume loop measurements in the murine heart were performed, as previously reported.9
An expanded Materials and Methods section can be found in the online data supplement available at http://www.circresaha.org.
Results
Expression of the Active Inhibitor-1 In Vivo Enhances Cardiac Function
To determine the long-term in vivo effects of decreased protein phosphatase 1 activity, we expressed a constitutively active, truncated inhibitor-1 (I1c) in a cardiomyocyte restricted manner. This form of inhibitor-1 was chosen because it specifically inhibits protein phosphatase 1, albeit at higher concentration than the native phosphorylated inhibitor.10
Three transgenic lines were obtained with similar levels of active inhibitor-1 expression. Echocardiographic assessment revealed enhanced basal contractility (see supplemental Table I, available in the online data supplement). Moreover, cardiac function was similarly increased at 6 months of age and longevity studies [19 wild type (WT) and 19 TG] indicated no evidence of sudden death, whereas Kaplan-Meier survival analysis up to 2 years of age revealed no significant differences in mortality rates. Subsequent studies were performed with mice from transgenic line C. Transgenic hearts exhibited a significant decrease (15%) in cardiac protein phosphatase 1 activity (Figure 1A) without changes in its protein level or protein phosphatase 2A activity. The apparent modest decrease in in vitro enzymatic activity may not be reflective of the in vivo activity associated with phospholamban.
Langendorff perfused hearts also indicated enhanced cardiac contractility. In active inhibitor-1eCexpressing hearts, the maximal left ventricular pressure was increased (23%) and the +dP/dt and eCdP/dt were augmented by 39% and 36%, relative to wild-type cohorts (Figure 1B). Accordingly, isolated calcium-tolerant cardiomyocytes exhibited increases (56%) in fractional shortening. Rates of myocyte shortening (eCdL/dt) and relengthening (+dL/dt) were also enhanced over 2-fold by active inhibitor-1 expression (Figure 1C). The times to 50% peak and relaxation were significantly abbreviated. Furthermore, on maximal stimulation with isoproterenol (100 nmol/L) both ±dL/dt continued to be enhanced (Figure 1C). The alterations in mechanical parameters reflected similar enhancement in calcium cycling. The amplitude of calcium transients was increased, and the time to 50% decay of the Ca2+ signal (T50) was reduced by 37% (Figure 1D), suggesting enhanced SERCA2 function. Remarkably, even under isoproterenol stimulation, the active inhibitor-1 cardiomyocytes continued to exhibit an abbreviated T50 (Figure 1D), consistent with the enhanced phosphorylation of phospholamban compared with wild-type stimulated cells (supplemental Figure I). However, the amplitude of the calcium transient was not different from WTs (Figure 1D).
Effect of Active Inhibitor-1 on Ca2+ Handling Proteins
As described, -adrenergic receptoreCdependent protein phosphorylation of key regulatory phosphoproteins, such as phospholamban, the ryanodine receptor, troponin I, and the L-type calcium channel, constitutes a critical regulatory mechanism that governs Ca2+ cycling and cardiac contractility. Thus, we investigated the expression and phosphorylation levels of these key substrates in our transgenic model. There was no significant difference in -adrenergic receptor density (data not shown). However, phosphorylation of phospholamban at both its cAMP-dependent (Ser16) and Ca2+/calmodulin-dependent (Thr17) protein kinase sites was increased significantly compared with wild types (Figure 2A), consistent with previous reports that protein phosphatase 1 is the predominant phospholamban phosphatase.11 Interestingly, the cardiac ryanodine receptor protein levels were decreased by 26%, whereas the relative (mol Pi/mol RyR2) phosphorylation of this channel was not altered (Figure 2A). In addition, the phosphorylation level of troponin I was not different between WT and transgenics (Figure 2A).
There were no alterations in L-type Ca2+ channel protein levels, and examination of the channel activity revealed that the mean peak Ca2+ current (ICa) and the steady-state inactivation of the current-voltage relationship (I-V) were similar between active inhibitor-1 and WT myocytes. However, inactivation of ICa was faster in the transgenics (Figure 2B), similar to previous observations in the hyperdynamic phospholamban knock-out myocytes.12
Importantly, we investigated glycogen metabolism and observed no significant difference in glycogen synthase and glycogen phosphorylase activities, between the WTs and transgenics.
Active Inhibitor-1 Attenuates Functional and Morphological Deterioration on Chronic Pressure-Overload
To examine the hypothesis that the active inhibitor-1 expression, associated with enhanced Ca2+ cycling, may be protective against cardiac remodeling induced by hemodynamic stress, we subjected the transgenic and isogenic wild-type mice to banding of the transverse aorta. Function was evaluated by echocardiography and cardiac catheterization. Echocardiography revealed that banded transgenic mice did not exhibit the pathological increases in left-ventricular end-diastolic and end-systolic dimensions, observed in banded wild-types (Figure 3A; supplemental Table I). The h/r ratio was also markedly increased in the banded inhibitor-1 mice (Figure 3B), consistent with a more compensated hypertrophy and reduced wall-stress, as determined by La Place’s law.
Although transaortic gradients were similar between the two groups (WT: 55.3±3.68; TG: 53.9±4.64, mm Hg), banded transgenic hearts exhibited less hypertrophy than wild types (Figure 3B), even under similar pressure gradients (Figure 3C). Furthermore, the rate of pressure development of banded inhibitor-1 mice was superior to that of banded wild types at similar pressure gradients (Figure 3C). Examination of lung weights also revealed significant increases in banded wild types, whereas banded transgenics were not different from sham-operated animals. Importantly, the alterations in lung weight were different at similar pressure gradients (Figure 3D).
Aortic constriction was also associated with a functional decline in banded wild types, whereas function was fully preserved in the inhibitor-1 mice, compared with their sham-operated cohorts (Figure 4A). In addition, the dobutamine response of the contraction rate (+dP/dt) was blunted in banded WTs, whereas this response was preserved in the banded inhibitor-1 group. Similarly, the end-diastolic volume (EDV) was only increased in the banded WTs, whereas it was not altered in the banded transgenics (Figure 4B). Representative occlusion analysis pressure-volume loops from these groups are shown in Figure 4C. The slope of the end-systolic pressure-volume relationship (ESPVR) was similar between WTs and transgenics under baseline conditions. However, on pressure-overload, this variable was significantly greater only in the banded transgenics (WT sham: 4.1±1.1; WT banded 7.4±2.0, mm Hg/e蘈; TG sham 4.5±0.5; TG banded 12.2±3.6 mm Hg/e蘈). Similar results were observed for preload-recruitable stroke work and time-varying maximal elastance (Emax). Interestingly, peripheral perfusion pressure was well-preserved in the inhibitor-1 banded mice (I1 sham: 108.6±6.9; I1 banded: 98.5±21.9 mm Hg; P=0.30), whereas it significantly declined in banded WTs (WT sham: 82.5±6.9; WT banded: 31.4±2.0, mm Hg), further supporting the well compensated stage of hypertrophy in the transgenics.
Further examination of the hearts revealed morphological enlargement and increased interstitial fibrosis in banded WTs relative to their transgenic counterparts (Figure 5A). Wheat germ agglutinin staining indicated that the cardiomyocyte cross sectional area in banded WTs was substantially increased, relative to banded transgenics (Figure 5B). Given the antihypertrophic effects of inhibitor-1, we examined the MAP-kinase hypertrophic pathways. There was a significant decrease in ERK1/2 activation in the banded transgenics compared with their WT cohorts, but the activation of p38 was not different (Figure 5C). Further examination of other pathways (PKC- and CREB) revealed no alterations. However, expression levels of ANF and -MHC were significantly increased in the banded WTs, although these genes were not elevated in banded inhibitor-1 hearts.
The protective effects of inhibitor-1 were not associated with any alterations in the levels of phospholamban, SERCA, and calsequestrin but the phosphorylation of phospholamban at Ser16 was markedly increased (Figure 5D), under baseline control conditions as well as posttransverse aortic constriction. There were no differences in the phosphorylation of phospholamban at Thr17 or the ryanodine receptor at Ser2809.
