Bohuslav Ostadal

Cardioprotective effects of chronic hypoxia and ischaemic preconditioning are not additive

Abstract The objective of the work was to examine whether adaptation to intermittent high altitude hypoxia and ischaemic preconditioning provide additive protection of the heart against subsequent acute ischaemic injury. Adult male rats were exposed to hypoxia (7000 m, 8 h/day, 24–30 exposures) in a hypobaric chamber. Susceptibility of their hearts to ischaemia-induced ventricular arrhythmias and infarction was evaluated in open-chest animals subjected to 30-min coronary artery occlusion and 4-h reperfusion. Preconditioning was induced by either two (PC1) or five (PC2) occlusions of the same artery for 5 min, each followed by 5-min reperfusion. Adaptation to hypoxia decreased the arrhythmia score from 2.75 ± 0.13 in normoxic controls to 2.17 ± 0.18. Both PC1 and PC2 reduced the arrhythmia score in the controls (0.15 ± 0.10 and 0.71 ± 0.24, respectively), as well as in the hypoxic groups (0.40 ± 0.15 and 0.27 ± 0.15, respectively). The infarct size was reduced from 66.6 ± 2.3% of the area at risk in the controls to 50.2 ± 1.9% in the adapted rats. PC1 conferred further protection in adapted animals (38.4 ± 2.8%) but this combined effect was of the same magnitude as that of preconditioning in the controls (37.5 ± 1.6%). Similar results were obtained using PC2. It is concluded that adaptation to hypoxia decreases the efficiency of ischaemic preconditioning; cardioprotective effects of these two phenomena are not additive. The results are consistent with the view that the mechanisms of protection conferred by chronic hypoxia and preconditioning may share the same signalling pathway.

Effects of mitochondrial KATP modulators on cardioprotection induced by chronic high altitude hypoxia in rats

OBJECTIVES Adaptation of rats to intermittent high altitude hypoxia increases the tolerance of their hearts to acute ischemia/reperfusion injury. Our aim was to examine the role of mitochondrial ATP-sensitive potassium channels (K(ATP)) in this form of protection. METHODS Adult male Wistar rats were exposed to hypoxia of 5000 m in a barochamber for 8 h/day, 5 days a week; the total number of exposures was 24-32. A control group was kept under normoxic conditions (200 m). Infarct size (tetrazolium staining) was measured in anesthetized open-chest animals subjected to 20-min regional ischemia (coronary artery occlusion) and 4-h reperfusion. Isolated perfused hearts were used to assess the recovery of contractile function following 20-min global ischemia and 40-min reperfusion. In the open-chest study, a selective mitochondrial K(ATP) blocker, 5-hydroxydecanoate (5 mg/kg), or openers, diazoxide (10 mg/kg) or BMS-191095 (10 mg/kg), were administered into the jugular vein 5 and 10 min before occlusion, respectively. In the isolated heart study, 5-hydroxydecanoate (250 micromol/l) or diazoxide (50 micromol/l) were added to the perfusion medium 5 or 10 min before ischemia, respectively. RESULTS In the control normoxic group, infarct size occupied 62.2+/-2.0% of the area at risk as compared with 52.7+/-2.5% in the chronically hypoxic group (P<0.05). Post-ischemic recovery of contractile function (dP/dt) reached 60.0+/-3.9% of the pre-ischemic value and it was improved to 72.4+/-1.2% by adaptation to hypoxia (P<0.05). While 5-hydroxydecanoate completely abolished these protective effects of chronic hypoxia, it had no appreciable influence in normoxic groups. In contrast, diazoxide significantly increased the recovery of contractile function and reduced infarct size in normoxic groups only. The later effect was also observed following treatment with BMS-191095. CONCLUSION The results suggest that opening of mitochondrial K(ATP) channels is involved in the cardioprotective mechanism conferred by long-term adaptation to intermittent high altitude hypoxia.

