On the relation between ATP splitting and secretion in the adrenal chromaffin cell: extrusion of ATP (unhydrolysed) during release of catecholamines

Changes in Corticotrope Gene Expression Upon Increased Expression of Peptidylglycine α-Amidating Monooxygenase

Throughout evolution, secretion has played an essential role in the ability of organisms and single cells to survive in the face of a changing environment. Peptidylglycine α-amidating monooxygenase (PAM) is an integral membrane monooxygenase, first identified for its role in the biosynthesis of neuroendocrine peptides released by the regulated secretory pathway. PAM was subsequently identified in Chlamydomonas reinhardtii, a unicellular green alga, where it plays an essential role in constitutive secretion and in ciliogenesis. Reduced expression of C. reinhardtii PAM resulted in significant changes in secretion and ciliogenesis. Hence, a screen was performed for transcripts and proteins whose expression responded to changes in PAM levels in a mammalian corticotrope tumor cell line. The goal was to identify genes not previously known to play a role in secretion. The screen identified transcription factors, peptidyl prolyl isomerases, endosomal/lysosomal proteins, and proteins involved in tissue-specific responses to glucose and amino acid availability that had not previously been recognized as relevant to the secretory pathway. Perhaps reflecting the dependence of PAM on molecular oxygen, many PAM-responsive genes are known to be hypoxia responsive. The data highlight the extent to which the performance of the secretory pathway may be integrated into a wide diversity of signaling pathways.

Functional distribution of Ca2+-coupled P2 purinergic receptors among adrenergic and noradrenergic bovine adrenal chromaffin cells

BACKGROUND

Adrenal chromaffin cells mediate acute responses to stress through the release of epinephrine. Chromaffin cell function is regulated by several receptors, present both in adrenergic (AD) and noradrenergic (NA) cells. Extracellular ATP exerts excitatory and inhibitory actions on chromaffin cells via ionotropic (P2X) and metabotropic (P2Y) receptors. We have taken advantage of the actions of the purinergic agonists ATP and UTP on cytosolic free Ca2+ concentration ([Ca2+]i) to determine whether P2X and P2Y receptors might be asymmetrically distributed among AD and NA chromaffin cells.

RESULTS

The [Ca2+]i and the [Na+]i were recorded from immunolabeled bovine chromaffin cells by single-cell fluorescence imaging. Among the ATP-sensitive cells ~40% did not yield [Ca2+]i responses to ATP in the absence of extracellular Ca2+ (Ca2+o), indicating that they expressed P2X receptors and did not express Ca2+- mobilizing P2Y receptors; the remainder expressed Ca2+-mobilizing P2Y receptors. Relative to AD-cells approximately twice as many NA-cells expressed P2X receptors while not expressing Ca2+- mobilizing P2Y receptors, as indicated by the proportion of cells lacking [Ca2+]i responses and exhibiting [Na+]i responses to ATP in the absence and presence of Ca2+o, respectively. The density of P2X receptors in NA-cells appeared to be 30-50% larger, as suggested by comparing the average size of the [Na+]i and [Ca2+]i responses to ATP. Conversely, approximately twice as many AD-cells expressed Ca2+-mobilizing P2Y receptors, and they appeared to exhibit a higher (~20%) receptor density. UTP raised the [Ca2+]i in a fraction of the cells and did not raise the [Na+]i in any of the cells tested, confirming its specificity as a P2Y agonist. The cell density of UTP-sensitive P2Y receptors did not appear to vary among AD- and NA-cells.

CONCLUSION

Although neither of the major purinoceptor types can be ascribed to a particular cell phenotype, P2X and Ca2+-mobilizing P2Y receptors are preferentially located to noradrenergic and adrenergic chromaffin cells, respectively. ATP might, in addition to an UTP-sensitive P2Y receptor, activate an UTP-insensitive P2Y receptor subtype. A model for a short-loop feedback interaction is presented whereby locally released ATP acts upon P2Y receptors in adrenergic cells, inhibiting Ca2+ influx and contributing to terminate evoked epinephrine secretion.

Naloxone inhibits nicotine-induced receptor current and catecholamine secretion in bovine chromaffin cells

Nicotine-induced catecholamine (CA) secretion and inward ionic currents were inhibited by the opioid antagonist naloxone in cultured bovine chromaffin cells. Naloxone inhibited nicotine-induced CA secretion, as detected by an on-line real-time electrochemical technique, in a dose-dependent manner (IC(50)=29 microM). In voltage-clamped chromaffin cells, nicotine (10 microM) evoked an average peak inward current of -146 pA that was inhibited by low concentrations of naloxone (42% at 0.1 microM). The antagonist also inhibited total charge influx associated with nicotinic receptor activation (53% at 0.1 microM). This provides strong evidence that naloxone modulation of nicotine-induced CA secretion does not involve opioid receptors but results from the direct interaction with the nicotinic receptor itself, which might also be the case for other related opioid compounds.

