Potentiation of K+-evoked catecholamine release in the cat adrenal gland treated with ouabain

Real Time Recording of Perifused Chromaffin Cells

Amperometry is an electrochemical method based on the oxidation or reduction of molecules. Many secretion products, including catecholamines, contain in their molecule chemical groups with the ability to yield (oxidize) or capture (reduce) electrons upon its exposure to an electrical field. In order to measure the secretion of catecholamines, they are oxidized at +650 mV with a carbon electrode, releasing every molecule of catecholamine that is oxidized two electrons (e^-) that are recorded as an electrical current. Amperometry is an easy-to-use and noninvasive technique for cells (unlike patch-clamp techniques for measuring membrane capacitance) and has been widely used to monitor online catecholamine release from perifused bovine chromaffin cell populations.

How many endobains are there?

Oxidative metabolism is very active in brain, where large amounts of chemical energy as ATP molecules are consumed, mostly required to maintain cellular Na+/K+ gradients through the participation of the sodium pump (Na+,K+-ATPase), whose activity is selectively and potently inhibited by the alkaloid ouabain. Na+/K+ gradients are involved in nerve impulse propagation, in neurotransmitter release and cation homeostasis in the nervous system. Likewise, enzyme activity modulation is crucial for maintaining normal blood pressure and cardiovascular contractility as well as renal sodium excretion. The present article reviews the progress in disclosing putative ouabain-like substances, examines their denomination according to different research teams, tissue or biological fluid sources, extraction and purification, assays, biological properties and chemical and biophysical features. When data is available, comparison with ouabain itself is mentioned. Likewise, their potential action in normal physiology as well as in experimental and human pathology is summarized.

The novel Na(+)/Ca(2+) exchange inhibitor KB-R7943 also blocks native and expressed neuronal nicotinic receptors

We studied the effects of the novel Na(+)/Ca(2+) exchange inhibitor KB-R7943, 2-[2-[4-(4-nitrobenzyloxy)phenyl]ethyl]isothiourea methanesulphonate, on the native nicotinic receptors present at the bovine adrenal chromaffin cells, as well as on rat brain alpha(3)beta(4) and alpha(7) nicotinic acetylcholine receptors (AChRs) expressed in Xenopus oocytes. As expected, KB-R7943 blocked the Na(+)-gradient dependent (45)Ca(2+) uptake into chromaffin cells (IC(50) of 5.5 microM); but in addition, the compound also inhibited the (45)Ca(2+) entry and the increase of cytosolic Ca(2+) concentration, [Ca(2+)](c), stimulated by 5 s pulses of ACh (IC(50) of 6.5 and 1.7 microM, respectively). In oocytes expressing alpha(3)beta(4) and alpha(7) nicotinic AChRs, voltage-clamped at -60 mV, inward currents elicited by 1 s pulses of 100 microM ACh (I(ACh)) were blocked by KB-R7943 with an IC(50) of 0.4 microM and a Hill coefficient of 0.9. Blockade of alpha(3)beta(4) currents by KB-R7943 was noncompetitive; moreover, the blocker (0.3 microM) became more active as the ACh concentration increased (34 versus 66% blockade at 30 microM and 1 mM ACh, respectively). Inhibition of alpha(3)beta(4) currents by 0.3 microM KB-R7943 was more pronounced at hyperpolarized potentials. If given within the ACh pulse (10 microM), the inhibition amounted to 33, 64 and 80% in oocytes voltage-clamped at -40, -60 and -100 mV, respectively. The onset of blockade was faster and the recovery slower at -100 mV; the reverse was true at -40 mV. In conclusion, KB-R7943 is a potent blocker of nicotinic AChRs; moreover, it displays many features of an open-channel blocker at the rat brain alpha(3)beta(4) AChR. These results should be considered when KB-R7943 is to be used to study Ca(2+) homeostasis in cells expressing nicotinic AChRs and the Na(+)/Ca(2+) exchanger.

