The antilipolytic effect of endogenous and exogenous adenosine in canine adipose tissue in situ

The effects of adenosine, 2-Cl-adenosine, two adenosine uptake inhibitors (dipyridamole and dilazep) and the adenosine deaminase (ADA) inhibitor erythro-9-(2-hydroxy-3-nonyl) adenine (EHNA) were studied on basal and stimulated lipolysis in subcutaneous adipose tissue. The basal lipolysis was unaffected by all agents. Lipolysis induced by nerve stimulation (4 Hz, 5 min) was dose-dependently antagonized (up to 100%) by close i.a. infusions of adenosine (1–40 μM in blood); if the nerve induced vasoconstriction was prevented by α-adrenoceptor-blockade. 2-Cl-adenosine was a more potent antilipolytic agent than adenosine. EHNA (3–10 μM in blood) did not inhibit stimulated lipolysis in vivo possibly because of the low ADA activity in fat cells. Dipyridamole (0.5-1.5 μM in blood) in combination with EHNA increased the venous plasma concentration of adenosine from 0.3±0.05 to 0.7±0.1 μM and enhanced the tissue concentration close to 3-fold. Lipolysis induced by nerve stimulation (4 Hz) was reduced by about 40% by dipyridamole + EHNA and that induced by close i.a. noradrenaline injection (20 nmol) by approximately 60%. It is concluded that adenosine is an antagonist of stimulated lipolysis in subcutaneous adipose tissue in situ in concentrations that are reached during prolonged sympathetic nerve stimulation.     

Antilipolytic effect of adenosine in isolated perifused fat cells

Adenosine markedly inhibits cyclic AMP accumulation in isolated fat cells, whereas inhibitory effects of adenosine on lipolysis have been difficult to demonstrate. The present study has been performed on isolated “perifused” fat cells where continuous monitoring of the lipolytic rate is possible and where modulating substances, such as adenosine, are not allowed to accumulate. Adenosine deaminase was ineffective as a lipolytic agent in perifused fat cells, suggesting no important background activity of adenosine in this system. Micromolar concentrations of adenosine inhibited lipolysis induced by noradrenaline (0.3-1 μM) and theophylline (1 mM). Theophylline was an effective lipolytic agent also in perifused fat cells suggesting that antagonism of adenosine is not the major mode of action of this drug on fat cells.     

Cyclic AMP-dependent and independent inhibition of lipolysis by adenosine and decreased pH.

NA-stimulated lipolysis and cAMP formation in isolated rat fat cells is inhibited by acidosis. In the present report we have examined the quantitative relationship between lipolysis and cAMP formation at normal and reduced pH and the possible involvement of adenosine, an endogenous inhibitor of cAMP formation. Adenosine antagonized cAMP accumulation and to a considerably lower degree lipolysis, effects potentiated by acidosis. Theophylline, an antagonist of adenosine effects, stimulated lipolysis and cAMP-accumulation, and potentiated responses to NA. Adenosine deaminase (ADA) had theophylline-like effects. Acidosis inhibited lipolysis and cAMP accumulation induced by ADA and theophylline to a larger extent than those induced by NA. It is suggested that adenosine modulates fat cell cAMP production and may contribute to the antilipolytic effect of acidosis. There was a curvilinear relationship between cAMP elevation and glycerol production in fat cell suspensions, which was different at pH 7.4 and at pH 6.6. The amount of cAMP needed for half-maximal activation of lipolysis increased from 1.3 (pH 7.4) to 3.1 pMol X 10(-5) cells (pH 6.6). The maximal glycerol production was reduced from 1 300 to 900 nMol X 10(-5) cells. The antilipolytic effect of acidosis is apparently due partly to an inhibition of cAMP formation and partly to inhibition of subsequent step(s) in the activation sequence.     