P2Y purinoceptors inhibit exocytosis in adrenal chromaffin cells via modulation of voltage-operated calcium channels

We have used combined membrane capacitance measurements (C(m)) and voltage-clamp recordings to examine the mechanisms underlying modulation of stimulus-secretion coupling by a G(i/o)-coupled purinoceptor (P2Y) in adrenal chromaffin cells. P2Y purinoceptors respond to extracellular ATP and are thought to provide an important inhibitory feedback regulation of catecholamine release from central and sympathetic neurons. Inhibition of neurosecretion by other G(i/o)-protein-coupled receptors may occur by either inhibition of voltage-operated Ca(2+) channels or modulation of the exocytotic machinery itself. In this study, we show that the P2Y purinoceptor agonist 2-methylthio ATP (2-MeSATP) significantly inhibits Ca(2+) entry and changes in C(m) evoked by single 200 msec depolarizations or a train of 20 msec depolarizations (2.5 Hz). We found that P2Y modulation of secretion declines during a train such that only approximately 50% of the modulatory effect remains at the end of a train. The inhibition of both Ca(2+) entry and DeltaC(m) are also attenuated by large depolarizing prepulses and treatment with pertussis toxin. Inhibition of N-type, and to lesser extent P/Q-type, Ca(2+) channels contribute to the modulation of exocytosis by 2-MeSATP. The Ca(2+)-dependence of exocytosis triggered by either single pulses or trains of depolarizations was unaffected by 2-MeSATP. When Ca(2+) channels were bypassed and exocytosis was evoked by flash photolysis of caged Ca(2+), the inhibitory effect of 2-MeSATP was not observed. Collectively, these data suggest that inhibition of exocytosis by G(i/o)-coupled P2Y purinoceptors results from inhibition of Ca(2+) channels and the Ca(2+) signal controlling exocytosis rather than a direct effect on the secretory machinery.

P2Y purinoceptors inhibit exocytosis in adrenal chromaffin cells via modulation of voltage-operated calcium channels

We have used combined membrane capacitance measurements (C(m)) and voltage-clamp recordings to examine the mechanisms underlying modulation of stimulus-secretion coupling by a G(i/o)-coupled purinoceptor (P2Y) in adrenal chromaffin cells. P2Y purinoceptors respond to extracellular ATP and are thought to provide an important inhibitory feedback regulation of catecholamine release from central and sympathetic neurons. Inhibition of neurosecretion by other G(i/o)-protein-coupled receptors may occur by either inhibition of voltage-operated Ca(2+) channels or modulation of the exocytotic machinery itself. In this study, we show that the P2Y purinoceptor agonist 2-methylthio ATP (2-MeSATP) significantly inhibits Ca(2+) entry and changes in C(m) evoked by single 200 msec depolarizations or a train of 20 msec depolarizations (2.5 Hz). We found that P2Y modulation of secretion declines during a train such that only approximately 50% of the modulatory effect remains at the end of a train. The inhibition of both Ca(2+) entry and DeltaC(m) are also attenuated by large depolarizing prepulses and treatment with pertussis toxin. Inhibition of N-type, and to lesser extent P/Q-type, Ca(2+) channels contribute to the modulation of exocytosis by 2-MeSATP. The Ca(2+)-dependence of exocytosis triggered by either single pulses or trains of depolarizations was unaffected by 2-MeSATP. When Ca(2+) channels were bypassed and exocytosis was evoked by flash photolysis of caged Ca(2+), the inhibitory effect of 2-MeSATP was not observed. Collectively, these data suggest that inhibition of exocytosis by G(i/o)-coupled P2Y purinoceptors results from inhibition of Ca(2+) channels and the Ca(2+) signal controlling exocytosis rather than a direct effect on the secretory machinery.

Tricyclic antidepressants block cholinergic nicotinic receptors and ATP secretion in bovine chromaffin cells

Nicotine-induced ATP secretion from chromaffin cells was blocked by imipramine and desipramine. This blocking action took place on both, fast and slow, components of ATP secretion. Exposure of chromaffin cells to nicotine (10 microM) for 4 s induced an inward current of about -155 pA. Imipramine and desipramine blocked, in a concentration-dependent manner, both peak inward current and total charge influx in response to nicotine. In addition, imipramine and desipramine partially (40%) blocked depolarization-induced ATP secretion and Ca2+ currents evoked by high K+. This suggests that tricyclic antidepressants block nicotine-induced ATP secretion by acting on two targets: one is the nicotinic receptor itself and the second one are voltage-dependent Ca2+ channels.

Stimulatory action of Ba2+ on catecholamine biosynthesis in cultured bovine adrenal chromaffin cells: possible relation to protein kinase C

The effect of Ba2+ on the catecholamine biosynthetic activity was studied by measuring the formation of [14C]catecholamines from L-[14C]tyrosine in cultured adrenal chromaffin cells. In the absence of Ca2+, [14C]catecholamine formation was markedly stimulated by Ba2+, and this stimulation was observed in a manner dependent on its concentration. The stimulation of [14C]catecholamine formation by relatively low concentrations of Ba2+ was suppressed by polymyxin B, a typical inhibitor of Ca2+/phospholipid-dependent protein kinase (protein kinase C); and this inhibitory action of polymyxin B was attenuated by increasing the Ba2+ concentration. On the other hand, a tendency toward the enhancement of Ba2+-stimulated [14C]catecholamine formation was observed by a protein kinase C activator, 12-O-tetradecanoylphorbol 13-acetate (TPA). In contrast to the acute effect of TPA, [14C]catecholamine formation stimulated by Ba2+ was reduced by long-term exposure of chromaffin cells to a high concentration of TPA, which has already been reported to cause the reduction of protein kinase C activity as a result of the down-regulation of this enzyme. These findings suggest that Ba2+ stimulates catecholamine biosynthesis, probably through its direct action on protein kinase C in adrenal chromaffin cells.