Active Inhibitor-1 Expression Rescues a Rat Model of Cardiac Pressure-Overload Hypertrophy in Transition to Failure
Because the studies in our transgenic model suggested that chronic expression of active inhibitor-1 may attenuate hypertrophy and functional deterioration, we investigated whether short-term expression of this inhibitor-1 could improve hemodynamics in the setting of preexisting heart failure. Thus, we used a rat model of pressure overload, which exhibits characteristics of heart failure by 22 weeks after banding.13 When decreases of more than 25% in left ventricular fractional shortening were observed, gene transfer was performed. Delivery of active inhibitor-1 or the reporter gene (GFP) induced an expression pattern that was grossly homogenous throughout the ventricles in failing and nonfailing hearts at one week after gene transfer. The expression level of the active inhibitor-1 was also confirmed by immunoblotting (Figure 6A) and biochemical assays indicated a decrease in type 1 phosphatase activity with no effect on type 2A activity (Figure 6B).
Remarkably, gene transfer of the active inhibitor-1 restored the rate of pressure rise (+dP/dt) to non-failing levels (Figure 6C), whereas left ventricular function was decreased in the failing control group (Figure 6C). Diastolic parameters were also normalized, as evidenced by restoration of the maximal rate of decline of left ventricular systolic pressure (eCdP/dt) and the time course for pressure decline, measured by tau (), the isovolumic relaxation constant (Figure 6D).
To further define ventricular function in a load-independent fashion, pressure-volume analysis was performed (Figure 6E). The maximal slope of the end-systolic pressure dimension relationship (Emax, or Maximal Elastance) was lower in failing hearts, infected with control virus (Ad.GFP), compared with nonfailing hearts, indicating a diminished state of intrinsic myocardial contractility. Importantly, the expression of the active inhibitor-1 completely restored the maximal elastance to nonfailing levels (Figure 6F).
Biochemical characterization revealed that the SERCA2a levels were significantly decreased in the failing hearts, consistent with previous reports,13 and they remained depressed on control or active inhibitor-1 gene transfer. The levels of phospholamban or the ryanodine receptor were not different (Figure 7A). Phosphorylation of phospholamban at serine 16 was significantly depressed in failing hearts, but adenoviral gene transfer of the active inhibitor-1 significantly increased it (Figure 7B). Interestingly, both failing groups infected with either control or active inhibitor-1 virus, exhibited increases in Thr-17 phosphorylation of phospholamban (Figure 7B), consistent with increased CAM-kinase activity (see online data supplement). The phosphorylation level of the ryanodine receptor at serine 2809 was also increased in the failing groups, and infection with the active inhibitor-1 had no effect (Figure 7B).
Examination of the effects of active inhibitor-1 on MAP-kinase activation indicated a complete reversal of the overactivated p38-MAP kinase, with no alteration in ERK or JNK activation (Figure 7C). Thus, the enhanced contractility and relaxation, associated with active inhibitor-1 gene transfer, may decrease wall tension leading to normalization of the p38 MAP-kinase.
Discussion
In the present study, we found that chronic increases in the activation of the protein phosphatase 1 inhibitor-1 are associated with enhanced cardiac contractility and may be protective against the development of cardiac hypertrophy and deterioration of function in the face of increased hemodynamic load. Importantly, acute increases in active inhibitor-1 protein also results in improved function and attenuated remodeling in the setting of preexisting heart failure. To our knowledge, this is the first report demonstrating the efficacy of selective therapeutic protein phosphatase 1 targeting by its inhibitor-1 in the settings of hypertrophy, heart failure, and the transition to heart failure. The beneficial effects of inhibitor-1 may be associated with increases in PLN phosphorylation, because the phosphorylation status of other key phosphoproteins, RyR and troponin I, were not affected. Such unique preference of inhibitor-1 may be important from a therapeutic point of view because inhibition of PLN, and the subsequent enhancement of SR Ca2+ ATPase activity, has been suggested to be beneficial in experimental and genetic heart failure.14,15
In failing hearts, the downregulation of -adrenergic receptors and decreased cAMP-dependent protein kinase activity results in decreased phosphorylation (Threonine 35) and inactivation of inhibitor-1, leading to increased protein phosphatase 1 activity2,5 and dephosphorylation of key phosphoproteins, including phospholamban.16,17 Interestingly, hypophosphorylation of inhibitor-1 in heart failure may also reflect enhanced activity of calcineurin (PP2B).18 This fine cross talk between cAMP and Ca2+ at the level of inhibitor 1 has been recently shown to be complemented by PKC-, a calcium-dependent PKC isoform, which phosphorylates the inhibitor-1 at a different site, Ser67, and reduces its activity.19 Indeed, ablation of PKC- is associated with decreased phosphatase activity and enhanced function.19 Thus, inhibitor 1 appears to be an integrator of multiple neurohormonal pathways, associated with regulation of cardiac function and hypertrophy.
Active Inhibitor-1 Enhances Basal Cardiac Contractility
Inhibitor-1 has been shown to regulate synaptic mechanisms involved in learning and memory,20,21 as well as the adrenergic and cholinergic pathways in the heart.22 Although this phosphoprotein has long been known to play a major regulatory role in neuronal tissue,20,23 its significance in the heart has only recently been emerging. Previous studies indicated that genetic ablation of inhibitor-1 resulted in depressed cardiac contractility,2 whereas adenoviral infection of rat cardiomyocytes with inhibitor-1 enhanced cardiac contractility.24
Expression of the active inhibitor-1 in the transgenic mouse heart appeared to specifically increase phosphorylation of phospholamban at Ser16 and Thr17, without altering the phosphorylation levels of the ryanodine receptor and troponin I. This finding was unexpected because both the ryanodine receptor and troponin I are substrates for protein kinase A, similar to phospholamban. Increases in troponin I phosphorylation would be expected to decrease myofilament sensitivity to Ca2+, whereas increases in ryanodine receptor phosphorylation would cause SR Ca2+ leakage and arrhythmias,8 both counteractive to the beneficial effects of the active inhibitor observed in this study. Importantly, there were no sudden deaths linked to arrhythmias in the inhibitor-1 mice. However, the protein levels of the ryanodine receptor were decreased in the transgenic hearts with enhanced contractility, similar to our previous findings in the phospholamban-knockout hyperdynamic hearts.25 Thus, downregulation of the ryanodine receptor may represent an important compensatory response to maintain calcium homeostasis in models where SR Ca2+-cycling and SR Ca2+-load are increased.
It has been suggested that besides protein phosphatase 1, other phosphatases, such as protein phosphatase 2A, also regulate cardiac function.4 However, the activity of this phosphatase does not appear to change in vivo on isoproterenol stimulation.22 Importantly, the type 2A phosphatase activity was unaffected in the inhibitor-1 transgenic hearts. The apparent specificity of the active inhibitor-1 for the phospholamban-phosphatase may involve its specific anchoring subunit and the relative affinity between the catalytic and binding subunits of this enzyme in the various macromolecular complexes.26 Future phosphoproteomic studies may reveal novel, yet unknown, substrates for protein phosphatase 1/inhibitor-1, which also participate in the augmentation of cardiac contractility in this model.25
Inhibitor-1 Prevents Cardiac Dysfunction and Delays Hypertrophy
To assess whether chronic expression of active inhibitor-1 and associated depressed protein phosphatase 1 activity may be protective against pathological progression of cardiac hypertrophy, the transgenic mice underwent transverse aortic constriction, along with their isogenic wild-type cohorts. Active inhibitor-1 expression was protective against functional deterioration and the geometric alterations leading to cardiac dilatation. The augmentation of phospholamban phosphorylation at Ser16 persisted in the active inhibitor-1 expressing hearts subjected to long-term aortic constriction, indicating enhanced SR Ca2+-cycling. Interestingly, the banded transgenic mice also exhibited decreased cardiac hypertrophy and decreased activation of the ERK1,2 MAP-kinase pathway. Regardless, our findings indicate a pivotal role of inhibitor-1 in protection against the stress of pressure overload on the heart.
Acute Gene Transfer of Active Inhibitor-1 Restores Function and Remodeling in the Failing Heart
The intricate balance of protein kinase and phosphatase activities is shifted in favor of the phosphatases in heart failure due to decreased PKA activation and increased protein phosphatase activity.5,27 To assess whether inhibition of this phosphatase by the active inhibitor-1 may have therapeutic effects in established heart-failure, we used a catheter-based adenoviral delivery technique to transfer this molecule into pressure overloadeCinduced failing rat hearts. Gene transfer resulted in relatively low expression levels of the active inhibitor-1 protein. However, because protein phosphatase 1 activity is chronically increased in heart failure, expression of the active inhibitor-1 resulted in substantial inhibition of this enzyme. This translated into increases in systolic pressure and the maximal rates of pressure development, as well as a decrease in the time constant of isovolumic relaxation, which indicates enhanced active relaxation. Furthermore, the maximal elastance of the failing rat hearts, treated with the constitutively active inhibitor-1, was restored to normal, indicating complete rescue of intrinsic contractility and contractile reserve.