Brain soluble fractions which modulate Na+, K+-ATPase activity likewise modify muscarinic receptor

Two brain soluble fractions, named peaks I and II, which respectively stimulate and inhibit neuronal Na+, K+-ATPase activity, have been isolated by gel filtration in Sephadex G-50. Since cholinergic transmission seems related to such enzyme activity, in this study we evaluated the effect of brain peak I, peak II, a more purified fraction II-E and commercial ouabain, on specific binding of the muscarinic antagonist [3H]quinuclidinyl benzilate to membranes from rat cerebellum, hippocampus and cerebral cortex. We found that binding was increased by peak I and decreased by peak II, II-E and ouabain, all effects proving concentration-dependent. Since the changes exerted on the muscarinic receptor followed a pattern similar to the one already described for synaptosomal membrane Na+, K+-ATPase activity, both systems seem to interact at a functional level.

Release properties and functional integration of noradrenergic-rich tissue grafted to the denervated spinal cord of the adult rat

Noradrenaline- (NA-) containing grafts of central (embryonic locus coeruleus, LC) or peripheral (juvenile adrenal medullary, AM, autologous superior cervical ganglionic, SCG) tissue were implanted unilaterally into rat lumbar spinal cord previously depleted of its NA content by 6-hydroxydopamine (6-OHDA) intraventricularly. A microdialysis probe was implanted in the spinal cord 3-4 months after transplantation, and extracellular levels of noradrenaline were monitored in freely moving animals during basal conditions and following administration of pharmacological or behavioural stimuli. Age-matched normal and lesioned animals both served as controls. Morphometric analyses were carried out on horizontal spinal sections processed for dopamine-beta-hydroxylase (DBH) immunocitochemistry, in order to assess lesion- or graft-induced changes in the density of spinal noradrenergic innervation, relative to the normal patterns. In lesioned animals, the entire spinal cord was virtually devoid of DBH-positive fibers, resulting in a dramatic 88% reduction in baseline NA, compared with that in controls, which did not change in response to the various stimuli. LC and SCG grafts reinstated approximately 80% and 50% of normal innervation density, respectively, but they differed strikingly in their release ability. Thus, LC grafts restored baseline NA levels up to 60% of those in controls, and responded with significantly increased NA release to KCl-induced depolarization, neuronal uptake blockade and handling. In contrast, very low NA levels and only poor and inconsistent responses to the various stimuli were observed in the SCG-grafted animals. In AM-grafted animals, spinal extracellular NA levels were restored up to 45% of those in controls, probably as a result of nonsynaptic, endocrine-like release, as grafted AM cells retained the chromaffine phenotype, showed no detectable fibre outgrowth and did not respond to any of the pharmacological or behavioural challenges. Thus, both a regulated, impulse-dependent, and a diffuse, paracrine-like, NA outflow may play roles in the recovery of lesion-induced sensory and/or motor impairments previously reported with these types of grafts following transplantation into the severed spinal cord.

The actions of ouabain and lithium chloride on cytosolic Ca2+ in single chromaffin cells

The effects of ouabain, Li+ and veratridine on the concentration of cytosolic free Ca2+ ([Ca2+]i) were studied in single fura-2-loaded bovine adrenal chromaffin cells. Superfusion of cells with ouabain (10 microM for 60 min) caused only a delayed mild increase of the Ca2+]i, from around 0.1 microM to 0.2-0.3 microM; this increase was Nao(+)-dependent. Replacement of all NaCl of the Krebs-Hepes solution by LiCl (144 mM) produced a gradual increase of [Ca2+]i, which remained elevated at a stable plateau of 0.4-0.5 microM for 40-50 min. When ouabain (in the presence of normal Nao+) or Li+ (in the absence of Nao+) was given in Krebs-Hepes solution containing no Ca2+, the reintroduction of 2.5 mM Ca2+ produced a fast elevation of the [Ca2+]i. In the case of ouabain-treated cells, the [Ca2+]i curve exhibited an initial phasic component which inactivated to a tonic component. omega-Conotoxin MVIIC (3 microM) and R56865 (10 microM) inhibited the phasic but not the tonic component. Veratridine (30 microM) induced large [Ca2+]i oscillations. Both ouabain or Li+ abolished such oscillations. These results are compatible with ouabain causing elevation of [Ca2+]i in bovine chromaffin cells through a dual mechanism, i.e. cell depolarisation and slowing down of the Na(+)-Ca2+ exchanger of their plasmalemma. Through its binding to the Na+ site on the Na(+)-Ca2+ exchanger, Li+ ions generate powerful Cai2+ signals that might be relevant to its known effects on neurosecretory mechanisms.