Evidence for evoked release of adenosine and glutamate from cultured cerebellar granule cells

Evoked release of [3H]-D-aspartate which labels the neurotransmitter glutamate pool in cultured cerebellar granule cells was compared with evoked release of adenosine from similar cultures. It was found that both adenosine and [3H]-D-aspartate could be released from the neurons in a calcium dependent manner after depolarization of the cells with either 10-100 microM glutamate or 50 mM KCl. Cultures of cerebellar granule cells treated with 50 microM kainate to eliminate GABAergic neurons behaved in the same way. This together with the observation that cultured astrocytes did not exhibit a calcium dependent, potassium stimulated adenosine release strongly suggest that cerebellar granule cells release adenosine in a neurotransmitter-like fashion together with glutamate which is the classical neurotransmitter of these neurons. Studies of the metabolism of adenosine showed that in the granule cells adenosine is rapidly metabolized to ATP, ADP, and AMP, but in spite of this, adenosine was found to be released preferential to ATP.

Ba2+-induced ATP release from adrenal medullary chromaffin cells is mediated by Ba2+ entry through both voltage- and receptor-gated Ca2+ channels

We have measured on-line the exocytotic secretion of ATP from adrenal medullary chromaffin cells induced by Ba2+ using a luciferin/luciferase assay. We have found that Ba2+-induced ATP release requires the entry of Ba2+ through either voltage- or receptor-gated Ca2+ channels. This conclusion is based on the observations that short preincubations with low concentrations of either nicotine or K+ greatly enhance Ba2+-induced ATP release and that this augmentation can be blocked with the nicotinic receptor antagonist, hexamethonium, and the Ca2+ antagonist, nifedipine, respectively. Moreover, both nicotine and K+ stimulate 133Ba2+ uptake, which in the case of K+ is inhibited by nifedipine. These results support the hypothesis that the cellular events leading to Ba2+-induced secretion coincide at least in part with the events leading to Ca2+-dependent exocytosis.

Role of adenine compounds in autonomic neurotransmission

Clearly adenine compounds exert numerous effects throughout the autonomic nervous system. The responses of various peripheral tissues to purines are summarized in Table 2. The evidence supporting a possible excitatory neurotransmitter function for ATP is very good in the vas deferens and good in both the bladder detrusor and certain blood vessels. ATP may also be an excitatory neurotransmitter in the colon, hepatocytes and frog atrium. These responses appear to be mediated by P2x-purinoceptors. There is good evidence supporting a role for ATP as an inhibitory neurotransmitter in the taenia coli and duodenum, and some support in the anal sphincter and possibly the rabbit portal vein; these responses appear to be mediated by P2y-purinoceptors. There is good evidence against ATP being an inhibitory neurotransmitter in the stomach fundic muscle and ileum. ATP (or more likely its metabolite adenosine) may act as an inhibitory neurotransmitter by interacting with postsynaptic P1-purinoceptors in cultured sympathetic neurones and also in the parasympathetic vesicle ganglion of the cat. It seems likely that ATP released from heart, platelets or vascular endothelium could be an endogenous relaxant of blood vessels through its actions on the endothelium. Although the addition of exogenous adenosine affects many tissues, evidence supporting modulatory functions for endogenous extracellular adenosine has only been clearly demonstrated in the ileum, gallbladder, vas deferens, fallopian tubes, kidney, blood vessels, carotid sinus, heart and adipose tissue. Both ATP and adenosine, released during periods of hypoxia or ischemia, could exert negative inotropic, chronotropic and dromotropic actions in the heart. In many cases, the potential sources of extracellular purines have not been established. This is particularly important when attempting to establish a neurotransmitter function for ATP in a tissue. For instance, the one outstanding piece of evidence required to confirm that ATP is an excitatory neurotransmitter released from sympathetic nerves in blood vessels is the unequivocal demonstration that it is, in fact, released from the sympathetic nerves when they are stimulated. To date, only the release of radiolabeled metabolites of ATP, possibly from post- rather than presynaptic sites, has been detected. Studies of the release of ATP are complicated by its rapid degradation extracellularly by ecto-ATPase. Unfortunately, there are no specific inhibitors of ecto-ATPase available at present, but one hopes that a suitable inhibitor will be developed shortly.(ABSTRACT TRUNCATED AT 400 WORDS)

Inhibition of catecholamine secretion from bovine chromaffin cells by adenine nucleotides and adenosine

ATP, ADP, and adenosine have been found to inhibit acetylcholine-stimulated secretion from isolated cells of bovine adrenal medulla (chromaffin cells). Maximal inhibition is approximately 30% under the conditions studied; half-maximal inhibition occurs at nucleotide concentration in the micromolar range. Cells must be incubated with ATP for approximately 90 s for maximal inhibition, but inhibition by adenosine occurs much faster, an observation suggesting the possibility that ATP and ADP exert their effect after being converted to adenosine. Experiments with cells preloaded with the fluorescent calcium chelator quin 2 indicate that external ATP can diminish the rise in cytosolic Ca2+ concentration that follows stimulation by acetylcholine.

