Effect of hypokinesia and muscle training on catecholamine levels of the myocardium of rats in postnatal ontogeny

Following muscular training and hypokinesia in postnatal ontogenesis (10 weeks) rats were examined by fluorometry for the content of catecholamines at rest and after extreme exertion (swimming). Regular muscular training led to an increase in catecholamine concentration in the myocardium. Hypokinesia decelerated catecholamine accumulation by the myocardium. A single extreme swimming exercise brought about a decrease in catecholamine concentration in the myocardium. The minimal adrenaline concentration was the same, being equal to 0.04 microgram/g crude tissue whatever the age and locomotion pattern.     

Adrenal function of rats in hypokinesia

Histological and biochemical examinations of the adrenals and plasma of rats for 3 months exposed to hypokinesia have shown that low motor activity led to a decrease in blood corticosterone level in spite of adrenal cortex hypertrophy. The decreased corticosterone blood level was not indicative of adrenal exhaustion, as the adrenals produced a greater amount of corticosterone in response to additional stress stimulus (5-hour immobilisation of animals in an extended state), as compared to the control. The increased production of corticosterone in response to stress stimulus caused no structural transformations or delipoidization of the cortical substance. This indicated that the reserve potentials of the adrenals increased with the animal adaptation to hypokinesia. The major morphological indication of higher adrenal functional activity in hypokinetic animals was an enhanced destruction of lymphocytes in the thymus cortex, the target organ for corticosteroids produced by the adrenals in response to an additional stress stimulus.     

Unexpected increase in catecholamines in adrenals of rats treated with 3-deazaadenosine

Using electrochemical detection, 3-deazaadenosine, a proximal inhibitor of methylation via the inhibition of S-adenosylhomocysteine hydrolase, perturbed the metabolism of catecholamines in the adrenals of rats. In adrenals of rats treated with 3-deazaadenosine, both norepinephrine and epinephrine increased significantly by about two-fold. 3-Deazaadenosine may inhibit the release of catecholamines from the adrenals by affecting membrane functions of the adrenals.     

Influence of fasting and dopamine on the tissue catecholamines diurnal variations

To define the role of catecholamines (CA) in the metabolic adaptation to fasting we examined the effect of exogenous dopamine(DA) on heat production(HP) and CA content in the interscapular brown adipose tissue(IBAT) and adrenals of control-fed and 2-day fasted rats in the morning(M) and in the evening(E). DA stimulates HP in fed rats in the M by 45% but the thermogenic effect of this CA is markedly higher in the E. However, DA had no thermogenic effect in fasted rats. The tissue CA in fed rats fluctuates diurnally: in the IBAT noradrenaline(NA) was much higher in the E while adrenaline(A) in adrenals was lower. DA in fed rats did not change the adrenal A but reduced NA content both in the adrenals and in the IBAT all over the day. Fasting depleted A from adrenals but increased NA content both in the M and in the E. Unlike the adrenals in the IBAT fasting did not affect NA content. In the adrenal gland of fasted rats DA significantly increased the A content to the equal degree during the day, while this CA had no effect on NA content of the IBAT.     

Influence of plasma substitutes on the concentration of tissue catecholamines in rats

The concentration of catecholamines was determined in the brain, heart and adrenals in normovolaemic and hypovolaemic rats after reinfusion of the lost blood and after infusion of equivalent volumes of plasma substitutes (dextran and modified gelatins). After infusion of these preparations in normovolaemic rats noradrenaline concentration increased significantly in the myocardium. It was found also that restoration of normal blood volume by infusion of plasma substitutes prevented changes in catecholamine concentrations induced by hypovolaemia in the brain but not in the adrenals.     

