Biochemical mechanism(s) of stunning in conscious dogs

Effects of acute ischemia and hypoxia in young and adult calsequestrin (CSQ2) knock-out and wild-type mice

Calsequestrin (CSQ2) is the main Ca²⁺-binding protein in the sarcoplasmic reticulum of the mammalian heart. In order to understand the function of calsequestrin better, we compared two age groups (young: 4-5 months of age versus adult: 18 months of age) of CSQ2 knock-out mice (CSQ2(-/-)) and littermate wild-type mice (CSQ2(+/+)). Using echocardiography, in adult mice, the basal left ventricular ejection fraction and the spontaneous beating rate were lower in CSQ2(-/-) compared to CSQ2(+/+). The increase in ejection fraction by β-adrenergic stimulation (intraperitoneal injection of isoproterenol) was lower in adult CSQ2(-/-) versus adult CSQ2(+/+). After hypoxia in vitro (isolated atrial preparations) by gassing the organ bath buffer with 95% N₂, force of contraction in electrically driven left atria increased to lower values in young CSQ2(-/-) than in young CSQ2(+/+). In addition, after global ischemia and reperfusion (buffer-perfused hearts according to Langendorff; 20-min ischemia and 15-min reperfusion), the rate of tension development was higher in young CSQ2(-/-) compared to young CSQ2(+/+). Finally, we evaluated signs of inflammation (immune cells, autoantibodies, and fibrosis). However, whereas no immunological alterations were found between all investigated groups, pronounced fibrosis was found in the ventricles of adult CSQ2(-/-) compared to all other groups. We suggest that in young mice, CSQ2 is important for cardiac performance especially in isolated cardiac preparations under conditions of impaired oxygen supply, but with differences between atrium and ventricle. Lack of CSQ2 leads age dependently to fibrosis and depressed cardiac performance in echocardiographic studies.

Influence of Serotonin 5-HT4 Receptors on Responses to Cardiac Stressors in Transgenic Mouse Models

The current study aimed to deepen our knowledge on the role of cardiac 5-HT4 receptors under pathophysiological conditions. To this end, we used transgenic (TG) mice that overexpressed human 5-HT4a receptors solely in cardiac myocytes (5-HT4-TG mice) and their wild-type (WT) littermates that do not have functional cardiac 5-HT4 receptors as controls. We found that an inflammation induced by lipopolysaccharide (LPS) was detrimental to cardiac function in both 5-HT4-TG and WT mice. In a hypoxia model, isolated left atrial preparations from the 5-HT4-TG mice went into contracture faster during hypoxia and recovered slower following hypoxia than the WT mice. Similarly, using isolated perfused hearts, 5-HT4-TG mice hearts were more susceptible to ischemia compared to WT hearts. To study the influence of 5-HT4 receptors on cardiac hypertrophy, 5-HT4-TG mice were crossbred with TG mice overexpressing the catalytic subunit of PP2A in cardiac myocytes (PP2A-TG mice, a model for genetically induced hypertrophy). The cardiac contractility, determined by echocardiography, of the resulting double transgenic mice was attenuated like in the mono-transgenic PP2A-TG and, therefore, largely determined by the overexpression of PP2A. In summary, depending on the kind of stress put upon the animal or isolated tissue, 5-HT4 receptor overexpression could be either neutral (genetically induced hypertrophy, sepsis) or possibly detrimental (hypoxia, ischemia) for mechanical function. We suggest that depending on the underlying pathology, the activation or blockade of 5-HT4 receptors might offer novel drug therapy options in patients.

TNNI1, TNNI2 and TNNI3: Evolution, regulation, and protein structure-function relationships

Troponin I (TnI) is the inhibitory subunit of the troponin complex in the sarcomeric thin filament of striated muscle and plays a central role in the calcium regulation of contraction and relaxation. Vertebrate TnI has evolved into three isoforms encoded by three homologous genes: TNNI1 for slow skeletal muscle TnI, TNNI2 for fast skeletal muscle TnI and TNNI3 for cardiac TnI, which are expressed under muscle type-specific and developmental regulations. To summarize the current knowledge on the TnI isoform genes and products, this review focuses on the evolution, gene regulation, posttranslational modifications, and structure-function relationship of TnI isoform proteins. Their physiological and medical significances are also discussed.

