Song-Jung Kim

Activation of Mst1 causes dilated cardiomyopathy by stimulating apoptosis without compensatory ventricular myocyte hypertrophy

Activation of mammalian sterile 20-like kinase 1 (Mst1) by genotoxic compounds is known to stimulate apoptosis in some cell types. The importance of Mst1 in cell death caused by clinically relevant pathologic stimuli is unknown, however. In this study, we show that Mst1 is a prominent myelin basic protein kinase activated by proapoptotic stimuli in cardiac myocytes and that Mst1 causes cardiac myocyte apoptosis in vitro in a kinase activity-dependent manner. In vivo, cardiac-specific overexpression of Mst1 in transgenic mice results in activation of caspases, increased apoptosis, and dilated cardiomyopathy. Surprisingly, however, Mst1 prevents compensatory cardiac myocyte elongation or hypertrophy despite increased wall stress, thereby obscuring the use of the Frank-Starling mechanism, a fundamental mechanism by which the heart maintains cardiac output in response to increased mechanical load at the single myocyte level. Furthermore, Mst1 is activated by ischemia/reperfusion in the mouse heart in vivo. Suppression of endogenous Mst1 by cardiac-specific overexpression of dominant-negative Mst1 in transgenic mice prevents myocyte death by pathologic insults. These results show that Mst1 works as both an essential initiator of apoptosis and an inhibitor of hypertrophy in cardiac myocytes, resulting in a previously unrecognized form of cardiomyopathy.

Program of Cell Survival Underlying Human and Experimental Hibernating Myocardium

Hibernating myocardium refers to chronically dysfunctional myocardium in patients with coronary artery disease in which cardiac viability is maintained and whose function improves after coronary revascularization. It is our hypothesis that long-term adaptive genomic mechanisms subtend the survival capacity of this ischemic myocardium. Therefore, the goal of this study was to determine whether chronic repetitive ischemia elicits a gene program of survival protecting hibernating myocardium against cell death. Accordingly, we measured the expression of survival genes in hibernating myocardium, both in patients surgically treated for hibernation and in a chronic swine model of repetitive ischemia reproducing the features of hibernation. Human hibernating myocardium was characterized by an upregulation of genes and corresponding proteins involved in anti-apoptosis (IAP), growth (VEGF, H11 kinase), and cytoprotection (HSP70, HIF-1&agr;, GLUT1). In the swine model, the same genes and proteins were upregulated after repetitive ischemia, which was accompanied by a concomitant decrease in myocyte apoptosis. These changes characterize viable tissue, because they were not found in irreversibly injured myocardium. Our report demonstrates a novel mechanism by which the activation of an endogenous gene program of cell survival underlies the sustained viability of the hibernating heart. Potentially, promoting such a program offers a novel opportunity to salvage postmitotic tissues in conditions of ischemia.

Gene program for cardiac cell survival induced by transient ischemia in conscious pigs

Therapy for ischemic heart disease has been directed traditionally at limiting cell necrosis. We determined by genome profiling whether ischemic myocardium can trigger a genetic program promoting cardiac cell survival, which would be a novel and potentially equally important mechanism of salvage. Although cardiac genomics is usually performed in rodents, we used a swine model of ischemia/reperfusion followed by ventricular dysfunction (stunning), which more closely resembles clinical conditions. Gene expression profiles were compared by subtractive hybridization between ischemic and normal tissue of the same hearts. About one-third (23/74) of the nuclear-encoded genes that were up-regulated in ischemic myocardium participate in survival mechanisms (inhibition of apoptosis, cytoprotection, cell growth, and stimulation of translation). The specificity of this response was confirmed by Northern blot and quantitative PCR. Unexpectedly, this program also included genes not previously described in cardiomyocytes. Up-regulation of survival genes was more profound in subendocardium over subepicardium, reflecting that this response in stunned myocardium was proportional to the severity of the ischemic insult. Thus, in a swine model that recapitulates human heart disease, nonlethal ischemia activates a genomic program of cell survival that relates to the time course of myocardial stunning and differs transmurally in relation to ischemic stress, which induced the stunning. Understanding the genes up-regulated during myocardial stunning, including those not previously described in the heart, and developing strategies that activate this program may open new avenues for therapy in ischemic heart disease.