The influence of prostaglandins on neurotransmission in the rabbit isolated vas deferens

Arachidonic acid and PGs of the D, E, F and I series were examined for influences on neurogenic contractions of the rabbit isolated vas deferens. This preparation exhibits two pharmacologically distinct contractions in response to electrical stimulation. All of the PGs tested inhibited the neurogenic contractions but the pattern of inhibition differed. PGE1 and PGI2 inhibited the adrenergic contractile phase more potently than the nonadrenergic, and PGF2 alpha exhibited the opposite selectivity. Arachidonic acid, PGE2 and PGD2 produced equipotent effects on both contractile phases, although PGE2 was the most potent in producing these effects. None of the PGs altered the concentration-response curve to norepinephrine. Contractile responses to ATP, a putative neurotransmitter, were inhibited by PGF2 alpha but not by the other PGs. These results suggest that the PG effects are predominantly prejunctional. The differing potencies of the PGs on the two neural components are consistent with the hypothesis that neurotransmitters in the vas deferens are released by distinct types of nerves.

On mechanical aspects of vesicular transport

From the chain of events leading to secretion we have identified and isolated stages in which mechanical and physical mechanics may play important roles. These include the vesicle motion towards the cell wall, drainage of the cytoplasmic fluid from the gap between the membranes, reorganization of the membrane constituents, failure of the membrane structure and coalescence into a new configuration. We suggest a unified mechanism, relevant to the neural, secretory and vascular systems, based on physical factors as flow, pressure and stress distributions, and membranes properties. The simulation of several stages of secretion is coupled with experimental observations. By use of the proposed hypothesis it is possible to explain some observed phenomena, such as spontaneous and induced secretion, membrane failure, protein lateral dislocation and the omega-shapes in electron microscopic exposures of fusion sites.

ATP excites a subpopulation of rat dorsal horn neurones

The peripheral receptive properties and central projections of different classes of dorsal root ganglion neurones are well characterized. Much less is known about the transmitters used by these neurones. Excitatory amino acids have been proposed as sensory transmitters but the sensitivity of virtually all central neurones to those compounds has made it difficult to assess their precise role in sensory transmission. Several neuropeptides have been localized within discrete subclasses of primary sensory neurones that project to the superficial dorsal horn of the spinal cord and may be afferent transmitters. However, only about one-third of spinal sensory neurones have been shown to contain neuropeptides. We have recently described the presence of a 5'-nucleotide hydrolysing acid phosphatase in a separate subpopulation of dorsal root ganglion neurones that project to the superficial dorsal horn. This enzyme also appears in certain autonomic and endocrine cells that contain high concentrations of releasable nucleotides in their storage granules. It is possible that the presence of this enzyme in sensory neurones is also associated with a releasable pool of nucleotides. Holton and Holton have provided evidence that ATP is released from the peripheral terminals of unmyelinated sensory fibres and have suggested that release of ATP might also occur from central sensory terminals. To investigate the possibility that nucleotides act as central sensory transmitters we have examined their actions on rat dorsal horn and dorsal root ganglion neurones maintained in dissociated cell culture. We report here a selective and potent excitation of subpopulations of both neuronal types by ATP.

Time course of release of catecholamine and other granular contents from perifused adrenal chromaffin cells of guinea-pig

Experiments were carried out to investigate the time course of the release of catecholamine, dopamine-beta-hydroxylase (DBH) and adenine nucleotides from isolated chromaffin cells of guinea-pig adrenal gland. When the isolated chromaffin cells were incubated with medium containing acetylcholine (ACh) (0.1 mM), veratridine (0.1 mM) or scorpion (Leiurus quinquestriatus) venom, (10 micrograms/ml.), catecholamine was released into the medium. Catecholamine secretion induced by veratridine or scorpion venom was inhibited by tetrodotoxin (1 microM) but not by atropine (0.1 mM) plus hexamethonium (0.1 mM). On the other hand, the secretory response to ACh was abolished by the cholinergic blocking drugs but not by tetrodotoxin. DBH was released together with catecholamine into the medium in which cells were suspended with these drugs. The ratio of catecholamine (n-mole) to DBH activity (n-mole/hr) appearing in the supernatant was 7.08 +/- 0.55, 6.60 +/- 0.27 and 8.91 +/- 0.47 for ACh, veratridine and scorpion venom, respectively. These values were close to that found in the lysate of chromaffin granules obtained from guinea-pig adrenal glands (7.37 +/- 0.39). The application of ACh or veratridine to perifused chromaffin cells was found to cause a parallel increase in catecholamine and DBH secretion in the perifusion medium without corresponding amounts of phenylethanolamine-N-methyltransferase leakage. However, DBH secretion tended to last for a longer period than catecholamine secretion. Adenine nucleotides were released from perifused chromaffin cells together with catecholamine, by ACh and veratridine. ATP added to the perifusion medium was metabolized to ADP and AMP, of which the ratio (ATP, 21.6%; ADP, 34%; AMP, 17.9%) was close to those of adenine nucleotides released from the cells. The secretion of adenine nucleotides induced by both secretagogues ceased much faster than the catecholamine secretion, so that molar ratio of catecholamine to adenine nucleotides was gradually increased during and after stimulation. The results indicate that catecholamine secretion is accompanied with a simultaneous release of DBH and ATP from adrenal chromaffin cells. Therefore, it is suggested that the delayed output of DBH, unlike catecholamine secretion, in perfused adrenal glands results from the presence of a diffusion barrier for this protein. The releasable secretory granules of isolated chromaffin cells are suggested to be heterogeneous with respect to the ratio of catecholamine to ATP.

