The action of ouabain in promoting the release of catecholamines

The role of Ca2+ in the regulation of embryogenesis in early amphibian and echinoderm embryos

It is difficult to measure intracellular calcium concentrations in dividing embryos and, furthermore, these interact with pHi and with cyclic nucleotides. Nevertheless, the evidence currently suggests that changing [Ca2+]i levels probably do not have a major role in controlling normal cell-to-cell communication and so do not integrate cell division during programmed cleavage in amphibian embryos. However, treatments that are known or expected to raise artificially cytoplasmic calcium to relatively high levels cause abnormal embryogenesis, probably via the uncoupling of intercellular communication of the blastomeres, and also cortical contractions in early echinoderm and amphibian embryos.

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.

The spontaneous and evoked release of spermine from rat brain in vitro

1 The efflux of previously accumulated [3H]-spermine from brain slices was measured using a continuous perfusion system. The spontaneous efflux was biphasic, consisting of an initial rapid efflux followed by a much slower release. 2 The slices were depolarized by the addition to the medium of high potassium concentrations, ouabain or veratrine. 3 At concentrations greater than 30 mM, potassium evoked a striking increase in the release of [3H]-spermine. Following uptake in the presence of 5.7 x 10(-9)M [3H]-spermine, K+-evoked release was dependent on the presence of calcium ions. Release of spermine after uptake at 5.6 x 10(-8)M or 5.0 x 10(-7)M was not calcium-dependent. 4 The calcium-dependent, K+-stimulated release of spermine was inhibited in the presence of diphenylhydantoin (5 x 10(-5)M) or ruthenium red (10(-5)M). 5 Following uptake of 5.7 x 10(-9)M [3H]-spermine in a sodium-free medium, the calcium-dependent, K+-stimulated release was significantly inhibited. 5 Ouabain (10(-4)M) caused a large but calcium-independent increase in the efflux of [3H]-spermine. 7 Veratrine-induced release was less substantial but was increased in a calcium-free medium. Release evoked by veratrine was abolished in the absence of sodium. 8 These results are discussed with respect to a possible 'neurotransmitter' or 'neuromodulator' role for spermine.

Correlation between catecholamine secretion from bovine isolated chromaffin cells and [3H]-ouabain binding to plasma membranes

1 Secretion of catecholamines (CA) evoked by ouabain, chlormadinone acetate (CMA), phenoxybenzamine (Pbz) and vanadate, four agents known to inhibit Na(+), K(+)-dependent Mg(2+)-activated adenosine triphosphatase (ATPase) activity has been studied in suspensions of bovine isolated adrenal medullary cells.2 Acetylcholine (ACh) evoked a 5 fold increase of the basal CA secretion from isolated cells suspended in oxygenated Krebs-bicarbonate solution kept at 27 degrees C. Secretion was antagonized by Ca(2+)-deprivation or hexamethonium, indicating good functional viability of the cells.3 Ouabain (10(-7) to 10(-4) M) evoked a progressive, dose-dependent release of CA from cell suspensions. Study of the time course of the secretory response for 2 h allowed the separation of two components in the secretory response at all doses studied: a slow initial component (0.011 pg/min CA) and a second faster component (0.032 pg/min CA).4 CMA evoked a clear-cut CA secretory response. The ED(50) for CMA was 10(-4) M, as compared to 3 x 10(-6) M for ouabain. Pbz and vanadate did not induce CA release.5 [(3)H]-ouabain was taken up and bound to intact isolated cells by a non-saturable binding process. However, in semi-purified plasma membranes from bovine adrenal medulla a saturable specific [(3)H]-ouabain binding process was observed with a K(D) of 8.1 nM. Binding to the membranes was ATP-dependent and antagonized by K(+).6 [(3)H]-ouabain specific binding to membranes was antagonized by ouabain and CMA, but not by Pbz or vanadate; the ID(50) for ouabain and CMA were 10(-6) and 10(-5) M respectively.7 Ouabain partially inhibited, in a dose-dependent manner, Na(+), K(+)-Mg(2+) ATPase activity of the semi-purified plasma membranes.8 The results demonstrate a good correlation between the ability of different drugs, known to inhibit ATPase activity, to displace [(3)H]-ouabain binding to adreno-medullary plasma membranes and their capacity to evoke a CA secretory response from isolated chromaffin cells. The data also suggest that the CA secretory effects of ouabain may not be due simply to inhibition of the Na(+) pump and the subsequent ionic redistribution across the plasma membrane; a second mechanism may also be involved.