Gender Differences in Cardiac Ischemic Injury and Protection—Experimental Aspects

This review summarizes some available information on gender differences of myocardial injury with particular attention to experimental approach. It has been observed that significant gender differences exist already in normal heart. They involve among others cardiac growth, contractile function, calcium metabolism and function of mitochondria. Differences, characteristic of the normal myocardium, generate the logical presumption of the different reaction of the male and female heart to various pathogenic factors. Most of the experimental studies confirm the clinical observations: increased resistance of the female heart to ischemia/reperfusion injury was shown in dogs, rats, mice and rabbits. Furthermore, gender differences in the ischemic tolerance of the adult myocardium can be influenced by interventions (e.g. hypoxia) imposed during the early phases of ontogenetic development. The already high tolerance of the adult female heart can be increased by adaptation to chronic hypoxia and ischemic preconditioning. It seems that the protective effect depends on age: it was absent in young, highly tolerant heart but it appeared with the decrease of natural resistance during aging. Both experimental and clinical studies have indicated that female gender influences favorably also the remodeling and the adaptive response to myocardial infarction. It follows from the data available that male and female heart differs significantly in many parameters under both physiological and pathological conditions. Detailed molecular and cellular mechanisms of these differences are still unknown; they involve genomic and non-genomic effects of sex steroid hormones, particularly the most frequently studied estrogens. The cardiovascular system is, however, influenced not only by estrogens but also by other sex hormones, e.g. androgens. Moreover, steroid hormone receptors do not act alone but interact with a broad array of co-regulatory proteins to alter transcription. The differences are so important that they deserve serious consideration in clinical practice in search for proper diagnostic and therapeutic procedures.

Effects of melatonin on ischemia and reperfusion injury of the rat heart.

Effects of melatonin on various manifestations of ischemia/reperfusion injury of the isolated perfused rat heart were examined. Ischemia- and reperfusion-induced ventricular arrhythmias were studied under constant flow in hearts subjected to 10, 15 or 25 min of regional ischemia (induced by LAD coronary artery occlusion) and 10-min reperfusion. Melatonin was added to the perfusion medium 5 min before ischemia at concentrations of 10 μmol/l or 10 nmol/l and was present throughout the experiment. Recovery of the contractile function was evaluated under constant perfusion pressure after 20-min global ischemia followed by 40-min reperfusion. Hearts were treated with melatonin at a high concentration (10 μmol/l) either 5 min before ischemia only (M1) or 5 min before ischemia and during reperfusion (M2) or only during reperfusion (M3). At the high concentration, melatonin significantly reduced the incidence of reperfusion-induced ventricular fibrillation and decreased arrhythmia score (10% and 2.2 ± 0.3, respectively) as compared with the corresponding untreated group (62% and 4.1 ± 0.3, respectively); the low concentration had no effect. This substance did not affect the incidence and severity of ischemic arrhythmias. Melatonin (M2, M3) significantly improved the recovery of the contractile function as compared with the untreated group; this protection did not appear if melatonin was absent in the medium during reperfusion (M1). Our results show that melatonin, in accordance with its potent antioxidant properties, effectively protects the rat heart against injury associated with reperfusion. It appears unlikely that melatonin is cardioprotective at physiological concentrations.

Regression of Chronic Hypoxia-Induced Pulmonary Hypertension, Right Ventricular Hypertrophy, and Fibrosis: Effect of Enalapril

Chronic hypoxia induces pulmonary hypertension and right ventricular hypertrophy. These changes are completely reversible, except for persistent myocardial fibrosis. The aim of the present study was to determine whether treatment with the angiotensin-converting enzyme (ACE) inhibitor enalapril can reduce the ventricular collagen content in animals recovering from chronic hypoxia. Adult male Wistar rats were exposed to intermittent high-altitude hypoxia simulated in a barochamber (7000 m, 8 hr/day, 5 days a week, 24 exposures), then transferred to normoxia and divided into two groups: (a) treated with enalapril (0.1 g/kg/day for 60 days) and (b) without treatment. The corresponding control groups were kept under normoxic conditions. Enalapril significantly decreased the heart rate, systemic arterial pressure, and absolute left and right ventricular weights in both hypoxic and control rats; on the other hand, the pulmonary blood pressure was unchanged. The content and concentration of collagen was reduced in both ventricles of enalapril-treated hypoxic and control animals by 10–26% compared with the corresponding untreated groups. These data suggest that the partial regression of cardiac fibrosis due to enalapril may be independent of the pressure load.