Differential stimulation of noradrenaline release by reversal of the Na+/Ca2+ exchanger and depolarization in chromaffin cells

We compared the effectiveness of Ca2+ entering by Na+/Ca2+ exchange with that of Ca2+ entering by channels produced by membrane depolarization with K+ in inducing catecholamine release from bovine adrenal chromaffin cells. The Ca2+ influx through the Na+/Ca2+ exchanger was promoted by reversing the normal inward gradient of Na+ by preincubating the cells with ouabain to increase the intracellular Na+ and then removing Na+ from the external medium. In this way we were able to increase the cytosolic free Ca2+ concentration ([Ca2+]c) by Na+/Ca2+ exchange to 325 +/- 14 nM, which was similar to the rise in [Ca2+]c observed upon depolarization with 35 mM K+ of cells not treated with ouabain. After incubating the cells with ouabain, K+ depolarization raised the [Ca2+]c to 398 +/- 31 nM, and the recovery of [Ca2+]c to resting levels was significantly slower. Reversal of the Na+ gradient caused an approximately 6-fold increase in the release of noradrenaline or adrenaline, whereas K+ depolarization induced a 12-fold increase in noradrenaline release but only a 9-fold increase in adrenaline release. The ratio of noradrenaline to adrenaline release was 1.24 +/- 0.23 upon reversal of the Na+/Ca2+ exchange, whereas it was 1.83 +/- 0.19 for K+ depolarization. Reversal of the Na+/Ca2+ exchange appeared to be as efficient as membrane depolarization in inducing adrenaline release, in that the relation of [Ca2+]c to adrenaline release was the same in both cases. In contrast, we found that for the same average [Ca2+]c, the Ca2+ influx through voltage-gated channels was much more efficient than the Ca2+ entering through the Na+/Ca2+ exchanger in inducing noradrenaline release from chromaffin cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Studies on secretion of catecholamine evoked by caffeine from the isolated perfused rat adrenal gland

The influence of caffeine on secretion of catecholamines (CA) was examined in the isolated perfused rat adrenal gland. Caffeine (0.3 mM) perfused into an adrenal vein of the gland produced a marked increase in secretion of CA. This secretory effect of CA evoked by perfusion of caffeine for one minute was considerably prolonged, lasting for more than 90 minutes. The tachyphylaxis to releasing effect of CA induced by caffeine was observed by repeated perfusion of this drug. The caffeine-evoked CA secretion was markedly inhibited by pretreatment with ouabain, trifluoperazine, TMB-8 and perfusion with calcium-free Krebs solution containing 5 mM EGTA, but was not affected by perfusion of calcium-free Krebs solution without other addition. CA secretion evoked by caffeine was not reduced significantly by pretreatment with chlorisondamine but after the first collection of perfusate for 3 min was clearly inhibited. Interestingly, the caffeine-evoked CA secretion was considerably potentiated by pretreatment with atropine or pirenzepine, but after the first collection for 3 min it was markedly decreased. These experimental results suggest that caffeine causes a marked increase in secretion of CA from the isolated perfused rat adrenal gland by an extracellular calcium-independent exocytotic mechanism. The secretory effect of caffeine may be mainly due to mobilization of calcium from an intracellular calcium pool in the rat chromaffin cells and partly due to stimulation of both muscarinic and nicotinic receptors.