Gene regulation, alternative splicing, and posttranslational modification of troponin subunits in cardiac development and adaptation: a focused review

Troponin plays a central role in regulating the contraction and relaxation of vertebrate striated muscles. This review focuses on the isoform gene regulation, alternative RNA splicing, and posttranslational modifications of troponin subunits in cardiac development and adaptation. Transcriptional and posttranscriptional regulations such as phosphorylation and proteolysis modifications, and structure-function relationships of troponin subunit proteins are summarized. The physiological and pathophysiological significances are discussed for impacts on cardiac muscle contractility, heart function, and adaptations in health and diseases.

Cell-to-cell variability in troponin I phosphorylation in a porcine model of pacing-induced heart failure

We tested the hypothesis that myocardial contractile protein phosphorylation and the Ca²⁺ sensitivity of force production are dysregulated in a porcine model of pacing-induced heart failure (HF). The level of protein kinase A (PKA)-dependent cardiac troponin I (TnI) phosphorylation was lower in the myocardium surrounding the pacing electrode (pacing site) of the failing left ventricle (LV) than in the controls. Immunohistochemical assays of the LV pacing site pointed to isolated clusters of cardiomyocytes exhibiting a reduced level of phosphorylated TnI. Flow cytometry on isolated and permeabilized cardiomyocytes revealed a significantly larger cell-to-cell variation in the level of TnI phosphorylation of the LV pacing site than in the opposite region in HF or in either region in the controls: the interquartile range (IQR) on the distribution histogram of relative TnI phosphorylation was wider at the pacing site (IQR = 0.53) than that at the remote site of HF (IQR = 0.42; P = 0.0047) or that of the free wall of the control animals (IQR = 0.36; P = 0.0093). Additionally, the Ca²⁺ sensitivities of isometric force production were higher and appeared to be more variable in single permeabilized cardiomyocytes from the HF pacing site than in the healthy myocardium. In conclusion, the level of PKA-dependent TnI phosphorylation and the Ca²⁺ sensitivity of force production exhibited a high cell-to-cell variability at the LV pacing site, possibly explaining the abnormalities of the regional myocardial contractile function in a porcine model of pacing-induced HF.

Myocardial stunning is associated with impaired calcium uptake by sarcoplasmic reticulum

Myocardial stunning (temporary post-ischaemic contractile dysfunction) may be caused by oxidative stress and/or impaired myocyte calcium homeostasis. Regional myocardial stunning was induced in open-chest pigs (segment shortening reduced to 68.3+/-4.7% of baseline) by repetitive brief circumflex coronary occlusion (I/R). Reduced glutathione was depleted in stunned myocardium (1.34+/-0.06 vs. 1.77+/-0.11 nmol/mg, p=0.02 vs. remote myocardium) indicating regional oxidant stress, but no regional differences were observed in protein-bound 3-nitrotyrosine or S-nitrosothiol content. Repetitive I/R did not affect myocardial quantities of the sarcolemmal sodium-calcium exchanger, L-type channel, SR calcium ATPase and phospholamban, or the kinetics of ligand binding to L-type channels and SR calcium release channels. However, initial rates of oxalate-supported (45)Ca uptake by SR were impaired in stunned myocardium (41.3+/-13.5 vs. 73.0+/-15.6 nmol/min/mg protein, p=0.03). The ability of SR calcium ATPase to sequester cytosolic calcium is impaired in stunned myocardium. This is a potential mechanism underlying contractile dysfunction.