At the SR level, SERCA2 protein decreased significantly in failing-hearts, consistent with previous studies.13 There were no differences in phospholamban or ryanodine receptor levels, but phospholamban was hypophosphorylated at Ser16 and hyperphosphorylated at Thr17, consistent with the increased CaM-Kinase activity in these hearts. Importantly, the phosphorylation of the ryanodine receptor was increased in the failing hearts, further confirming that there may be compartmentalization of protein kinase/phosphatase signaling in the SR.
Gene transfer of the active inhibitor-1 was associated with improved function and enhanced phosphorylation of phospholamban. There were no differences in ryanodine receptor phosphorylation levels. These paradoxical findings further exemplify the complex interplay between kinases and phosphatases in the microenvironment of each phosphoprotein. The enhanced phospholamban phosphorylation, leading to enhanced SR calcium-transport and reduced diastolic calcium levels, was probably the predominant mechanism underlying improved contractility in failing hearts in the absence of reversal of other biochemical changes characteristic of heart failure. Similar findings were observed by direct phospholamban inhibition in various experimental models of heart failure.15,28 These studies are also consistent with our previous work, showing that cardiac overexpression of protein phosphatase 1 decreased phospholamban phosphorylation and resulted in dilated cardiomyopathy and heart failure.2 Thus, the active inhibitor-1 may offer a novel approach to interfere with the phospholamban/SERCA2a interaction, independent of the yet unsuccessful strategy of targeting the highly hydrophobic phospholamban by small molecules or antibodies.
Importantly, the active inhibitor-1 gene transfer resulted in partial rescue of the cardiac geometric alterations, associated with heart failure, and complete normalization of the hyperactive p38 MAP-kinase. However, future studies should address the long-term effects of active inhibitor-1 on cardiac function, molecular pathways, and survival.
Limitations of This Study
The present study along with a number of other recent ex vivo and in vivo reports indicate that SR Ca2+-transport may represent a nodal point in the progression of compensatory hypertrophy and heart failure.2,11,29,30 Accordingly, restoring the depressed SR Ca2+-cycling through increased SERCA2a expression or decreased activity of PLN has been shown to benefit experimental and genetic models of heart failure.13,31
However, concerns have been raised by recent genetic complementation studies with the phospholamban-null mouse. Although some genetic models of heart failure were rescued, others were not affected by phospholamban deficiency.15,32 Given that each genetic model carries a large number of secondary alterations, as compensatory responses to the insult by the genetic manipulation, the results from such complementation studies must be viewed with caution. Furthermore, phospholamban ablation did not appear to benefit cardiac function on sustained aortic constriction.33 However, the transaortic gradients were markedly greater in the knockout relative to WT mice,33 making direct comparisons difficult.
Nevertheless, the recent findings on human phospholamban mutants, associated with phospholamban ablation,34 raised additional concerns and challenges on the role of phospholamban and augmented SR Ca2+-cycling in the human heart. While the mechanism associated with the apparently null human phospholamban mutant is currently being explored, parallel studies in higher mammalian species may provide a better understanding of the potential benefit of restoring SR Ca2+-transport in the human failing heart.
Conclusion
The elegant balance between protein kinase and protein phosphatase activities, regulating cardiac function, shifts in favor of the protein phosphatases in heart failure. The present findings demonstrate that partial restoration of this balance through inhibitor-1 may represent a potential therapeutic intervention. Furthermore, chronic increases in this inhibitor-1 activity may enhance basal cardiac contractility and -adrenergic responses, as well as protect the heart against pressure overloadeCinduced hypertrophy. Unlike agents that increase cAMP, thereby increasing intracellular Ca2+, expression of the active inhibitor-1 improves cardiac function by targeting downstream substrates and by specifically enhancing SR Ca2+ cycling.
Acknowledgments
This work was supported in part by grants from the National Institutes of Health: HL26057, HL64018, and HL52318 (E.G.K.), HL 57623 (R.J.H.), DK36569 (A.A.D.-R.), HL07382eC27 (A.P.), and the American Heart Association Predoctoral Fellowship 0215138B (A.P.).
Both authors contributed equally.
Both senior authors contributed equally.
References
Bers DM. Cardiac excitation-contraction coupling. Nature. 2002; 415: 198eC205.
Carr AN, Schmidt AG, Suzuki Y, del Monte F, Sato Y, Lanner C, Breeden K, Jing SL, Allen PB, Greengard P, Yatani A, Hoit BD, Grupp IL, Hajjar RJ, DePaoli-Roach AA, Kranias EG. Type 1 phosphatase, a negative regulator of cardiac function. Mol Cell Biol. 2002; 22: 4124eC4135.
Molkentin JD, Lu JR, Antos CL, Markham B, Richardson J, Robbins J, Grant SR, Olson EN. A calcineurin-dependent transcriptional pathway for cardiac hypertrophy. Cell. 1998; 93: 215eC228.
Gergs U, Boknik P, Buchwalow I, Fabritz L, Matus M, Justus I, Hanske G, Schmitz W, Neumann J. Overexpression of the catalytic subunit of protein phosphatase 2A impairs cardiac function. J Biol Chem. 2004: 279: 40827eC40834.
Neumann J, Eschenhagen T, Jones LR, Linck B, Schmitz W, Scholz H, Zimmermann N. Increased expression of cardiac phosphatases in patients with end-stage heart failure. J Mol Cell Cardiol. 1997; 29: 265eC272.
Gupta RC, Tanimura M, Lesch M, Sabbah HN. Protein phosphatase activity is increased and phosphorylation state of phospholamban is decreased in myocardium of dogs with chronic heart failure. Circulation. 1997; 96: I-361.
El-Armouche A, Pamminger T, Ditz D, Zolk O, Eschenhagen T. Decreased protein and phosphorylation level of the protein phosphatase inhibitor-1 in failing human hearts. Cardiovasc Res. 2004; 61: 87eC93.
Marx SO, Reiken S, Hisamatsu Y, Jayaraman T, Burkhoff D, Rosemblit N, Marks AR. PKA phosphorylation dissociates FKBP12.6 from the calcium release channel (ryanodine receptor): defective regulation in failing hearts. Cell. 2000; 101: 365eC376.
Lips DJ, Nagel TVD, Steendijk P, Palmen M, Janssen BJ, Dantzig JV, Windt LJD, Doevendans PA. Left ventricular pressure-volume measurements in mice: Comparison of closed-chest versus open-chest approach. Basic Res Cardiol. 2004; 99: 351eC359.
Endo S, Zhou X, Connor J, Wang B, Shenolikar S. Multiple structural elements define the specificity of recombinant human inhibitor-1 as a protein phosphatase-1 inhibitor. Biochemistry. 1996; 35: 5220eC5228.
Kranias EG, Di Salvo J. A phospholamban protein phosphatase activity associated with cardiac sarcoplasmic reticulum. J Biol Chem. 1986; 261: 10029eC10032.
Masaki H, Sato Y, Luo W, Kranias EG, Yatani A. Phospholamban deficiency alters inactivation kinetics of L-type Ca2+ channels in mouse ventricular myocytes. Am J Physiol. 1997; 272: H606eCH612.
del Monte F, Williams E, Lebeche D, Schmidt U, Rosenzweig A, Gwathmey JK, Lewandowski ED, Hajjar RJ. Improvement in survival and cardiac metabolism after gene transfer of sarcoplasmic reticulum Ca2+-ATPase in a rat model of heart failure. Circulation. 2001; 104: 1424eC1429.
del Monte F, Harding SE, Schmidt U, Matsui T, Kang ZB, Dec GW, Gwathmey JK, Rosenzweig A, Hajjar RJ. Restoration of contractile function in isolated cardiomyocytes from failing human hearts by gene transfer of SERCA2a. Circulation. 1999; 100: 2308eC2311.