The key role of sodium in the ouabain-mediated potentiation of potassium-evoked catecholamine release in cat adrenal glands

1. The effect of [Na]o on the catecholamine release evoked by K in ouabain pretreated, isolated adrenal glands of the cat, was investigated. 2. Reduction of [Na]o to 70, 50 and 25 mM, with sucrose as a substitute, did not modify the spontaneous catecholamine release but progressively increased the K (17.7 mM)-evoked secretory response. 3. Ouabain pretreatment (100 microM; 10 min) greatly increased the K (17.7 mM)-evoked catecholamine secretory response in glands perfused with normal Krebs. Such an increase was still seen in glands perfused with 70 mM Na-containing solution but disappeared when [Na]o was reduced to 25 and 10 mM. 4. Preperfusion of non-ouabain treated glands with Li-enriched Krebs, for a 40 min period, caused an increase in the K (17.7 mM)-evoked secretory response which was dependent on [Li]o and essentially similar to that induced by ouabain pretreatment. 5. Ouabain treatment (100 microM; 10 min) of glands perfused with normal Krebs evoked a long lasting catecholamine release, which reached a plateau at about 36 min and amounted to 0.68 +/- 0.25 microgram 2 min-1 (n = 9). Such a secretory response was dramatically increased, and its shape modified, when glands were preperfused with K (17.7 mM)-Krebs: a peak of 3.77 +/- 0.42 micrograms 2 min-1 (n = 7) was reached at 18 min. This response was drastically reduced in the presence of nitrendipine (1 microM). 6. In summary, our results indicate that both [Na]0 reduction or Na accumulation into the chromaffin cell by inhibition of the Na pump with ouabain, greatly enhance the secretory efficacy of small increments of [K]0, and suggest that sodium may play a role in the regulation of catecholamine release mediated by voltage-dependent Ca channels in adrenal glands.

Ouabain distinguishes between nicotinic and muscarinic receptor-mediated catecholamine secretions in perfused adrenal glands of cat

1. The effect of ouabain on catecholamine (adrenaline and noradrenaline) secretion induced by agents acting on cholinoceptors was studied in perfused cat adrenal glands. Acetylcholine (ACh) (5 x 10(-7) to 10(-3) M), pilocarpine (10(-5) to 10(-3) M) and nicotine (10(-6) to 5 x 10(-5) M) caused dose-dependent increases in catecholamine secretion. Both ACh and nicotine released more noradrenaline than adrenaline and the reverse was the case for pilocarpine. 2. Ouabain (10(-5) M) enhanced catecholamine secretion induced by ACh (10(-5) M), pilocarpine (10(-3) M) and nicotine (3 x 10(-6) M) during perfusion with Locke solution. The ratio of adrenaline to noradrenaline was not affected by ouabain. 3. In the absence of extracellular Ca2+, ACh and pilocarpine, but not nicotine, still caused a small increase in catecholamine secretions, which were enhanced by treatment with ouabain (10(-5) M) plus Ca2+ (2.2 mM) for 25 min. The effect of ouabain was much more significant on noradrenaline secretion than on adrenaline secretion. The enhanced response was blocked by atropine (10(-6) M) but not by hexamethonium (5 x 10(-4) M). 4. Nifedipine (2 x 10(-6) M) inhibited the responses to pilocarpine and nicotine. The treatment with ouabain (10(-5) M) reversed only the response to pilocarpine and resulted in a significant increase in the proportion of noradrenaline released. 5. It is suggested that ouabain enhances evoked catecholamine secretions by facilitating Ca2+ entry through nicotinic receptor-linked Ca2+ channels and by increasing the intracellular Ca2+ pool linked to muscarinic receptors.

Effects of Bay K 8644 on cat adrenal catecholamine secretory responses to A23187 or ouabain