Phosphorylation of phospholamban and troponin I through 5-HT4 receptors in the isolated human atrium

We studied the mRNA expression and function of 5-hydroxytryptamine (5-HT) receptors as well as their signal transduction in right atrial tissue from patients undergoing cardiac surgery and right ventricular tissue from human donor hearts. In isolated, electrically driven strips from human right atrium, 5-HT exerted concentration-dependent positive inotropic effects (EC(50) value = 0.10 +/- 0.01 microM) and hastened relaxation (positive lusitropic effect). The 5-HT(4) receptor antagonists SB203186 or GR125487 antagonised these effects. 5-HT (2 microM) increased the content of cyclic adenosine monophosphate (cAMP) from 6.86 +/- 1.36 to 19.1 +/- 2.45 pmol/mg protein (n = 6, p < 0.05) but did not alter the tissue content of inositol-1,4,5-trisphosphate (IP(3)). With reverse transcription polymerase chain reaction, mRNAs coding for the 5-HT(4) receptor splice variants 5-HT(4(a)), 5-HT(4(b)) and 5-HT(4(c)) were detected in human right atrium and right ventricle. 5-HT(2A) mRNA only was measurable in human atrium. Expression level of total 5-HT(4) receptor mRNA in the right ventricle amounted to 41% (n = 5-8) of that in the right atrium. 5-HT (2 microM) increased the atrial phosphorylation states of phospholamban to 168% at serine-16 and to 150% at threonine-17 (n = 4; p < 0.05) and of the inhibitory subunit of troponin to 150% (n = 6; p < 0.05). In conclusion, the positive inotropic and lusitropic effects of 5-HT in electrically driven human right atria are mediated via 5-HT(4) receptors. These effects are accompanied by and probably due to an increase in cAMP content and the subsequent elevation of the phosphorylation state of Ca(2+) regulatory proteins.

Gene Expression of the Na+–Ca2+ Exchanger, SERCA2a and Calsequestrin after Myocardial Ischemia in the Neonatal Rabbit Heart

BACKGROUND

Neonatal hearts are less susceptible to developing myocardial dysfunction after hypoxia and/or ischemia than adult hearts. Differences in intracellular calcium homeostasis may be responsible for reduced calcium overload of the immature myocardium leading to the observed protection against ischemia.

OBJECTIVE

To assess differences in baseline and post-ischemic gene expression of calcium handling proteins after ischemia in neonatal and adult rabbit hearts.

METHODS

We used isolated antegrade perfused rabbit hearts (age 2 days, 28 days, n = 32), which were exposed to ischemia and hypothermia simulating myocardial stunning comparable to neonatal asphyxia. Gene and protein expression of the sodium-calcium exchanger (NCX), the sarco-endoplasmatic reticulum Ca2+-ATPase 2a (SERCA) and calsequestrin (CSQ) were measured using quantitative real-time PCR and Western blotting.

RESULTS

After ischemia and reperfusion in neonatal and adult hearts, a significant decrease in myocardial performance was recorded. At the mRNA level, significant differences in the baseline expression of NCX, SERCA and CSQ between neonatal and adult hearts were observed. In neonatal post-ischemic hearts, NCX and CSQ expression were significantly higher at the mRNA level than in controls. In contrast, SERCA expression remained unchanged in neonatal hearts and decreased in adult hearts compared to the non-ischemic controls.

CONCLUSION

These findings suggest that changes in gene expression of calcium handling proteins may be involved in the different susceptibility of neonatal compared to adult hearts to developing myocardial dysfunction after ischemia.