Persistent Stunning Induces Myocardial Hibernation and Protection Flow/Function and Metabolic Mechanisms

Abstract —To test the hypothesis that persistent myocardial stunning can lead to hibernating myocardium, 13 pigs were chronically instrumented, and persistent stunning was induced regionally by 6 repetitive episodes of 90‐minute coronary stenosis (CS) (30% reduction in baseline coronary blood flow [CBF]) followed by full reperfusion every 12 hours. During the 1st CS, CBF fell from 43±2 to 31±2 mL/min, and anterior wall thickening (AWT) fell by 54±8%, but posterior WT did not change. AWT never recovered fully and remained depressed by 31±7% before the 6th CS, reflecting persistent myocardial stunning, but baseline CBF was not changed. Surprisingly, during the 6th CS, AWT did not fall further despite a similar reduction in CBF during CS, as occurred with the 1st episode. Regional MVÿo2 fell similarly during the 1st and 6th CS. During the 1st CS, plasma glucose uptake increased, whereas free fatty acid (FFA) uptake was reduced. Before the 6th CS, glucose uptake remained elevated, whereas FFA uptake remained reduced. Histology revealed enhanced glycogen deposition, which could be explained by decreased glycogen synthase kinase (GSK)‐3&bgr; protein levels and activity. These results indicate that persistent stunning, even in the absence of chronic ischemia, can recapitulate the phenotype of myocardial hibernation. This results in a shift in the flow/function relationship where a 30% decrease in CBF is no longer accompanied by a fall in myocardial function, which could be explained, in part, by a shift in substrate utilization. These hemodynamic/metabolic adjustments could facilitate survival of hibernating myocardium. (Circ Res. 2003;92:1233–1239.)

Delayed Enhanced Nitric Oxide–Mediated Coronary Vasodilation Following Brief Ischemia and Prolonged Reperfusion in Conscious Dogs

The goal of this study was to determine both the early and delayed effects of a brief (10-minute) coronary artery occlusion (CAO) and prolonged (5-day) reperfusion (CAR) on coronary endothelial function. Fourteen mongrel dogs were chronically instrumented to measure aortic and left ventricular pressures, wall thickness, and left circumflex coronary blood flow (CBF). Before CAO and during CAR, coronary vascular reactivity was investigated by 15-second CAO and subsequent reactive hyperemia (RH) and by the selective intracoronary infusion of acetylcholine (ACh, 10 micrograms/min) and bradykinin (BK, 2.5 micrograms/min), endothelium-dependent vasodilators, and sodium nitroprusside (SNP, 40 micrograms/min), an endothelium-independent vasodilator. CBF responses to ACh and BK began to increase after 6 hours of CAR, reached a peak after 1 to 2 days of CAR, and then subsided over the subsequent 4 days. After 1 day of CAR, compared with before CAO, enhanced CBF responses (P < .05), associated with increased coronary sinus oxygen content, were observed for-ACh (+66 +/- 20%), BK (+74 +/- 24%), and RH (+24 +/- 5%) but not SNP (-2 +/- 10%). Production of NO metabolites (nitrate and nitrite), measured as their coronary arteriovenous differencexCBF, was significantly increased after 1 to 2 days of CAR, both at baseline (153 +/- 56%) and during BK infusion (220 +/- 76%) (P < .05). Holding CBF at pre-CAO levels during the initial CAR period did not attenuate the delayed enhanced endothelial vasodilation to ACh and BK. However, NO blockade with intracoronary NG-nitro-L-arginine blocked the enhanced coronary vasodilation to ACh and BK. Thus, in contrast to previous studies, these data indicate that brief ischemic episodes induce delayed enhanced coronary endothelial function, which is delayed in onset and prolonged in duration. This can be explained by an upregulation of coronary vascular NO production, potentially involved in the mechanism of the delayed window of preconditioning.

Paradoxical Cellular Ca2+ Signaling in Severe but Compensated Canine Left Ventricular Hypertrophy

In conscious dogs with severe left ventricular (LV) hypertrophy (H) (doubling of LV/body weight), which developed gradually over 1 to 2 years after aortic banding, baseline LV function was well compensated. The LV was able to generate twice the LV systolic pressure without an increase in LV end-diastolic pressure, or decrease in LV dP/dt or LV wall thickening. However, LV myocytes isolated from LVH dogs exhibited impaired contraction at baseline and in response to Ca2+. There was no change in L-type Ca2+ channel current (ICa) density but the ability of ICa to trigger Ca2+ release from the sarcoplasmic reticulum (SR) was reduced. Immunoblot analysis revealed a 68% decrease in SERCA2a, and a 35% decrease in the number of ryanodine receptors (RyR2), with no changes in protein level of calsequestrin, Na+/Ca2+ exchanger or phospholamban (PLB), but with both RyR2 and PLB hyperphosphorylated. Spontaneous Ca2+ sparks in LVH cells were found to have prolonged duration but similar intensities despite the reduced SR Ca2+ load. A higher Ca2+ spark rate was observed in LVH cells, but this is inconsistent with the reduced SR Ca2+ content. However, Ca2+ waves were found to be less frequent, slower and were more likely to be aborted in Ca2+-challenged LVH cells. These paradoxical observations could be accounted for by a nonuniform SR Ca2+ distribution, RyR2 hyperphosphorylation in the presence of decreased global SR Ca2+ load. We conclude that severe LVH with compensation masks cellular and subcellular Ca2+ defects that remain likely contributors to the limited contractile reserve of LVH.

