Prevention of processes coupled with free radical formation prevents also the development of calcium-resistance in the diabetic heart

Recently it was shown that besides their negative role in pathogenesis of diabetes, reactive oxygen species (ROS) and particularly the products of non-enzymatic glycation of proteins (NEGP) may also participate in some processes of adaptation of the myocardium to diabetes, such as in the mechanism of development of calcium resistance of the heart. Our study revealed that the hearts of rats with experimentally induced diabetes (single dose of streptozotocin, 45 mg/kg i.v., 6 U/kg insulin daily) develop considerable resistance against calcium overload (induced by means of Ca-paradox). On the day 63 after the beginning of experiment, when the diabetic cardiomyopathy became fully developed but the hearts were still not failing, their calcium resistance was increased to 83.33%. Our results provide evidence that, when applied in a special regimen, resorcylidene aminoguanidine (RAG, 4 mg/kg) prevented both, the formation of fructosamine (a source of ROS generation), and also that of the advanced Maillard products, in the heart sarcolemma of diabetic rats. The effect of RAG was accompanied by a decrease in calcium resistance in the group of rats with chronic diabetes (63 days) from 83.3 to 46.7%. It is concluded that NEGP and ROS formation are inevitably needed for development of calcium resistance in the diabetic hearts.     

Preconditioning modulates susceptibility to ischemia-induced arrhythmias in the rat heart: the role of alpha-adrenergic stimulation and K(ATP) channels

A new concept of cardioprotection based on the exploitation of endogenous mechanisms is known as ischemic preconditioning (IPC). It has been hypothesized that substances released during brief ischemic stress (e.g. catecholamines) stimulate the receptors and trigger multiple cell signaling cascades. Opening of ATP-sensitive K+ channels [K(ATP)] has been suggested as a possible final step in the mechanisms of protection. In this study, the role of adrenergic activation was tested in Langendorff-perfused rat hearts subjected to test ischemia (TI; 30 min occlusion of LAD coronary artery) by: 1) mimicking IPC (5 min ischemia, 10 min reperfusion) with short-term (5 min) administration of norepinephrine (NE, 1 microM), 15 min prior to TI; 2) blockade with beta- or alpha1-receptor antagonists, propranolol (10 microM) and prazosin (2 microM), respectively, applied 15 min prior to TI during IPC. The role of K(ATP) opening was examined by perfusion with a K(ATP) blocker glibenclamide (10 microM) during IPC. Both IPC and NE-induced PC effectively reduced the incidence of ventricular tachycardia (VT) to 33% and 37%, respectively, vs 100% in the non-PC controls, whereby ventricular fibrillation (VF) was totally abolished by IPC and markedly suppressed by PC with NE (0% and 10%, respectively, vs 70% in the non-PC hearts; P < 0.05). The severity of arrhythmias (arrhythmia score, AS) was also markedly attenuated by both interventions (IPC: AS 1.7 +/- 0.4; NE-PC: AS 1.8 +/- 0.3 vs AS 4.1 +/- 0.2 in the controls; P < 0.05). Protection was not suppressed by propranolol (VT 28%; VF 14%; AS 2.2 +/- 0.6), whereas prazosin reversed the protective effect of PC (VT 83%; VF 67%; AS 4.0 +/- 0.8). Antiarrhythmic protection afforded by NE-PC was abolished by pretreatment of rats with pertussis toxin (25 microg/kg, i.p.) given 48 h prior to the experiments. Glibenclamide did not suppress the IPC-induced protection. In conclusion, the sensitivity of the rat heart to ischemic arrhythmias can be modulated by IPC. Protection is mediated via stimulation of alpha1-adrenergic receptors coupled with Gi-proteins but glibenclamide-sensitive K(ATP) channels do not appear to be involved in the mechanisms of antiarrhythmic protection in this model.     

Effect of melatonin on the isolated heart in the standard perfusion conditions and in the conditions of calcium paradox

The effect of melatonin (MLT) on the isolated rat heart was studied using the standard perfusion conditions (Langendorff preparation) and model of calcium paradox (Ca(2+)-paradox). Ca(2+)-paradox was induced by 1 minute perfusion with Ca(2+)-free Krebs-Henseleit (KH) solution and subsequent 20 minutes perfusion with a normal Ca(2+)-containing KH solution. In MLT group, MLT (10 micromol/l) was in the perfusion solution throughout the experiment. In controls, there was no MLT. VARIABLES: heart rate, coronary flow, systolic and diastolic pressure, +dP/dt max (index of contractility) and -dP/dt max (index of relaxation) were measured at the end of stabilization, i.e. after 30 minutes of standard perfusion and then in the 5th, 10th, 15th, 20th minute after perfusion with Ca(2+)-free KH solution. RESULTS: There was no difference between MLT group and controls in the standard perfusion conditions at the end of stabilization. After perfusion with Ca(2+)-free KH solution, systolic-diastolic difference (in the 10th, 15th, 20th minute), +dP/dt max (in the 5th, l0th, 15th, 20th minute) and -dP/dt max (in the 15th minute) were significantly decreased in MLT group in comparison to controls. CONCLUSION: Melatonin didn't influence rat isolated heart in standard perfusion conditions but it made the heart more susceptible to Ca(2+)-paradox.     