Dual effects of adenosine and adenosine analogues on motor activity of the human fallopian tube

Effects of adenosine and adenosine analogues on spontaneous contractility of the human fallopian tube during different phases of the menstrual cycle were studied. In isthmic preparations, a stimulatory effect by L-N6-phenylisopropyladenosine (L-PIA), with preference for adenosine A1-receptors, was seen mainly during the proliferative phase. In ampullary preparations, stimulation by L-PIA was seen both in the secretory and proliferative phases. Adenosine and 2-chloroadenosine exerted similar stimulatory effects. 5'-N-ethylcarboxamide-adenosine (NECA), with selectivity for adenosine A2-receptors, or D-PIA never showed a stimulatory effect. At concentrations above those needed for stimulation, adenosine, 2-chloroadenosine and L-PIA inhibited spontaneous contractions, in common with NECA and D-PIA. Here, NECA was more potent than L-PIA. The D-PIA and L-PIA were equipotent. The inhibition was seen during the whole menstrual cycle. The competitive adenosine antagonist 8-p-sulphophenyltheophylline (PS?T) reversibly antagonized the stimulatory and inhibitory effects elicited by adenosine and the analogues. The PS?T alone could exert a stimulatory or an inhibitory action on spontaneous contractility. We suggest that adenosine can modulate contractile activity in the human fallopian tube via stimulatory A1-and inhibitory A2-receptors. These receptors are located on the smooth muscle cells, and might act via cAMP. The relative receptor dominance may be influenced by cyclic hormonal changes.     

Influence of cyclic 3',5'-adenosine monophosphate and adenosine on vascular reactivity.

cAMP, 5'-AMP and adenosine in doses of 1, 2 and 5 mg/kg i.v. in rats diminish vascular resistance in the hind limbs in vivo and in isolated limbs perfused with nutrient fluid containing adrenaline (A) (10(-3) M), slowing action of the heart and lowering blood pressure. After administration of cAMP, 5'-AMP and adenosine (5 mg/kg), vasoconstricting action of noradrenaline (NA) and A was depressed, and the vasodilating action of isoprenaline (I) was enhanced. The changes in blood pressure observed after administration of the tested adenosine compounds were not blocked by phentolamine, but after I were blocked by propranolol. cAMP, 5'-AMP and adenosine had no influence on the drop in blood pressure elicited by acetylcholine. The results indicate that cAMP, 5'-AMP and adenosine increase reactivity of beta-receptors of the sympathetic system in the blood vessels and modify the action of catecholamines on blood vessels.     

Control of brown adipose tissue lipolysis and respiration by adenosine

Adenosine competitively inhibited the stimulatory effects of (-)-isoproterenol on lipolysis and respiration in hamster brown adipocytes. The low value of the apparent ki for respiratory inhibition by adenosine (7 nM) indicated that the nucleoside may control brown adipocyte function under physiological concentrations. Significantly, the dose-response curves for isoproterenol stimulation of lipolysis and respiration were both shifted by adenosine to higher agonist concentrations by the same order of magnitude, providing additional evidence for a tight coupling between lipolysis and respiration. The inhibitory effects of adenosine were rapidly reversed by a) adenosine deaminase, b) agents known to increase intracellular cyclic AMP levels (isoproterenol, isobutylmethylxanthine, dibutyryl cyclic AMP), and c) direct stimulation of respiration with palmitic acid. These results, combined with the fact that adenosine failed to affect respiration evoked either by dibutyryl cyclic AMP or by palmitic acid, strongly indicate that adenosine regulates brown adipose tissue respiration at an early metabolic step of the stimulus-thermogenesis sequence, most probably at the level of the adenylate cyclase complex.     