Calcium ionophore A23187 increases the rate of spontaneous catecholamine release from cat adrenal glands perfused at 37 degrees C with oxygenated Krebs bicarbonate solution, in a time- and Ca-concentration-dependent manner. The secretory profile obtained with the ionophore was not modified in the presence of the Ca channel activator Bay K 8644. Ouabain also enhanced the rate of spontaneous catecholamine outputs in a time- and concentration-dependent manner. The threshold ouabain concentration capable of producing a clear, yet delayed secretory response was 10(-6) M. Increasing ouabain concentrations up to 10(-4) M enhanced catecholamine release and shortened the time to peak release. The dihydropyridine Ca channel activator Bay K 8644 (10(-6) M) markedly potentiated the secretory effects of all ouabain concentrations used (10(-7)-10(-4) M). However, the most impressive potentiations were seen at 10(-5)M ouabain; while at this concentration ouabain alone released 2.6 +/- 0.07 micrograms catecholamines per 30 min, in the presence of Bay K 8644 the release was 73.4 +/- 5.7 micrograms per 30 min. Conversely, at a fixed ouabain concentration (10(-5) M), the potentiation was also dependent on the Bay K 8644 concentration (10(-8)-10(-5) M). Although K deprivation inhibits Na pumping as does ouabain, Bay K 8644 did not modify the rate of catecholamine release evoked by K removal from the perfusion medium. Potassium deletion, nimodipine or high Mg all reversed the fully developed secretory response evoked by ouabain plus Bay K 8644. In glands depolarized by continuous perfusion with high K solutions, once the secretory response was inactivated, the introduction of ouabain caused an enhancement of the catecholamine secretory rate. This increase was dependent on the extracellular Na concentration and was not affected by Bay K 8644. In the presence of 6 mm Na the secretory effects of Bay K 8644 plus ouabain were abolished. 7 These results are compatible with the following conclusions: (i) Bay K 8644 potentiates only those catecholamine secretory responses that are known to be mediated through the activation of voltagesensitive Ca channels; the drug does not seem to affect secretory responses by acting on the membrane Na/Ca exchange system or at some intracellular Ca-dependent component of the secretory machinery of Ca buffering systems. (ii) It is likely that ouabain enhances the rates of adrenal catecholamine release by a dual mechanism: chromaffin cell depolarization and activation of a membrane Na/Ca exchange system.

Facilitation of transmitter action on catecholamine output by cardiac glycoside in perfused adrenal gland of guinea-pig

Effects of K+ deprivation and ouabain on catecholamine secretion evoked by splanchnic nerve stimulation (5 Hz), ACh (10(-5) M) and/or excess K+ (56 mM) were studied in isolated and perfused adrenal glands of guinea-pig. Exposure to K+-free Locke solution initially reduced and later enhanced catecholamine secretion sequentially evoked by splanchnic nerve stimulation and ACh. The enhancement attained a maximum, 185% in magnitude of the corresponding control response at 35 min for splanchnic nerve stimulation and 135% at 65 min for ACh after the start of exposure to K+-free solution. Ouabain (10(-5) M) caused a larger increase in the evoked catecholamine section than K+ deprivation did. The maximum effect was obtained from 40 to 50 min after the start of exposure to ouabain in which the magnitude of responses to splanchnic nerve stimulation, excess K+ and ACh was about 500, 400 and 300% of each control response, respectively. The effect of ouabain on the evoked catecholamine secretion increased as the concentration of extracellular Na+ was increased from 25 to 154 mM, regardless of the kind of stimuli. The ouabain-induced enhancement in the evoked responses was reversibly inhibited by removing Ca2+ from, or by adding Mg2+, Co2+ or Ni2+ to the perfusion medium. The ID50 values for Mg2+ were about 9.4 and 7.3 mM and those for Co2+ were 0.8 and 0.4 mM against ouabain on the responses to ACh and excess K+, respectively. The inhibitory effect of Mg2+ and Co2+ on the ouabain action was counteracted by increasing the concentration of Ca2+ from 2.2 to 8.8 mM in the perfusion medium. These results suggest that ouabain enhances catecholamine secretion evoked by splanchnic nerve stimulation, ACh and excess K+ by increasing the rate of Ca2+ influx through the ACh receptor linked Ca2+ channel and/or voltage-dependent Ca2+ channels on adrenal chromaffin cells of guinea-pig in a Na+-dependent manner.