Novel Mechanisms Mediating Stunned Myocardium

Myocardial stunning is defined as the prolonged contractile dysfunction following an ischemic episode that does not result in necrosis, which also occurs in patients with coronary artery disease. There is also evidence to consider myocardial stunning as a fundamental component of hibernating myocardium. Various experimental approaches (from a brief episode to prolonged partial ischemia) and animal models (from rodents to large mammals) have been developed to investigate the pathogenesis of myocardial stunning. Three hypotheses to explain the mechanism, i.e. oxygen radical, Troponin I degradation, and Ca2+, have been proposed. The first was tested primarily using large mammalian models, whereas the others were tested primarily using rodent models. Recently, the Ca2+ handling hyothesis has been tested in a large mammalian swine model of myocardial stunning, in which both Ca2+ and transients and L-type Ca2+ current density were decreased. Relaxation function and phospholamban phosphorylation are also radically different in large mammalian and rodent models. In addition, troponin I degradation, which was identified as the mechanism of stunning in rodent models, was not found in stunned swine myocardium. Interestingly, the large mammalian model demonstrates that stunning elicits broad changes in gene and protein regulation, some of which have not been observed in the heart previously. The overall genomic adaptation upregulates the expression of survival genes that prevent irreversible damage. Pursuing these new concepts derived from large mammalian models of ischemia/reperfusion will provide more comprehensive mechanistic information underlying myocardial stunning and will serve to devise new therapeutic modalities for patients.

Differential regulation of inotropy and lusitropy in overexpressed Gsalpha myocytes through cAMP and Ca2+ channel pathways.

We investigated the mechanisms responsible for altered contractile and relaxation function in overexpressed Gsalpha myocytes. Although baseline contractile function (percent contraction) in Gsalpha mice was similar to that of wild-type (WT) mice, left ventricular myocyte contraction, fura-2 Ca2+transients, and Ca2+ channel currents (ICa) were greater in Gsalpha mice in response to 10(-8) M isoproterenol (ISO) compared with WT mice. The late phase of relaxation of the isolated myocytes and fura-2 Ca2+ transients was accelerated at baseline in Gsalpha but did not increase further with ISO. In vivo measurements using echocardiography also demonstrated enhanced relaxation at baseline in Gsalpha mice. Forskolin and CaCl2 increased contraction similarly in WT and Gsalpha mice. Rp-cAMP, an inhibitor of protein kinase, blocked the increases in contractile response and Ca2+ currents to ISO in WT and to forskolin in both WT and Gsalpha. It also blocked the accelerated relaxation in Gsalpha at baseline but not the contractile response to ISO in Gsalpha myocytes. Baseline measurements of cAMP and phospholambation phosphorylation were enhanced in Gsalpha compared with WT. These data indicate that overexpression of Gsalpha accelerates relaxation at end diastolic but does not affect baseline systolic function in isolated myocytes. However, the enhanced responses to sympathetic stimulation partly reflect increased Ca2+ channel activity; i.e the cellular mechanisms mediating these effects appear to involve a cAMP-independent as well as a cAMP-dependent pathway.

Chronic treatment with insulin-like growth factor I enhances myocyte contraction by upregulation of Akt-SERCA2a signaling pathway

Chronic treatment with insulin-like growth factor I (IGF-I) improves contractile function in congestive heart failure and ischemic cardiomyopathy. The present study investigated the effect of chronic treatment with IGF-I on intrinsic myocyte function and the role of the phosphatidylinositol (PI)3-kinase-Akt-sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA)2a signaling cascade in these responses. Myocytes were isolated from 23 adult rats and cultured with and without IGF-I (10(-6) M). After 48 h of treatment, myocyte function was evaluated. IGF-I increased contractile function (percent contraction, 7.7 +/- 0.3% vs. 4.5 +/- 0.3%; P < 0.01) and accelerated relaxation time (time for 70% relengthening, 81 +/- 4 vs. 106 +/- 5 ms; P < 0.05) compared with untreated myocytes [control (Con)]. The enhanced function was associated with an increase in Ca(2+) transients assessed by fura-2 (340/380 nm; IGF-I, 0.42 +/- 0.02 vs. Con, 0.25 +/- 0.01; P < 0.01). The PI3-kinase inhibitor LY-249002 (10(-9) M) abolished the enhanced function caused by IGF-I. IGF-I increased both Akt and SERCA2a protein levels 2.5- and 4.8-fold, respectively, compared with those of Con (P < 0.01); neither phospholamban nor calsequestrin was affected. To evaluate whether the SERCA2a protein was directly mediated by Akt-SERCA2a signaling, IGF-I-induced changes in the SERCA2a protein were compared in myocytes transfected with adenovirus harboring either constitutively active Akt [multiplicity of infection (MOI), 15] or dominant negative Akt (dnAkt; MOI, 15). The ability of IGF-I to upregulate the SERCA2a protein in myocytes transfected with active Akt was absent in dnAkt myocytes. Taken together, our findings indicate that chronic treatment with IGF-I enhances intrinsic myocyte function and that this effect is due to an enhancement in intracellular Ca(2+) handling, secondary to the activation of the PI3-kinase-Akt-SERCA2a signaling cascade.