Ischemic preconditioning in chronically hypoxic neonatal rat heart.

Rat hearts isolated on d 1, 4, 7, and 10 of postnatal life were perfused (in Langendorff mode) with Krebs-Henseleit solution at constant pressure, temperature, and stimulation rate. Recovery of the contractile function after global ischemia was measured by an isometric force transducer and analyzed using an online computer. Ischemic preconditioning (IP) was induced by three 3-min periods of global ischemia, each separated by a 5-min period of reperfusion. Prenatal hypoxia was induced by exposure of pregnant mothers to intermittent high altitude (IHA), simulated in a barochamber (8 h/d, 5000 m) from d 15 to 20 of pregnancy. Postnatal hypoxia was simulated by the identical procedure from postnatal d 1 to 6 and 9. Prenatal exposure to IHA failed to improve ischemic tolerance on d 1, but postnatal exposure to IHA improved recovery of the developed force after ischemia on d 7 (33 ± 3%versus 43 ± 4%) and 10 (39 ± 2%versus 54 ± 2%). Combination of IHA and IP induced higher protective effects in all age groups, including postnatal d 1 (48 ± 2%versus 56 ± 3%), whereas IHA and IP applied separately failed to improve ischemic tolerance. Neither the mitochondrial KATP channel blocker 5-hydroxydecanoate nor the nitric oxide synthase inhibitor Nω-nitro-l-arginine methyl ester abolished protection by IP in normoxic animals, but they decreased significantly protection by IHA hypoxia. The final recovery was even lower than the corresponding normoxic values. It seems likely that mitochondrial KATP channels and nitric oxide may be involved in the protective mechanisms of adaptation to chronic hypoxia but not to that of IP, at least in neonates.

Neonatal cardiac mitochondria and ischemia/reperfusion injury

Postnatal maturation of the heart is characterized by decreasing tolerance to ischemia/reperfusion (I/R) injury associated with significant changes in mitochondrial function. The aim of this study is to test the hypothesis that the role of the mitochondrial membrane permeability transition pore (MPTP) in the I/R injury differs in the neonatal and in the adult heart. For this purpose, the effect of blockade of MPTP on the degree of I/R injury and the sensitivity of MPTP to swelling-inducing agents was compared in hearts from neonatal (7 days old) and adult (90 days old) Wistar rats. It was found that the release of NAD+ from the perfused heart induced by I/R can be prevented by sanglifehrin A (SfA) only in the adult myocardium; SfA had no protective effect in the neonatal heart. Furthermore, the extent of Ca-induced swelling of mitochondria from neonatal rats was significantly lower than that from the adult animals; mitochondria from neonatal rats were more resistant at higher concentrations of calcium. In addition, not only the extent but also the rate of calcium-induced swelling was about twice higher in adult than in neonatal mitochondria. The results support the idea that lower sensitivity of the neonatal MPTP to opening may be involved in the mechanism of the higher tolerance of the neonatal heart to I/R injury.

The past, the present and the future of experimental research on myocardial ischemia and protection

At present, cardiovascular diseases represent the most important health risks because they are responsible for more than 50% of total mortality. Among them, ischemic heart disease is the leading cause of morbidity and mortality, and according to the World Health Organization, will be the major global cause of death by the year 2020. Major progress in the prognosis, diagnosis and therapy of ischemic heart disease would be impossible without notable achievements of the 20th century that have been critical for further development of cardiology.We are now living in the era of molecular medicine, and the influence of basic research on clinical practice has never been more pronounced. This, however, necessitates a new strategy; future cardiovascular research should include the following general guidelines: 1) to evaluate the role and proportion of already described molecular pathways; descriptive approaches will gradually disappear; 2) to distinguish between acute, chronic and pleiotropic effects of different drugs under in vitro and in vivo conditions, with respect to possible clinical use; 3) to use clinically relevant genetic models; 4) to study possible alterations in intracellular signaling in order to find the decisive steps responsible for abnormal control of cell growth, contractile function, lipid metabolism, cardiac ischemic tolerance, etc.; 5) to study the molecular mechanisms of cardiovascular diseases not only in healthy individuals, but also under different pathological conditions. Such an approach must include developmental and gender differences, which are particularly important for the field of ischemic heart disease; therefore, experimental cardiovascular research can no longer be restricted to males of uncertain age. It is hoped that patients in future decades will profit from the progress of basic cardiovascular research.