Secretagogue effect of barium on output of melanocyte-stimulating hormone from pars intermedia of the mouse pituitary

Ba ions caused an intense and prolonged discharge of melanocyte-stimulating hormone (MSH) from perifused neurointermediate lobes of mouse pituitaries and dispersed pars intermedia cells. The effect persisted in chronically cultured lobes or cells. It did not require Ca, but, like the Ca-dependent response to excess K, was blocked by cyanide combined with glucose lack. The secretagogue effect of Ba was blocked or prevented by Co or by excess Ca, both of which can reduce inward Ba currents through Ca channels. Prior exposure to excess K partially reduced the secretagogue effect of Ba, suggesting that depolarization caused some inactivation of Ba current. In contrast to Ba, excess K elicited secretion that was transient, and prior exposure of preparations to excess K (in the absence of Ca) profoundly suppressed the secretagogue effect of Ca. The evidence is consistent with the view that inward Ca current rapidly inactivates in these cells. It is concluded that Ba ions have a potent and persistent direct secretagogue effect on the melanotrophs that may reflect, in part, their ability to penetrate Ca channels more easily than Ca ions. The strong secretagogue effects of Ba on melanotrophs may be of considerable utility in studies on MSH secretion since a physiological secretagogue has yet to be discovered. Moreover, since the responses of melanotrophs (and other endocrine cells) to Ba can be distinguished from those of various other secretory cells and neurones, it is suggested that Ba may provide a tool for characterizing the distinctive membrane properties of the Ba-responsive endocrine cells.

Alpha- and beta-receptor control of catecholamine secretion from isolated adrenal medulla cells

The regulation of secretion of catecholamines from bovine adrenal medulla cells was investigated by use of an improved and highly efficient method for isolating viable and responsive cells from this tissue. The method involves an in situ collagenase perfusion affecting only the connective tissue matrix of the medulla while leaving the cortex intact. The cells released both epinephrine and norepinephrine in response to stimulation by 100 microM acetylcholine. The ratio of epinephrine to norepinephrine in the medium following non-stimulated (basal) release, was similar to that found in the intact cells. On the other hand, a lower ratio of epinephrine to norepinephrine was found in the medium following stimulation by acetylcholine due mainly to preferential secretion of norepinephrine. This release ceased after 15 min of incubation and consisted of 15--20% of the catecholamines initially present in the cells. Exogenous epinephrine was found to inhibit total catecholamine secretion; however, it stimulated norepinephrine release. Addition of isoproterenol caused a stimulation of release while propranolol was inhibitory. Norepinephrine inhibited total release not favoring any specific catechol. Other alpha-agonists, such as clonidine, also had an inhibitory effect. These results suggest a receptor-mediated mechanism for the fine regulation of secretion from the adrenal medulla.

Tensile strength of the chromaffin granule membrane

Catecholamine release from chromaffin granules, suspended in sucrose solutions of various osmotic strengths, was determined at different temperatures between 2 degrees and 44 degrees C. Dynamic measurements showed that steady state is achieved within 15 min of incubation at all temperatures. The effect of temperature on the release was established in terms of the median granular fragility (MGF) defined as the concentration of sucrose solution causing 50% lysis. The MGF was determined as the inflection point of the Gaussian distribution of granular fragility. The MGF was found to decrease with fall in temperature implying a corresponding increase of the tensile strength of the vesicle membrane. Critical resultant forces at lysis were calculated and found to vary from 8.2 dyn/cm at 2 degrees C to 4.2 dyn/cm at 44 degrees C. These compare well with tensions at lysis found earlier for erythrocytes.

Studies on secretion of catecholamines evoked by acetylcholine or transmural stimulation of the rat adrenal gland

1. A method of studying the secretion of catecholamines (CA) in the isolated perfused rat adrenal gland by transmural stimulation or by application of acetylcholine (ACh) has been described. 2. Secretion of CA was practically linear in response to ACh administration, starting from 4.42 microM to 1.32 mM. Transmural stimulation enhanced secretion from a stimulation frequency of 0.5--3 Hz; the effect levelled at 10 Hz, and declined as frequency was raised to 30 Hz. The secretory response to transmural stimulation was maximal over 1 msec duration and 60 V. 3. Secretion evoked by transmural stimulation was blocked (70-95%) by 0.31 microM-tetrodotoxin (TTX) irrespective of stimulus duration, voltage and frequency of stimulation. Secretion evoked by ACh was depressed 43% by TTX. After mecamylamine (0.59 mM) treatment, secretory response evoked by either procedure was blocked by about 80%. 4. Adenosine (0.18 mM), adenosine monophosphate (0.28 mM), or adenosine triphosphate (0.19 mM) lowered CA secretion evoked by transmural stimulation by about 40%, but had no effect on secretion induced by ACh. 5. Isoprenaline (4.52 microM), propranolol (11.58 microM), clonidine (13.00 microM), phenoxybenzamine (3.30 microM), and 4-aminopyridine (3 mM) did not modify CA secretion evoked by transmural stimulation or by ACh. 6. Perfusion of the adrenal gland with 0.25 mM-Ca-Krebs solution completely abolished CA secretion evoked by transmural stimulation, but ACh-induced secretion was still 30-50% of the control value. 20 mM-Mg blocked electrically induced secretion by 60%, but that evoked by ACh was unaffected. 7. Perfusion with Ca-free Krebs solution for 2 hr did not completely abolish the response. However, treatment with EGTA (5 mM) for 30 min totally blocked ACh-induced secretion. 8. La or Mn were more effective in blocking transmurally evoked secretion than ACh-evoked secretion of CA. Verapamil (0.1 mM) had no significant effect on secretion evoked by either procedure. A 5-fold increase in its concentration caused about 75% blockade of secretion. 9. Differential effects of various ions and agents on CA secretion are explained on the basis that these compounds affect neurosecretory properties of the presynaptic splanchnic nerve terminals and of chromaffin cells differently.

