Effects of adaptation to exposure to short-term stress on indices of resistance of energy metabolism and contractile function of the myocardium to acute hypoxic hypoxia and reoxygenation

Effect of preliminary adaptation to immobilization stress with progressive duration from 15 min. to 1 h (every second day, 8 sessions) on the resistance of indices of myocardial energy metabolism and contractile function to acute hypoxic hypoxia and subsequent reoxygenation was studied. It was shown, that adaptation to short-term stress exposure by some way provided the retention of activities of important enzymes like creatine-phosphokinase and phosphorylase under the harmful action of acute hypoxia and subsequent reoxygenation. At the same time, the ATP restoration and the CP super-restoration were observed during reoxygenation. This effect, in its turn, was accompanied by a more pronounced super-restoration of the heart contractile function than in control.     

Nitric oxide storage in rats of various genetic strains and its role in the antistressor effect of adaptation to hypoxia

Adaptation to hypobaric hypoxia induced a gradual increase in the NO production along with a progressive NO storage in vascular wall. Unadapted August rats were more resistant against stress-induced stomach ulceration than the Wistar rats. Following a 6-day adaptation rats of both strains revealed a protective antiulcerogenic effect. A long-term adaptation potentiated the stress damage of the stomach rather than protected against it. A higher basal NO production seems to provide a more efficient antistress defence in the August rats. An intense NO storage may create a relative NO shortage and thus predispose to stress-induced vasoconstriction and ulceration.     

Reaction of rats to the effect of hyperbaric oxygenation after preliminary adaptation to hypoxia

Preliminary adaptation of rats to hypoxia in the regimen exceeding the resistance to many stress agents not only produced no protective effect in response to the action of increased oxygen pressure (IOP) up to 6 kg/cm2, but, on the contrary, decreased the organism resistance. Thus, the time of occurrence of convulsions in the adapted rats was shortened, particularly when IOP acted 24 or 48 hours after the termination of training to hypoxia; this effect was somewhat weaker in experiments conducted in 3 to 4 days. Reactions became completely normal one month after the termination of training to hypoxia. Possible causes of the phenomena detected are discussed.     

Increase of alpha 1-adrenoreactivity of the rat heart in adaptation to periodic hypoxia]

There is a possibility that the cardioprotective effect of adaptation to intermittent hypoxia is due to changes in receptors apparatus of the heart. In this connection the effect of preliminary adaptation to intermittent hypoxia (4 hours per day at the altitude of 4000 m during 40 days) on the state of beta-receptors-adenylate-cyclase system and same other receptors of the heart were studied. It was shown that at the end of the course of adaptation the number of beta-adrenoceptors in the heart was increased with simultaneous decrease in basal adenylate-cyclase activity, accompanied by the diminution of its response to beta-agonist. The number of beta-adrenoceptors was increased by 48% and their affinity to ligand was increased by almost 2 times. The revealed decrease in the reactivity of beta-receptor-adenylate-cyclase system and increase of alpha 1-adrenoreactivity can play a certain role in the mechanism of cardioprotective effect of adaptation to hypoxia.     

Production of reactive oxygen species and antioxidant enzymes of pea and soybean plants under hypoxia and high CO<Subscript>2</Subscript> concentration in medium

Generation of reactive oxygen species (ROS) and activities of antioxidant enzymes (catalase, peroxidase, ascorbate peroxidase) in pea (Pisum sativum L.) and soybean (Glycine max L.) under hypoxia (3–24 h) and high CO₂ concentration in medium were studied. In sensitive to hypoxia pea seedlings, hypoxia enhanced markedly production of superoxide anion-radical, hydroperoxides, and especially hydrogen peroxide. In more tolerant soybean plants, these changes were less pronounced. During first hours of hypoxia, activity of lipoxygenase in plant cells increased. This allows a suggestion that this enzyme is involved in the processes of hydroperoxide accumulation in plant tissues under oxygen deficit. In pea and soybean plants, a correlation between tolerance to hypoxia, the rate of ROS generation, and antioxidant enzyme activities was established. During the first hours of hypoxia, the catalase activity in soybean plants increased stronger than in sensitive to hypoxia pea plants. At longer exposure to hypoxia (24 h), peroxidases started to play the higher role in cell defense against hypoxia, but only in soybean plants. The medium with the higher CO₂ content induced higher changes in the processes of ROS accumulation and activities of lipoxygenase and antioxidant enzymes. This permits us to refer CO₂, accumulated as a product of respiration in the cells, to low-molecular signal molecules switching on plant adaptation to hypoxic stress.     