Exercise training and the stress response in rainbow trout, Salmo gairdneri Richardson

Plasma levels of catecholamines, cortisol, and glucose were monitored in rainbow trout during a 6-week forced swimming exercise programme. Compared to resting non-exercised controls, resting trained fish had lower levels of epinephrine, norephinephrine, cortisol, and glucose during the last 3 weeks of training. Initially, trained fish that were swimming had higher levels of epinephrine than resting trained fish. After 2 weeks of exercise, swimming did not significantly elevate epinephrine levels in trained fish. Glucose levels were consistently greater in swimming fish than in resting fish. At the end of the training period, exercised trout had lower (15–20%) oxygen consumption rates while resting or swimming than unexercised fish.
After a 5-month forced swimming exercise programme plasma levels of catecholamines and glucose were monitored in trained and untrained cannulated rainbow trout after 2 min of mild agitation. Trained fish showed an immediate (within 1 min) increase in the levels of epinephrine, but not norepinephrine and a delayed (within 15 min) increase in the levels of plasma glucose. Epinephrine levels returned to pre-stress levels within 15 min. Untrained fish had no significant increase in the plasma levels of norepinephrine, epinephrine, or glucose.     

Plasma renin activity, aldosterone and catecholamine levels when swimming and running

The purpose of this study was to determine the response of plasma renin activity (PRA), plasma aldosterone concentration (PAC) and catecholamines to two graded exercises differing by posture. Seven male subjects (19-25 years) performed successively a running rest on a treadmill and a swimming test in a 50-m swimming pool. Each exercise was increased in severity in 5-min steps with intervals of 1 min. Oxygen consumption, heart rate and blood lactate, measured every 5 min, showed a similar progression in energy expenditure until exhaustion, but there was a shorter time to exhaustion in the last step of the running test. PRA, PAC and catecholamines were increased after both types of exercise. The PRA increase was higher after the running test (20.9 ng AngI X ml-1 X h-1) than after swimming (8.66 ng AngI X ml-1 X h-1). The PAC increase was slightly greater after running (123 pg X ml-1) than swimming (102 pg X ml-1), buth the difference was not significant. Plasma catecholamine was higher after the swimming test. These results suggest that the volume shift induced by the supine position and water pressure during swimming decreased the PRA response. The association after swimming compared to running of a decreased PRA and an enhanced catecholamine response rule out a strict dependence of renin release under the effect of plasma catecholamines and is evidence of the major role of neural pathways for renin secretion during physical exercise.     

Catecholamines in the tissues and blood of rats after administration of acetaldehyde and ethanol

Acetaldehyde alone and in combination with acute and chronic ethanol intoxication has been studied for its effect on the concentration of epinephrine and norepinephrine in different brain areas, in the heart muscle, in adrenals and blood plasma of rats. Acetaldehyde is shown to enhance the epinephrine and norepinephrine levels in the brain areas which are non-specific for neuromediation of the mentioned catecholamines. The joint administration of acetaldehyde and ethanol increased the epinephrine concentration in adrenals probably due to the effect of acetaldehyde. On the contrary, the norepinephrine concentration in the heart decreased because of the action of ethanol. The authors' data show that acetaldehyde becomes an inductor of the mechanisms of hormone-mediator dissociation, thus altering the functions of vegetative-adrenal system. The results of the investigation support the hypothesis that acetaldehyde plays a significant role among pathogenic factors of ethanol intoxication, since it changes in a special way the catecholamine concentration in the brain and in peripheral tissues.     

The physical work capacity of the body in experiments with the combined action of hypokinesia and radiation]

After combined exposures to hypokinesia and radiation, hybrid CBA x C57BL mice of the first generation showed a drop in their working capacity as estimated by the rate of swimming through a limited distance. It was found that hypokinesia was a sufficiently strong stressor, no less affecting the working capacity than ionizing radiation in LD50. There was no summation in effects of these irritants with respect to the drop in working capacity.     