Minamisawa S, Hoshijima M, Chu G, Ward CA, Frank K, Gu Y, Martone ME, Wang Y, Ross J Jr, Kranias EG, Giles WR, Chien KR. Chronic phospholamban-sarcoplasmic reticulum calcium ATPase interaction is the critical calcium cycling defect in dilated cardiomyopathy. Cell. 1999; 99: 313eC322.
Schwinger RH, Bolck B, Munch G, Brixius K, Muller-Ehmsen J, Erdmann E. cAMP-dependent protein kinase A-stimulated sarcoplasmic reticulum function in heart failure. Ann NY Acad Sci. 1998; 853: 240eC250.
Dash R, Frank KF, Carr AN, Moravec CS, Kranias EG. Gender influences on sarcoplasmic reticulum Ca2+-handling in failing human myocardium. J Mol Cell Cardiol. 2001; 33: 1345eC1353.
Mulkey RM, Endo S, Shenolikar S, Malenka RC. Involvement of a calcineurin/inhibitor-1 phosphatase cascade in hippocampal long-term depression. Nature. 1994; 369: 486eC488.
Braz JC, Gregory K, Pathak A, Zhao W, Sahin B, Klevitsky R, Kimball TF, Lorenz JN, Nairn AC, Liggett SB, Bodi I, Wang S, Schwartz A, Lakatta EG, DePaoli-Roach AA, Robbins J, Hewett TE, Bibb JA, Westfall MV, Kranias EG, Molkentin JD. PKC-alpha regulates cardiac contractility and propensity toward heart failure. Nat Med. 2004; 10: 248eC254.
Genoux D, Haditsch U, Knobloch M, Michalon A, Storm D, Mansuy IM. Protein phosphatase 1 is a molecular constraint on learning and memory. Nature. 2002; 418: 970eC975.
Allen PB, Hvalby O, Jensen V, Errington ML, Ramsay M, Chaudhry FA, Bliss TV, Storm-Mathisen J, Morris RG, Andersen P, Greengard P. Protein phosphatase-1 regulation in the induction of long-term potentiation: heterogeneous molecular mechanisms. J Neurosci. 2000; 20: 3537eC3543.
Ahmad Z, Green FJ, Subuhi HS, Watanabe AM. Autonomic regulation of type 1 protein phosphatase in cardiac muscle. J Biol Chem. 1989; 264: 3859eC3863.
Nairn AC, Palfrey HC. Identification of the major Mr 100,000 substrate for calmodulin-dependent protein kinase III in mammalian cells as elongation factor-2. J Biol Chem. 1987; 262: 17299eC17303.
El-Armouche A, Rau T, Zolk O, Ditz D, Pamminger T, Zimmermann WH, Jackel E, Harding SE, Boknik P, Neumann J, Eschenhagen T. Evidence for protein phosphatase inhibitor-1 playing an amplifier role in beta-adrenergic signaling in cardiac myocytes. FASEB J. 2003; 17: 437eC439.
Chu G, Ferguson DG, Edes I, Kiss E, Sato Y, Kranias EG. Phospholamban ablation and compensatory responses in the mammalian heart. Ann NY Acad Sci. 1998; 853: 49eC62.
DePaoli-Roach AA. Protein Phosphatase 1 Binding Proteins. In: Handbook of Cell Signaling: Elsevier Science; 2003: 613eC619.
Bristow MR, Ginsburg R, Minobe W, Cubicciotti RS, Sageman WS, Lurie K, Billingham ME, Harrison DC, Stinson EB. Decreased catecholamine sensitivity and beta-adrenergic-receptor density in failing human hearts. N Engl J Med. 1982; 307: 205eC211.
Hoshijima M, Ikeda Y, Iwanaga Y, Minamisawa S, Date MO, Gu Y, Iwatate M, Li M, Wang L, Wilson JM, Wang Y, Ross J, Jr., Chien KR. Chronic suppression of heart-failure progression by a pseudophosphorylated mutant of phospholamban via in vivo cardiac rAAV gene delivery. Nat Med. 2002; 8: 864eC871.
Gwathmey JK, Copelas L, MacKinnon R, Schoen FJ, Feldman MD, Grossman W, Morgan JP. Abnormal intracellular calcium handling in myocardium from patients with end-stage heart failure. Circ Res. 1987; 61: 70eC76.
Gwathmey JK, Morgan JP. Altered calcium handling in experimental pressure-overload hypertrophy in the ferret. Circ Res. 1985; 57: 836eC843.
del Monte F, Harding SE, Dec GW, Gwathmey JK, Hajjar RJ. Targeting phospholamban by gene transfer in human heart failure. Circulation. 2002; 105: 904eC907.
Song Q, Schmidt AG, Hahn HS, Carr AN, Frank B, Pater L, Gerst M, Young K, Hoit BD, McConnell BK, Haghighi K, Seidman CE, Seidman JG, Dorn GW II, Kranias EG. Rescue of cardiomyocyte dysfunction by phospholamban ablation does not prevent ventricular failure in genetic hypertrophy. J Clin Invest. 2003; 111: 859eC867.
Kiriazis H, Sato Y, Kadambi VJ, Schmidt AG, Gerst MJ, Hoit BD, Kranias EG. Hypertrophy and functional alterations in hyperdynamic phospholamban-knockout mouse hearts under chronic aortic stenosis. Cardiovasc Res. 2002; 53: 372eC381.
Haghighi K, Kolokathis F, Pater L, Lynch RA, Asahi M, Gramolini AO, Fan GC, Tsiapras D, Hahn HS, Adamopoulos S, Liggett SB, Dorn GW II, MacLennan DH, Kremastinos DT, Kranias EG. Human phospholamban null results in lethal dilated cardiomyopathy revealing a critical difference between mouse and human. J Clin Invest. 2003; 111: 869eC876.(Anand Pathak, Federica de)
Molecular Genetics and Biochemistry (L.J.), University of Cincinnati, Ohio
Cardiology Division (F.d.M., E.K.H., J.L.G., R.J.H.), Harvard Medical School and Massachusetts General Hospital, Boston, Mass
Department of Pharmacology and Cancer Biology (D.W.), Duke University Medical Center, Durham, NC
Department of Biochemistry and Molecular Biology (N.M., A.A.D.-R.), Indiana University, Indianapolis, Ind.
Abstract
Abnormal calcium cycling, characteristic of experimental and human heart failure, is associated with impaired sarcoplasmic reticulum calcium uptake activity. This reflects decreases in the cAMP-pathway signaling and increases in type 1 phosphatase activity. The increased protein phosphatase 1 activity is partially due to dephosphorylation and inactivation of its inhibitor-1, promoting dephosphorylation of phospholamban and inhibition of the sarcoplasmic reticulum calcium-pump. Indeed, cardiac-specific expression of a constitutively active inhibitor-1 results in selective enhancement of phospholamban phosphorylation and augmented cardiac contractility at the cellular and intact animal levels. Furthermore, the -adrenergic response is enhanced in the transgenic hearts compared with wild types. On aortic constriction, the hypercontractile cardiac function is maintained, hypertrophy is attenuated and there is no decompensation in the transgenics compared with wild-type controls. Notably, acute adenoviral gene delivery of the active inhibitor-1, completely restores function and partially reverses remodeling, including normalization of the hyperactivated p38, in the setting of pre-existing heart failure. Thus, the inhibitor 1 of the type 1 phosphatase may represent an attractive new therapeutic target.
Key Words: protein phosphatase 1 protein phosphatase 1 inhibitor 1 heart failure hypertrophy phospholamban gene therapy
Introduction
Reversible protein phosphorylation represents the cellular basis for integration of key signaling pathways, mediating a fine crosstalk between external effector molecules and intracellular events. In the heart, Ca2+ cycling and contractility are controlled by a fine balance of protein kinase and phosphatase activities in response to various second messenger signals. Demands on the heart’s pumping action, during fight-or-flight situations, can increase human cardiac output by nearly 5-fold. This is linked to -adrenergic activation of the cAMP dependent protein kinase (PKA). PKA then phosphorylates a set of key regulatory Ca2+ handling proteins that control excitation-contraction coupling cycle, such as phospholamban, the ryanodine receptor, the L-type Ca2+ channel, and troponin I.1
The protein kinases and their phosphoprotein substrates underlying augmentation of the heart’s pumping action have been well characterized. However, similar studies on the protein phosphatases, reversing the increased cardiac contractility, are less well developed. The major Ser/Thr phosphatases [type 1, type 2A, and type 2B (calcineurin)] stem from a common gene family and are highly homologous proteins (40% to 50%) that play critical roles in the control of cardiac contractility and hypertrophy.