Effects of adaptation to intermittent high altitude hypoxia on ischemic ventricular arrhythmias in rats

We compared the effects of adaptation to intermittent high altitude (IHA) hypoxia of various degree and duration on ischemia-induced ventricular arrhythmias in rats. The animals were exposed to either relatively moderate hypoxia of 5000 m (4 or 8 h/day, 2-3 or 5-6 weeks) or severe hypoxia of 7000 m (8 h/day, 5-6 weeks). Ventricular arrhythmias induced by coronary artery occlusion were assessed in isolated buffer-perfused hearts or open-chest animals. In the isolated hearts, both antiarrhythmic and proarrhythmic effects were demonstrated depending on the degree and duration of hypoxic exposure. Whereas the adaptation to 5000 m for 4 h/day decreased the total number of premature ventricular complexes (PVCs), extending the daily exposure to 8 h and/or increasing the altitude to 7000 m led to opposite effects. On the contrary, the open-chest rats adapted to IHA hypoxia exhibited an increased tolerance to arrhythmias that was even more pronounced at the higher altitude. The distribution of PVCs over the ischemic period was not altered by any protocol of adaptation. It may be concluded that adaptation to IHA hypoxia is associated with enhanced tolerance of the rat heart to ischemic arrhythmias unless its severity exceeds a certain upper limit. The opposite effects of moderate and severe hypoxia on the isolated hearts cannot be explained by differences in the occluded zone size, heart rate or degree of myocardial fibrosis. The proarrhythmic effect of severe hypoxia may be related to a moderate left ventricular hypertrophy (27 %), which was present in rats adapted to 7000 m but not in those adapted to 5000 m. This adverse effect can be overcome by an unknown protective mechanism(s) that is absent in the isolated hearts.     

Effects of adaptation to stress exposure and periodic hypoxia on bioelectric activity of cardiomyocytes of isolated heart in ischemia and reperfusion]

Action potential (AP) of cardiomyocytes was recorded in experiments on isolated perfused according to Langendorf rat hearts. The effect was estimated of preliminary adaptation to intermittent hypobaric hypoxia or to repeated short-term stress exposure on the resting potential (RP) and the amplitude and duration of action potential (APD) in global ischemia and reperfusion. It was shown that adaptation to hypoxia is more effective in prevention of ischemic fall of RP, AP and APD. In reperfusion, the parameters enumerated restored more quickly and efficiently in hearts from adapted to stress animals.     

Significance of ATP-sensitive K(+)-channel in the mechanism of antiarrhythmic and cardioprotective effect of adaptation to intermittent hypobaric hypoxia

Adult male Wistar rats were exposed to intermittent hypobaric hypoxia (5000 m, 6 h/day, 6 weeks). It has been found that such mode of adaptation increased cardiac tolerance to arrhythmogenic action of a 45-min coronary artery occlusion but did not change an infarct size/area at risk (IS/AAR) ratio. In a separate series, rats were exposed to stronger intermittent hypobaric hypoxia (7000 m, 8 h/day, 6 weeks) and subjected to 20-min coronary artery occlusion and 3-h reperfusion on the day after the last hypoxic exposure. It has been established that in this case adaptation decreased the IS/AAR ratio, increased cardiac tolerance to arrhythmogenic action of reperfusion but had no effect on the incidence of ventricular arrhythmias occurred during ischemic period. We found that cardioprotective and antiarrhythmic effect of adaptation to the "altitudes" of 7000 m and antiarrhythmic effect of adaptation to the "altitude" of 5000 m is mediated via K(ATP)-channel activation.     

Comparative assessment of the effect of adaptation to stress exposure and high altitude hypoxia on heart resistance to reperfusion injury after total ischemia]

Experiments on isolated Wistar rat hearts perfused according to Langendorff showed that adaptation to stress exposure limited the depression of contraction amplitude and contracture and possessed an antiarrhythmic effect in reperfusion. Furthermore, adaptation to stress exposure efficiently limited reperfusion damage to sarcolemma. It was shown that adaptation to hypoxia did not result in any increase in the heart resistance to reperfusion damage following total ischemia. Possible mechanisms of differences in the protective effects of adaptation to stress exposure and hypoxia are discussed.     