Salutary effect of tedisamil on post-ischemic recovery rat heart: Involvement of sarcolemmal (Na,K)-ATPase

The in vitro effect of tedisamil on the specific activity and kinetic parameters of the sarcolemmal (Na,K)-ATPase as well as its ex vivo effect on the (Na,K)-ATPase in the isolated, perfused rat hearts was determined. Five mol/l of tedisamil was added 5 min before the onset of 30 min global normothermic ischemia followed by 10 min reperfusion. At the conditions of its maximal cardioprotective effect (heart rate reduction, improved postischemic recovery of left ventricular developed pressure), the hearts were immediately used for isolation of sarcolemmal vesicles. In vitro, 1–100 mol/l of tedisamil produced a concentration-dependent stimulatory effect on (Na,K)-ATPase activity, with a peak seen at 20 mol/l (p < 0.01), while Mg-dependent ATPase was almost unchanged. Kinetic analysis revealed a significant increase in the affinity of the Na-binding sites on ATPase molecule at 20 mol/l of tedisamil. These biochemical findings were confirmed by cytochemistry. Moreover, ex vivo experiments revealed that tedisamil rendered the sarcolemmal (Na,K)-ATPase activity to be a more resistant to detrimental effects of ischemia. In conclusion, the cardioprotective action of tedisamil was accompanied with a better preservation of the specific activity of (Na,K)-ATPase.     

Activation of adenylate cyclase system in the preconditioned rat heart

Ischemic preconditioning (IP) protects the heart against subsequent prolonged ischemia. Whether the beta-adrenoceptor/adenylate cyclase pathway contributes to this cardioprotection is not yet fully known. Using enzyme catalytic cytochemistry we studied the adenylate cyclase activity and its distribution in the preconditioned rat heart. Adenylate cyclase activity was examined in Langendorff-perfused rat hearts subjected to the following conditions: control perfusion; 30 min regional ischemia; 5 min occlusion and 10 min reperfusion (IP); IP followed by ischemia. Ischemia-induced arrhythmias and the effect of ischemic preconditioning on the incidence of arrhythmias were analyzed. At the end of experiment the heart was shortly prefixed with glutaraldehyde. Tissue samples from the left ventricle were incubated in a medium containing the specific substrate AMP-PNP for adenylate cyclase and then routinely processed for electron microscopy. Adenylate cyclase activity was cytochemically demonstrated in the sarcolemma and the junctional sarcoplasmic reticulum (JSR) in control hearts, while it was absent after test ischemia. The highest activity of the precipitate was observed after ischemic preconditioning. In the preconditioned hearts followed by test ischemia, adenylate cyclase activity in the precipitate was preserved in sarcolemma and even more in JSR. Protective effect of ischemic preconditioning was manifested by the suppression of severe arrhythmias. These results indicate the involvement of the adenylate cyclase system in mechanisms underlying ischemic preconditioning.     

Morphological alterations and NO-synthase expression in the heart after continuous light exposure of rats

Although exposure to continuous light is associated with hypertension and modulates the outcome of ischemia-reperfusion injury, less attention has been paid to its effects on cardiac morphology. We investigated whether 4-week exposure of experimental rats to continuous 24 h/day light can modify cardiac morphology, with focus on heart weight, fibrosis and collagen I/III ratio in correlation with NO-synthase expression. Two groups of male adult Wistar rats were studied: controls exposed to normal light/dark cycle (12 h/day light, 12 h/day dark) and rats exposed to continuous light. After 4 weeks of treatment the absolute and the relative heart weights were determined and myocardial fibrosis and collagen type I/III ratio were evaluated using picrosirius red staining. Endothelial and inducible NO-synthase expression was detected immunohistochemically. The exposure of rats to continuous light resulted in an increase of body weight with proportionally increased heart weight. Myocardial fibrosis remained unaffected but collagen I/III ratio increased. Neither endothelial nor inducible NO-synthase expression was altered in light-exposed rats. We conclude that the loss of structural homogeneity of the myocardium in favor of collagen type I might increase myocardial stiffness and contribute to functional alterations after continuous light exposure.     