Appearance of the signs of stress in mice as affected by lymphoid cells from syngeneic hypokinetic animals

Lymphoid cells of the spleen were transferred from F1(CBA X C57BL/6) mice exposed to hypokinesia for 17 hours to unoperated and partially hepatectomized syngeneic recipients. It caused (on days 2, 3 and 7) changes in the body weight, thymus, spleen, adrenals and in proliferative activity of hepatocytes in the intact and regenerating liver, with these changes being similar to those induced by stress alone.     

Effects of acute exercise and prolonged exercise training on blood pressure, vasopressin and plasma renin activity in spontaneously hypertensive rats

The purpose of this study was to investigate the effect of swimming training on systolic blood pressure (BPs), plasma and brain vasopressin (AVP), and plasma renin activity (PRA) in spontaneously hypertensive rats (SHR) during rest and after exercise. Resting and postexercise heart rate, as well as blood parameters such as packed cell volume (PCV), haemoglobin concentration (Hb), plasma sodium and potassium concentrations ([Na+], [K+]) osmolality and proteins were also studied. Hypophyseal AVP had reduced significantly after exercise in the SHR, whereas PRA had increased significantly in the Wistar-Kyoto (WKY) strain used as normotensive controls. Plasma AVP concentration increased in both strains. By the end of the experiment, training had reduced body mass and BPs by only 10% and 6%, respectively. Maximal oxygen uptake was increased 10% and plasma osmolality 2% by training. The postexercise elevation of heart rate was not significantly attenuated by training. A statistically significant reduction in postexercise plasma osmolality (10%) and [Na+] (4%) was observed. These results suggested that swimming training reduced BPs. Plasma and brain AVP played a small role in the hypertensive process of SHR in basal conditions because changes in AVP contents did not correlate with those of BPs. Moreover, there were no differences between SHR and WKY in plasma, hypophyseal and hypothalamic AVP content in these basal conditions. Finally, during moderate exercise a haemodilution probably occurred with an increase of plasma protein content. This was confirmed by the exercise-induced increase of plasma AVP and the reduction of hypophyseal AVP content, suggesting a release of this hormone, which probably contributed to the water retention and haemodilution.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tyrosine content, influx and accumulation rate, and catecholamine biosynthesis measured in vivo, in the central nervous system and in peripheral organs of the young rat. Influence of neonatal hypo- and hyperthyroidism

The influence of neonatal hypo- and hyperthyroidism on different aspects of tyrosine metabolism in the hypothalamus, striatum, brainstem, adrenal glands, heart and brown adipose tissue (BAT) were studied in 14-day old rats. The synthesis rate of catecholamines (CA) was also determined in vivo after the injection of labelled tyrosine. Hypothyroidism increases tyrosinaemia and endogenous tyrosine concentration in the hypothalamus and BAT. Hyperthyroidism decreases tyrosinaemia and endogenous tyrosine levels in the striatum, adrenals and heart. The accumulation rate of tyrosine determined 30 min after an intravenous injection of the labelled amino acid has been determined in the organs, together with the influx of the amino acid, determined within 20s. Hypothyroidism increases tyrosine accumulation rate in all the organs studied, and tyrosine clearance is decreased in the striatum and brainstem; together with an increased tyrosinaemia, this leads to a normal influx. The influx of tyrosine is increased in the hypothalamus. Hyperthyroidism decreases tyrosine accumulation rate in all the organs except the adrenals. These results indicate that the thyroid status of the young rat can influence tyrosine uptake mechanisms, without modifying an organ's tyrosine content. The fact that hypothyroidism increases tyrosine influx in the hypothalamus without modifying it in the brainstem and striatum reflects an heterogeneous reactivity to the lack of thyroid hormones in different brain structures. Neonatal hypothyroidism decreases the CA synthesis rate in the striatum, the heart and the interscapular brown adipose tissue, while synthesis was enhanced in the brainstem and the adrenals. It is likely that these variations in CA synthesis are due to thyroid hormone modulation of tyrosine hydroxylase activity, the enzyme which catalyses the rate limiting step in CA biosynthesis.     

Physical training under the influence of beta blockade in rats: effect on adrenergic responses.

