Dopamine accumulation after dopamine beta-hydroxylase inhibition in rat heart as an index of norepinephrine turnover

Dopamine concentration in rat heart is normally very low, only a few percent of the concentration of norepinephrine. After treatment of rats with a dopamine beta-hydroxylase inhibitor, 1-cyclohexyl-2-mercapto-imidazole (CHMI), there was a rapid increase in dopamine concentration even before norepinephrine concentration had decreased perceptibility. This accumulation of dopamine was readily measured by liquid chromatography with electrochemical detection. Since the percentage change in dopamine was much greater than the percentage change in norepinephrine, especially at early times, measurement of dopamine accumulation rather than norepinephrine decline was considered as a useful measure of norepinephrine turnover. Drugs that act on noradrenergic receptors and are known to alter norepinephrine turnover were found to alter the rate of dopamine accumulation. Clonidine and guanabenz decreased dopamine accumulation after CHMI, whereas piperoxan (but not prazosin) increased dopamine accumulation after CHMI. Pergolide, a dopamine agonist whose lowering of blood pressure and cardiac rate has been suggested to be due to suppression of neurogenic release or norepinephrine, also decreased dopamine accumulation after CHMI. The results suggest that measuring dopamine accumulation may have advantages over measuring norepinephrine disappearance after dopamine beta-hydroxylase inhibition as an indicator of norepinephrine turnover in heart.     

Potassium turnover and norepinephrine sensitivity in the thoracic aorta of the Dahl rat

This in vitro study evaluated the basal 42K turnover and response to norepinephrine (NE) in the thoracic aorta removed from Dahl salt-sensitive (S) and salt-resistant (R) rats. Five-week-old S and R rats were placed on either a high-salt (HS) or low-salt (LS) diet. After 5 weeks of the diet, systolic blood pressure, aortic weight/length ratio, and the cellular pool of K+ were elevated in the S-HS group only. In contrast, the steady state turnover of 42K, the NE ED50, and the response to a supramaximal dose of NE were the same in both groups of salt-sensitive and salt-resistant rats. These results suggest that, despite the presence of a greatly elevated systolic blood pressure and evidence of aortic hypertrophy, the intrinsic electrolyte metabolism of the vascular smooth muscle in the Dahl hypertensive rat is the same as that of the Dahl normotensive rat.     

Atrial natriuretic factor inhibits norepinephrine biosynthesis and turnover in the rat hypothalamus

We have previously reported that atrial natriuretic factor (ANF) increased neuronal norepinephrine (NE) uptake and reduced basal and evoked neuronal NE release. Changes in NE uptake and release are generally associated to modifications in the synthesis and/or turnover of the amine. On this basis, the aim of the present work was to study ANF effects in the rat hypothalamus on the following processes: endogenous content, utilization and turn-over of NE; tyrosine hydroxylase (TH) activity; cAMP and cGMP accumulation and phosphatidylinositol hydrolysis. Results showed that centrally applied ANF (100 ng/microl/min) increased the endogenous content of NE (45%) and diminished NE utilization. Ten nM ANF reduced the turnover of NE (53%). In addition, ANF (10 nM) inhibited basal and evoked (with 25 mM KCl) TH activity (30 and 64%, respectively). Cyclic GMP levels were increased by 10 nM ANF (100%). However, neither cAMP accumulation nor phosphatidylinositol breakdown were affected in the presence of 10 nM ANF. The results further support the role of ANF in the regulation of NE metabolism in the rat hypothalamus. ANF is likely to act as a negative putative neuromodulator inhibiting noradrenergic neurotransmission by signaling through the activation of guanylate cyclase. Thus, ANF may be involved in the regulation of several central as well as peripheral physiological processes such as cardiovascular function, electrolyte and fluid homeostasis, endocrine and neuroendocrine synthesis and secretion, behavior, thirst, appetite and anxiety that are mediated by central noradrenergic activity.     

Effects of aminoglutethimide on ovarian histology in the rat

Aminoglutethimide, a corticosteroid inhibitor, administered at a daily dose of 150 mg per kg body weight, showed a dramatic interference with ovarian histology in the rat. The drug caused thinning of the germinal epithelium and disruption of the layers of the follicular cells. It also resulted in the appearance of cytoplasmic vacuoles and distortion of follicle cell nuclei. In the corpus luteum, it caused shrinkage of the lutein cells, resulting in large spaces between the cords of cells. It also arrested immature follicles at various stages of their development. Our results indicate that aminoglutethimide, by modifying ovarian structure in the rat, interferes with the ovulation process.     

Tissue norepinephrine turnover and cardiovascular responses during intermittent dehydration in the rat.

We investigated the central and peripheral sympathetic responses to intermittent dehydration in rats. The norepinephrine (NE) turnover, a biochemical index correlated with noradrenergic neuronal activity, was measured. The modification of blood pressure was also determined by telemetry during the different cycles of dehydration. Dehydration caused a decrease of NE turnover in A2, A5 and A6 nuclei and in peripheral organs. The vasopressinergic level of dehydrated rats decreased in hypophysis and hypothalamus, and increased in plasma. A repeated gradual increase of arterial blood pressure during the first three days of dehydration, followed by a sudden drop when the rats were rehydrated on the fourth day was observed. In conclusion, our study revealed an increase in blood pressure and in central sympathetic activity during dehydration.     