The influence of exaprolol upon the ischaemic rat heart and its interaction with sarcolemmal (Na+ + K+)-ATPase

The capability of cyclohexylphenol exaprolol of protecting the ischaemic myocardium during ischaemic cardiac arrest was assessed in the isolated working rat heart. Exaprolol added to the perfusion medium in a dose of 10(-7) mol.l-1 only minimally influenced the left ventricular function (reduced the stroke volume by 18.84% and cardiac output by 14.63%). The hearts were subjected to global ischaemia for 75 min at 26 degrees C and subsequently reperfused for 60 min at 37 degrees C. The recovery of left ventricular function following reperfusion, expressed as a percentage of preischaemic functional performance was used as an indicator of the ischaemic tolerance of the heart. The effect of exaprolol on sarcolemmal (Na+ + K+)-, Mg2+- and Ca2+-ATPase activities was also examined. Exaprolol-pretreated hearts revealed better postischaemic recovery of the left ventricular dP/dt max and stroke volume as well as improved efficiency in the transformation of chemical energy to mechanical work. Exaprolol in 10(-4) mol.l-1 concentration significantly stimulated the specific activity of sarcolemmal (Na+ + K+)-ATPase. Possible mechanisms of the salutary effect of exaprolol on the ischaemic heart are discussed.     

Species differences in localization of cardiac cAMP-phosphodiesterase activity: A cytochemical study

The localization of the membrane-bound cyclic 3,5-AMP phosphodiesterasein cardiac tissues of both, rat and dog was studied by cytochemical method.40 µm thick slices from glutaraldehyde fixed heart tissue wereincubated in the medium with cAMP as a substrate and Pb ions as a capturemetal of the reaction product. The cAMP-PDE activity in the rat ventriclewas only shown positive on the sarcolemma. Whereas, in canine ventriculartissue the cAMP-PDE activity in cardiomyocytes was shown on the sarcolemma,on the junctional sarcoplasmic reticulum and on subsarcolemmal cisternae.The results confirm differences in the localization of cAMP-PDE in dog andrat heart.     

Mechanisms that may be involved in calcium tolerance of the diabetic heart

In diabetes the hearts exhibit impaired membrane functions, but also increased tolerance to Ca²⁺ (iCaT) However, neither the true meaning nor the molecular mechanisms of these changes are fully understood. The present study is devoted to elucidation of molecular alterations, particularly those induced by non-enzymatic glycation of proteins, that may be responsible for iCaT of the rat hearts in the stage of fully developed, but still compensated diabetic cardiomyopathy (DH). Insulin-dependent diabetes (DIA) was induced by a single i.v. dose of streptozotocin (45 mg.kg^-1). Beginning with the subsequent day, animals obtained 6 U insulin daily. Glucose, triglycerides, cholesterol and glycohemoglobin were investigated in blood. ATPase activities, the kinetics of activation of (Na,K)-ATPase by Na⁺ and K⁺, further the fluorescence anisotropy of diphenyl-hexatriene as well as the order parameters of membranes in isolated heart sarcolemma (SL) were also investigated. In addition, the degree of glycation and glycation-related potency for radical generation in SL proteins were determined by investigating their fructosamine content. In order to study calcium tolerance of DH in a 'transparent' model, hearts were subjected to calcium paradox (Ca-Pa, 3 min of Ca²⁺ depletion; 10 min of Ca²⁺ repletion). In this model of Ca²⁺-overload, Ca²⁺ ions enter the cardiac cells in a way that is not mediated by receptors. Results revealed that more than 83% of the isolated perfused DH recovered, while the non-DIA control hearts all failed after Ca-Pa. DH exhibited well preserved SL ATPase activities and kinetics of (Na,K)-ATPase activation by Na⁺, even after the Ca-Pa. This was considered as a reason for their iCaT. Pretreatment and administration of resorcylidene aminoguanidine (RAG 4 or 8 mg.kg^-1) during the disease prevented partially the pathobiochemical effects of DIA-induced glycation of SL proteins. DIAinduced perturbations in anisotropy and order parameters of SL were completely prevented by administration of RAG (4 mg.kg^-1). Although, the latter treatment exerted little influence on the (Na,K)-ATPase activity, it decreased the calcium tolerance of the DH. Results are supporting our hypothesis that the glycation-induced enhancement in free radical formation and protein crosslinking in SL may participate in adaptive mechanisms that may be also considered as 'positive' and are responsible for iCaT of the DH.