Calpain-1-sensitive myofibrillar proteins of the human myocardium

Calpain-1 is a ubiquitous intracellular Ca2+-activated protease, which has been implicated in the pathogenesis of reversible myocardial depression (i.e. myocardial stunning) that follows ischemia and reperfusion via myofibrillar protein degradation. However, the target proteins of this degradative process in the human myocardium have not yet been identified. In order to compare the levels of Calpain-1 susceptibility within a set of human myofibrillar proteins (titin, alpha-fodrin, desmin, troponin T (cTnT), troponin I (cTnI) and alpha-actinin), crude left ventricular tissue homogenates were incubated for 0.5, 15, 30, 60 or 120 min in the presence of Calpain-1 (1 U or 5 U). Differences in the kinetics and extents of protein degradation were subsequently evaluated by using silver-stained SDS-polyacrylamide gels and Western immunoblot analyses. These assays revealed myofibrillar proteins with high (titin and alpha-fodrin), moderate (desmin and cTnT), or low (cTnI and alpha-actinin) relative Calpain-1 susceptibilities. The level of phosphorylation of cTnI did not explain its relatively low Calpain-1 susceptibility. Moreover, the molecular mass distributions of the truncated alpha-fodrin, desmin and cTnI fragments resulting from Ca2+-dependent autoproteolysis exhibited marked similarities with those of their Calpain-1-clipped products. These in vitro results shed light on a number of structural (titin, alpha-fodrin, desmin and alpha-actinin) and regulatory (cTnT and cTnI) proteins within the contractile apparatus as potential targets of Calpain-1. Their degradation may contribute to the development of postischemic stunning in the human myocardium.

Positive inotropism in mammalian skeletal muscle in vitro during and after fatigue

We tested the hypothesis that positive inotropic factors decrease fatigue and improve recovery from fatigue in mammalian skeletal muscle in vitro. To induce fatigue, we stimulated mouse soleus and extensor digitorum longus (EDL) to perform isometric tetanic contractions (50 impulses x s(-1) for 0.5 s) at 6 contractions x min(-1) for 60 min in soleus and 3 contractions x min(-1) for 20 min in EDL. Muscles were submerged in Krebs-Henseleit bicarbonate solution (Krebs) at 27 degrees C gassed with 95% nitrogen - 5% carbon dioxide (anoxia). Before and for 67 min after the fatigue period, muscles contracted at 0.6 contractions x min(-1) in 95% oxygen - 5% carbon dioxide (hyperoxia). We added a permeable cAMP analog (N6, 2'-O-dibutyryladenosine 3':5'-cyclic monophosphate at 10(-3) mol x L(-1) (dcAMP)), caffeine (2 x 10(-3) mol x L(-1), or Krebs as vehicle control at 25 min before, during, or at the end of the fatigue period. In soleus and EDL, both challenges added before fatigue significantly increased developed force but only caffeine increased developed force when added during the fatigue period. At the end of fatigue, the decrease in force in challenged muscles was equal to or greater than in controls so that the force remaining was the same or less than in controls. EDL challenged with dcAMP or caffeine at any time recovered more force than controls. In soleus, caffeine improved recovery except when added before fatigue. With dcAMP added to soleus, recovery was better after challenges at 10 min and the end of the fatigue period. Thus, increased intracellular concentrations of cAMP and (or) Ca2+ did not decrease fatigue in either muscle but improved recovery from fatigue in EDL and, in some conditions, in soleus.

Biology of the troponin complex in cardiac myocytes

Troponin is the regulatory complex of the myofibrillar thin filament that plays a critical role in regulating excitation-contraction coupling in the heart. Troponin is composed of three distinct gene products: troponin C (cTnC), the 18-kD Ca(2+)-binding subunit; troponin I (cTnI), the approximately 23-kD inhibitory subunit that prevents contraction in the absence of Ca2+ binding to cTnC; and troponin T (cTnT), the approximately 35-kD subunit that attaches troponin to tropomyosin (Tm) and to the myofibrillar thin filament. Over the past 45 years, extensive biochemical, biophysical, and structural studies have helped to elucidate the molecular basis of troponin function and thin filament activation in the heart. At the onset of systole, Ca2+ binds to the N-terminal Ca2+ binding site of cTnC initiating a conformational change in cTnC, which catalyzes protein-protein associations activating the myofibrillar thin filament. Thin filament activation in turn facilitates crossbridge cycling, myofibrillar activation, and contraction of the heart. The intrinsic length-tension properties of cardiac myocytes as well as the Frank-Starling properties of the intact heart are mediated primarily through Ca(2+)-responsive thin filament activation. cTnC, cTnI, and cTnT are encoded by distinct single-copy genes in the human genome, each of which is expressed in a unique cardiac-restricted developmentally regulated fashion. Elucidation of the transcriptional programs that regulate troponin transcription and gene expression has provided insights into the molecular mechanisms that regulate and coordinate cardiac myocyte differentiation and provided unanticipated insights into the pathogenesis of cardiac hypertrophy. Autosomal dominant mutations in cTnI and cTnT have been identified and are associated with familial hypertrophic and restrictive cardiomyopathies.