Overexpression of the catalytic subunit of the protein phosphatase 1 at similar levels observed in human heart failure was associated with dephosphorylation of phospholamban, depressed cardiac function, dilated cardiomyopathy, and premature mortality.2 Furthermore, PP2A and PP2B (calcineurin) overexpression have been shown to result in decreased function and pathological hypertrophy.3,4
In human and experimental heart failure, the activity of the type 1 phosphatase, associated with the sarcoplasmic reticulum (SR) is significantly increased.5,6 It has been suggested that this increase may be a contributing factor to depressed function, dilated cardiomyopathy, and premature death.2 Some studies indicate that the increased SR-protein phosphatase 1 activity5 may be due to dephosphorylation of its inhibitor protein, inhibitor-1.2,7 Accordingly, expression of the constitutively active inhibitor-1 in human failing cardiomyocytes2 increased contractility, indicating that this may represent a viable approach for enhancing the depressed function in heart failure. However, even though such inhibition of protein phosphatase 1, leading to enhanced PKA phosphorylation of calcium-handling proteins, may be initially beneficial, it may become detrimental in the long term. Specifically, phosphorylation of the ryanodine receptor may alter its function by changing its sensitivity to calcium. This would result in leaky channels, which may cause diastolic calcium increases and exacerbate contractile dysfunction.8 To address the potential benefits and limitations of chronic protein phosphatase 1 suppression, we used transgenesis and gene-transfer of the constitutively active inhibitor-1. Our findings indicate that inhibition of the type 1 phosphatase is associated with enhanced cardiac function in the long term and may confer protection against heart failure propensity. Furthermore, acute gene transfer of active inhibitor-1 in failing hearts restores cardiac function and rescues left-ventricular contractility. The beneficial effects of inhibitor-1 are mediated, at least partially, through increased phospholamban phosphorylation. Thus, the inhibitor-1 of protein phosphatase 1 may hold promise as a therapeutic agent in heart failure.
Materials and Methods
Generation of Mice
A 5.6-kb transgene, consisting of the -MHC promoter, the mouse I-T35D (AA1eC65) cDNA, and the simian virus 40 polyadenylation site was used for pronuclear microinjection. The transgenic (TG) mice were generated at the University of Cincinnati and were handled as approved by the Institutional Animal Care and Use Committee.
Cardiac Function
In vivo cardiac function was assessed by noninvasive echocardiography, whereas in vitro contractility was examined using the Langendorff perfusion system. Cardiac catheritization and pressure-volume loop measurements in the murine heart were performed, as previously reported.9
An expanded Materials and Methods section can be found in the online data supplement available at http://www.circresaha.org.
Results
Expression of the Active Inhibitor-1 In Vivo Enhances Cardiac Function
To determine the long-term in vivo effects of decreased protein phosphatase 1 activity, we expressed a constitutively active, truncated inhibitor-1 (I1c) in a cardiomyocyte restricted manner. This form of inhibitor-1 was chosen because it specifically inhibits protein phosphatase 1, albeit at higher concentration than the native phosphorylated inhibitor.10
Three transgenic lines were obtained with similar levels of active inhibitor-1 expression. Echocardiographic assessment revealed enhanced basal contractility (see supplemental Table I, available in the online data supplement). Moreover, cardiac function was similarly increased at 6 months of age and longevity studies [19 wild type (WT) and 19 TG] indicated no evidence of sudden death, whereas Kaplan-Meier survival analysis up to 2 years of age revealed no significant differences in mortality rates. Subsequent studies were performed with mice from transgenic line C. Transgenic hearts exhibited a significant decrease (15%) in cardiac protein phosphatase 1 activity (Figure 1A) without changes in its protein level or protein phosphatase 2A activity. The apparent modest decrease in in vitro enzymatic activity may not be reflective of the in vivo activity associated with phospholamban.
Langendorff perfused hearts also indicated enhanced cardiac contractility. In active inhibitor-1eCexpressing hearts, the maximal left ventricular pressure was increased (23%) and the +dP/dt and eCdP/dt were augmented by 39% and 36%, relative to wild-type cohorts (Figure 1B). Accordingly, isolated calcium-tolerant cardiomyocytes exhibited increases (56%) in fractional shortening. Rates of myocyte shortening (eCdL/dt) and relengthening (+dL/dt) were also enhanced over 2-fold by active inhibitor-1 expression (Figure 1C). The times to 50% peak and relaxation were significantly abbreviated. Furthermore, on maximal stimulation with isoproterenol (100 nmol/L) both ±dL/dt continued to be enhanced (Figure 1C). The alterations in mechanical parameters reflected similar enhancement in calcium cycling. The amplitude of calcium transients was increased, and the time to 50% decay of the Ca2+ signal (T50) was reduced by 37% (Figure 1D), suggesting enhanced SERCA2 function. Remarkably, even under isoproterenol stimulation, the active inhibitor-1 cardiomyocytes continued to exhibit an abbreviated T50 (Figure 1D), consistent with the enhanced phosphorylation of phospholamban compared with wild-type stimulated cells (supplemental Figure I). However, the amplitude of the calcium transient was not different from WTs (Figure 1D).
Effect of Active Inhibitor-1 on Ca2+ Handling Proteins
As described, -adrenergic receptoreCdependent protein phosphorylation of key regulatory phosphoproteins, such as phospholamban, the ryanodine receptor, troponin I, and the L-type calcium channel, constitutes a critical regulatory mechanism that governs Ca2+ cycling and cardiac contractility. Thus, we investigated the expression and phosphorylation levels of these key substrates in our transgenic model. There was no significant difference in -adrenergic receptor density (data not shown). However, phosphorylation of phospholamban at both its cAMP-dependent (Ser16) and Ca2+/calmodulin-dependent (Thr17) protein kinase sites was increased significantly compared with wild types (Figure 2A), consistent with previous reports that protein phosphatase 1 is the predominant phospholamban phosphatase.11 Interestingly, the cardiac ryanodine receptor protein levels were decreased by 26%, whereas the relative (mol Pi/mol RyR2) phosphorylation of this channel was not altered (Figure 2A). In addition, the phosphorylation level of troponin I was not different between WT and transgenics (Figure 2A).
There were no alterations in L-type Ca2+ channel protein levels, and examination of the channel activity revealed that the mean peak Ca2+ current (ICa) and the steady-state inactivation of the current-voltage relationship (I-V) were similar between active inhibitor-1 and WT myocytes. However, inactivation of ICa was faster in the transgenics (Figure 2B), similar to previous observations in the hyperdynamic phospholamban knock-out myocytes.12
Importantly, we investigated glycogen metabolism and observed no significant difference in glycogen synthase and glycogen phosphorylase activities, between the WTs and transgenics.
Active Inhibitor-1 Attenuates Functional and Morphological Deterioration on Chronic Pressure-Overload
To examine the hypothesis that the active inhibitor-1 expression, associated with enhanced Ca2+ cycling, may be protective against cardiac remodeling induced by hemodynamic stress, we subjected the transgenic and isogenic wild-type mice to banding of the transverse aorta. Function was evaluated by echocardiography and cardiac catheterization. Echocardiography revealed that banded transgenic mice did not exhibit the pathological increases in left-ventricular end-diastolic and end-systolic dimensions, observed in banded wild-types (Figure 3A; supplemental Table I). The h/r ratio was also markedly increased in the banded inhibitor-1 mice (Figure 3B), consistent with a more compensated hypertrophy and reduced wall-stress, as determined by La Place’s law.
Although transaortic gradients were similar between the two groups (WT: 55.3±3.68; TG: 53.9±4.64, mm Hg), banded transgenic hearts exhibited less hypertrophy than wild types (Figure 3B), even under similar pressure gradients (Figure 3C). Furthermore, the rate of pressure development of banded inhibitor-1 mice was superior to that of banded wild types at similar pressure gradients (Figure 3C). Examination of lung weights also revealed significant increases in banded wild types, whereas banded transgenics were not different from sham-operated animals. Importantly, the alterations in lung weight were different at similar pressure gradients (Figure 3D).