Rats were trained by daily swimming or running exercises with and without daily propranolol injections. Both training methods resulted in cardiac enlargement, but only swimming exercise caused hypertrophy of the brown adipose tissue. These changes were antagonized by beta blockade. The size of the adrenals reflected the stress of the treatments, but other known stress parameters, such as the size of the thymus or sexual organs dit not. Only swimming training without beta blockade sensitized the rats to the calorigenic action of noradrenaline. The cooling rate of the rats in water, when taking into account the insulative capacity of the body, was decreased in swimming-trained as well as in propranolol-treated rats but increased in running-trained rats. The latter two changes may be due to circulatory alterations, while the delayed body cooling in swimming-trained rats probably results from increased heat production capacity. Training-induced resting bradycardia and enhanced tachycardic response to isoprenaline were observable only in the animal groups trained without beta blockade. The pressor response to noradrenaline tended to be higher in the trained groups and the propranolol-treated group than in the controls and was smaller in the animal groups trained under the influence of beta blockade. On the other hand, the hypotonic response to isoprenaline was smaller in the propranolol-treated and running-trained animals. The results emphasize the importance of the sympathetic nervous system in the adaptation of an organism to physical training.     

The effects of burst swimming on aerobic swimming in chinook salmon (Oncorhynchus tshawytscha)†

Burst swimming in fish results in a marked metabolic acidosis. Chinook salmon (Oncorhynchus tshawytscha) blood was shown to have a marked Root shift, such that burst swimming and the subsequent metabolic acidosis should impair oxygen delivery to the tissues and, therefore, aerobic swimming capacity. Burst swimming was found to have no effect on aerobic swimming capacity in Chinook salmon and it is concluded that any effects on aerobic swimming, of the induced metabolic acidosis following burst swimming, was offset by the release of catecholamines.     

State of the peripheral catecholaminergic systems during pharmacologic correction of immobilization stress using sodium oxybutyrate

Fluorescent microscopy and spectrofluorometry of biogenic amines were employed to study the peripheral catecholaminergic systems in immobilized rats which received sodium hydroxybutyrate. The content of catecholamines was measured in the adrenergic nerves of dura mater, vas deferens and chromaffin tissue of the adrenals. It was established that sodium hydroxybutyrate in a dose of 40 mg/kg intraperitoneally promoted returning to normal of the adrenergic mediator activity during alarm and resistance stages. The role of the peripheral catecholaminergic systems in the mechanism of the stress-protective effect of sodium hydroxybutyrate is discussed.     

Effect of small doses of ionizing radiation on the level of catecholamines and corticosteroids in mouse adrenals

Effects of 137Cs gamma-radiation (0.06-0.54 cGy, 0.06 cGy/day) on the levels of catecholamines and corticosteroids in mouse adrenals were investigated. There were observed increase of these parameters after mice irradiation during 1-2 days and their decrease after mice irradiation during 9 days.     

Effect of physical training by swimming on the arterial pressure, plasma and hypothalamo-post-hypophyseal vasopressin in genetically hypertensive rats of the Lyon strain

The effect of a 5-week swimming training on systolic blood pressure (PAS) and vasopressin (AVP) and Neurophysins (NpT) concentration in the blood and content in the pituitary and the hypothalamus was studied in Lyon genetically hypertensive rats [LH] and in their controls: the normotensive [LN] and low blood pressure [LL] rats belonging to the 28th generation. Nine female rats of each group were trained 5 days a week for 5 weeks, starting with 2 h a day, with a 15 min increase every day, up to 6 h a day. The PAS was measured using an indirect plethysmographic technique one time a week during the whole training session. At the end of the training, the rats were decapitated. AVP and NpT were measured in blood, pituitary and hypothalamus, by radioimmunoassay (RIA). Hematocrit as well as plasma Na+, K+, protein and osmotic content were also measured. Results show that the training did not affect any of the studied parameters: mainly, there was no decrease in PAS or plasma AVP level in the hypertensive rats compared to the normotensive ones. The only difference was a lower AVP content in the pituitary of LH rats compared to LN (p less than 0.01), which is difficult to interpret. Our results shed doubt on the efficiency of a swimming training on the evolution of hypertension in the Lyon rat model.     