Degradation of rat cardiac troponin I during ischemia independent of reperfusion

Cardiac troponin I (cTnI) degradation has been noted in the stunned myocardium of rodents after ischemia and reperfusion and is one proposed mechanism for the decreased left ventricular (LV) contractility in postischemic hearts. cTnI degradation has been best described after reperfusion of the ischemic myocardium. The effect of ischemia, independent of reperfusion, on cTnI breakdown has not been well characterized. We tested the hypothesis that progressive cTnI degradation occurs with increasing durations of ischemia and that this ischemia-based degradation is, in part, oxidant mediated. Isolated perfused rat hearts underwent global ischemia of 15, 20, or 25 min with and without reperfusion. A second series of hearts was treated with the antioxidants tiron (10 mM) and N-acetylcysteine (4 mM) before 20 min of global ischemia without reperfusion. cTnI degradation was measured using a cTnI-specific antibody and Western blot analyses. A progressive increase in cTnI degradation was seen with increasing duration of ischemia (no reperfusion), which correlated with the return of LV developed pressure during reperfusion. The extent of cTnI degradation was increased in hearts pretreated with antioxidants, although the qualitative degradation pattern was not altered. We conclude that a time-dependent cTnI breakdown occurs during global ischemia that is independent of reperfusion. cTnI breakdown during ischemia is further increased in the presence of antioxidants, suggesting ROS generated during ischemia may play a cTnI protective role.

Phospholamban phosphorylation in ischemia-reperfused heart. Effect of pacing during ischemia and response to a beta-adrenergic challenge

The status of phospholamban (PLB) phosphorylation in the ischemia-reperfused hearts remains controversial. Although a decrease in the phosphorylation of both PLB residues (Ser16, PKA site, and Thr17, CaMKII site) was previously reported, experiments from our laboratory failed to detect this decrease. In an attempt to elucidate the cause for this discrepancy, experiments were performed in Langendorff-perfused rat hearts with two main goals: (1) To determine whether keeping pacing during ischemia, a protocol followed in other ischemia-reperfusion models, decreases the phosphorylation of PLB residues, below pre-ischemic values; (2) To investigate whether a maximal beta-adrenergic challenge allows to detect a decrease in the ability of PLB to be phosphorylated in ischemia-reperfused hearts. Hearts were submitted to a global ischemia/reperfusion protocol (20/30 min) with (P) or without (NP) pacing during ischemia, and phosphorylation of PLB residues was assessed by immunodetection. The recovery of contractility upon reperfusion was lower in P vs. NP hearts. Ser16 of PLB, was phosphorylated at the end of ischemia in NP hearts. This increase appeared earlier in P hearts and was significantly diminished by catecholamine depletion and beta-blockade. Thr17 site was phosphorylated at the beginning of ischemia and the onset of reperfusion. The ischemia-induced phosphorylation of Thr17 was higher and more sustained in P vs. NP hearts, and inhibited by the calcium channel blocker, nifedipine, whereas the reperfusion-induced increase in Thr17 phosphorylation was similar in P and NP hearts and was significantly diminished by the Na+/Ca2+ exchanger inhibitor KB-R7943. Phosphorylation of PLB residues did not decrease below basal levels at any time during ischemia and reperfusion. However, the phosphorylation, inotropic and lusitropic response to beta-adrenergic stimulation was significantly decreased both in P and NP hearts.