Regulation of thymocyte proliferation by endogenous adenosine and adenosine deaminase

Spontaneous proliferation of thymocytes after 20-25 h of culture was significantly increased by the presence of adenosine deaminase (ADA) or theophylline. The effect of ADA was counteracted by the ADA inhibitor EHNA. When given alone, EHNA inhibited proliferation. This effect was not blocked by inhibition of adenosine uptake with dipyridamol. These results suggest that proliferation in culture is regulated by a balance between endogenous adenosine and ADA, controlling the influence of adenosine on the intracellular cyclic AMP level via an adenosine receptor on the surface of thymocytes. According to the hypothesis, ADA would stimulate proliferation by decreasing extracellular adenosine levels and theophylline by blocking adenosine receptors on thymocytes. EHNA would inhibit proliferation by increasing extracellular adenosine levels. In accordance with this interpretation, the adenosine analogue phenylisopropyl adenosine (PIA) inhibited proliferation and the effect could be inhibited by theophylline. The postulated effect of endogenous adenosine could not be mimicked by a single administration of exogenous adenosine. Whereas most doses of adenosine were without effect, a high dose of adenosine (0.1 mM) in combination with EHNA unexpectedly stimulated proliferation. Since the effect was blocked by dipyridamol, an intracellular site of action for adenosine is suggested in this case.     

Inhibition by acidosis of adenosine 3',5'-cyclic monophosphate accumulation and lipolysis in isolated rat fat cells.

Lipolysis and cyclic AMP accumulation were studied in isolated rat fat cells at normal (7.4) and decreased (7.0, 6.6) pH. Acidosis inhibited lipolysis and cyclic AMP accumulation due to NA non-competetively. Maximal lipolysis (3 muM NA) was inhibited by 25% at pH 7.0 and by 61% at pH 6.6 Cyclic AMP accumulation 5 min after 3 muM NA was inhibited by 57% at pH 7.0 and by 83% at pH 6.6. Between 10 and 60 minutes of incubation NA-stimulated lipolysis was linear at pH 7.4, whereas a progressively increasing inhibition was seen at lower pH. The FFA production was inhibited to the same degree as glycerol production by acidosis. The fraction of FFA associated with the cells was the same at all pHs. Thus, we have no evidence that acidosis inhibits lipolysis via accumulation of FFA intracellularly. NA-induced accumulation of 3H-cAMP from 3H-ATP, endogenously formed by prelabelling the cells with 3H-adenine, was inhibited by acidosis both in the presence and absence of theophylline in the incubation medium (by 48 and 44% respectively at pH 7.0 and by 74 and 68% at pH 6.6). Cyclic nucleotide phosphodiesterase in homogenates of fat cells was inhibited by decreasing the pH, whether measured at high or low substrate concentrations. Basal adenylyl cyclase activity in a cell membrane fraction from fat cells was affected to a minor degree, while NA-stimulated activity was inhibited by decreased pH. The response to 3 muM NA at pH 6.6 was inhibited by 43% relative to control. The results show that acidosis inhibits NA-induced cyclic AMP accumulation by interfering with the formation, rather than the inactivation of the nucleotide. Since NA-induced lipolysis is a cyclic AMP-mediated process it is suggested that at least part of the antilipolytic effect of acidosis is due to inhibition of cyclic AMP formation.     

Effects on aggregation of human platelets of two xanthines and their interactions with adenosine

Adenosine receptor antagonism has been suggested to be the cellular basis for many extrapulmonary actions of xanthine derivatives, such as theophylline. Enprofylline (3-propylxanthine) is a poor adenosine antagonist but is five times as potent as theophylline as a bronchodilator in man. Adenosine is a potent inhibitor of platelet aggregation, but also xanthines are considered to exert this action. In the present study, effects of theophylline and enprofylline on ADP-induced aggregation of human platelets were studied in vitro. Theophylline alone in concentrations exceeding 280 microM inhibited platelet aggregation concentration-dependently. Enprofylline alone mimicked this effect but was about five times more potent than theophylline. At the lowest concentrations used, corresponding to upper therapeutic levels, neither of the two xanthines affected platelet aggregation by ADP. The interactions between these low concentrations of the xanthines and adenosine were then evaluated. In the presence of theophylline 110 microM the inhibitory effect of adenosine 4 microM was attenuated, whereas the presence of enprofylline 21 microM enforced the inhibitory effect of adenosine. Thus, at low concentrations where neither theophylline nor enprofylline inhibits platelet aggregation theophylline antagonizes the antiaggregatory effect of adenosine, whereas enprofylline acts in synergy with this nucleoside.     