Effect of short-term administration of vasopressin on arterial pressure and norepinephrine turnover in Long-Evans rats

Vasopressin (AVP) in acute experiments has been shown to influence cardiovascular reflexes, but the effect of a more prolonged administration of AVP on the sympathetic nervous system has not been investigated. Long-Evans rats were treated for 7 days with AVP (Pitressin tannate in oil, with single daily doses of 100 or 500 mU.100 g-1, s.c.) to determine whether AVP alters norepinephrine (NE) turnover in kidney, intestine, or skeletal muscle. Control rats were given equal doses of peanut oil daily. NE turnover was determined by measuring the decline in tissue levels of NE for 8 h after inhibition of tyrosine hydroxylase with alpha-methyl-p-tyrosine (300 mg.kg-1, i.p. every 4 h). Measurements of water intake, urine output, and urine osmolality showed that chronic administration of the high dose, but not the low dose, of AVP produced maintained increases in urine osmolality and decreases in water intake and urine output. Body weight, plasma osmolality, plasma electrolytes, and hematocrit were not significantly altered by AVP treatment, but mean arterial pressure was elevated significantly (control, 105 +/- 3 mmHg versus AVP, 119 +/- 4 mmHg, p less than 0.05) (1 mmHg = 133.3 Pa) in the high dose group. Plasma renin activity was decreased slightly, but significantly in rats treated with the high dose of AVP. Compared with results in control animals, there were no statistically significant changes in NE turnover after chronic administration of either the low or the high dose of AVP. The results indicate that administration of AVP for 7 days to rats in normal fluid balance does not result in a decrease in NE turnover in peripheral organs.     

Effect of lanthanum on the turnover of calcium in rat uterus.

Previous investigations suggest that lanthanum might enter uterine smooth muscle cells and work as intracellular calcium displacing agent. The present investigation had been carried out in order to confirm if lanthanum develops an intracellular effect. Experiments show that lanthanum brings about a marked increase of the intracellular calcium; the comparison of the uptake and of the wash-out curve of 45Ca shows that lanthanum induces a lowering of the rapid phase of 45Ca release from rat uterus, while the uptake of the labelled ion is not modified or is even enhanced. The present data demonstrate that the action of lanthanum in rat uterus is limited to the cell membrane, whose calcium extruding properties are inhibited.     

Regional turnover of norepinephrine and dopamine in rat brain following acute exposure to air ions

Exposure to air ions has been reported to influence serotonin (5HT), although critical reviews of these studies and previous measurements in our laboratory of the concentration, release, and utilization of brain 5HT indicate that neither the data nor the interpretations of the data are particularly convincing. Measurements of other possibly relevant neurotransmitter systems--norepinephrine (NE) and dopamine (DA)--were made in brain regions selected because of their importance in the modulation of brain functions relating to motivation, arousal, endocrine function, and motor activity, all responses that have been reported to be influenced by air ion exposure. Results indicate that exposure of male Holtzman rats to high concentrations (5.0 X 10(5)/cm3) of positive or negative air ions or to DC electric fields (3.0 kV/m) for periods up to 66 h failed to affect the concentration of NE or DA significantly in any of the brain regions.     

Effect of streptozotocin-induced diabetes on the turnover of hexokinase II in the rat

Skeletal muscle hexokinase II activity and turnover rates were measured in the normal and streptozotocin-induced diabetic rat. Enzyme activity decreases in the diabetic animal relative to the normal rat; however, the specific activity of hexokinase II is essentially the same for the two conditions. No alteration is observed in the relative rate of hexokinase II synthesis in the normal or diabetic rats, but there is a 3-fold increase in the rate of hexokinase II degradation in the latter group of animals. These results suggest that the primary cause of the well-established decrease in hexokinase II activity in skeletal muscle of the diabetic is an increase in the rate of enzyme degradation.     

Mitochondrial turnover in the heart

Mitochondrial quality control is increasingly recognized as an essential element in maintaining optimally functioning tissues. Mitochondrial quality control depends upon a balance between biogenesis and autophagic destruction. Mitochondrial dynamics (fusion and fission) allows for the redistribution of mitochondrial components. We speculate that this permits sorting of highly functional components into one end of a mitochondrion, while damaged components are segregated at the other end, to be jettisoned by asymmetric fission followed by selective mitophagy. Ischemic preconditioning requires autophagy/mitophagy, resulting in selective elimination of damaged mitochondria, leaving behind a population of robust mitochondria with a higher threshold for opening of the mitochondrial permeability transition pore. In this review we will consider the factors that regulate mitochondrial biogenesis and destruction, the machinery involved in both processes, and the biomedical consequences associated with altered mitochondrial turnover. This article is part of a Special Issue entitled: Mitochondria and Cardioprotection.

Research Highlights

?Mitochondrial quality control is accomplished by balanced destruction and production. ?Fission and fusion are essential for mitochondrial quality control. ?Mitophagy is mediated by Bnip3, Nix, Parkin, PINK1, and p62/SQSTM1. ?Impaired mitochondrial dynamics results in human disease. ?Mitophagy enables cardioprotection and metabolic reprogramming.     

Feed efficiency and norepinephrine turnover in iron deficiency

Norepinephrine turnover and energetic efficiency studies were conducted in three groups of male Sprague-Dawley rats placed on low iron diets for 5 weeks on weaning. Iron-deficient rats had significant anemia (hematocrit less than 20%) and growth retardation relative to pair-fed and ad libitum fed controls who received the same diet plus weekly iron dextran injections. Energetic efficiency over a 7-day period was nearly 30% less in anemic animals. This was associated with significantly higher rates of norepinephrine turnover in brown adipose tissue (110%) and heart (330%) with significant hypertrophy in both tissues. There was no difference in body composition in ad libitum groups. Plasma triiodothyronine and thyroxine were reduced by 37% in iron deficients compared to controls. Thus 39% increase in caloric requirements in iron deficiency is associated with increased sympathetic and perhaps thermogenic activity in brown adipocytes.