Expression of mitochondrial uncoupling protein 3 and adenine nucleotide translocase 1 genes in developing rat heart: putative involvement in control of mitochondrial membrane potential

Postnatal maturation of the heart depends on the switch from glycolytic to oxidative metabolism and it is associated with decreasing tolerance to oxygen deprivation. Therefore, changes in composition and function of cardiac mitochondria during postnatal development require detailed characterization. Left-ventricular myocardium of prenatal, and 1-, 2-, 5-, 10-, 20-, 28-, 50-, 60-, and 90-d-old male Wistar rats was studied. The expression of uncoupling proteins (UCPs), adenine nucleotide translocase (ANT), and peroxisome proliferator-activated receptor alpha (PPARalpha) genes was characterized by northern blotting (UCP2), real-time quantitative RT-PCR (UCP2, UCP3, ANT1, ANT2, and PPARalpha), and by immunoblotting (UCP3). In isolated mitochondria, cytochromes a + a(3) were quantified by a spectrophotometry, and mitochondrial membrane potential (MMP) was measured using Rhodamine 123 (by spectrofluorimetry and flow cytometry). The specific content of cytochromes in mitochondria increased two-fold between birth and day 30, similarly, as the expression of ANT1 and PPARalpha genes. Postnatal activation in the expression of UCP2, UCP3, ANT1 and PPARalpha genes resulted in the expression maxima between days 20 and 30. The content/expression declined following day 20 (UCP2, UCP3, and PPARalpha) or 30 (cytochromes and ANT1), while expression of ANT2 declined continuously during the first month of life. In 1-d-old animals a single population of mitochondria with a relatively high MMP was observed; with increasing age, a second population of mitochondria with a significantly lower MMP appeared. The results support the view that mitochondrial energy conversion in heart changes during ontogeny and suggest the involvement of UCP3 and/or ANT1 in the control mechanism.

Effect of perinatal hypoxia on cardiac tolerance to acute ischaemia in adult male and female rats

1 The number of adult patients undergoing surgery for congenital cyanotic defects in childhood has increased significantly. Therefore, the aim of the present study was to examine the effect of perinatal hypoxia on the tolerance of the adult myocardium to acute ischaemia–reperfusion injury. 2 Pregnant Wistar rats were exposed to intermittent hypobaric hypoxia 7 days before delivery; pups were born under normoxic conditions and exposed to hypoxia again for 10 postnatal days. After the last hypoxic exposure, all animals were kept for an additional 3 months under normoxic conditions. All experiments were performed on 90‐day‐old rats. 3 Ventricular arrhythmias were assessed on isolated perfused hearts during 30 min occlusion of the left anterior descending coronary artery. Infarct size was measured on isolated hearts (40 min regional ischaemia and 120 min reperfusion) and on open‐chest animals (20 min regional ischaemia and 3 h reperfusion). 4 Perinatal exposure to hypoxia significantly increased cardiac tolerance to ischaemic injury in adult females, as evidenced by the lower incidence and severity of ischaemic ventricular arrhythmias, compared with the normoxic group. The effect of perinatal hypoxia on ischaemic arrhythmias in males was quite the opposite. Myocardial infarct size measured in open‐chest animals only was significantly smaller in normoxic females compared with normoxic males. Perinatal exposure to hypoxia had no effect on infarct size in either setting or sex. 5 The results of the present study support the hypothesis that perinatal hypoxia is a primary programming stimulus in the heart that may lead to sex‐dependent changes in cardiac tolerance to acute ischaemia in later adult life. This would have important implications for patients who have experienced prolonged hypoxaemia in early life.