Cyclic AMP-Dependent and Independent Inhibition of Lipolysis by Adenosine and Decreased pH

NA-stimulated lipolysis and cAMP formation in isolated rat fat cells is inhibited by acidosis. In the present report we have examined the quantitative relationship between lipolysis and cAMP formation at normal and reduced pH and the possible involvement of adenosine, an endogenous inhibitor of cAMP formation. Adenosine antagonized cAMP accumulation and to a considerably lower degree lipolysis, effects potentiated by acidosis. Theophylline, an antagonist of adenosine effects, stimulated lipolysis and cAMP-accumulation, and potentiated responses to NA. Adenosine deaminase (ADA) had theophylline-like effects. Acidosis inhibited lipolysis and cAMP accumulation induced by ADA and theophylline to a larger extent than those induced by NA. It is suggested that adenosine modulates fat cell cAMP production and may contribute to the antilipolytic effect of acidosis. There was a curvilinear relationship between cAMP elevation and glycerol production in fat cell suspensions, which was different at pH 7.4 and at pH 6.6. The amount of cAMP needed for half-maximal activation of lipolysis increased from 1.3 (pH 7.4) to 3.1 pMol × 10^-5 cells (pH 6.6). The maximal glycerol production was reduced from 1 300 to 900 nMol × 10^-5 cells. The antilipolytic effect of acidosis is apparently due partly to an inhibition of cAMP formation and partly to inhibition of subsequent step(s) in the activation sequence.     

Direct antilipolytic effect of acidosis in isolated rat adipocytes.

The possibility that acidosis inhibits lipolysis indirectly by causing ionic shifts or by favouring the accumulation of an inhibitor has been tested in isolated fat cells. Lipolysis induced by 3 muM noradrenaline (NA) was inhibited by 40-60% and that induced by 1 mM theophylline (THEO) by about 75% when the pH was reduced to 6.6. Lipolysis induced by NA + THEO was inhibited by 20-30%. Changing the concentration of Ca++ or Mg++ did not alter the degree of inhibition. Reducing the K+-ion concentration enhanced the inhibitory effect of low pH on lipolysis induced by NA or NA + THEO, whereas cyclic AMP accumulation was uninfluenced. Omitting glucose from the incubation medium caused a slight enhancement of pH-induced inhibition of lipolysis (from 60 to 70%, p less than 0.01). Reducing the concentration of albumin, which binds inhibitory substances such as FFA, reduced lipolysis more at normal than at reduced pH. At high FFA/albumin ratios (5 or above) lipolysis was similar at normal and reduced pH. The antilipolytic effect of decreased pH was equally pronounced in perifused fat cells, where inhibitory substances are not allowed to accumulate. Our results suggest that the antilipolytic effect of acidosis is mainly a direct effect of the increase in H+ ion concentration. The inhibitory effect of acidosis on various responses to beta-adrenoceptor stimulation may be caused by a decreased formation of cyclic AMP in turn caused directly by the decrease in pH.     