Effect of hypoxia exposure on the recovery of skeletal muscle phenotype during regeneration

Hypoxia impairs the muscle fibre-type shift from fast-to-slow during post-natal development; however, this adaptation could be a consequence of the reduced voluntary physical activity associated with hypoxia exposure rather than the result of hypoxia per se. Moreover, muscle oxidative capacity could be reduced in hypoxia, particularly when hypoxia is combined with additional stress. Here, we used a model of muscle regeneration to mimic the fast-to-slow fibre-type conversion observed during post-natal development. We hypothesised that hypoxia would impair the recovery of the myosin heavy chain (MHC) profile and oxidative capacity during muscle regeneration. To test this hypothesis, the soleus muscle of female rats was injured by notexin and allowed to recover for 3, 7, 14 and 28 days under normoxia or hypobaric hypoxia (5,500 m altitude) conditions. Ambient hypoxia did not impair the recovery of the slow MHC profile during muscle regeneration. However, hypoxia moderately decreased the oxidative capacity (assessed from the activity of citrate synthase) of intact muscle and delayed its recovery in regenerated muscle. Hypoxia transiently increased in both regenerated and intact muscles the content of phosphorylated AMPK and Pgc-1α mRNA, two regulators involved in mitochondrial biogenesis, while it transiently increased in intact muscle the mRNA level of the mitophagic factor BNIP3. In conclusion, hypoxia does not act to impair the fast-to-slow MHC isoform transition during regeneration. Hypoxia alters the oxidative capacity of intact muscle and delays its recovery in regenerated muscle; however, this adaptation to hypoxia was independent of the studied regulators of mitochondrial turn-over.     

Effect of prostaglandin E2 on the development of myocardial damage in rats with various resistance to hypoxia

Experiments conducted on male rats with congenital high and low resistance to hypoxia (HH and LH, respectively) have revealed, that injection of prostaglandin E2 (PHE2) 15 min before the injection of adrenalin essentially decreases the activity of lipid peroxidation in myocardium as compared with animals which have been injected to only adrenalin. This modulative effect (PHE2) on the action of adrenalin was more pronounced in LH-rats. Consequently, the activity of the prostaglandin stress-limiting system determines to a great extent the organism resistance to hypoxia.     

Rab6A GTPase contributes to phenotypic modulation in pulmonary artery smooth muscle cells under hypoxia

Previous studies have demonstrated that hypoxia can induce phenotypic modulation of pulmonary smooth muscle cells; however, the mechanisms remain unclear. The present study aimed to investigate the effect of the GTPase Rab6A-mediated phenotypic modulation and other activities of rat pulmonary artery smooth muscle cells (RPASMCs). We revealed that Rab6A was induced by hypoxia (1% O₂) and was involved in a hypoxia-induced phenotypic switch and endoplasmic reticulum stress (ERS) in RPASMCs. After 48 hours of hypoxia, the expression of the phenotype marker protein smooth muscle actin was downregulated and vimentin (VIM) expression was upregulated. Rab6A was upregulated after 48 hours of hypoxia, and the level of glucose-regulated protein, 78 kDa (GRP78) after 12 hours of hypoxic stimulation was also increased. After transfection with a Rab6A short interfering RNA under hypoxic conditions, the expression levels of GRP78 and VIM in RPASMCs were downregulated. Overall, hypoxia-induced RPASMCs to undergo ERS followed by phenotypic transformation. Rab6A is involved in this hypoxia-induced phenotypic modulation and ERS in RPASMCs.     

The Role of Preventing Nitric Oxide Deficiency in the Antihypertensive Effect of Adaptation to Hypoxia

Shortage of endothelial nitric oxide (NO) manifested as decreased daily urinary excretion of nitrate and nitrite as well as attenuated endothelium-dependent relaxation of conduit and resistance vessels progresses with age-related increase of blood pressure (BP) in stroke-prone spontaneously hypertensive rats (SHRSP). Simultaneous NO-dependent suppression of vascular contractions is, apparently, due to the inducible NO synthase activity in vascular smooth muscle specific for spontaneously hypertensive rat. The adaptation of rats to hypobaric hypoxia initiated at early hypertensive stage (at the age of 5–6 weeks) decelerates hypertension progress. The antihypertensive effect of the adaptation was accompanied by stimulation of endothelial NO synthesis and prevention of impaired NO-dependent response in isolated blood vessels. Nitric oxide stores were formed in the vascular wall of SHRSP and WKY rats at the same time. The obtained data indicate that the correction of endothelial NO deficiency plays a significant role in the antihypertensive effect of adaptation to hypoxia.     

Body adaptation to stress exposure enhances cardiac resistance to adrenotoxic damage

Models of adrenergic arrhythmias were produced on isolated rat heart under the adrenalin concentration in the perfusion solution of 5.10(-5) M. The rhythm disturbances were accompanied by a pronounced depression of contractile function. It was shown that preliminary adaptation of animals to short-term stress exposures reduced the duration of arrhythmias more than sixfold the contractile function, being maintained at a higher level than in control. The adaptation cardioprotective effect was compared with the effects of adaptation and propranolol appeared similar.     