Augmented systolic response to the calcium sensitizer EMD-57033 in a transgenic model with troponin I truncation

Myocardial stunning is a form of acute reversible cardiac dysfunction that occurs after brief periods of ischemia and reperfusion. In several animal models, stunning is associated with proteolytic truncation of troponin I (TnI). Mice expressing the same proteolytic TnI fragment [TnI-(1–193)] demonstrate cardiac depression with a decreased maximal calcium-activated tension. We therefore hypothesized preferential improvement in mice expressing TnI-(1–193) treated with the calcium-sensitizing drug EMD-57033. TnI-(1–193) and nontransgenic myofibrils exhibited significant sensitization to calcium in Mg-ATPase assays after EMD-57033 exposure. However, only transgenic myofibrils exhibited an increase in maximal activity ( P = 0.023). EMD-57033 also increased maximal calcium-activated force in TnI-(1–193) muscle, such that it was comparable to nontransgenic cardiac muscle. EMD-57033 enhanced in vivo systolic function modestly in controls but had a marked effect in transgenic mice, with an almost threefold greater leftward shift of the end-systolic pressure-volume relation ( P = 0.0005). These data indicate a targeted efficacy of EMD-57033 in offsetting the contractile defect in TnI-(1–193) mice, and this may have therapeutic implications in models displaying this myofilament defect.

Reactive oxygen species as mediators of signal transduction in ischemic preconditioning

Ischemic preconditioning (IPC) is a most powerful endogenous mechanism for myocardial protection against ischemia/reperfusion injury. It is now apparent that reactive oxygen species (ROS) generated in the mitochondrial respiratory chain act as a trigger of IPC. ROS mediate signal transduction in the early phase of IPC through the posttranslational modification of redox-sensitive proteins. ROS-mediated activation of Src tyrosine kinases serves a scaffold for interaction of proteins recruited by G protein-coupled receptors and growth factor receptors that is necessary for amplification of cardioprotective signal transduction. Protein kinase C (PKC) plays a central role in this signaling cascade. A crucial target of PKC is the mitochondrial ATP-sensitive potassium channel, which acts as a trigger and a mediator of IPC. Mitogen-activated protein (MAP) kinases (extracellular signal-regulated kinase, p38 MAP kinase, and c-Jun NH(2)-terminal kinase) are thought to exist downstream of the Src-PKC signaling module, although the role of MAP kinases in IPC remains undetermined. The late phase of IPC is mediated by cardioprotective gene expression. This mechanism involves redox-sensitive activation of transcription factors through PKC and tyrosine kinase signal transduction pathways that are in common with the early phase of IPC. The effector proteins then act against myocardial necrosis and stunning presumably through alleviation of oxidative stress and Ca(2+) overload. Elucidation of IPC-mediated complex signaling processes will help in the development of more effective pharmacological approaches for prevention of myocardial ischemia/reperfusion injury.

Stunning and myocardial contractile autoregulation studied on the isolated isovolumic blood-perfused dog heart

AIM

To study, for the first time, the effects of stunning on homeometric and heterometric autoregulation.

METHODS AND RESULTS

Ischaemia (15 min)/reperfusion (30 min) was induced in the isovolumic blood-perfused dog heart preparation. Heart rate elevations (n = 9) from 60 to 200 beats min-1, in steps of 20 beats min-1, promoted the same inotropic stimulation in control (C) and stunning (S), indicating that ischaemia/reperfusion does not affect the changes in calcium kinetics elicited by the Bowditch effect. Sudden ventricular dilation (VD) (n = 10) evoked an instantaneous increase in developed pressure (Delta1DP) followed by a continuous slow performance increase (Delta2DP) in C and S. Delta1DP (C: 35 +/- 2.2 mmHg; S: 27 +/- 2.1 mmHg; P = 0.002) and Delta2DP (C: 20 +/- 1.6 mmHg; S: 14 +/- 1.3 mmHg; P = 0.002) decreased proportionally, while Delta2/Delta1DP (C: 0.57 +/- 0.13; S: 0.58 +/- 0.14) and slow response time course (T/2) were unchanged (C: 55 +/- 6.6 s; S: 57 +/- 7.7 s) after ischaemia/reperfusion. The reduction of Delta1DP can be understood as a decline of the myofilaments calcium responsiveness, the main pathophysiological effect of stunning. The reason for the weakening of Delta2DP, due to intracellular calcium gain, was not determined but it was supposed that its complete manifestation could be restricted by cyclic adenosine monophosphate (cAMP) myocardial content reduction. As reported by others, Delta2DP depends on myocardial cAMP, and it has been shown that myocardial cAMP is decreased after ischaemia/reperfusion.