Review lecture. Neurotransmitters and trophic factors in the autonomic nervous system

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Exocytotic release of catecholamine from perfused adrenal gland of guinea-pig induced by veratridine

1 Experiments were carried out on perfused adrenal glands of guinea-pig to determine whether veratridine caused the exocytotic release of catecholamine by comparing its effect with that of splanchnic nerve stimulation and secretagogues such as acetylcholine and excess K+. 2 Veratridine (100 microM) and excess K+ (56 mM) caused secretion of catecholamine and dopamine-beta-hydroxylase (DBH) activity in the venous effluents in the presence of atropine (30 microM) and hexamethonium (2 mM). Splanchnic nerve stimulation in the presence or absence of physostigmine (100 nM) and infusion of acetylcholine in the presence of physostigmine had the same effect. In all the responses, the release of DBH tended to last for a longer period than that of catecholamine. 3 The ratio of catecholamine to DBH activity appearing in the venous effluents was approximately 9, regardless of the method of stimulation. This value was close to the ratio of catecholamines to the 'soluble' DBH activity found in the chromaffin granules. 4 All the types of stimulation used caused a proportional release of adenine nucleotides and catecholamines in the effluents. The adenine nucleotides were mainly adenosine 5'-phosphate. 5 The ratio of catecholamine to adenine nucleotides was approximately 11, regardless of the method of stimulation. 6 It is suggested that the release of catecholamine induced by veratridine occurs by exocytosis in adrenal glands of guinea-pig.

Adenine nucleotides in the carotid body

Remarkably large amounts of adenine nucleotides are identified in type L-cells of the carotid body by fluorescence microscopy (labelling with quinacrine) and electron microscopy (uranaffin reaction). At the fine-structural level of the matrix material of specific granules displays enhanced electron density after fixation with uranium ions. It is suggested that ATP is stored within specific granules in addition to catecholamines and proteins. Adenine nucleotides should be considered as one of the secretion products of the chief cells in the carotid body, being capable locally of influencing vascular flow and/or chemoreceptor terminals. Histochemical analysis of the activities leading to a splitting of adenine nucleotides shows a high reactivity with ATP or ADP as substrates. Reaction products are confined to the entire vascular bed of the carotid body. Using AMP or beta-glycerophosphate as substrate, practically no phosphohydrolytic activity could be detected within the carotid body. Thus, the phosphatases are adequate to remove ATP and ADP, but not to form adenosine.

Effects of adenosine on neurally mediated norepinephrine release from the cat spleen

The effects of adenosine on the release of 3H-norepinephrine (3H-NE) from the isolated, perfused cat spleen consequent to nerve stimulation were evaluated. Electrical stimulation of the splenic nerve (5 Hz/100 impulses total) caused a release of 3H-NE and a rise in perfusion pressure. Adenosine added to the perfusion fluid (final concentrations 1 X 10(-6), 1 X 10(-5), and 1 X 10(-4) M) significantly reduced the pressure response elicited by nerve stimulation. In addition, adenosine (1 X 10(-4) M) slightly increased the release of total 3H consequent to nerve stimulation. Theophylline (1 X 10(-4) M) produced both a slight increase in the release of total 3H and a diminished pressure response. The effects of adenosine were effectively antagonized by this concentration of theophylline. Neither substance had any effect on the spontaneous release of total 3H. Adenosine (1 X 10(-4) M) also antagonized the pressure response elicited by perfusion of NE.

Catecholamine release from the adrenal medulla

Chromaffin cells in the adrenal medulla are specialized for the synthesis, storage, and secretion of catecholamines. These cells are innervated by preganglionic sympathetic neurons in the splanchnic nerves, and, because of their unique blood supply, are exposed to unusually high concentrations of glucocorticoids in the venous drainage from the adrenal cortex. Splanchnic nerve stimulation appears to be the most important determinant of adrenomedullary function. Chromaffin cells synthesize catecholamines from tyrosine. Splanchnic nerve stimulation leads to an increase in the activity of several of the catecholamine biosynthetic enzymes, and to an increase in the rate of catecholamine biosynthesis. Glucocorticoids cause the induction of the enzyme noradrenaline N-methyltransferase, and so are particularly important for the synthesis of epinephrine. Catecholamines are stored, together with ATP, Ca2+, and protein, in secretory vesicles known as chromaffin granules. Splanchnic nerve stimulation is the physiological stimulus for catecholamine secretion. Stimulation of the splanchnic nerves results in the release of ACh from nerve endings in the adrenal medulla. ACh causes an increase in the permeability of the chromaffin cells to Ca2+, and thereby leads to the entry of Ca2+ into the cells. Ca2+ then causes the secretion of catecholamines and of other chromaffin granule constituents from the chromaffin cells by exocytosis. The biochemical mechanisms of exocytosis, and the mechanism by which Ca2+ stimulates this process, are still unknown.