Effects of the novel dihydropyridine BAY-K-8644 on adrenomedullary catecholamine release evoked by calcium reintroduction

Reintroduction of Ca ions to cat adrenal glands perfused at room temperature with Krebs solution lacking Ca and Mg, evoked a catecholamine secretory response that was directly proportional to the concentration of Ca reintroduced. This secretory response inactivated quickly, was abolished by nM concentrations of nifedipine and was potentiated dramatically by nM concentrations of BAY-K-8644. Excess Ca antagonized the inhibitory effects of nifedipine and this drug inhibited competitively the potentiating effects of BAY-K-8644. These data suggest 1st) that extracellular divalent cations deprivation activates specific Ca channels; 2nd) that the dihydropyridine BAY-K-8644 increases the release of catecholamines by Ca reintroduction by activating and/or delaying the inactivation of Ca channels; and 3rd) that the access of the dihydropyridine-type Ca agonist and antagonists to their "intra-channel" site of action requires the pre-activation of Ca channels.

Effects of hypertonic solutions on catecholamine release from cat adrenal glands

The effects of hypertonic solutions on the spontaneous and evoked catecholamine release from isolated, perfused cat adrenal glands were studied. Hypertonic solutions enhanced three times the spontaneous release of the amines, but markedly inhibited the release evoked by nicotine (5 microM for 2 min) or high K+ (17.7 mM for 2 min). Using sucrose as osmoticant, the secretory response to high K+ was decreased to 53 and 15% of controls at 344 and 416 mosM, respectively. At 512 mosM sucrose inhibited poorly the release of catecholamines evoked by nicotine, but reduced it by 90% at 1000 mosM; sodium chloride behaved similarly to sucrose. A rise in the osmolarity of only 7.5% with choline chloride produced a complete inhibition of the K+-evoked response. These effects were not seen using isotonic choline chloride; on the contrary, isotonic choline chloride enhanced the K+ response, probably by stimulating nicotinic receptors. Since atropine did not modify this effect, it seems that secretion of catecholamines evoked by choline is mediated by nicotinic receptors. While the inhibitory effects of sucrose and NaCl were completely reversed when the tonicity of the perfusion medium was restored to its normal value (320 mosM), the effects of choline seemed to be long lasting and were reversed only partially. It is worth noting that the inhibitory effects of hyperosmotic solutions developed very fast.(ABSTRACT TRUNCATED AT 250 WORDS)

Correlation between catecholamine release and sodium pump inhibition in the perfused adrenal gland of the cat

1 Ca(2+) reintroduction to retrogradely perfused and ouabain (10(-4) M)-treated cat adrenal glands caused a catecholamine secretory response which was greater the longer the time of exposure to the cardiac glycoside. Such a response was proportional to the external Na(+) concentration [Na(+)](o).2 A qualitatively similar, yet smaller response was observed when glands were perfused with Krebs solution lacking K(+) ions; thus, K(+) deprivation mimicked the secretory effects of ouabain. Catecholamine secretion evoked by Ca(2+) reintroduction in K(+)-free solution (0-K(+)) was also proportional to [Na(+)](o) and greater the longer the time of exposure of the gland to 0-K(+) solution.3 The ionophore X537A also mimicked the ouabain effects, since Ca(2+) reintroduction to glands treated with this agent (25 muM) caused a sharp secretory response. When added together with X537A, ouabain (10(-4) M) did not modify the response to the ionophore.4 N-ethylmaleimide (NEM), another Na(+), K(+)-ATPase inhibitor, did not evoke the release of catecholamines; on the contrary, NEM (10(-4) M) inhibited the catecholamine secretory response to high [K(+)](o), acetylcholine, Ca(2+) reintroduction and ouabain.5 Ouabain (10(-4) M) inhibited the uptake of (86)Rb into adreno-medullary tissue by 60%. Maximal inhibition had already occurred 2 min after adding the drug, indicating a lack of temporal correlation between ATPase inhibition and the ouabain secretory response, which took longer (about 30-40 min) to reach its peak. NEM (10(-4) M) blocked (86)Rb uptake in a similar manner.6 The results are further evidence in favour of the presence of a Na(+)-Ca(2+) exchange system in the chromaffin cell membrane, probably involved in the control of [Ca(2+)](i) and in the modulation of catecholamine secretion. This system is activated by increasing [Na(+)](i), either directly (ionophore X537A, increased [Na(+)](o)) or indirectly (Na(+) pump inhibition). However, the simple inhibition of Na(+) pumping does not always lead to a catecholamine secretory response; such is the case for NEM.