CONCLUSIONS

Contractile depression due to stunning has no effect on the inotropic stimulation generated by the Bowditch phenomenon. Immediate and time-dependent enhancements of contraction evoked by sudden VD are proportionally reduced and the slow response time course is unaffected in the stunned myocardium.

Effects of brief ischemia and reperfusion on the myocardium and the role of nitric oxide

Brief myocardial ischemia/reperfusion has complex effects on the myocardium. In the short term the myocardium may be stunned with temporarily reduced contractile function, though this may also be accompanied by the modification and de novo synthesis of proteins that protect the heart against subsequent early or delayed insults. Repeated episodes of non-lethal ischemia, which are common in the clinical setting, combine all of these phenomena and may ultimately result in chronic contractile dysfunction. Nitric oxide is intimately linked to many of these alterations in cellular function and defense. This article examines data predominantly from in vivo large animal studies that relate to these ischemia-induced changes, the evidence for the proposed mechanisms behind both myocardial stunning and preconditioning while concentrating on the role of nitric oxide in these conditions.

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 Ca(2+), have been proposed. The first was tested primarily using large mammalian models, whereas the others were tested primarily using rodent models. Recently, the Ca(2+) handling hyothesis has been tested in a large mammalian swine model of myocardial stunning, in which both Ca(2+) and transients and L-type Ca(2+) 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.

Short-term administration of ethanol does not affect functional recovery from myocardial stunning in awake dogs

Chronic ingestion of small doses of ethanol protects the myocardium from ischemic damage. It was demonstrated that short-term administration of ethanol (SAE) enhances the recovery of stunned myocardium in acutely instrumented, anesthetized dogs. It is unclear whether this beneficial effect of SAE also occurs in awake dogs. Therefore, we investigated the effects of SAE on regional myocardial stunning in awake dogs. Thirty-six dogs were chronically instrumented for measurement of heart rate, left atrial, aortic, and left ventricular pressure, left systolic ventricular contactility (dP/dt(max)) and diastolic ventricular function (dP/dt(min)), and regional myocardial wall-thickening fraction (WTF). Occluders around the left anterior descending (LAD) artery allowed the induction of reversible ischemia in the LAD-perfused myocardium. The dogs were assigned to one of three groups that differed in the dose of ethanol administered in the ethanol experiment (I, 0.125 g/kg [n = 12]; II, 0.25 g/kg [n = 12]; III, 0.5 g/kg [n = 12]). In each group, the dogs underwent two ischemic episodes (randomized crossover fashion; separate days): 10 min of LAD occlusion after the application of ethanol IV over 30 min (ethanol group) and without ethanol (control). WTF and hemodynamic variables were measured at baseline and at predetermined time points until complete recovery of myocardial stunning occurred. LAD-ischemia led to a significant decrease of LAD-WTF in all groups. There was no difference in WTF and hemodynamic variables with or without SAE during reperfusion. We conclude that SAE (0.125 g/kg, 0.25 g/kg, and 0.5 g/kg) does not significantly affect myocardial stunning in conscious dogs.

IMPLICATIONS

In contrast to previous experiments in anesthetized dogs, short-term administration of ethanol does not alter myocardial stunning in conscious dogs.