Aortic constriction was also associated with a functional decline in banded wild types, whereas function was fully preserved in the inhibitor-1 mice, compared with their sham-operated cohorts (Figure 4A). In addition, the dobutamine response of the contraction rate (+dP/dt) was blunted in banded WTs, whereas this response was preserved in the banded inhibitor-1 group. Similarly, the end-diastolic volume (EDV) was only increased in the banded WTs, whereas it was not altered in the banded transgenics (Figure 4B). Representative occlusion analysis pressure-volume loops from these groups are shown in Figure 4C. The slope of the end-systolic pressure-volume relationship (ESPVR) was similar between WTs and transgenics under baseline conditions. However, on pressure-overload, this variable was significantly greater only in the banded transgenics (WT sham: 4.1±1.1; WT banded 7.4±2.0, mm Hg/e蘈; TG sham 4.5±0.5; TG banded 12.2±3.6 mm Hg/e蘈). Similar results were observed for preload-recruitable stroke work and time-varying maximal elastance (Emax). Interestingly, peripheral perfusion pressure was well-preserved in the inhibitor-1 banded mice (I1 sham: 108.6±6.9; I1 banded: 98.5±21.9 mm Hg; P=0.30), whereas it significantly declined in banded WTs (WT sham: 82.5±6.9; WT banded: 31.4±2.0, mm Hg), further supporting the well compensated stage of hypertrophy in the transgenics.
Further examination of the hearts revealed morphological enlargement and increased interstitial fibrosis in banded WTs relative to their transgenic counterparts (Figure 5A). Wheat germ agglutinin staining indicated that the cardiomyocyte cross sectional area in banded WTs was substantially increased, relative to banded transgenics (Figure 5B). Given the antihypertrophic effects of inhibitor-1, we examined the MAP-kinase hypertrophic pathways. There was a significant decrease in ERK1/2 activation in the banded transgenics compared with their WT cohorts, but the activation of p38 was not different (Figure 5C). Further examination of other pathways (PKC- and CREB) revealed no alterations. However, expression levels of ANF and -MHC were significantly increased in the banded WTs, although these genes were not elevated in banded inhibitor-1 hearts.
The protective effects of inhibitor-1 were not associated with any alterations in the levels of phospholamban, SERCA, and calsequestrin but the phosphorylation of phospholamban at Ser16 was markedly increased (Figure 5D), under baseline control conditions as well as posttransverse aortic constriction. There were no differences in the phosphorylation of phospholamban at Thr17 or the ryanodine receptor at Ser2809.
Active Inhibitor-1 Expression Rescues a Rat Model of Cardiac Pressure-Overload Hypertrophy in Transition to Failure
Because the studies in our transgenic model suggested that chronic expression of active inhibitor-1 may attenuate hypertrophy and functional deterioration, we investigated whether short-term expression of this inhibitor-1 could improve hemodynamics in the setting of preexisting heart failure. Thus, we used a rat model of pressure overload, which exhibits characteristics of heart failure by 22 weeks after banding.13 When decreases of more than 25% in left ventricular fractional shortening were observed, gene transfer was performed. Delivery of active inhibitor-1 or the reporter gene (GFP) induced an expression pattern that was grossly homogenous throughout the ventricles in failing and nonfailing hearts at one week after gene transfer. The expression level of the active inhibitor-1 was also confirmed by immunoblotting (Figure 6A) and biochemical assays indicated a decrease in type 1 phosphatase activity with no effect on type 2A activity (Figure 6B).
Remarkably, gene transfer of the active inhibitor-1 restored the rate of pressure rise (+dP/dt) to non-failing levels (Figure 6C), whereas left ventricular function was decreased in the failing control group (Figure 6C). Diastolic parameters were also normalized, as evidenced by restoration of the maximal rate of decline of left ventricular systolic pressure (eCdP/dt) and the time course for pressure decline, measured by tau (), the isovolumic relaxation constant (Figure 6D).
To further define ventricular function in a load-independent fashion, pressure-volume analysis was performed (Figure 6E). The maximal slope of the end-systolic pressure dimension relationship (Emax, or Maximal Elastance) was lower in failing hearts, infected with control virus (Ad.GFP), compared with nonfailing hearts, indicating a diminished state of intrinsic myocardial contractility. Importantly, the expression of the active inhibitor-1 completely restored the maximal elastance to nonfailing levels (Figure 6F).
Biochemical characterization revealed that the SERCA2a levels were significantly decreased in the failing hearts, consistent with previous reports,13 and they remained depressed on control or active inhibitor-1 gene transfer. The levels of phospholamban or the ryanodine receptor were not different (Figure 7A). Phosphorylation of phospholamban at serine 16 was significantly depressed in failing hearts, but adenoviral gene transfer of the active inhibitor-1 significantly increased it (Figure 7B). Interestingly, both failing groups infected with either control or active inhibitor-1 virus, exhibited increases in Thr-17 phosphorylation of phospholamban (Figure 7B), consistent with increased CAM-kinase activity (see online data supplement). The phosphorylation level of the ryanodine receptor at serine 2809 was also increased in the failing groups, and infection with the active inhibitor-1 had no effect (Figure 7B).
Examination of the effects of active inhibitor-1 on MAP-kinase activation indicated a complete reversal of the overactivated p38-MAP kinase, with no alteration in ERK or JNK activation (Figure 7C). Thus, the enhanced contractility and relaxation, associated with active inhibitor-1 gene transfer, may decrease wall tension leading to normalization of the p38 MAP-kinase.
Discussion
In the present study, we found that chronic increases in the activation of the protein phosphatase 1 inhibitor-1 are associated with enhanced cardiac contractility and may be protective against the development of cardiac hypertrophy and deterioration of function in the face of increased hemodynamic load. Importantly, acute increases in active inhibitor-1 protein also results in improved function and attenuated remodeling in the setting of preexisting heart failure. To our knowledge, this is the first report demonstrating the efficacy of selective therapeutic protein phosphatase 1 targeting by its inhibitor-1 in the settings of hypertrophy, heart failure, and the transition to heart failure. The beneficial effects of inhibitor-1 may be associated with increases in PLN phosphorylation, because the phosphorylation status of other key phosphoproteins, RyR and troponin I, were not affected. Such unique preference of inhibitor-1 may be important from a therapeutic point of view because inhibition of PLN, and the subsequent enhancement of SR Ca2+ ATPase activity, has been suggested to be beneficial in experimental and genetic heart failure.14,15
In failing hearts, the downregulation of -adrenergic receptors and decreased cAMP-dependent protein kinase activity results in decreased phosphorylation (Threonine 35) and inactivation of inhibitor-1, leading to increased protein phosphatase 1 activity2,5 and dephosphorylation of key phosphoproteins, including phospholamban.16,17 Interestingly, hypophosphorylation of inhibitor-1 in heart failure may also reflect enhanced activity of calcineurin (PP2B).18 This fine cross talk between cAMP and Ca2+ at the level of inhibitor 1 has been recently shown to be complemented by PKC-, a calcium-dependent PKC isoform, which phosphorylates the inhibitor-1 at a different site, Ser67, and reduces its activity.19 Indeed, ablation of PKC- is associated with decreased phosphatase activity and enhanced function.19 Thus, inhibitor 1 appears to be an integrator of multiple neurohormonal pathways, associated with regulation of cardiac function and hypertrophy.
Active Inhibitor-1 Enhances Basal Cardiac Contractility
Inhibitor-1 has been shown to regulate synaptic mechanisms involved in learning and memory,20,21 as well as the adrenergic and cholinergic pathways in the heart.22 Although this phosphoprotein has long been known to play a major regulatory role in neuronal tissue,20,23 its significance in the heart has only recently been emerging. Previous studies indicated that genetic ablation of inhibitor-1 resulted in depressed cardiac contractility,2 whereas adenoviral infection of rat cardiomyocytes with inhibitor-1 enhanced cardiac contractility.24
Expression of the active inhibitor-1 in the transgenic mouse heart appeared to specifically increase phosphorylation of phospholamban at Ser16 and Thr17, without altering the phosphorylation levels of the ryanodine receptor and troponin I. This finding was unexpected because both the ryanodine receptor and troponin I are substrates for protein kinase A, similar to phospholamban. Increases in troponin I phosphorylation would be expected to decrease myofilament sensitivity to Ca2+, whereas increases in ryanodine receptor phosphorylation would cause SR Ca2+ leakage and arrhythmias,8 both counteractive to the beneficial effects of the active inhibitor observed in this study. Importantly, there were no sudden deaths linked to arrhythmias in the inhibitor-1 mice. However, the protein levels of the ryanodine receptor were decreased in the transgenic hearts with enhanced contractility, similar to our previous findings in the phospholamban-knockout hyperdynamic hearts.25 Thus, downregulation of the ryanodine receptor may represent an important compensatory response to maintain calcium homeostasis in models where SR Ca2+-cycling and SR Ca2+-load are increased.