Characteristics of the release of adenosine from slices of rat cerebral cortex

1. The characteristics of the release of adenosine have been examined from slices of rat cerebral cortex after incubation with [3H]adenine or [3H]adenosine. 2. Increasing the potassium concentration of the extracellular medium to 36 or 54 mM did not evoke any release, but release was observed in the first post-potassium sample. This occurred whether potassium was present for 2 or 10 min. 3. Calcium-free solutions or verapamil prevented the post-potassium release of tritium. Tetraethylammonium bromide and 4-aminopyridine had no effect. 4. Ouabain (100 microM) induced the release of tritium, and did not prevent an additional increment of release after potassium stimulation. Ouabain induced release did not occur in calcium-free or sodium-free media, but was increased in low calcium (0.1 mM) medium. 5. It is concluded that the characteristics of adenosine release are unlike those of conventional neurotransmitters. It is suggested that the release is associated with the influx of sodium and calcium ions through sodium channels.

On the release of catecholamines and dopamine-beta-hydroxylase evoked by ouabain in the perfused cat adrenal gland

1 Secretion of catecholamines (CA) and dopamine-beta-hydroxylase (DBH) activity from the retrogradely perfused cat adrenal gland was studied following ouabain infusion. Perfusion with ouabain (10(-4) M) for 10 min caused a gradual release of CA in the effluent which reached its peak 30 min after the ouabain pulse, and was maintained constant for at least 1 h. The effect of ouabain seemed to be irreversible. 2 Mecamylamine, while blocking the CA secretory effects of acetylcholine (ACh) perfusion, did not affect the secretion of CA evoked by ouabain. In denervated adrenal glands, ouabain-induced CA secretion was similar to that in the contralateral, innervated gland. However, physostigmine perfusion potentiated the CA secretory effects of ouabain. 3 The release of CA evoked by ouabain was accompanied by a proportional release of DBH activity. The time course of appearance of DBH activity followed the pattern of CA release. 4 The CA and DBH outputs in response to a pulse of ouabain were suppressed in the absence of calcium. Calcium reintroduction to a calcium-free perfused, ouabain-treated gland not only restored but greatly potentiated the release of CA and DBH. The amplitude of the secretory response to calcium reintroduction in ouabain-treated glands was proportional to the extracellular calcium concentration, and was antagonized by an external sodium-deficient medium. 5 These data demonstrate that ouabain releases CA from the perfused cat adrenal gland by a calcium-dependent exocytotic mechanism. The secretory effect of ouabain is not secondary to the release of ACh from cholinergic nerve terminals present in the adrenal gland, but due to a direct action on the chromaffin cell itself. In addition, the results suggest that this action is exerted through redistribution of monovalent cations secondary to the inhibition by the glycoside of the sodium pump. Such monovalent cation redistribution may cause a rise of intracellular ionized calcium levels through the activation of an internal sodium-dependent calcium influx system probably located in the chromaffin cell membrane.

A note on the mechanism of action of UV-irradiation of amphibian embryos

The actions on amphibian embryos of UV-irradiation, exposure to Li+ or exposure to ouabain show interesting parallels with their effects on spontaneous release at the presynaptic terminals of the neuromuscular junction. It is suggested that these treatments serve to raise intracellular Ca2+ ([Ca2+]i) in these examples, and that UV-promoted abnormalities in embryogenesis are a consequence of changes in [Ca2+]i at critical stages in development.

The action of verapamil on the rate of spontaneous release of transmitter at the frog neuromuscular junction

Verapamil is known to reduce Ca2+ entry in a variety of cells. At 10(-5) M it produces a small reduction in MEPP frequency at the frog neuromuscular junction, whereas the rate of spontaneous release rises following treatment at a concentration of 10(-4) M. This latter effect is augmented by raising [Ca2+]0 to 9 mM or, more especially, by raising the temperature from 17 to 23 degrees C. It is argued that both these opposing effects are related to the action of verapamil in modifying [Ca2+]i at the presynaptic terminals and it is suggested that the drug can affect both inward Ca2+ flux (so reducing the steady-state position of [Ca2+]i) and also, at higher concentration, either inhibit the membrane Ca2+ pump or cause the release of Ca2+ from intracellular Ca2+ stores (so raising [Ca2+]i).