Potentiation of postjunctional cholinergic sensitivity of rat diaphragm muscle by high-energy-phosphate adenine nucleotides

The cholinergic sensitivity of rat diaphragm muscle, me-sured as the magnitude of depolarization responses to repetitive, iontophoretic pulses of acetylcholine (ACh) onto neuromuscular endplates, is increased by addition of ATP to the perfusion medium. Depolarization responses begin to increase within the first min after addition of 10 mM ATP and plateau at 60% above control levels (mean value) after 4 to 6 min. Neither the magnitude nor the time course of the potentiations corresponds to changes in resting potential or membrane resistance. Other nucleotides are equally or less effective at the same concentration: ATP=ADP greater than UTP greater than AMP=GTP (=no added nucleotide control) The duration of the individual ACh responses does not increase during continuous exposure to the active nucleotides for up to 15 min except when the muscle is pretreated with eserine. Mild enzymatic predigestion of the muscle with collagenase and then protease, increasing the availability of the postjunctional membrane to bath-applied drugs, decreases the variability and increases the magnitude of the potentiation to a given dose of ATP. The dose-response curve for ATP is then more than half-maximal at 1 mM and the ranking of the other nucleotides relative to ATP is the same as without predigestion. There is an optimum Ca++ concentration for the potentiation between zero and 2 mM: potentiation is enhanced in Ca++ -free medium, partially blocked in twice-normal Ca++ medium, and totally blocked in Ca++ -free medium 10 min after a 5 min exposure to 2.5 mM EGTA. The similar Ca++ dependence of ACh receptor activation in the absence of added nucleotide suggests that ATP directly facilitates receptor activation by ACh. This facilitory action could be one of the physiological roles for the ATP released from stimulated phrenic nerve.

Do some nerve cells release more than one transmitter?

The concept that each nerve cell makes and releases only one nerve transmitter (widely known as Dale's Principle) has been re-examined. Experiments suggesting that some nerve cells store and release more than one transmitter have been reviewed. Developmental and evolutionary factors are considered. Conceptual and experimental difficulties in investigating this problem are discussed. It is suggested that the term 'transmitter' should be applied to any substance that is synthesised and stored in nerve cells, is released during nerve activity and whose interaction with specific receptors on the postsynaptic membrane leads to changes in postsynaptic activity. Expressed in this way, it seems likely that while many nerves do have only one transmitter, others in some species, during development or during hormone-dependent cycles, employ multiple transmitters.

Catecholamine release from bovine adrenal medulla in response to maintained depolarization

Prolonged exposure of venous-perfused bovine adrenal glands to high K in the presence of external Ca produces a transient increase in catecholamine output that reaches a maximum after about 1 min and then declines with a half-time of about 1-2 min. 2. The time course of the transient secretory response to high K does not depend appreciably on the total catecholamine output which indicates that depletion of releasable catecholamine is unlikely to be responsible for the transient nature of the response. 3. Application of 3-6 mM-Ba stimulates secretion from a gland after many minutes exposure to high K, when catecholamine output has declined close to resting levels. This provides further evidence that depletion does not play a major role in the transient response and shows that maintained depolarization does not inhibit the secretory mechanism. 4. Exposure to high K solutions in which Ca has been replaced isomotically by Mg does not evoke any catecholamine output. Subsequent application of Ca always elicits some secretion although the size of this response to added Ca declines rapidly during exposure to Ca-free, high K solutions. The failure of the secretory response in these experiments is more rapid, and earlier in onset than the declining phase of the normal secretory response evoked in the presence of calcium. 5. Pre-treatment with Ca-free solutions of intermediate K content reduces the response to subsequent simultaneous application of high K and Ca. There is a roughly sigmoidal relation between the reduction in response and the logarithm of the K concentration used for pre-treatment. 6. Thin slices of bovine adrenal medulla show qualitatively similar responses on exposure to high K. Examination of the flourescent signal from slices dyed with the potential-sensitive dye DiS-C(3)-(5) suggests that maintained exposure to high K produces a stable depolarization. 7. The most likely explanation for these results is that K-depolarization first activates and subsequently inactivates a potential-sensitive Ca permeability channel. This inactivation is time and possibly potential dependent. 8. The effect of high K on calcium movements in medullary slices was examined. Exposure to 72 mM-K increases (45)Ca uptake, the increase being greatest during the first 10 min. The efflux of Ca is also increased on exposure to high K in the presence of Ca. The net Ca uptake in 72 mM-K is smaller than the tracer uptake of Ca. These findings indicate that K depolarization stimulates a Ca-Ca exchange process. They are also consistent with, but do not offer strong positive support for, the idea that K-depolarization first activates and subsequently inactivates Ca entry. 9. It is suggested that Ca inactivation might play a role in the modulation of neurosecretion and neurotransmitter release by changes in membrane potential.

Ultrastructure of the adrenal medulla of normal and insulin-treated hamsters

Fine structural characteristics of the chromaffin cells both in normal and insulin-administered hamster adrenal gland were studied. Exocytosis occurs in 5 per cent of nonstimulated cells especially on the apical cell surfaces. At the same time the occurrence of a great number of closely attached secretory granules was conspicuous on the lateral plasma membrane in the untreated hamster adrenal medulla. Following insulin treatment (10 IU/100 g/body weight), characteristic was the development of large intercellular vacuoles between the lateral plasma membrane, in which electron-dense secretory material was frequently present. On the basis of this observation it is suggested that in the case of insulin-induced hormone secretion, exocytosis preferentially occurs on the lateral plasma membrane, and may play an important role in the discharge of secretory materials from the cells.