Direct Antilipolytic Effect of Acidosis in Isolated Rat Adipocytes

The possibility that acidosis inhibits lipolysis indirectly by causing ionic shifts or by favouring the accumulation of an inhibitor has been tested in isolated fat cells. Lipolysis induced by 3 μM noradrenaline (NA) was inhibited by 40–60% and that induced by 1 mM theophylline (THEO) by about 75% when the pH was reduced to 6.6. Lipolysis induced by NA+THEO was inhibited by 20–30%. Changing the concentration of Ca⁺⁺or Mg⁺⁺did not alter the degree of inhibition. Reducing the K⁺-ion concentration enhanced the inhibitory effect of low pH on lipolysis induced by NA or NA + THEO, whereas cyclic AMP accumulation was uninfluenced. Omitting glucose from the incubation medium caused a slight enhancement of pH-induced inhibition of lipolysis (from 60 to 70%, p<0.01). Reducing the concentration of albumin, which binds inhibitory substances such as FFA, reduced lipolysis more at normal than at reduced pH. At high FFA/albumin ratios (5 or above) lipolysis was similar at normal and reduced pH. The antilipolytic effect of decreased pH was equally pronounced in perifused fat cells, where inhibitory substances are not allowed to accumulate. Our results suggest that the antilipolytic effect of acidosis is mainly a direct effect of the increase in H⁺ion concentration. The inhibitory effect of acidosis on various responses to β-adrenoceptor stimulation may be caused by a decreased formation of cyclic AMP in turn caused directly by the decrease in pH.     

Adenosine and adenosine analogues increase blood flow in oral mucosa

The effect of adenosine and some related compound was studied on blood flow in feline oral mucosa. Changes in the rate of disappearance of 125Iodine (k-value) from a local depot in the oral mucosa was used to determine changes in the mucosal blood flow. Infusion of adenosine caused a dose-dependent increase of blood flow. Two stable adenosine analogues, adenosine 5'- ethylcarboxamide ( NECA ) and L-phenylisopropyl-adenosine (L-PIA), were 20 and 10 times more potent than the parent compound. Dipyridamole (2 mg/kg), which blocks adenosine uptake, significantly enhanced the potency of adenosine. Theophylline (10 mg/kg) inhibited the vasodilatory effect of adenosine and of the adenosine analogues. The result suggest that adenosine may be involved in the regulation of blood flow in the oral mucosa.     

Stimulus-secretion coupling: role of cyclic AMP, cyclic GMP and calcium in mediating enzyme (kallikrein) secretion in the submandibular gland.

1. The role of adenosine 3':5'-phosphate (cyclic AMP) and guanosine 3':5'-phosphate (cyclic GMP) as second messengers for the enzyme secretory response evoked by the autonomic neurotransmitters, noradrenaline and acetylcholine, is examined in this in vitro study on the guinea-pig submandibular gland. 2. Noradrenaline increased enzyme (kallikrein) secretion. The initial stimulation of enzyme release appeared to be dose-dependent. The time course of cumulative kallikrein secretion revealed a complex pattern. Isoprenaline and phenylephrine were almost as potent as noradrenaline in releasing kallikrein. Both propranolol and phentolamine were required to fully inhibit the noradrenaline-stimulated enzyme secretion. 3. The cumulative secretion of kallikrein evoked by acetylcholine was dose-dependent. The onset of secretion showed a significantly greater time-lag than that observed with noradrenaline. Atropine effectively blocked the release of kallikrein by acetylcholine. 4. Dibutyryl cyclic AMP stimulated enzyme secretion. Dibutyryl cyclic GMP caused an initial increase which was not maintained. 5. The cyclic nucleotide phosphodiesterase inhibitors, theophylline and papaverine, increased basal kallikrein secretion. The action of the cyclic phosphodiesterase inhibitors on the secretory response to noradrenaline, acetylcholine, dibutyryl cyclic AMP and dibutyryl cyclic GMP was complex. In general, the increase in enzyme release produced by the secretagogues was additively enhanced by both inhibitors. 6. Omission of calcium inhibited both acetylcholine and dibutyryl cyclic GMP stimulated kallikrein release, but to a lesser degree than that of noradrenaline and dibutyryl cyclic AMP. High concentrations of extracellular calcium (10 mM) appeared to enhance the action of acetylcholine. 7. Noradrenaline produced a rise in the intracellular level of cyclic AMP. The increase preceded the stimulated secretion of kallikrein. Of the various adrenergic agonists, noradrenaline and isoprenaline were the most potent, whereas phenylephrine was significantly less effective in raising basal cyclic AMP values. Acetylcholine was without effect, even in the presence of a cyclic phosphodiesterase inhibitor. 8. Acetylcholine and noradrenaline raised intracellular levels of cyclic GMP only when the tissue incubations were performed in the presence of a cyclic phosphodiesterase inhibitor. The increase in cyclic GMP produced by acetylcholine preceded enzyme secretion. 9. Morphological data substantiated the finding that the in vitro release of kallikrein evoked by the secretagogues was associated with the depletion of secretory granules and vacuolations in acinar cells of the gland slices. 10. The molecular mechanisms which control enzyme secretion in the exocrine submandibular gland are discussed. Models are presented for the role of transmitter-specific cyclic nucleotides and calcium in stimulus-secretion coupling.     