It has been suggested that besides protein phosphatase 1, other phosphatases, such as protein phosphatase 2A, also regulate cardiac function.4 However, the activity of this phosphatase does not appear to change in vivo on isoproterenol stimulation.22 Importantly, the type 2A phosphatase activity was unaffected in the inhibitor-1 transgenic hearts. The apparent specificity of the active inhibitor-1 for the phospholamban-phosphatase may involve its specific anchoring subunit and the relative affinity between the catalytic and binding subunits of this enzyme in the various macromolecular complexes.26 Future phosphoproteomic studies may reveal novel, yet unknown, substrates for protein phosphatase 1/inhibitor-1, which also participate in the augmentation of cardiac contractility in this model.25
Inhibitor-1 Prevents Cardiac Dysfunction and Delays Hypertrophy
To assess whether chronic expression of active inhibitor-1 and associated depressed protein phosphatase 1 activity may be protective against pathological progression of cardiac hypertrophy, the transgenic mice underwent transverse aortic constriction, along with their isogenic wild-type cohorts. Active inhibitor-1 expression was protective against functional deterioration and the geometric alterations leading to cardiac dilatation. The augmentation of phospholamban phosphorylation at Ser16 persisted in the active inhibitor-1 expressing hearts subjected to long-term aortic constriction, indicating enhanced SR Ca2+-cycling. Interestingly, the banded transgenic mice also exhibited decreased cardiac hypertrophy and decreased activation of the ERK1,2 MAP-kinase pathway. Regardless, our findings indicate a pivotal role of inhibitor-1 in protection against the stress of pressure overload on the heart.
Acute Gene Transfer of Active Inhibitor-1 Restores Function and Remodeling in the Failing Heart
The intricate balance of protein kinase and phosphatase activities is shifted in favor of the phosphatases in heart failure due to decreased PKA activation and increased protein phosphatase activity.5,27 To assess whether inhibition of this phosphatase by the active inhibitor-1 may have therapeutic effects in established heart-failure, we used a catheter-based adenoviral delivery technique to transfer this molecule into pressure overloadeCinduced failing rat hearts. Gene transfer resulted in relatively low expression levels of the active inhibitor-1 protein. However, because protein phosphatase 1 activity is chronically increased in heart failure, expression of the active inhibitor-1 resulted in substantial inhibition of this enzyme. This translated into increases in systolic pressure and the maximal rates of pressure development, as well as a decrease in the time constant of isovolumic relaxation, which indicates enhanced active relaxation. Furthermore, the maximal elastance of the failing rat hearts, treated with the constitutively active inhibitor-1, was restored to normal, indicating complete rescue of intrinsic contractility and contractile reserve.
At the SR level, SERCA2 protein decreased significantly in failing-hearts, consistent with previous studies.13 There were no differences in phospholamban or ryanodine receptor levels, but phospholamban was hypophosphorylated at Ser16 and hyperphosphorylated at Thr17, consistent with the increased CaM-Kinase activity in these hearts. Importantly, the phosphorylation of the ryanodine receptor was increased in the failing hearts, further confirming that there may be compartmentalization of protein kinase/phosphatase signaling in the SR.
Gene transfer of the active inhibitor-1 was associated with improved function and enhanced phosphorylation of phospholamban. There were no differences in ryanodine receptor phosphorylation levels. These paradoxical findings further exemplify the complex interplay between kinases and phosphatases in the microenvironment of each phosphoprotein. The enhanced phospholamban phosphorylation, leading to enhanced SR calcium-transport and reduced diastolic calcium levels, was probably the predominant mechanism underlying improved contractility in failing hearts in the absence of reversal of other biochemical changes characteristic of heart failure. Similar findings were observed by direct phospholamban inhibition in various experimental models of heart failure.15,28 These studies are also consistent with our previous work, showing that cardiac overexpression of protein phosphatase 1 decreased phospholamban phosphorylation and resulted in dilated cardiomyopathy and heart failure.2 Thus, the active inhibitor-1 may offer a novel approach to interfere with the phospholamban/SERCA2a interaction, independent of the yet unsuccessful strategy of targeting the highly hydrophobic phospholamban by small molecules or antibodies.
Importantly, the active inhibitor-1 gene transfer resulted in partial rescue of the cardiac geometric alterations, associated with heart failure, and complete normalization of the hyperactive p38 MAP-kinase. However, future studies should address the long-term effects of active inhibitor-1 on cardiac function, molecular pathways, and survival.
Limitations of This Study
The present study along with a number of other recent ex vivo and in vivo reports indicate that SR Ca2+-transport may represent a nodal point in the progression of compensatory hypertrophy and heart failure.2,11,29,30 Accordingly, restoring the depressed SR Ca2+-cycling through increased SERCA2a expression or decreased activity of PLN has been shown to benefit experimental and genetic models of heart failure.13,31
However, concerns have been raised by recent genetic complementation studies with the phospholamban-null mouse. Although some genetic models of heart failure were rescued, others were not affected by phospholamban deficiency.15,32 Given that each genetic model carries a large number of secondary alterations, as compensatory responses to the insult by the genetic manipulation, the results from such complementation studies must be viewed with caution. Furthermore, phospholamban ablation did not appear to benefit cardiac function on sustained aortic constriction.33 However, the transaortic gradients were markedly greater in the knockout relative to WT mice,33 making direct comparisons difficult.
Nevertheless, the recent findings on human phospholamban mutants, associated with phospholamban ablation,34 raised additional concerns and challenges on the role of phospholamban and augmented SR Ca2+-cycling in the human heart. While the mechanism associated with the apparently null human phospholamban mutant is currently being explored, parallel studies in higher mammalian species may provide a better understanding of the potential benefit of restoring SR Ca2+-transport in the human failing heart.
Conclusion
The elegant balance between protein kinase and protein phosphatase activities, regulating cardiac function, shifts in favor of the protein phosphatases in heart failure. The present findings demonstrate that partial restoration of this balance through inhibitor-1 may represent a potential therapeutic intervention. Furthermore, chronic increases in this inhibitor-1 activity may enhance basal cardiac contractility and -adrenergic responses, as well as protect the heart against pressure overloadeCinduced hypertrophy. Unlike agents that increase cAMP, thereby increasing intracellular Ca2+, expression of the active inhibitor-1 improves cardiac function by targeting downstream substrates and by specifically enhancing SR Ca2+ cycling.
Acknowledgments
This work was supported in part by grants from the National Institutes of Health: HL26057, HL64018, and HL52318 (E.G.K.), HL 57623 (R.J.H.), DK36569 (A.A.D.-R.), HL07382eC27 (A.P.), and the American Heart Association Predoctoral Fellowship 0215138B (A.P.).
Both authors contributed equally.
Both senior authors contributed equally.
References
Bers DM. Cardiac excitation-contraction coupling. Nature. 2002; 415: 198eC205.
Carr AN, Schmidt AG, Suzuki Y, del Monte F, Sato Y, Lanner C, Breeden K, Jing SL, Allen PB, Greengard P, Yatani A, Hoit BD, Grupp IL, Hajjar RJ, DePaoli-Roach AA, Kranias EG. Type 1 phosphatase, a negative regulator of cardiac function. Mol Cell Biol. 2002; 22: 4124eC4135.
Molkentin JD, Lu JR, Antos CL, Markham B, Richardson J, Robbins J, Grant SR, Olson EN. A calcineurin-dependent transcriptional pathway for cardiac hypertrophy. Cell. 1998; 93: 215eC228.
Gergs U, Boknik P, Buchwalow I, Fabritz L, Matus M, Justus I, Hanske G, Schmitz W, Neumann J. Overexpression of the catalytic subunit of protein phosphatase 2A impairs cardiac function. J Biol Chem. 2004: 279: 40827eC40834.