The adrenal medulla: a model for studies of hormonal and neuronal storage and release mechanisms

We have observed that phospholipids and protein of the catecholamine (CA) storage granules, i.e. the chromaffin granules, interact in an in vitro system to form liposomal particles, which in many respects resemble the intact matrix of the bovine chromaffin granule. A model has been suggested which consists of an aqueous phase, containing the acidic chromogranins and intact dopamine-beta-hydroxylase (DBH) ATP and CA, embedded in a liquid crystal of the matrix phospholipids. Ca2+ may play a significant role in the sequence of functional transitions of such an organelle, not only in the accumulation of Ca2+, as during the secretory phase of the intact cell, but also as the agent inducing a separation of the outer membrane bilayer from the matrix phase to be released, as during exocytosis. Furthermore, a liposome model of the matrix may also tentatively explain the occurrence of intact matrices in the interstitium of stimulated glands. Recent evidence for the identity between chromogranin A and DBH subunits have been summarized and a possible role for the inactive subunits in the ionic binding of ATP and CA in the aqueous phase of the matrix is discussed. A role of Ca2+ and cyclic AMP in the mediation of beta-adrenergic modulation is postulated on the basis of our recent work on acetylcholine-induced release of CA from perfused and stimulated bovine adrenals. We conclude that such a beta-adrenergic modulation is secondary to that of the cholinergic response. Hence, this activation is able to enhance the output induced by mild cholinergic stimulation although insufficient to evoke a CA release by itself.

Release of catecholamines and dopamine beta-hydroxylase from the perfused adrenal gland of the cat

1. Secretion of catecholamines (CA) and dopamine beta-hydroxylase (DBH) activity from the perfused cat adrenal gland was studied following splanchnic nerve stimulation or infusion of acetylcholine (ACh). 2. Splanchnic nerve stimulation (30 Hz) or perfusion with a low concentration of ACh (10-minus5 M) caused a marked release of CA in the venous effluent, but release of DBH activity was minimal while a higher concentration of ACh (10-minus 4 M) enhanced the release of CA and DBH. 3. The ratio of DBH/CA released in the perfusate by splanchnic nerve stimulation or ACh infusion was only a small fraction of the ratio in the soluble lysate of purified chromaffin vesicles. 4. Following reserpine treatment, adrenal CA levels fell to 25% of the control value in 24 hr, remained depressed on days 2, 3, 4 and 5 at 5% of the control and recovered to 60% of the control value on the 6th day. DBH activity was unchanged from the control value at 24 hr after treatment, then rose as high as 5 times the control on the 5th day and was still twice the control value on the 6th day. 5. CA secretion in response to ACh (10-minus 4 M) perfusion was reduced to 30% of the control value on the first day after reserpine treatment, while DBH secretion was unchanged. On the 2nd day, CA secretion was depressed further to 5% of the control and remained at this low level up to 5 days after treatment while DBH secretion was twice the control value at 48 hr and then on days 3, 4 and 5 rose up to 5 times the control value. On the 6th day, secretion of CA recovered to 30% of the control while DBH secretion was now twice the control. 6. Isopycnic sucrose density (discontinuous) gradient centrifugation of vesicles from adrenal glands of control cats, and of cats given reserpine 1 or 2 days perviously, indicated that new vesicles or vesicles depleted of CA by reserpine had a lower equilibrium density than the original population of vesicles. 7. These results suggest that the release of CA is quantal in nature, but the release of DBH is not necessarily coupled with it. Release of DBH by ACh from reserpinized glands suggests that the vesicles which were once involved in secretion may be re-used for synthesis and storage of CA.

Relationship of glucose metabolism to adrenergic transmission in rat mesenteric arteries. Effects of glucose deprivation, glucose metabolites, and changes in ionic composition on adrenergic mechanisms

The vasoconstrictor response of perfused rat mesenteric arteries to stimulation of sympathetic nerve fibers is markedly potentiated by glucose deprivation; this potentiation is abolished or reduced when glucose or other sugars are added. The augmentation of the vasoconstrictor response to nerve stimulation produced by glucose deprivation presumably results from an increased release of the adrenergic transmitter, since (1) the response to injected norepinephrine is much less affected by glucose deprivation and (2) the increase in the vasoconstrictor response to either adrenergic stimulus produced by inhibition of neuronal reuptake by cocaine is unaltered by glucose deprivation. The inhibitory effect of glucose may involve its metabolite(s). Pyruvic and lactic acids inhibit the vasoconstrictor response to nerve stimulation previously augmented by glucose deprivation but do not affect adrenergic transmission in the presence of glucose. Also, the inhibitory effect of glucose on the potentiated response is abolished by the simultaneous infusion of 2-deoxy- D -glucose or iodoacetic acid, inhibitors of glucose metabolism. The inhibitory effect of glucose and its metabolite(s) on adrenergic transmission may also involve changes in the ionic permeability of the nerve terminal. In the absence of glucose, raising the Na + and K + concentrations affects the vasoconstrictor response differently, namely, Na + potentiates and K + attenuates the response. These effects are abolished by addition of glucose. In contrast, the effects of increased concentrations of either Ca 2+ (facilitation) or Mg 2+ (inhibition) on neurotransmission are unaffected by removal or restoration of glucose. We conclude that glucose deprivation does not affect adrenergic transmission by acting directly through Ca 2+ . Rather, glucose deprivation decreases pyruvate and possibly other products of glucose metabolism, and these decreases, in turn, alter the concentrations of Na + and K + within the neuron. These latter changes then enhance the availability of Ca 2+ and, thereby, increase the release of the adrenergic transmitter.