Day-night differences in the response of the pineal gland to swimming stress

The effect of swimming stress on pineal N-acetyltransferase activity, hydroxyindole-O-methyltransferase (HIOMT) activity, and melatonin content was studied during the day and night in adult male rats. At night, elevated pineal activity was suppressed by light exposure before the animals swam. During the day, swimming for 2 hr did not stimulate NAT activity unless the animals were pretreated with desmethylimipramine (DMI), a norepinephrine uptake blocker. Pineal melatonin content after daytime swimming exhibited a weak rise, unless DMI was injected, in which case melatonin levels showed a highly significant increase. Swimming at night caused a greater (compared to daytime levels) increase in NAT activity in both noninjected and DMI-injected rats. Melatonin levels at night were highly significantly stimulated (compared to daytime values) even without pretreatment of the rats with DMI. The greater response of the rat pineal to swimming stress at night may relate either to an increase in the number of beta-adrenergic receptors in the pinealocyte membrane at night or to a reduced capacity of the sympathetic neurons in the pineal to take up excess circulating catecholamines. Pineal HIOMT activity was not influenced by swimming (with or without DMI) either during the day or at night.     

Effect of Escapable and Inescapable Stress on Levels of Catecholamines in Adrenals and Corticosterone in Blood Plasma in Young and Aged Rats

Effect of escapable and inescapable electrical stress (ES, IS) on the catecholaminergic system was studied in young (3 months) and aged (25 months) male Wistar rats on the day 3 after stress, using radioimmune analysis and high-pressure liquid chromatography. Catecholamine concentration in adrenals and corticosterone level in blood of control aged rats was lower than in young animals. On the third day after the electrical stimulation in cages with current-conducting floor, production of hormones of adrenal cortical and medullar layers rose significantly in aged rats, with a more pronounced increase of noradrenaline after IS, while of blood adrenaline and corticosterone, after ES. In young rats no significant changes in catecholamines were revealed, whereas the blood corticosterone level was increased after IS. Thus, in aged rats, a low basal level of catecholamines and corticosterone and a delayed stress response can be established. In old animals after ES, a long post-action was observed, which was quite comparable with the results obtained after IS in the both age groups.     

Iron distribution in different tissues in rats following exercise

Iron plays an essential role in blood oxygen transport and in muscle physiology. No conclusive data exist in the literature concerning its tissue distribution and behavior following exercise and training. The aim of the present work was to analyze the Fe content in different tissues following a single session of swimming to exhaustion and after swimming training in rats in order to more extensively describe the changes of Fe distribution provoked by exercise. Animals were divided into four groups (n=10): control group at rest, trained group at rest, control group after exercise, and trained group after exercise. First, rats swam until exhaustion and the maximal swimming time was noted. The training protocol consisted of swimming (5 d/week for 3 wk), limiting the time to 60% of the maximum obtained during the first session to exhaustion of each rat. The variables measured were erythrocytes, hemoglobin, hematocrit, mean corpuscular volume, mean corpuscular hemoglobin, mean corpuscular hemoglobin concentration, and, Fe in liver, kidney, erythrocytes, heart, muscle, bone, and serum. Variations in plasma volume were also calculated. Tissues presented two different profiles with regard to the changes of Fe concentration provoked by training: those displaying higher values of Fe after training, such as liver, heart, muscle, and serum, and those displaying lower values, such as bone, kidney, and red blood cells. These changes in the distribution of Fe in different tissues could be the result of an increase in the needs and use of Fe, shown by active tissues at exercise, and it is possible that the hormonal changes provoked by stress lead to a different behavior of Fe proteins.