Neumann J, Eschenhagen T, Jones LR, Linck B, Schmitz W, Scholz H, Zimmermann N. Increased expression of cardiac phosphatases in patients with end-stage heart failure. J Mol Cell Cardiol. 1997; 29: 265eC272.
Gupta RC, Tanimura M, Lesch M, Sabbah HN. Protein phosphatase activity is increased and phosphorylation state of phospholamban is decreased in myocardium of dogs with chronic heart failure. Circulation. 1997; 96: I-361.
El-Armouche A, Pamminger T, Ditz D, Zolk O, Eschenhagen T. Decreased protein and phosphorylation level of the protein phosphatase inhibitor-1 in failing human hearts. Cardiovasc Res. 2004; 61: 87eC93.
Marx SO, Reiken S, Hisamatsu Y, Jayaraman T, Burkhoff D, Rosemblit N, Marks AR. PKA phosphorylation dissociates FKBP12.6 from the calcium release channel (ryanodine receptor): defective regulation in failing hearts. Cell. 2000; 101: 365eC376.
Lips DJ, Nagel TVD, Steendijk P, Palmen M, Janssen BJ, Dantzig JV, Windt LJD, Doevendans PA. Left ventricular pressure-volume measurements in mice: Comparison of closed-chest versus open-chest approach. Basic Res Cardiol. 2004; 99: 351eC359.
Endo S, Zhou X, Connor J, Wang B, Shenolikar S. Multiple structural elements define the specificity of recombinant human inhibitor-1 as a protein phosphatase-1 inhibitor. Biochemistry. 1996; 35: 5220eC5228.
Kranias EG, Di Salvo J. A phospholamban protein phosphatase activity associated with cardiac sarcoplasmic reticulum. J Biol Chem. 1986; 261: 10029eC10032.
Masaki H, Sato Y, Luo W, Kranias EG, Yatani A. Phospholamban deficiency alters inactivation kinetics of L-type Ca2+ channels in mouse ventricular myocytes. Am J Physiol. 1997; 272: H606eCH612.
del Monte F, Williams E, Lebeche D, Schmidt U, Rosenzweig A, Gwathmey JK, Lewandowski ED, Hajjar RJ. Improvement in survival and cardiac metabolism after gene transfer of sarcoplasmic reticulum Ca2+-ATPase in a rat model of heart failure. Circulation. 2001; 104: 1424eC1429.
del Monte F, Harding SE, Schmidt U, Matsui T, Kang ZB, Dec GW, Gwathmey JK, Rosenzweig A, Hajjar RJ. Restoration of contractile function in isolated cardiomyocytes from failing human hearts by gene transfer of SERCA2a. Circulation. 1999; 100: 2308eC2311.
Minamisawa S, Hoshijima M, Chu G, Ward CA, Frank K, Gu Y, Martone ME, Wang Y, Ross J Jr, Kranias EG, Giles WR, Chien KR. Chronic phospholamban-sarcoplasmic reticulum calcium ATPase interaction is the critical calcium cycling defect in dilated cardiomyopathy. Cell. 1999; 99: 313eC322.
Schwinger RH, Bolck B, Munch G, Brixius K, Muller-Ehmsen J, Erdmann E. cAMP-dependent protein kinase A-stimulated sarcoplasmic reticulum function in heart failure. Ann NY Acad Sci. 1998; 853: 240eC250.
Dash R, Frank KF, Carr AN, Moravec CS, Kranias EG. Gender influences on sarcoplasmic reticulum Ca2+-handling in failing human myocardium. J Mol Cell Cardiol. 2001; 33: 1345eC1353.
Mulkey RM, Endo S, Shenolikar S, Malenka RC. Involvement of a calcineurin/inhibitor-1 phosphatase cascade in hippocampal long-term depression. Nature. 1994; 369: 486eC488.
Braz JC, Gregory K, Pathak A, Zhao W, Sahin B, Klevitsky R, Kimball TF, Lorenz JN, Nairn AC, Liggett SB, Bodi I, Wang S, Schwartz A, Lakatta EG, DePaoli-Roach AA, Robbins J, Hewett TE, Bibb JA, Westfall MV, Kranias EG, Molkentin JD. PKC-alpha regulates cardiac contractility and propensity toward heart failure. Nat Med. 2004; 10: 248eC254.
Genoux D, Haditsch U, Knobloch M, Michalon A, Storm D, Mansuy IM. Protein phosphatase 1 is a molecular constraint on learning and memory. Nature. 2002; 418: 970eC975.
Allen PB, Hvalby O, Jensen V, Errington ML, Ramsay M, Chaudhry FA, Bliss TV, Storm-Mathisen J, Morris RG, Andersen P, Greengard P. Protein phosphatase-1 regulation in the induction of long-term potentiation: heterogeneous molecular mechanisms. J Neurosci. 2000; 20: 3537eC3543.
Ahmad Z, Green FJ, Subuhi HS, Watanabe AM. Autonomic regulation of type 1 protein phosphatase in cardiac muscle. J Biol Chem. 1989; 264: 3859eC3863.
Nairn AC, Palfrey HC. Identification of the major Mr 100,000 substrate for calmodulin-dependent protein kinase III in mammalian cells as elongation factor-2. J Biol Chem. 1987; 262: 17299eC17303.
El-Armouche A, Rau T, Zolk O, Ditz D, Pamminger T, Zimmermann WH, Jackel E, Harding SE, Boknik P, Neumann J, Eschenhagen T. Evidence for protein phosphatase inhibitor-1 playing an amplifier role in beta-adrenergic signaling in cardiac myocytes. FASEB J. 2003; 17: 437eC439.
Chu G, Ferguson DG, Edes I, Kiss E, Sato Y, Kranias EG. Phospholamban ablation and compensatory responses in the mammalian heart. Ann NY Acad Sci. 1998; 853: 49eC62.
DePaoli-Roach AA. Protein Phosphatase 1 Binding Proteins. In: Handbook of Cell Signaling: Elsevier Science; 2003: 613eC619.
Bristow MR, Ginsburg R, Minobe W, Cubicciotti RS, Sageman WS, Lurie K, Billingham ME, Harrison DC, Stinson EB. Decreased catecholamine sensitivity and beta-adrenergic-receptor density in failing human hearts. N Engl J Med. 1982; 307: 205eC211.
Hoshijima M, Ikeda Y, Iwanaga Y, Minamisawa S, Date MO, Gu Y, Iwatate M, Li M, Wang L, Wilson JM, Wang Y, Ross J, Jr., Chien KR. Chronic suppression of heart-failure progression by a pseudophosphorylated mutant of phospholamban via in vivo cardiac rAAV gene delivery. Nat Med. 2002; 8: 864eC871.
Gwathmey JK, Copelas L, MacKinnon R, Schoen FJ, Feldman MD, Grossman W, Morgan JP. Abnormal intracellular calcium handling in myocardium from patients with end-stage heart failure. Circ Res. 1987; 61: 70eC76.
Gwathmey JK, Morgan JP. Altered calcium handling in experimental pressure-overload hypertrophy in the ferret. Circ Res. 1985; 57: 836eC843.
del Monte F, Harding SE, Dec GW, Gwathmey JK, Hajjar RJ. Targeting phospholamban by gene transfer in human heart failure. Circulation. 2002; 105: 904eC907.
Song Q, Schmidt AG, Hahn HS, Carr AN, Frank B, Pater L, Gerst M, Young K, Hoit BD, McConnell BK, Haghighi K, Seidman CE, Seidman JG, Dorn GW II, Kranias EG. Rescue of cardiomyocyte dysfunction by phospholamban ablation does not prevent ventricular failure in genetic hypertrophy. J Clin Invest. 2003; 111: 859eC867.
Kiriazis H, Sato Y, Kadambi VJ, Schmidt AG, Gerst MJ, Hoit BD, Kranias EG. Hypertrophy and functional alterations in hyperdynamic phospholamban-knockout mouse hearts under chronic aortic stenosis. Cardiovasc Res. 2002; 53: 372eC381.
Haghighi K, Kolokathis F, Pater L, Lynch RA, Asahi M, Gramolini AO, Fan GC, Tsiapras D, Hahn HS, Adamopoulos S, Liggett SB, Dorn GW II, MacLennan DH, Kremastinos DT, Kranias EG. Human phospholamban null results in lethal dilated cardiomyopathy revealing a critical difference between mouse and human. J Clin Invest. 2003; 111: 869eC876.(Anand Pathak, Federica de)