Mitochondria are More Resistant to Hypoxic Depolarization in the Newborn than in the Adult Brain

Hypoxic-ischemic brain injury subsequent to asphyxia represents a major cause of morbidity and death in the newborn. The newborn brain has been considered more resistant to hypoxia than the adult brain because of lower energy demand. The mechanisms underlying hypoxic brain injury, in particular the age-related vulnerability, are still only partially understood. The mitochondrial function is pivotal for the function and survival of neurons. Acutely isolated CA1 neurons from neonatal (3-6 days) and adult rats (5-6 weeks) were loaded with Rh 123, and the effect of hypoxia on the inner mitochondrial membrane potential (Delta psi(m)) was compared. During prolonged hypoxia (15 min), Delta psi(m) was lost in a majority of the neonatal neurons (83%) and in all the adult neurons. During hypoxia (5 min) followed by reoxygenation the mitochondria in 23% of the neonatal neurons were completely depolarized, whereas 85% of the adult neurons demonstrated a complete loss of Delta psi(m). In conclusion hippocampal CA1 mitochondria in the newborn rat are more resistant to hypoxic depolarization than in the adult rat.     

Catecholamines,nitrogen oxide,and resistivity to stressor lesions: effect of adaptation to hypoxia

Pronouncement of stress-induced disturbance of searching behaviour (using "open field" test) and stomach ulceration were compared for the first time with activity of the catecholamine system in hypothalamus and striatum and also with activity of the stress-limiting system of nitric oxide (NO) in the rats of two strains August and Wistar, which differ in their resistance against stress-induced cardiovascular disorders. The effect of prior adaptation to hypobaric hypoxia on these disorders was also studied. August rats appeared to be more resistant than Wistar rats against stress-induced disturbance of the searching behaviour and stomach ulceration. Results of measuring the content of catecholamines in brain structures and the content of NO stable metabolites nitrate/nitrite in plasma suggested that these differences could be due to the stress activation of the nigro-striatal dopaminergic system in August rats, which was not observed in Wistar rats, and also to the higher production of NO in August than in Wistar rats. Adaptation to hypoxia considerably restricted these stress disorders in rats of both strains. Importantly, the protective effects were associated with activation of the nigro-striatal dopaminergic system in all the animals. In the result, adapted Wistar rats, as distinct from non-adapted Wistar rats, displayed a stress activation of this system. The protective effects of adaptation were also accompanied by an increased NO synthesis. Taken together, the data suggest an important role of the responsiveness of the brain dopaminergic system and NO system in the mechanism of resistance against stress-induced disturbances.     

Characteristics of ultrastructure of the myocardium of rats with different resistance to oxygen deficiency after acute and periodic effects of hypoxia]

In experiments on rats with different resistance to oxygen deficiency (high-resistant--HR, and low-resistant LR animals) the myocardium ultrastructure of nonadapted and adapted rats was studied. It was shown that there were more glycogen granules and lipid drops initially in cardiomyocytes of nonadapted HR animals in comparison with LR ones. After a long-term adaptation to hypoxia the hypertrophia and hyperplasia of mitochondria, the nucleus and endoplasmatic reticulum hypertrophy were observed. Moreover, the increase of glycogen and lipids content was more pronounced in the myocardium of LR rats. Besides, the activation of protein-synthesizing processes was observed not only as a result of long-term adaptation, but also after single acute hypoxic effect. The results of submicroscopic cardiomyocyte studies of HR and LR rats are in good correlation with the peculiarities of energetic metabolism.     

Effect of adaptation to hypoxia on the antioxidant enzyme activity in the liver in animals that have undergone stress

It was shown in experiments on rats that emotional-painful stress resulted in a rapid increase in malonic dialdehyde (MDA) and in a decrease in the activity of superoxide dismutase (SOD) in liver. Adaptation to moderate intermittent hypoxia in altitude chamber did not affect MDA and increased hepatic SOD by 65%. Stress exposure caused no change in SOD and MDA, but abruptly reduced the fall of SOD in adapted animals. These data are in accordance with the well-known idea that adaptation to hypoxia prevents the activation of lipid peroxidation and the hepatic damage in stress.     

Adaptation of the body to stress effects increases resistance of nuclear DNA of cardiac cells due to accumulation of heat shock proteins in the nucleus]

It was shown that adaptation to stress exposure increased the resistance of nuclear DNA in myocardial cells to the damaging action of exogenous one-chain DNA (50 micrograms/ml). This protective effect was accompanied by a pronounced accumulation of heat shock proteins (hsp) 70 in nucleoplasm of myocardial cells from adapted animals. Possible mechanism of the DNA protective effect of adaptation and the role of hsp 70 are under discussion.