Post-inhibitory excitation of adenosine on neurotransmission in guinea pig hippocampal slices.

The postsynaptic field potential (population spike potential; PS) was recorded from the granule cell layer of guinea pig hippocampal slices. Adenosine at low concentrations ranging from 10 nM to 1 microM enhanced the amplitude of PS, whereas at concentrations over 10 microM it inhibited the neurotransmission. There appeared to be a rebound phenomenon after the removal of adenosine at inhibitory concentrations and the amplitude of the PS overshot the initial amplitude (we called this post-inhibitory excitation; PIE). Neither depressants such as gamma-aminobutyric acid (GABA; 1 mM) nor sodium pentobarbital (100 microM) by itself induced PIE. After application of GABA or sodium pentobarbital together with adenosine (0.1 microM), however, removal of all agents could induce the PIE. PIE as well as the excitatory effect of adenosine at low concentrations was counteracted by application of H-7 (100 microM), melittin or polymyxin B, potent protein kinase C (PKC) inhibitors, suggesting that the excitatory effect of adenosine is mediated by a metabolic process involving PKC. These results indicate that PIE induced by adenosine at high concentrations is due to a mechanism similar to the excitatory effect induced by adenosine at low concentrations, and that during application of adenosine at high concentrations the excitation is masked by its potent inhibitory effect.     

Structure activity relations for inhibition of neurotransmission in rat vas deferens by adenosine

Adenosine inhibits the isometric contractions of the rat vas deferens in response to field stimulation in vitro by presynaptic inhibition of transmitter release. In the present study the structure activity relations for the inhibition of neurotramsmission in the rat vas deferens by adenosine were examined. Adenosine and adenosine-N¹-oxide were the most potent inhibitors studied. 6-Methylaminopurine riboside, 6-hydroxylaminopurine riboside, 5′-deoxyadenosine and 5′-nitroadenosine were slightly less potent inhibitors. The common structural requirements for activity include a primary or secondary amine function at C₆ of the purine ring with little tolerance for major steric changes or substitutions on the sugar moiety. None of the analogues studied prevented the presynaptic inhibitory action of adenosine.     

Zaprinast stimulates extracellular adenosine accumulation in rat pontine slices

Adenosine appears to be an endogenous somnogen. The lateral dorsal tegmental/pedunculopontine nucleus (LDT/PPT) located in the mesopontine tegmentum is important in the regulation of arousal. Neurons in this nucleus are strongly hyperpolarized by adenosine and express neuronal nitric oxide synthase. Zaprinast is a cyclic nucleotide phosphodiesterase inhibitor, and has been shown in the hippocampal slice to inhibit the field excitatory postsynaptic potential. This action could be blocked by an adenosine receptor antagonist, and therefore is presumably due to adenosine release stimulated by zaprinast. In the present study we tested the effect of zaprinast on extracellular adenosine accumulation in pontine slices containing the LDT. Zaprinast at 10 microM evoked an increase in extracellular adenosine concentration. This effect was blocked by impermeant inhibitors of 5'-nucleotidase, indicating that the extracellular adenosine was derived from extracellular AMP. However, inhibitors of cAMP degradation had little or no effect on zaprinast-evoked adenosine accumulation, suggesting that extracellular cAMP was not the source. Removal of extracellular calcium inhibited the effect of zaprinast. These results demonstrate that a pathway exists by which zaprinast stimulates extracellular adenosine accumulation, and the presence of this pathway in the pontine slice suggests the possibility that it may be relevant for the regulation of behavioral state.     