Selective large coronary endothelial dysfunction in conscious dogs with chronic coronary pressure overload

Coronary vascular responses to acetylcholine (ACh, 3 μg/kg iv), nitroglycerin (NTG, 25 μg/kg iv), and a 20-s coronary artery occlusion (reactive hyperemia, RH) were investigated in seven conscious dogs with severe left ventricular (LV) hypertrophy and chronic coronary pressure overload (CCPO) due to supravalvular aortic banding and in seven control dogs. All dogs were instrumented for measurement of ultrasonic coronary diameter (CD) and Doppler coronary blood flow (CBF). LV-to-body weight ratio was increased by 82% in CCPO dogs. In control dogs, ACh increased CD (+5.9 ± 1.7%). This response was reduced ( P < 0.05) in CCPO dogs (+1.9 ± 0.9%). Similarly, flow-mediated increases in CD after RH were blunted ( P < 0.01) in CCPO (+2.1 ± 0.8) vs. control dogs (+6.8 ± 1.8%). In contrast, ACh and RH increased CBF similarly in both groups. Increases in both CD and CBF to NTG were not different between control dogs and CCPO. Peak systolic CBF velocity was greater, P< 0.01, in CCPO (94 ± 17 cm/s) compared with control (35 ± 7 cm/s) dogs, most likely secondary to the increased systolic coronary perfusion pressure (215 vs. 130 mmHg). Histological analyses of large coronary arteries in CCPO revealed medial thickening, intimal thickening, and disruption of the internal elastic lamina and endothelium. In contrast, small intramyocardial arterioles failed to show the intimal and endothelial lesions. Thus, in CCPO selective to the coronary arteries, i.e., a model independent from systemic hypertension and enhanced levels of plasma renin activity, endothelial control was impaired for both flow-mediated and receptor-mediated large coronary artery function, which could be accounted for by the major morphological changes in the large coronary arteries sparing the resistance vessels. The mechanism may involve chronically elevated systolic coronary perfusion pressure, CBF velocity, and potential disruption of laminar flow patterns.Coronary vascular responses to acetylcholine (ACh, 3 micrograms/kg i.v.), nitroglycerin (NTG, 25 micrograms/kg i.v.), and a 20-s coronary artery occlusion (reactive hyperemia, RH) were investigated in seven conscious dogs with severe left ventricular (LV) hypertrophy and chronic coronary pressure overload (CCPO) due to supravalvular aortic banding and in seven control dogs. All dogs were instrumented for measurement of ultrasonic coronary diameter (CD) and Doppler coronary blood flow (CBF). LV-to-body weight ratio was increased by 82% in CCPO dogs. In control dogs, ACh increased CD (+ 5.9 +/- 1.7%). This response was reduced (P < 0.05) in CCPO dogs (+ 1.9 +/- 0.9%). Similarly, flow-mediated increases in CD after RH were blunted (P < 0.01) in CCPO (+ 2.1 +/- 0.8) vs. control dogs (+ 6.8 +/- 1.8%). In contrast, ACh and RH increased CBF similarly in both groups. Increases in both CD and CBF to NTG were not different between control dogs and CCPO. Peak systolic CBF velocity was greater, P < 0.01, in CCPO (94 +/- 17 cm/s) compared with control (35 +/- 7 cm/s) dogs, most likely secondary to the increased systolic coronary perfusion pressure (215 vs. 130 mmHg). Histological analyses of large coronary arteries in CCPO revealed medial thickening, intimal thickening, and disruption of the internal elastic lamina and endothelium. In contrast, small intramyocardial arterioles failed to show the intimal and endothelial lesions. Thus, in CCPO selective to the coronary arteries, i.e., a model independent from systemic hypertension and enhanced levels of plasma renin activity, endothelial control was impaired for both flow-mediated and receptor-mediated large coronary artery function, which could be accounted for by the major morphological changes in the large coronary arteries sparing the resistance vessels. The mechanism may involve chronically elevated systolic coronary perfusion pressure, CBF velocity, and potential disruption of laminar flow patterns.