Effect of treatment on ventricular function and troponin I proteolysis in reperfused myocardium

Effects of ischemia time and treatment interventions upon troponin I (TnI) proteolysis and function of reperfused myocardium were examined in isolated, perfused rabbit hearts. Hearts were randomized to 90 min aerobic perfusion, 15 min low-flow (1 ml/min) ischemia (I) and 60 min reperfusion (R) or 60 min low-flow I and 60 min R. Hearts subject to 60 min I and 60 min R received either no treatment, l -arginine treatment, or treatment with oxygen free radical (OFR) scavengers (mercapto-proponyl-glycine, catalase and superoxide dismutase). Hearts from cholesterol-fed rabbits were also studied after 60 min I and R. Isovolumic LV pressure and heart rate were recorded throughout and Western analysis of ventricular myocardium, using 3 specific antibodies, detected intact TnI (29 kDa) and TnI fragment (25 kDa). Hearts subject to 15 min I had minimal irreversible injury (TTC negative region=0.6+/-0.4% LV) but hearts subject to 60 min I had more extensive injury (TTC negative=40.7+/-5.8% LV). Recovery of rate-pressure product after 15 min I and 60 min R (56+/-9% of baseline) was better than after 60 min I and 60 min R (23+/-9%, P<0.01). Both l -arginine and OFR scavengers were associated with better recovery of function after 60 min I, (66+/-7% and 72+/-3% of baseline respectively, P<0.01 v no treatment) but cholesterol hearts had poor recovery after 60 min I (37+/-8%). The 25 kDa TnI (% total TnI immunoreactivity) was 8.7+/-0.9% in controls, 10.0+/-1.6% after 15 min I and 60 min R, and 17.4+/-2.4% after 60 min I and 60 min R (P<0.01 v controls and 15 min I). The proportion of 25 kDa TnI was increased in all hearts after 60 min I and did not change with treatment (l -arginine 16.8+/-1.8%, OFR scavengers 16.0+/-3.2%, cholesterol 14.0+/-1.9%). There was no relation between proportion of 25 kDa TnI and recovery of function. Samples from freshly excised rabbit hearts and human right atria also had 25 kDa TnI (relative intensities 8.5+/-2.3% and 5.1+/-2.6% respectively). Although TnI fragmentation increases after prolonged ischemia and reperfusion, the functional recovery of stunned myocardium is independent of degree of TnI fragmentation.

The role of troponin abnormalities as a cause for stunned myocardium

Myocardial stunning is a form of ischemic injury, which occurs with transient ischemia followed by re-establishment of flow, and which results in reversible cardiac dysfunction. There is evidence that the molecular defect in stunning is at the level of the contractile apparatus. Selective proteolysis of the myofilament protein, troponin I, appears to underlie the phenotype of stunning in some models, but other myofilament protein modifications may also have a role.

Beneficial effects of adenosine A(2a) agonist CGS-21680 in infarcted and stunned porcine myocardium

Although there are conflicting results on whether adenosine infusion during reperfusion alters infarct size, there are several reports that indicate adenosine A(2a) agonists reduce infarct size. There are also reports that the A(2a) agonist CGS-21680 increases cAMP and contractility in ventricular myocytes. The purpose of this study was to determine whether low-dose intracoronary infusions of CGS-21680 during reperfusion exert any beneficial effects in irreversibly and reversibly injured myocardium. Open-chest pigs were submitted to 60 min of coronary artery occlusion and 3 h of reperfusion. Treated pigs were administered intracoronary CGS-21680 (0.2 microg x kg(-1) x min(-1)) for the first 60 min of reperfusion. Pigs submitted to regional stunning (15 min ischemia) were treated with intracoronary CGS-21680 (0.15 microg x kg(-1) x min(-1)) after 2 h of reperfusion. In the infarct protocol, CGS-21680 reduced infarct size from 62 +/- 2% of the region at risk to 36 +/- 2%. In stunned myocardium, CGS increased load-independent regional preload recruitable stroke work and area by > or =70%, but the same infusion in normal myocardium was associated with no inotropic effect. Both beneficial effects were associated with little systemic hemodynamic effects. These findings suggest that reperfusion infusions of low doses of the A(2a) agonist CGS-21680 exert beneficial effects in reversibly and irreversibly injured myocardium.