Protein kinase C-dependent inhibition of K+ currents in noradrenaline-induced depolarization of smooth muscle of guinea-pig vas deferens

Ionic mechanisms and signal transduction underlying noradrenaline (NA)-induced depolarization in single smooth muscle cells of guinea-pig vas deferens were studied. NA caused depolarization followed by action potentials through activation of 1-adrenoceptors. In the presence of nifedipine, no action potential was generated, and the magnitude of the depolarization depended on the concentration of NA (0.1-100 micrometer). NA, through 1-adrenoceptor activation, reduced the magnitude of membrane currents in response to voltage ramp pulses from -90 to -30 mV in a concentration-dependent manner. The reversal potential of the current inhibited by NA changed proportionally to the change in the equilibrium potential of K+, suggesting that NA inhibited K+ channel activity. Treatment of cells with GDPS, an inhibitor of G proteins, or bisindolylmaleimide (BIM), a selective protein kinase C (PKC) inhibitor, prevented the NA inhibition of the currents. Application of 12-O-tetradecanoylphorbol 13-acetate (TPA), an activator of PKC, mimicked the effect of NA. It is suggested that in the smooth muscle of guinea-pig vas deferens, activation of 1-adrenoceptors and the subsequent activation of PKC led to inhibition of K+ currents, which is responsible for the depolarization induced by NA.     

Synergistic action of histamine and adenosine triphosphate on the response to noradrenaline in rabbit pulmonary artery smooth muscle cells

The interaction between histamine, adenosine triphosphate (ATP) and noradrenaline was studied with the perforated-patch technique in single cells isolated from the rabbit pulmonary artery. In these cells all of the agents activated caffeine-sensitive currents. In potassium-free conditions at a holding potential of –50 mV bath applied histamine, in concentrations that did not produce a response, greatly enhanced the magnitude of inward currents evoked by ionophoretic application of noradrenaline. These inward currents were calcium-activated chloride currents, I _Cl(Ca). In potassiumcontaining solutions at a holding potential of 0 mV, bath applied histamine potentiated the outward currents (calcium-activated potassium currents (I _K(Ca)) induced by noradrenaline. This synergistic action was rapid in onset, sustained during the continued presence of histamine and reversible. Bath application of noradrenaline inhibited the response to ionophoretically applied noradrenaline but not the caffeine-induced currents. ATP also stimulated I _Cl(Ca) and I _K(Ca) through a mechanism dependent on the caffeine-sensitive intracellular calcium store and also potentiated the currents activated by noradrenaline. It is concluded that one explanation for the phenomenon of potentiation in smooth muscle is convergence of several distinct pharmacological receptors to a common cellular mechanism.     

Modulation of low calcium induced field bursts in the hippocampus by monoamines and cholinomimetics

The influence of monoamine transmitter candidates, acetylcholine and related substances on rhythmic depolarization shifts (field bursts) in the CA1 area of hippocampal slices from rats in low calcium (0.2 mmol·l^–1) high magnesium (4 mmol·l^–1) was investigated. Acetylcholine (ACh), histamine (HA) and H₂-agonists, noradrenaline (NA) and beta-agonists at nano- to micromolar concentrations as well as dopamine (DA) and 8-bromo-cyclic AMP at 100 mol·l^–1 accelerated the field bursts. H₂-antagonists blocked HA actions, beta-antagonists blocked NA actions selectively; muscarinic antagonists blocked ACh, HA and NA actions. H₁-agonists, serotonin, dopamine and adenosine slowed the field bursts at micromolar concentrations. These effects parallel the action of the tested substances on afterhyperpolarizations in CA 1 pyramidal cells. High sensitivity and specificity make this response of the field bursts an excellent model to study postsynaptic transmitter actions in the central nervous system.